CA1318473C - Polyolefin-containing extrudable compositions and methods for their formation into elastomeric products - Google Patents

Abstract

ABSTRACT OF THE DISCLOSURE

The disclosure is generally directed to an extrudable elastomeric composition formed by blending from at least 10 percent, by weight, of an A-B-A' elastomeric block copolymer where "A" and "A"' are each at thermoplastic endblock which includes a styrenic moiety and where "B" is an elastomeric poly(ethylene-butylene) midblock with up that least about 90 percent, by weight, of at least one polyolefin which, when blended with the A-B-A' block copolymer and subjected to an effective combination of elevated temperature and elevated pressure conditions, is adapted to be extruded in blended form, with the A-B-A' block copolymer. Fibrous nonwoven elastomeric webs may be formed from the extrudable composi-tion and processes for forming the fibrous nonwoven elas-tomeric webs are also disclosed. In the disclosed method, the extrudable composition is subjected to a combination of elevated temperature and elevated pressure conditions to effect extrusion of the extrudable composition from a meltblowing die as molten threads. The heated, pressurized stream of an attenuating gas is applied to the molten threads to attenuate the molten threads to microfibers, and the microfibers are collected as a cohesion fibrous nonwoven elastomeric web.

Description

- 2 - ~3~ 3 The present invention is generally directed to certain extrudable elastomeric compositions and methods for forming the extrudable elastomeric compositions into elastomeric products such as, for example, fibrous nonwoven elastomeric webs~

Meltblowing techniques for forming very small diameter fibers, sometimes referred to as microfibers or meltblown fibers, from thermoplastic resins are well-known in the art.
For example, t~e production of fibers by meltblowing is described in an article entitled "Superfine Thermoplastic Fibers", appearing in Industrial and Engineering Chemistry, Vol. 48, No. 8, pp. 1342-1346. This ar-ticle describes work done at the Naval Research Laboratories in Washington, D.C.
Another publication dealing with meltblowing is Naval Research Laboratory Report 111437, dated April 15, 1954.
Generally, meltblowing techniques include heating a ther-moplastic fiber-forming resin to a molten state and extruding the molten resin from a die arrangement having a plurality of linearly arranged small diameter capillaries as molten threads. The molten threads exit the die into a high velocity stream of gas, usually air, which is maintained at an elevated temperature, and which serves to attenuate the threads of molten resin to ~orm fibers having a diameter which is less than the diameter of the capillaries of the die arrangement.

U.S. Patent 3,849,241 to Buntin discloses the manufac-ture of nonwoven mats of meltblowing and describes, at column 4, line 57, et. seq., the formation of meltblown fibers having diameters of from about 0.5 to about 400 microns by 3D extruding degraded fiber-forming molten pl/mc ' ; _ 3 _ .~3~73 thermoplastic polymer resin5 as molten threads into an attenuating gas stream. Also disclosed is the fact that the diameter of the attenuated fibexs will decrease as the gas flow of the attenuating gas through the gas outlets, 5 which are located on either side of the die tip extrusion capillaries, increases. It is also stated that, at low to moderate attenuating gas velocities, the extnlded molten threads, even after attenuation by the gas into fibers, remain essentially continuous with little or no fiber 10 breakage and that fibers produced in such an arrangement have diameters of, preferably, from about 8 to S0 microns.
Prior to extrusion the fiber-forming thermoplastic polymer resins are subjected to controlled thermal and oxidative degradation at temperatures ranging from about 550 degrees 15 Fahrenheit to abou~ 900 degrees Fahrenheit, that is from about 288 degrees Centigrade to abou~ 482 degrees Centigrade, preferably from about 600 degrees Fahrenheit to 750 degrees Fahrenheit, that is from about 316 degrees Centigrade to about 399 degrees Centigrad~, to effect a 20 requisite degradation of the resin which reduces the viscosity of the fiber-forming resin. Typical fiber-forming thermoplastic resins are listed at column 4, line 35 et. seq. and commercially useful resin throughput rates are stated to be from about 0.07 to 5 grams per 25 minute per die extrusion capillary, preferably at least l gram per minute per die extrusion capillary.
While degradation of some thermoplastic resins prior to their extrusion may be necessary in order to reduce their viscosity sufficiently to allow their extrusion and 30 attenuation ~y the high velocity stream of attenuating gas, there is a limit to the degree of degradation prior to extrusion which can be imposed on a given resin without adversely affecting the properties of the extsuded product.
For example, excessive degradation of polymeric elastomeric 35 polystyrene/poly (ethylene- butylene)/polystyrene block copolymer resins, may result in the formation of a - 4 - ~ 3 ~ ~ 7 3 non-elastic resin. It is believed that the deyraded material is non-elastic because the block copolymer resin degrades to form a di-block copolymer resin. Other danyers may be associated with high degradation temperatures. For example, Technical Bulletins SC: 38-82 and SC: 39-85 o~ The Shell Chemical Company o~ Houston, Texas, in describing polystyrene/poly (ethylene-butylene)/polystyrene elastomeric block copolymer resins sold by it under the trade-mark KRATON state that, with respect to the KRATON G
10 1650 and KRATON G 1652, both of which are block copolymer resins, compounding temperatures of the resin should not be allowed to exceed 525 degrees Fahrenheit, that is 274 degrees Centigrade and that a fire watch should be maintained if the temperature o~ the resins reaches 475 degrees Fahrenheit, that is 246 degrees Centigrade. With respect to the KRATON GX 1657 block copolymer resin, Shell Technical Bulletin SC: 607-84 gives a warning not to allow the temperature of the block copolymer resin to exceed 450 degrees Fahrenheit, that is 232 degrees Centigrade, and to maintain a fire watch should that temperature be reached.
Shell Material Safety Data Sheet designated as MSDS number 2,136 states, with respect to KRA~'ON G-1657 thermoplastic rubber, that the procPssing temperature of the material should not be allowed to exceed 550 degrees Fahrenheit and that a fire watch should be maintained if that temperature is reached. A Shell Matexial Safety Data Sheet designated as MSDS 2,031-1 states, with respec~ to KRATON G-1652 thermoplastic rubber, that the processing temperature of the material should not excaed 550 degrees Fahrenheit and that a ~ire watch should be maintained if that temperature is reached. Shell Chemical Company Technical Bulletins SC:
68-85 "KRATON Thermoplastic Rubber'~ and SC: 72-85 'ISolution Behavior Of KRATON Thermoplastic Rubbers" give detailed information concerning various thermoplastic block copolymer resins which may be obtained from Shell under the trade-mark KRATON. The KRATON thermoplastic resins ~ ej ~ S3 ~ 3 are stated by Shell to be A-B-A block copolymers in which the "A" endblocks are polystyrene and the "B" midblock is, in KRATON G resins, poly (ethylene-butylene) or, in KRATON D resins, either polyisoprene or polybutadiene.
Shell Chemical Company Technical Bulletin SC: 198-83, at page l9, gives example~ of commercially available resins and plastlcizers useable with KRATON rubber resins. The Bulletin distinguishes between rubber phase, B midblock, associating materials and polystyrene phase, A endblock, 10 associating materials. Among the rubber phase associating materials is a group of resins which are identified as "Polymerized Mixed Olefin" and a plasticizer identified as "Wingtrack 10" having a chemical base of "mixed olefin".
For quite some time those in the art have been 15 attempting to form elastomeric resins into fibrous nonwoven elastomeric webs. In fact, the prior art reveals that experimentation with KRATON G 1650 and K~TON G 1652 brand materials has occurred. For example, U.S. patent 4,323,534 to des Marais discloses that it was concluded by those in 20 the art that the KRATON G rubber resins are too viscous to be extruded alone without substantial melt fracture of the product. However, des Marais does disclose a process which utilizes blended KRATON G 1650 and KRATON G 1652 resins in the formation of fibrous nonwoven webs and films. In order 25 to overcome the stated viscosity problem the KRATON G 1650 block or KRATON G 1652 copolymer resin was blended with about 20 percent to 50 percent, by weight, of a fatty chemical such as stearic acid prior to extrusion and meltblowingO An extrusion temperature range of 400 to 460 30 degrees Fahrenheit is disclosed at column 8, line 64 et.
seq. and this temperature range is generally within that recommended by the above-mentioned Shell Chemical Company technical bulletins. Unfortunately, the physical properties of ~he product obtained by this process, for 35 example, a nonwoven mat of meltblown fibers~ were apparently unsatisfactory because, after formation of the ~ - 6 ~
, ~

nonwoven web, substantiallY all the fatty chemical is leached out of the nonwOven web of extruded microfibers by soaking the web in alcohols ha~ing a good ability to solubilize the fatty chemical utll1zed. In one embodiment, 5 discussed at column 3, line5 8 and 9, the thermoplastic rubber resin is an A-B-A' block copolymer wherein B is poly ~ethylene-butylene) and A and A' are selected from the group including polystyrene and poly (alpha-methylstyrene).
U.S. Patent 4,305,990 to Kelly disclo~es that A-B-A
10 bloc~ compolymers having a polybutadiene or polyisoprene midblock and polystyrene endblocks may be extruded as films when blended with an amount of amorphous polypropylene sufficient to enhance the processability of the blend. It is stated in the abstract that the films retain their 15 elastomeric properties and are significantly more processable ,owing to the presence of the amorphous polypropylene.
Another patent apparently dealing with subject matter stemming from or at least related to the subject matter 20 disclosed in des Marais is U.S. patent 4,355,425 to Jones which discloses an undergarment that may be made of a fiber formed by meltblowing a blend of a X~ATON G rubber with stearic acid. The examples are apparently limited to KRATON G-1652 blocX copolymers. An extrudable composition, 25 which is stated to be particularly useful at column 4, line 24 et~ seq., is a blend of KRATON G 1652 rubber and 20 percent by weight stearic acid as well as minor amounts of other materials. An extrusion temperature of 390 degrees Fahrenheit for the blend of KRATON G 1652 rubber and 30 stearic acid, which ls disclosed at column 5, lines 14 and 19, is within the temperature range set forth in the above-mentioned Shell Chemical Company technical bulletins.
It is further stated that fibers for making the materlal can be meltblown as taught in U.S. patent 3,825,380, to 35 Harding which is said to disclose a die configuration suited ~or meltblowing the fibers. It should also be no~ed - 7 ~ 3 that the procedures of Jones, as was the case with the procedure of des M~rais, indicate the desirability o~
leaching out the fatty chemical after formation o~ a fibrous nonwoven web or film from the blend of fatty chemical and KRATON G. See, for example, column 5, lines 60 et seq.
The present invention overcomes the above-discussed difficulties which have been encountered by those in the art when attempting to form elastomeric A-B-A' block copolymer materials into elastomeric products by providing extrudable elastomeric compositions which, after extrusion, solidify to form elastomeric products such as, for example, fibrous nonwoven elastomeric webs. For example, leaching of materials out of the fibrous nonwoven web ox other elastomeric products formed from the extrudable compositions of the present invention is avoided.
According to one aspect of the present invention there is provided a fibrous nonwoven elastomeric web which includes microfibres, the micro~ibre~ being from at least about 10 percent, by weight, of an A-B-A' blocX
copolymer, where "A" and "A"' are each a thermoplastic polymer endblock which includes a styrenic moiety~ such as a poly (vinyl arene), and where "B" is an elastomeric poly (ethylene-butylene) midblock, and from greater than 0 percent, by weight, to about go percent, by weight, of a polyolefin which, when blended with the A-B-A' block copolymer and subjected to appropriate ~levated pressure and elevated temperature conditions, is extrudable, in blend~d form, - 7a 13 .l ~ ~ 7 3 with the A-B-A' block copolymer.
According to another aspect of the present invention, there is provided a process for forming a cohesive fibrous nonwoven elastomeric web from an extrudable composition compris.ing at least about 10~, by weight of A-B-A' block copolymer where "A"
and "A' 1l are each a thermoplastic endblock which includes a styrenic moiety and where "B" is an elastorneric polymer ~ethylene-butylene) midblock and from greater than 0 percent by weight, to about 90 percen-t, by weight, of a polyolefin which, when blended with A-B-A' block copolymer and subjected to an effective combination of elevated temperature and elevated pressure conditions, is adapted to be extruded, in blended form, with the A~B-A' block copolymer. The process includes the steps of subjecting the extrudable composition to a combination of elevated temperature and elevated pressure conditions to effect extrusion of the extrudable composit.ion from a meltblowing die as molten threads~ applying a heated pressurized steam of an attenuated gas to the molten threads to attenuate the molten threads to microfibres, and collecting the microfibres as a cohesive fibrous nonwoven elastomeric web.
The A-B-A' block copolymer serves to impart elastomeric properties to products formed from the extrudable composition and the presence of the polyolefin in the blend serves to reduce the viscosity oE the composition as compared to the viscosity of the neat, i.e. pure, A-B-A' block copolymer and thus enhances the extrudability of the composition.

b.

\- 8 -~3~7~3 Preferably, the A and A' thermoplastic styrenic moiety containing endblocks of the block copolymer are selected from the group including polystyrene and polystyrene homoloqs such as, for example, poly ~alpha-methylstyrene). r"~, 5 In some e~bodiments the A and A' thermoplastic styrenic ;r moiety containing endblocks are identical. Preferably, the polyolefin is selected from the group including a~ least one polymer selected from the group including polyethylene, polypropylene, polybutene, ethylene copolymers, propylene 10 copolymers, butene copolymers or blends of two or more of these materials.
The blend usually includes from at least about 20 percent, by weight, to about 95 percent, by weight, of the block copolymer and from at least about 5 percent, by 15 weight, to about 80 percent, by weight, of the polyolefin.
For example, the blend may include from abouk 30 percent, by weight, to about 90 percent, by weight, of the block copolymer and from about 10 percent, by weight, to about 70 percent, by weight, of the polyolefin. Preferably, the 20 blend includes from about 50 pexcent, by weight, to about 90 percent, by weight, of the block copolymer and from about 10 percent, by weight, to about 50 percent, by weight, of the polyolefin. For example, the blend may include from about 50 percent, by weight, to about 70 25 percent, by weight, of the block copolymer and from about 30 percent, by weight, to about 50 percent, by weight, of the polyolefin. One blend includes about 60 percent, by weight, of the block copolymer and about 40 per~ent, by weight, of the polyolefin.
The extrudable composition is extrud~d or otherwise formed such as, for example, by molding, for example, injection moldins, at an appropriate, that is effective, co~bination of elevated pressure and elevated temperature conditions. These conditlons will vary depending on the 35 polyolefin utilized. For example, the extrudable composition should be extruded or otherwise formed at a ~ 3.~

temperature of at least about 125 degrees Cen-tigracle if polyethylene is utilized as the polyolefin in the blend or at least about 175 degrees Centigrade if polypropylene is utilized in the blend, for example, at a temperature of from at least about 290 de~rees Centigrade to about 345 degrees Centigrade, more speciFically, at a temperature of Erom at least about 300 degrees Centigrade to about 335 degrees Centigrade, into elas-tomeric products such as, for example, elas-tomeric fiber.s, which may be collected as a Eibrous nonwoven elas-tomeric web.
The blends may be extrudable within the above-defined temperature ranges at elevated pressures within -the die tip, (for example, within the extrusion capillaries of a die tip having thirty (30) extrusion capillaries per lineal inch of die tip with each of the capillaries having a diameter of 0.0145 inches and a length of 0.113 inches,) of no more than about 300 pounds per square inch, gage, for e~ample, from pressures of from about ~0 pounds per square inch, gage to about 250 pounds per square inch, gage. More specifically, the blends are extrudable within the above-defined temperature ranges at pressures of from about 50 pounds per square inch, gage to about 250 pounds per square inch, gage, for e~ample, from about 125 pounds per square inch;, gage to about ~25 pounds per square inch, gage. ~i~her elevated pressures can be utilized with other die designs having a lower number of capillaries per inch of die, but, generally speaking, lower production rates result.
Importantly, it has been found that the extrudable composi-tions oE the present invention, when treated in accordance with the method of the present invention, are extrudahle at satisfac-tory throughput rates beca~lse the presence of the polyolefin inthe extrudable composition reduces the viscosity of -the ex-trudable composition, as compared to the viscosity of the neat, i.e. pure, block copolymer, to satisfactory levels. This reduced viscosity , , 1 o -- 1 3 ~ $ l~ 7 3 :
proportionally reduces the die tip pressure if all other parameters remain the same. For example, the viscosity of the extrudable compositions will generally be less than about S00 poise when extruded at the above-defined elevated 5 temperature and elevated pressure ranges. Preferably, the viscosity of the extrudable composition is less than about 300 poise when extruded at the above~defined elevated temperature and elevated pressure ranges. For example, the viscosity of the extrudable composition may be from at 10 least about 100 poise to about 200 poise when extruded at the above-identified elevated temperature and elevated pressure conditions.
Because the polyolefin reduces the viscosity of the blend, as compared to the viscosity of the block copolymer, 15 the extrudable composition is extrudable within the above-identified elevated temperature and elevated pressure ranges, through a die tip having, for example, thirty capillaries per inch of die tip with the capillaries having a diameter of about 0.0145 inches and a length of about 20 0.113 inche at a rate of from at least about 0.02 grams per capillary per minute to about 1.7 or more grams per capillary per minute. For example, the extrudable composition may be extruded through the above-identified die tip having capillaries with a diameter of about 0.0145 25 inches and a length of about 0.113 inches at the rate of from at least about 0.1 grams per capillary per minute to about 1.25 grams per capillary per minute. Preferably, the extrudable composition i5 extrudable through the above-identified die tip having capillaries witn a diameter 30 of about 0.0145 inches and a length of about 0.113 inches at the rate of from at least about 0.3 grams per capillary per minute to about 1.1 grams per capillary per minute.
The extrudable composition may be formed into a variety of products such as, for example, fibrous nonwoven 3i elastomeric webs preferably having microfibers with an average diameter of not greater than about 100 microns, and ~ 3 1 ~

preferably having an average basis weight of not more than about 300 grams per square meter, for example, an average basis weight of from about 5 grams p~r square meter to about 100 grams or more per squaxe meter. More 5 specifically, an average basis weight of from about 10 grams per square meter to about 75 grams per square meter.
For example, a fibrous nonwoven elastomeric web may be formed by extruding the extrudable composition at an appropriate, i.e. effective~ combination of elevated 10 temperature and elevated pressure conditions. Preferably, the extrudable composition is extruded at a temperature of from at least about 125 degrees Centigrade ~ if the polyolefin is a polyethylene or at least about 175 degrees Centigrade if the polyolefin is polypropylene, for example, 15 from about 290 degrees Centigrade to about 345 degrees Centigrade, more specifically from about 300 degrees Centigrade to about 335 degrees Centigrade. Preferably, the extrudable composition is extruded within the above-identified temperature ranges at pressures, within 20 the die tip, (for example, within the extrusion capillaries of a die tip having thirty (30) extrusion capillaries per lineal inch of die tip with each of the capillaries having a diameter of 0.0145 inches and a length of 0.113 inches) of no more than about 300 pounds per square inch, gage, for 25 example, from about 20 pounds per square inch, gage to about 250 pounds per square inch, gage. More specifically, the extrudable composition is extruded at a pressure within the capillaries of the above-identified die tip of from about 50 pounds per square inch, gage to about 250 pounds 30 per square inch, gage, for example, from about 125 pounds per square inch, gage to about 225 pounds per square inch, gage.
In the formation of elastomeric nonwoven webs, the extrudable composition is extruded, at the above-defined 35 elevated tempera~ure and elevated pressure conditions at a rate of from at least about 0.02 gram per capillary per - 12 ~

minute to about 1.7 or more grams per capillary per minute, for example, from at least about 0.1 gram per capillary per minute to about 1.25 grams per capillary per minute, more specifically, from at least about 0.3 gram per capillary 5 per minute to about 1.1 grams per capillary per minute, through a die having a plurali~y of small diame~er extrusion capillaries as molten threads into a gas stream which attenuates the molten threads to provide a gas-borne stream of microfibers which are then formed into the 10 fibrous nonwoven elastomeric web upon their deposition on a collecting arrangement. The attenuating gas stream is -applied to the molten thxeads at a temperature of from at least about 100 degrees Centigrade to about 400 degrees Centigrade, for example, from about 200 degrees Centigrade 15 to about 350 degrees Centigrade and at a pressure of from at least about 0.5 pound per square inch, gage to about 20 pounds per square inch, gage, for example, from at least about 1 pound per square inch, gage to about 10 pounds per square inch, gage. The thread attenuating gas stream may 20 be an inert, non-oxidizing, gas s~ream such as, for example, a stream of nitrogen gas. Xn some embodiments the velocity and temperature of the thread-attenuating gas stream is adjusted so that the fibers are collected as substantially continuous fibers having diameters of from 25 about ten (10) microns to about sixty (60) microns, for example, from at least about ten (10) microns to about forty (40) microns. In accordance with the present invention, the fibrous nonwoven elastomeric webs so formed will include elastomeric fibers composed of from at least 30 about lO percen~, by weight, of the block copolymer and greater than 0 percent, by weight, and up to about 90 percent, by weight, of the polyolefin. The ibers are usually composed of from at least about 20 percent, by weight, to about 95 percent, by weight, of the block 35 copolymer and .rom at least about 5 percent, by weight, to about 80 percent, by weight of the polyolefin. For - 13 ~ 3 example, the fibers may be composed of from at least about 30 percentl by weight, to about 90 percent, by weight, of the block copolymer and from at least about 10 percent, by weight, to about 70 percent, by weight, of the polyolefin.
5 Preferably, the fibers are composed of from about 50 percent, by weight, to about 90 percent, by weight, of the block copolymer and from at least about 10 percent, by weight, to about 50 percent, by weight, of the polyolefin.
For example, the fibers may be composed of from at least 10 about 50 percent, by weight, to about 70 percent, by weight, of the block copolymer and from at least about 30 percent, by weight; to about 50 percent, by weight, of the polyolefin. Exemplary fibrous nonwoven elastomeric webs have been formed from fibers composed of about 15 60 percent, by weight, of the block copolymer and about 40 percent, by weight, of the polyolefin.
Still other aspects of the present invention will become apparent to those skilled in the art upon review of the following detailed disclosure.

DEFINITIONS
___ The terms "elastic" and "elastomeric" are used interchangeably herein to mean any material which, upon 25 application of a biasing force, is stretchable to a stretched, biased length which is at least about 125 percent, that is about one and one quarter, of its relaxed, unbiased length, and which, will recover at least 40 percent of its elongation upon release of the 30 stretching, elongating force. A hypothetical example which would satisfy this definition of an elastomeric material would be a one (1) inch sample of a material which is elongatable to at least 1.25 i~ches and which, upon being elongated to 1.25 inches and released, will recover to a 35 length of not more than 1.15 inches. Many elastic materials may be stretched by much more than 25 percent of ` - 14 ~ ~31~7~

their relaxed length and many of these will recover to substantially their original relaxed length upon release of the stretching, elongating force and this later class of materials is generally preferred for purposes of the 5 present invention.
As used herein the term "recover" refers to a contraction of a stretched material upon termination of a biasing force following stretching of the material by application of the biasing force. For example, if a 10 material having a relaxed, unbiased length of one (1) inch was elongated 50 percent by stretching to a length of one and one half ~1.5) inches the material would have been elongated 50 percent and would have a stretched length that is 150 percent of its relaxed length. If this exemplary 15 stretched material contracted, that is recovered to a length of one and one tenth (1.1) inches after release of the biasing and stretching force, the material would have recovered 80 percent (0.4 inch) of its elongation.
The term "microfibers" is used herein to refer to 20 small diameter flbers having an average diameter not greater than about 100 microns, preferably having a diameter of from about 0.5 microns to about 50 microns, more preferably having an average diameter of from about 4 microns to about 40 microns and which may be made by 25 extruding a molten thermoplastic material through a plurality of small di~meter, usually circular, die capillaries as molten threads and attenuating the molten threads by application of a high velocity gas, usually air, stream to reduce their diameter to the range stated above.
As used herein the term "nonwoven web" means a web of material which has been formed without use of weaving processes which produce a structure of individual fibers or threads which are interwoven in an identifiable repeating manner. Nonwoven webs have been, in the past, formed by a 35 variety of processes such as, for example, meltblowing .:

- 1S- ~31~7~

processeq, spunbonding processes, film aperturing processes and staple fiber carding processes.
As used herein the term "styrenic moiety" refers to the monomeric unit represented by the formula:
~ c~,-c~ ~

CH CH
C~ l C~
CH

As used herein the term "poly (ethylene butylene)"
refers to a polymer segment represented by the formula:

ooly(et~yl~ne-butylene) ~[8~H~ ~n where x, y and n are positive integers.
As used herein the term "polystyrene" refers to a polymer segment represented by the formula:
~ CHz--CH ~
C
CH CH polystyrene 2 5 ^i1 C~
C~
where n is a positive integer.
~nless specifically set forth and defined or otherwise limited, the terms "polymer" or "polymer resin" as used 30 herein generally include, but are not limited to, homopolymers, copolymers, such as, for example, block, graft, random and alternating copolymers, terpolymers, etc.
and blends and modifications thereof. Furthermore, unless otherwise specifically limited, the terms ~polymer" or 35 "polymer resin" shall include all possible geometrical configurations of the material. These configurations . .

, , - 16 - ~ 3 ~ 3 include, but are not limited to, isotactic, syndiotactic and random symmetries.
As used herein the term "viscosity" refers to a value which has been calculated by utllizing the well-known Hagen-Poiseuille equation:

viscosity = ~pi)(delta P)~R )D

where pi = 3.14....
delta P = the pressure drop through an extrusion capillary.
R = the radius of the extrusion capillary.
Q = the volume rate of extrusion ~through-put~ through the extrusion capillary. `
L = the length of the extrusion capillary~
D - the density of the molten polymer, assumed in all cases herein to be 0.8 grams per cubic centimeter.

As used herein an "inert" attenuating gas is a non-oxidizing gas which does not degrade the material being meltblown.
As used herein the term "consisting essentially of"
does not exclude the presence of additional materials which 30 do not significantly affect the elastic properties and characteristics of a given compositic,n. Exemplary materials of this sort would include, without limitation, pigments, antioxidants, stabilizers, surfactants, waxes, 10w promoters, solid solvents, particulates and materials 35 added to enhance processability of the composition.

. .

- 17 - 1 3'~ 7 3 ~RIEF D ~

Figure l ls a perspective schematic view illustrating one embodiment of a process for for~ing a nonwoven elastomeric web in accordance with the present in~ention.
Figure 2 is a perspective view of the meltblowing die illustrated in Figure 1 which illustrates the linear arrangement of the capillaries of the die.
Figure 3 is a schematic cross-sectional view of the die illustrated in Figure 1, along line 2-2 of Figure 2, illustrating the die in a recessed die tip arrangement.
Figure 4 is a schematic cross~sectional view of the die illustrated in Figure l, along line 2-2 of Figure 2, illustrating the die in a positive die tip stick-out arrangement.
Figure 5 is a schematic cross-sectional view with portions broken away for purposes of illustration of an arrangement which may be utilized to incorporate discrete particles, fibers or other materials into the extruded threads of molten material prior to their formation into a nonwoven web.

DESCRIPTION OF THE PREFERRED EMBODIMENTS
.

The methods and extrudable compositions of the present inventlon have broad application in the formation of elastomeric materials such as elastomeric fibers which may be formed into elastomeric webs or other products, by suitable methods such as, for example, extrusion or molding processes. A particularly preferred method, however, is to meltblow fibers to form a fibrous nonwoven elastomeric web.
Meltblowing processes generally involve extruding a thermoplastic polymer resin through a plurality of small diameter capillaries of a meltblowing die as molten threads into a heated gas stream which is flowing generally in the same d~rection as that of the extruded threads so that the extruded threads are attenuated, i.e., drawn or extended, to reduce their diameter to fiber or preferably mlcrofiber size. The thus ormed microfibers are then borne away from the viclnity of the die by the gas stream. The gas stream 5 is directed onto a foraminous member, such as a screen belt or a screen drum which is moving over a vacuum box, so that the gas-borne fibers impinge upon and are collected on the surface of the foraminous member and form a cohesive fibrous nonwoven web. Meltblowing die arrangements usually 10 extend across the foraminous collecting member in a direction which is substantially transverse to the direction of movement of the collecting surface. The die arrangements include a plurality of small diameter capillaries arranged linearly along the transverse extent 15 of the die with the transverse extent of the die being approximately as long as the desired width of the fibrous nonwoven web which is to be produced. That is, the transverse dimension o the die is the dimension which is defined by the linear array of die capillaries. Typically, 20 the diameter of the capillaries will be on the order of from about 0.01 inches to about 0.02 inches, for example, from about 0.0145 to about 0.018 inches. From about 5 to about 50 such capillaries will be provided per linear inch of die face. Typically, the length of the capillaries will 25 be from about 0.05 inches to about 0.20 inches, for example, about 0.113 inches to about 0.14 inches long. A
meltblowing die can extend for from about 30 inches to about 60 or more inches in length in the transverse direction. As a result of the above-discussed linear 30 capillary configuration meltblowing dies, in the vicinity of the capillaries, are usually held together only by a thin and relatively fragile portion OI metal which remains between the adjacent capillaries. Consequently, controlling the viscosity of the molten thermoplastic 35 polymer resin as it is e~truded through the capillaries is important because the die will rupture or otherwise break ~ ~ - 19 -~ 3 ~ 3 7 if subjected to extreme pressure. It is ~herefore generally preferred, at least for many such dies, that the extrusion pressure of the molten thermoplastic polymer in the die tip capillaries not exceed more than about 300 5 pounds per square inch, gage (psi,g), more specifically not more than about 200 psi,g.
As has been stated by those in the art in the above-discussed patents to des Marais and Jones, the viscosity of KRATON G brand A-B-A' block copolymers is so 10 great that extrusion of these materials, in pure or neat form, within the typical extrusion temperature and pressure ranges stated therein is, for all practical purposes, very difficult, if not impossible, without mel~ fracture of the composition. In attempting to overcome tne dificulties of 15 extruding neat ~R~TON G brand materials des Marais and Jones appear to have discovered ~hat the the use of a blend of a fatty chemical with elastomeric A-B~A' rubber resins, of the type sold under the trademark KRATON G by the Shell Chemical Company, facilitated extrusion of the KRATON G
20 materials. However, they also state that, in order to achieve desirable properties in the film or the web of meltblown fibers obtained from ~his blend, it was necessary to leach out the fatty chemical from the extruded product.
In contrast to such teachings, it has now been found 25 that a blend o~ from greater than 0 percent, by weight, to about 90 percent, by weight, of one or more polyolefins with from at least abou~ 10 percent, by weight, of certain A-B-A' elastomeric resins can be extruded and meltblown under appropriate, i.e. effective, elevated temperature and 30 elevated pressure conditions to provide satisfactory elastomeric materials such as elastomeric films and elastomeric fibrous nonwoven webs~ Preferably the material is extruded through the die capillaries at a temperature of at least about 125 degrees Centigrade if polyethylene is 35 utilized as the polyolefin in the blend or at least about 175 degrees Centigrade if a polypropylene is utilized as ~ 20 131~3 the polyolefin in the blend, for example at a temperature of from at least about 290 degrees Centigrade to abo~t 345 degree~ Centigrade, more speciflcally from a temperature of from at least about 300 degrees Centigrade s to about 335 degrees Centigrade.
The A-B-A' elastomeric materials which may be utilized generally include A-~-A' block copolymer~ where A and A' are each a the~moplastic polymer endblock which contains a styrenic moiety such as r for example, a poly ~vinyl arene) 10 where, in some embQdiments, A may be the same thermoplastic polymer endblock as A', and where B is an elastomeric poly (ethylene bu~ylene) polymer midblockD Preferably, the A
and A' endblocks are selected from the group of materials including polystyrene or polystyrene homologs such as, for 15 example, poly (alpha-methylstyrene). Materials of this general type, that is KRATON G 1650 and KRATON G 1652, are disclosed in U.S. patents 4,323,534 to des Marais and 4,355,425 to ~one~ and in the aforementioned Shell brochures which also discloses KRATON GX 1657.
20 Commercially available elastomeric A-B-A' block copolymers having a saturated or essentially saturated poly (ethylene-butylene~ midblock ~B~ represented by the formula:

5~ ~C2H~ ~n where x, y and n are positive integers and polystyrene endblocks "A" and "A"l ~ach represented by the formula:

/ \~
CH CH
C H C H
CH
po~yslyrene ~ 21 - 13L~73 where n is a positive integer which may be of the same or a different lnteger for the A and A' endblocks, are sometimes 5 referred to as S EB-S block copolymers and are available under the trade designation KRATON G, for example, KRATON G i~
1650, KRATON G 1652 and KRATON GX 1657, from the Shell Chemical Company~
A summary of the typical properties, as published by the Shell Chemical Company, of the above~identified KRATON
G resins at 74 degrees Fahrenheit i5 presented below in Table I.

'` ' - 22 - ~3~7~

TABLE I
. .

~RATON G
.

Tensile Strength, 2 2 2 p5il 5,000 4,500 3,400 10 300% Modulus, psil 800 700 350 Elongation, % 500 500 750 -Set at Break, ~

Hardness, Shore A 75 . 75 65 Specific Gravity 0~91 0.91 0.90 20 Brookfield Viscosity, (Toluene Solution) cps at 77 F1,500 550 1,200 Melt Viscosity, 25 MeIt IndeX, Condition G, gms/10 min. - - -Plastici~er Oil 30 Content, %w Sytrene/Rubber Ratio 28/72 29/71 14/86 35 Physical FormCrumb Crumb Pellet ~L 3 1$ ~ r~ 3 -- 23 ~

1 ASTM method D4l2-tensile test jaw separation speecl 10 in./min.
Typical properties determined on film cast from a toluene solution.
Neat polymer concentration, 20%w.
4 The ratio of the sum of -the molecular weights of the endblocks (A-~A') to the molecular weight oE the B
midblock. For example, with respect to KR~TON G-1650, the sum of -the molecular weights of the two endblocks (A+A') i5 28 percent of the molecular weight of the A-B-A' block copolymer.

Generally, the block resin must be one which is free of polymer segments which chain scission or which crosslink at the temperatures utilized by the process of the present invention because such materials will either tend to plug up the small diameter capillaries through which the molten extrudable composition must be extruded or will overly degrade and form unsatisfactory product. Surprisingly, it has been found that, even at high polyolefin contents, fibrous nonwoven webs having elastomeric properties can be formed without the necessity of a post Eormation treatment such as, for example, leaching to remove the additives Erom the finished product.

The polyolefin which is utilized in blending the extrudable composition must be one which, when blended with the A-~rA~ block copolymer and subjected to an appropriate combination of elevated pressure and elevated temperature conditions, as defined herein, is extrudable, in blended form, with the A-B~A' block copolymer. In particular, preferred polyolefin materials include polyethylene, polypropylene and polybutene, including ethylene copolymers, propylene copolymers and butene copolymers. Blends of two or more of the polyolefins may be utilized. A particularly preferred polyethylene may be obtained from U.S.I. Chemical Company under the trade-mark pl/mc ~ ~~ 2~ ~ .
~ 3 ~

Petrothene Na601. (Also xeferred to herein as PE Na601 ) A particularly preferred polypropylene may be obtained from The Himont Corporation under the trade designation PC-973.
Information obtained from ~.S.t. Chemical Company s 5 states that the Na601 is a low molecul.ar weight, low density polytheylene for application in the areas of hot melt adhesives and coatings. U.S.I. has also stated that the Na601 has the following nominal values: (1) a ~rookfield Viscosity, cP at 150 degrees Centigrade of 8500 10 and at 190 degrees Centigrade of 3300 when measured in accordance with ASTM D 3236; (2) a density of 0.903 grams per cubic centimeter when measured in accordance with ASTM
D 1505; (3) an equivalent Melt index of 2000 grams per ten minutes when measured in accordance with ASTM D 1238; (4) a 15 ring and ball softening point of 102 degrees Centigrade when measured in accordance with ASTM E 28; (5) a tensile of 850 pounds per square inch when measured in accordance with ASTM D 638, (6) an elongation of 90 percen~ when measured in accordance with ASTM D 638; (7) a modulus of 20 Rigidity, TF (45,000) of -34 degrees Centigrade and (8) a penetration Hardness, (tenths of mm) at 77 degrees Fahrenheit of 3.6.
~he Na601 is believed to have a number average molecular weight (Mn) of about 4,600; a weight average 25 molecular weight (~w) of about 22,400 and a Z average molecular weight tMZ) of about 83,300. ~he polydispersity (Mw/Mn) o~ the Na601 is about 4.87.

~n is calculated by the formula:

Mn = Sum~(n)tMW)]
Sum(n) ~ 3 1 ~ 4 7 3 Mw is calculated by the formula:

Mw = Sum~(n)(MW) ]
Sum[(n)(MW)]

Mz is calculated by the ~ormula:

Mz = Swn~(n)(MW) ]
Sum~(n~(MW) ]
where:
MW = The various molecular weights of the individual molecules in a sample, and n = The number of molecules in the given sample which have a given molecular weight of MW.

Typical characteristics of the Himont PC-973 polypropylene as stated by Himont are a density of abou~
0.g00 grams per cubic centimeter measured in accordance 20 with ASTM D 792. A meltflow rate obtained in accordance with ASTM D 1238, Condition L, of about 3S grams per ten (10) minutesO Other characteristics of the PC-973 are a tensile of about 4,300 pounds per square inch (psi) measured in accordance with ASl~M D638 a flex modulus of 25 about 182,000 psi measused in accordancs with ASTM D 790,B
and a Rockwell hardness, R scale, of about 93 measured in accordance with ASTM D 785A. The PC-973 is believed to have a number average molecular wei~ht (Mn) of about 40,100, a weight average molecular weight (Mw) of about 30 172,000 and a Z average weight (Mz) of about 674,000. The polydispersity of the PC-973 (Mw/Mn) is about 4.29.
The blend usually includes from at least abou~
20 percent, by weight, to about 95 percent, by weight, of the block copolymer and from at least about 5 percent, by 35 weight, to about 80 percent, by weight, of the polyolefin.
For example, the blend may include from at least about - ~6 ~ ~3~ 73 30 percent, by weight, to about 90 percent, by weight, of the block copolymer and from at least about 10 percent, by weight, to about 70 percent, b~ weight, of the polyolefin.
Preferably, the blend includes from at least about 5 50 percent, by weight, to about 90 percent, by weight, of the block copolymer and from at least about 10 percent, by weight, to about 50 percent, by weight, of the polyolefin.
For example, the blend may include from about S0 percent, by weight, to about 70 percent, by weight, of the block 10 copolymer and from about 30 percent, by weight, to about 50 percent, by weight, of the polyolefin. One preferred blend includes about 60 percent, by weight, of the block copolymer and about 40 percent, by weight, of the polyolefin.
The preferred elevated temperatures of extrusion and the presence of the specified polyolefin in the blend reduces the viscosity of the blend, as compared to the viscosity of the pure, i.e. neat, A-~-A' block copolymer, and thus forms an extrudable composition which can be 20 utilized in the meltblowing of fibers and microfibers.
However, both the block copolymer resins and the polyolefins must be able to sustain the extrusion temperatures utilized by the method of the present inven~ion without undergoing excessive chain scission or 25 excessive thermal or oxidative degradation. In this regard it is believed that the degree of oxidative degradatlon sustained by the extrudable composition ~ay be reduced by using an inert gas as ~he attenuating gas stream in the meltblowing step. It is also believed that the degree of 30 oxidative degredation can be reduced by blanketing the raw pellets of the resins utilized with an inert gas prior to their processing by an extruder. The fact that the amount o~ oxidative degradation which the block copolymer undergoes during extrusion may be reduced by using an inert 35 gas as the attenuating gas stream is generally implied by thermogravimetric analyses of KRATON GX 1657 block ~ ~ 27 - 13.L~73 copol~mer resin which were carried out in air and nitrogen In thes~ analyses samples of the KRATON GX 1657 block copolymer resin, when heated in air, showed a weight loss beginning at about 307 degrees Centigrade whereas a 5 comparison sample heated in nitrogen showed only a weisht loss starting at about 375 degrees Centigrade. It is believed that these results indicate that the e~fects of oxidative degradation on the sample heated in air could be avoided or diminished by use of an inert or, at least, a 10 non-oxidizing attenuating gas stream to thus limit de~radation of the extrudable composition during attenuation at high attenuating gas temperatures and/or by use of an inert or, at least, non-oxidizing gas to blanket the raw pellets.
Referring now to the drawings where like reference numerals represent like structure or like process steps and, in particular, to Figure 1 which schema~ically illustrates apparatus for foxming an elastomeric nonwoven web in accordance with the present invention, it can be 20 seen that a blend (not shown) of (a) from at least about 10 percent, by weight, of an A-B--A' block copolymer where and A' are both thermoplastic polymer endblocks containing a styrenic moiety such as, for example, a poly (vinyl arene) and where B is an elastomeric poly 25 (ethylene-butylene) midblock, with (b) from greater than 0 percent, by weight, to about 90 percent, by weight, of a polyolefin which, when blended with the A-B-A' block copolymer and subjected to an effective combination of elevated temperature and elevated pressure conditions, is 30 extrudable in blended form with the A-B-A' block copolymer, is supplied in, for example, pellet form to a hopper 10 of an extruder 12. The components of the blend may be supplied in pellet or other form. The components (i.e., pellets) may be blanketed with an inert or, at least, 35 non-oxidative gas while in the hopper 10. This is believed to reduce the effects of oxidative degradation on the blend ~ - 28 - ~3~73 1~`

by both reducing the contact of the blend with normal atmosphere while in the hopper 10 and also increasing the likelihood that any gas that is drawn into and through the extxuder 12 will be the inert gas as opposed to 5 oxygen-containing normal atmosphere. The blend usually inoludes from at least about 20 percent, by weight, to about 95 percent, by weight, of the block copolymer and from about 5 percent, by weight, to about 80 percent, by weight, of the polyolefin. For example, the blend may 10 include from about 30 percent, by weight, to about 90 percent, by weight, of the block copolymer and from about 10 percent, by weight, to about 70 percent, by weight, of the polyolefin. Preferably, the blend includes from about 50 percent, by weight, to about 90 percent, by 15 weight, of the block copolymer and from about 10 percent, by weight, to about 50 percent, by weight, of the polyolefin. For example, the blend may include from abou~
50 percent, by weightl to about 70 percent, by weight, of the block copolymer and from about 30 percent, by weight, 20 to about 50 percent, by weight, o the polyolefin. Several of the hereinafter discussed examples include about 60 percent, by weight, of the bloc~ copolymer and about 40 percent, by weight, of the polyolefin.
The temperature of the blend is elevated within the 25 extruder 12 by a conventional heating arrangement (not shown) to melt the blend and pressure is applied to the blend by the pressure-applying action of a ~urning screw (not shown~, loca~ed within the extuder, to form the blend into an extrudable composition. Preferably t~e blend is 30 heated to a temperature of at least about 125 degrees Centigrade if polyethylene is utllized as the polyolefin in the blend or at least about 175 degrees Centigrade if polypropylene is utilized as the polyolefin in the hlend, ,or example, at a temperature o~ from at least about 290 35 degrees Centigrade to about 345 degrees Centigrade, more specifically, at a temperature of from at least about 300 .

` - 29 - ~3~ 3 degrees Centigrade to about 335 degrees Centigrade. The extrudable composition is then forwarded by the pressure applying action of the turning screw to a meltblowing die 14. The elevated temperature of the extrudable composition 5 is maintained in the meltblowing die 14 by a conventional heating arrangement (not shown). The die 14 generally extends a distance which is about equal to the width 16 of the nonwoven we~ 18 which is to be formed by the process.
The combination of elevated temperature a~d elevated 10 pressure conditions which effect extrusion of the composition will vary over wide ranges. For example, at higher elevated temperatures, lower elevated pressures will result in satisfactory extrusion rates and, at higher elevated pressures of extrusion, lower eleva~ed 15 temperatures will effect satisfactory extrusion rates.
Figures 3 a~nd 4 best illustrate that the meltblowing die 14 includes an extrusion slot 20 which receives the extrudable composition from the extruder 12. The extrudable composition then passes through the extrusion slot 20 and 20 through a plurality of small diameter capillaries 22, which exit the die 14 in a linear arrangement, best illustrated in Figure 2, extending across the tip 24 of the die 14, to emerge from the capillaries 22 as molten ~hreads 26.
Preferably, the extrudable composition is extrudable, 25 within the above defined temperature ranges, through the small diameter capillaries, that is within the die tip, at pressures, as applied by the turning screw of the extruder 12, of no more ~han about 300 pounds per square inch, gage, for example, from pressures of from about 20 pounds per 30 square inch, gage to about 250 pounds per square inch, gage. More specifically, at pressures of from about 50 pounds per square inch~ gage to about 250 pounds per s~u~re inch, gage for example, from about 125 pounds per square inch, gage to about 225 pounds per square inch, gage.
35 Pressures in excess of these values may rupture or break some dies 14. Generally speaking, the extrudable _ 30 _ ~3~

composition is extruded through the capill~ries 22 o~ the die 14 at a rate of ~rom at least about 0.00044 pound per capillary per minute to about 0.00374 or more pounds per capillary per minute, for example, from at least about 0.00022 pound per capillary per minute to about 0.00275 pounds per cap~llary per minute. More speci~ically, from at least about 0.00066 pound per capillary per minute to abouk 0.00242 pounds per capillary per minute~
The die 14 also includes attenuating gas inlets 28 and 30 which are provided with heated, pressurized attenuating gas (not shown) by attenuating gas sources 32 a~d 34. The heated, pressurized attenuating gas enters the die 14 at the inlets 28 and 30 and follows the path generally designated by the arrows 36 and 38 in figures 3 and 4 through two chambers 40 and 42 and on through to narrow passageways or gaps 44 and 46 so as to contract the extruded threads 26 as they exit the capillaries 22 of the die 14. The chambers 40 and 42 are designed so that the heated attenuating gas exits the chambers 40 and 42 and passes through the gas passages 44 and 46 to form a stream (not shown) of attenuating gas which exits the die 14. The temperature and pressure of the heated stream of attenuating gas can vary widely. For example, the heated attenuating gas can be applied at a temperature of from 25 about 100 degrees Centigrade to about 400 degrees Centigrade, more specifically from about 200 degrees Centigxade to about 350 degrees Centigrade. The heated attenuating gas can be applied at a pressure of from about 0.5 pounds per square inch, gage to about 20 pounds per s~uare inch, gage, more specifically from about 1 pound per square inch, gage to about 10 pounds per square inch, gage.
The position of air plates 48 and 50 which, in conjunction with a die-~ip portion 52 of the die 14 define the chambers 40 and 42 and the passageways 44 and 46, may be adjusted relative to the die-tip portion 52 to widen or narrow the width 54 of the attenuating gas passageways 44 .. - 31 - 13.~73 and 46 so that the volume of attenuating gas passing through the air passageways 44 and 46 during a given time period can be varied without varying the velocity of the attenuating gas. Furthermore, the air plates 48 and 50 can 5 also be adjusted upwardly and downwardly to effect a "recessed" die-tip configuration or a positive die-tip "stick-out" configuration as discussed in detail below.
~enerally speak.ing, it is preferred to utilize attenuating gas pressures of less than about 20 pounds per square inch, 10 gage in conjunction with air passageway widths, which are usually the same, of no greater than about 0.20 inches.
Lower attenuating gas velocities and wider air passageway gaps are generally preferred if substantially continuous microfibers are to be produced.
The two streams of attenuating gas converge to form a stream of gas which entrains and attenuates the molten threads 26, as they exit the linearly arranged capillaries 22, into fibe~s or, depending upon the degree of attenuation, microfibers (also designated 26) of a small 20 diameter, to a diameter less than the diameter of the capillaries 22. Generally speaking, the attenuating gas may be applied to the molten threads 26 at a temperature of from at least about 100 degrees Centigrade to about 400 degrees Centigrade, for exarnple, from at least about 200 25 degrees Centigrade to about 350 degrees Centigrade and at pressures of from at least about 0.5 pounds per s~uare inch, gage to about 20 pounds per square inch, gage or more, for exarnple, from about 1 pound per square inch, gage to about 10 pounds per square inch, gage. The gas-borne 30 microfibers 26 are blown, by the action of the attenuating gas, onto a collecting arrangement which, in the ernbodiment illustrated in Figure 1, is a foraminous endless belt 56 conventionally driven by rollers 57.
Figure 1 illustrates the formation of substantially 35 con~inuous microfibers 26 on the surface of the belt 56.
However, the microfibers 26 can be formed in a ~ - 32 ~
~31~73 substantially discontinUOUS fa5hion as illustrated in Figure 5 by varying the velocity of the attenuating gas, the temperature of the attenuating gas and the volume of attenuating gas passing through the aix passageways in a 5 given time period. Other foraminous arrangements such as an endl~ss belt arrangement may be utillzed. ~he belt 56 may also include one or more vacuum boxes ~not shown) located below the surface of the foraminous belt 56 and between the rollers 57. The microfibers 26 are collected 10 as a fibrous nonwoven elastomeric web 18 on the surface of the drum 56 which is rotatiny as indicated by the arrow 58 in Fi~ure 1. The vacuum boxes assist in retention of the microfibers 26 on the surface of the belt 56. Typically the tip 24 of the die tip portion 52 of the meltblowing die 15 14 is fron~ about 4 inches to about 24 inches from the surface of the foraminous endless belt 56 upon which the microfibers 26 are collected. The thu~-collected, entangled microfibers 26 form a coherent, i.e. cohesive, fibrous nonwoven elastomeric web 18 which may be removed from the 20 foraminous endless belt 56 by a pair of pinch rollers 60 and 62 which may be designed to press the entangled fibers of the web 18 together to improve the integrity of the web 18. Thereafter, the web 18 may be transported by a conventional arransement to a wind-up roll (not shown) for 25 storage. Alternatively, the web 18 may be removed directly from the belt 56 by the wind-up roller. The web 18 may be pattern-embossed as by ultrasonic embossing equipment (not shown) or other embossing equipment, such as, for example, the pres~ure nip formed between a heated calender and anvil 30 roll (no~ shown).
Referring now to Figure 3, it can be seen that the mel~blowing die 14 includes a base portion 64 and a die tip portion 52 which generally centrally extends from the base portion 64. The centrally located die tip portion 52 is 3; inwardly tapered to a "knife-edge" point which forms the tip 24 of the die tip portion 52 of the die 14. In order - 33 ~ c~

to increase the pressures of extxusion which the die 1~ can withstand during operatiOn it ls preferred for the base portion 64 and die-tip portion 52 to be formed fro~ a single block of metal which 5urrounds the extrusion slot 20 5 and the extrusion capillaries 22. The die 14 also includes two air plates 48 and 50, discussed above, which are secured, by conventional means, to the base portion 64 of the die 14. The air plate 48, in conjunction with the die tip portion 52 of the die 14, deines the chamber 40 and 10 the attenuating gas alr passaye or gap 44. The air plate 50, in conjunction with the die tip portion 52, defines the chamber 42 and the air passageway or gap 46. Aix plate 48 and air plate 50 terminate, respectively, in air plate lip 66 and air plate lip 68. In the configuration illus~rated 15 in Figure 3, the knife-edge point which forms the tip 24 o~
the die tip portion 52 of the die 14 is recessed inwardly of ~he plane formed by the air plate lips 66 and 68. In this configuration the perpendicular distance between the plane formed by the lips 66 and 68 and the tip 24 of the 20 die tip portion 52 is sometimes referred to by those in the art as a "negative stick-outl' or a "recesse~" die tip configuration. If the tip of the die tip portion 52 of the die 14 were configured to protrude outwardly beyond the plane formed by the lips 66 and 68 of the air plates 48 and 25 50, as i5 illustrated in Figure 4, such a configuration is referred to, by those in the art, as a "positive stick-out"
of the tip 24 of the die tip 52. In the examples discussed below negative numbers are utilized with die tip 52 "stick-out" distances when tip 24 of the dié tip 52 is 30 recessed with regard to the plane formed by the lips 66 and 68 of the air plates ~8 and 50. If the tip 24 o~ the die tip 52 is configured so that it protrudes beyond the plane formed by the lips 66 and 68 of the air plates 48 and 50, the die tip "stick-out~' distances are given in positive 35 numbers. Both positive and negative die tip "stick-out"
values were obtained in the examples by measuring the ~31~fl~7~

perpendicular distance between the plane Eormed by the lips 66 and 68 of the air plates 48 and 50 and the knife-edge poin~ which forms the tip 2~ of -the die tip portion 52 of the die 14. In other words, the closest distance between the point 24 and the plane formed by the lips 66 and 68, as defined above. It should also be noted that, unless other-wise stated, the term "air gap or width~" as used herein, is the perpendicular, i.e. minimum, width 54 of either of the air passages 44 and 46. These widths are normally arranged to be identical.

In some situations it may be desirable to incorporate discrete particles of one or more solid materials into the extruded threads 26 prior to their collection as a nonwoven elastorneric web 18O Fo-r example, it may be desirable to incorporate one or more fibers such as cotton ~ibers, wood pulp fibers, polyester fibers or other types of fibers or particulates into the threads 26. ~lends of two or more of such fibers or particulates can be incorporated. This may be accomplished by utilization of a coforming apparatus such as is illustrated schematically in Figure 5 at 70. Several types of coforming arrangements are well-known to those in the art and one such arrangernent is represented by the apparatus disclosed in U.S. Patent 4,100,432 to Anderson et al. Figure 5 illustrates that, after formation of the microfibers 26, a stream of secondary fibers or particulates 72 i~ generally uniformly injected into the stream of microfibers 26. Distribution of the secondary fibers 72 generally uniformly throughout the stream of microfibers 26 is preferably accomplished by merging a secondary gas stream (not shown) containing the secondary fibers 72 with the stream of microfibers 26. Apparatus for accomplishing this merger includes a conventional picker roll 74 which has a plurality of teeth 76 that are adapted to separate a matt or batt of secondary fibers 78 into the individual secondary fibers 72. The , ~ pl/mc ,, 1 3 '~ 7 ~
matt or batt of secondary fibers 78 which is fed to the picker roll 74 may be a sheet of pulp fibers (if a two component mixture of elastomeric fibers and pulp fibers is desired), a matt or batt of staple fibers ~if a two 5 component mixture of elastomeric fibers and staple fibers i5 desired) or both a sheet of pulp fibers and a matt or batt of staple fibers (if a three component mixture of elastomeric fibers, pulp fibers and staple fi~ers desired).
Other combinations of one or more staple fiber~ and/or one 10 or more pulp fibers may be utilized. The sheets or matts of secondary fibers 72 are fed to the picker roll 74 by a roller arrangement 80. After the teeth 76 of the pic~er roll 74 have separated the sheet or matt 78 into separate secondary fibers 72 the individual secondary fibers 72 are lS conveyed toward the meltblown stream 26 o~ elastomeric . fibers through a forming duct or nozzle 82. A housing 84 encloses the picker roll 74 and provides a passayeway or gap 86 between the housing 84 and the surace of the picker roll 74. A gas (no~ shown), preferably air, is supplied to 20 the passageway or gap 86 between the su~face of the picker roll 74 and the housing 84 by way o.f a gas duct 88. The gas duct 88 preferably enters the passaseway or gap 86 generally at the junction 90 of the forming duct or nozzl~
82 and the passageway 860 The gas is supplied in 25 sufficient quantity to serve as a medium for conveying the secondary fibers 72 from the teeth 76 of the picker roll 74 and through the forming duct or nozzle 82 at a velocity approaching that of the teeth 76 of the picker roll 74.
As an aid in maintaining satisfactory secondary fiber 30 72 velocity, the forming duct or noz~le 82 is desirably positioned so that its longitudinal axis is substantially parallel to a plane which is tangent to the surface of the pic~er roll 74 at the junction 90 of the forming duct or nozzle 82 with the gap 86. As a result of this arrangement 35 the velocity of the secondary fibers 72 is not substantially changed by contact of the secondary fibers 72 - 36 - ~3~ 7~

with the walls of the ~Eorming duct or nozzle 82. IE the secondary fibers 72 remain in contact Wittl the teeth 76 oE
the picker roll 74 after they have been separated Erom the matt or shee-t 78, the axis of -the forming duct or nozzle 82 may be adjusted appropriately to be aligned in the direction of secondary fiber 72 velocity at the point where the secondary Eibers 72 disengage from the teeth 76 of the picker roll 74O If desired, the disengagement of the secondary fibers 72 with the teeth 76 of the picker roll 74 may be assisted by application of a pressurized gas, i.e., air, through duct 92.
The height 94 of the forming duct or nozzle 82 with respect to the die tip 24 may be adjusted to vary the properties of the coformed product~ ~ariation of the distance 96 of the tip 98 of the nozzle 82 from the die tip 24 will also achieve variations in the final coformed product. The height 94 and distance 96 values will also vary with the material being added to the microfibers 26. The width of the forming duct or nozzle 82 along the picker roll 7~ and the length 10Q that the Eorming duct or nozzle 82 extends from the picker roll 74 are also important in obtaining optimum distribution of the secondary fibers 72 throughout the stream of meltblown microfibers 26. Preferab-ly, the length 100 of the forming duct or nozzle 82 should be as short as equipment design will allow. The length 100 is usually limited to a minimum length which is generally e~ual to the radius of the picker roll 74. Preferably, the width of the forming duct or nozzle 82 should not exceed the width of the sheets or matts 78 that are being fed to the picker roll 74.
Figure 5 further illustrates that the gas stream carrying ~he secondary fibers 72 is preEerably arranged to move in a direction which is generally perpendicular to the direction of movement of the stream of the microfibers 26 at the point of merger oE the two gas streams. Other angles of merger of the two streams may be utilized. The velocity of pl/mc :

~ j ~3~7~

the gas stream carrying the secondary fibers 72 is usually adjusted so that it is less than the velocity of the gas stream which attenuateS the microfibers 26. T~is allows the streams, upon merger and integration thereof, to flow 5 in su~stantially the same direction as that of the stream of microfibers 26. Indeed, the merger of the two streams is preferably accomplished in a manner which is somewhat like an aspirating effect whereby the stream of a secondary fiber 72 is drawn into the stream of microfibers 26. It is 10 also preferred that the velocity difference between the two gas streams be such that the secondary fibers 72 are integrated into the microfibers 26 in a tur~ulent manner so that the secondary fibers 72 become thoroughly mixed with the microf,ibers 26. In general t increasing the velocity 15 differential between the two streams produces a more homogeneous integration of the secondary fibers 72 into the microibers Z6 and decreases i~ the velocity differential between the two streams are generally expected to produce concentrated areas of secondary fibers 12 within the 20 microfibers 26. Generally, for increased production rates it is preferred for the gas stream which entrains and attenua~es the stream of microfibers 26 to have an initial high velocity, for example from about 200 feet to about 1,000 feet per second and for the stream of gas which 25 carries the secondary fibers 72 to have an initial low . velocity, for example from about 50 ~o a~out 200 feet per second. Of course, after the stream of gas that entrains and attenuates the extruded threads 26 into elastomeric microfibers exits the air passageways 44 and 46 of ~he 30 meltblowing die 14 it immediately expands and decreases in velocity.
Upon merger and integration of the stream of secondary fibers 72 into the s~xeam of microfibers 26 to generally uniformly distribute the secondary fibers 72 throughou~ the 35 stream of mel~blown fibers 26, as discussed above, a composite s~ream 102 of mlcrofibers 26 and secondary fibers ~ 3 ~

~2 is formed. The mlcrofibers 26 may stlll be semi-molten and tacky at the time of incorporation of the secondary fibers 72 into the microfibers 26, and, in such a situation, the secondary fibers 72 are not only S mechanically entangled within the microfibers 26 but also usually become thermally bonded to the microfibess 26.
~owever, if the microfibers 26 are not semi-molten and tacky at the time of incorporation of the secondary fibers 72 therein, the secondary fibers 72 will only be 10 mechanically entangled within the microfibers 26.
In order to convert the composite stream 102 of microfibers 26 and secondary fibers 72 into a fibrous nonwoven elastomeric web 18 of elastomeric microfibers 26 havin~ the secondary fibers 72 generally uniformly 15 distribu~ed ~hroughout and, if desired, bonded to the microfibers 26 .of the web 18, a collec~ing device iq located in the path of the composite stream 102. The collecting device may be a rotating belt 56 as described with respect to Figure 1 upon which the composite stream 20 102 impacts to form the web 18. Preferably, the external suxface of the rotating drum is porous and the rotating drum includes a conventional vacuum arrangement ~not shown) which assists in retaining the composite stream 102 on the external surface of ~he drum. Other collecting devices are 25 well-Xnown to those of skill in the art and may be utilized in place of the rotating belt 56, for example, a porous rotating drum arrangement could be utilized. Thereafter, the web 18 may be removed from the belt 56 by a pair of nip rollers (now shown) in an arrangement equivalent to that 30 illustrated in Figure 1. Therea~ter, the web 18 may be transported by a conventional arrangement to a wind-up roller (not shown) for storage. Alternatively, the web 18 may be removed directly from the belt 56 by the wind-up roller.
Depending on the characteristics desired of the coformed fibrous nonwoven elastomeric web the web can _ 39 - ~3~

include (l) from at least about 20 percent, by weight, of a fibrous nonwo~en elastiC web of microfibers as defined herein, for example microfibers comprislng from (a) at le~st about 10 percent, by weight, or an A-B-A' block 5 copolymer where "A" and "A"' are each a thermoplastic endbloc~ which includes a styrenic moiety and where nB" is an elastomeric poly (ethylene-butylene) midbloc~ with (b) from greater than 0 percent, by weight, up to about 90 percent, by weight/ of a polyole~in which, when blended lO with the A-B-A' block copolymer and sub~ected to an effec~ive combination of elevated temperature and elevated pressure conditions, can be extruded in blended form, with the A-B-A' bloc~ copolymer and (2) from greater than 0 percent, by weight, to about 80 percent, by weight, of at 15 least one secondary fiber generally uniformly distributed . throughout the fibrous nonwoven elastomeric web. The fibrous nonwoven elastomeric web can be formed from a block copolymer/polyolefin blend within any of the above-mentioned blend ranges. Additionally, the secondary 20 fibers can form from about 30 percent, by weight, to about 70 percent, by weight, of the coformed web, even more specifically the secondary fibers can form from about 50 percent, by weight, to about 70 percent, by weight, of the coformed web.
The picker roll 74 may be replaced by a conventional ~ par~iculate injec~ion system to make a fihrous nonwoven elastomeric web- 18 ~ont~ining various particulates. A
combination of both coformed fibers and particulates could be added to the microfibers 26 prior to their formation 30 into a fibrous nonwoven elastomeric web 18.
Throughou~ the various examples discussed herein, a variety of meltblowing die extruders and configurations were utilized in a variety of combinations to illustrate the broad applicability of the present invention. Specific 35 details of the mel~blowing dies and extruders are, for ease of reference, tabulated in Tables II and III below: .

-- ~ u 3 ~ 3 TABLE II

~ 3 - ~

-5 Die ~o. Extent of Capillaries Capillary Capillary Capillary per inch of diameter length Array (inches) die extent (inches) (inches) 10 $1 20 15 0.018 0.1~
#2 20 30 O.û145 0.113 #3 1-5/8 20 0.0145 0.113 ~4 1-5/8 9 0.01~5 0.113 TABLE III

EXTRUDERS

Length/
Extrudex Diameter.Temperature Diameter Designation _ Type _ (inches) _ nes Ratio _ A Johnson1.5 3 24:1 B ~rabender 0,.7S 3 2~:1 .

~eltblowing dies 3 ana 4 are high pressure dies.
Reference will be made to certain combinations of 30 meltblowing dies and extruders with, for example, a designa~ion o "A2" meaning that extruder ~A" was utilized in conjunction with meltblowing die "2".

~3~ ~7~
EXAMPLE I

A fibrous nonwoven elastic web was formed by utilizing the techniques illustrated in Figure 4 to combine cotton fibers with meltblown microfibers formed from a blend of 60 percent, by weight, of a A-B-A' block copolymer having polystyrene "A'l and "A"' end blocks and a poly (ethylene-butylene) "B" midblock (obtained from the Shell Chemical Company under the trade-mark KRATON
GX 1657) and 40 percent, by weight, of a polyethylene (obtained from U.S.I. Chemical Company under the trade designation PE Na601).
~ eltblowing of the fibrous nonwoven elastic web was accomplished by extruding the blend of materials from a one and one-hal~ inch Johnson extruder and through a meltblowing die having 15 extrusion capillaries per lineal inch of die tip. rrhat is, meltblowing system Al, as defined herein, was utilized. The capillaries each had a diameter of about 0.018 inches and a length of about 0.14 inches. The blend was extruded through the capillaries at a rate of about 1.36 grams per capillary per minute at a temperature of about 314.4 degrees Centigrade. The extrusion pressure exerted upon the blend in the die tip was measured as 200 pounds per square inch, gage, giving a viscosity for the blend of about 153 poise in the die capillaries. The die tip configuration was adjusted so that it was recessed about 0.090 (-0.090 die tip stick-out) inches from the plan~
of the external surface of the lips of the air plates which form the attenuating air passageways on either side o~ the rsw of capillaries. The air plates were adjusted so that the two attenuating air passages, one on each side of the extrusion capillaries, formed passageways having air gaps, i.e. widths, of about 0.067 inches. It should ~e noted that the air passageway or gap configuration utilized in this Example 1 differed slightly from the configuration illustrated in Figure 3 in - ~ 3 ~ 3 ~hat the angle formed by the dle tip portion 52, that is the angle which the capillaries 22 bisect, is 90 degrees and, therefore, the air gaps 44 and 46 are wider near the tip 24 of the die tip 52 than at the areas 40 and 42. Ir.
5 other words, the air gaps 44 and 46, of this die configuratlon, widen as opposed to narrowing as the attenuating air pro~resses as indicated by the arrows 36 and 38. Forming air for meltblowing the blend was supplied to the air passageways at a tempexature of ahout 341.1 10 degrees Centigrade and at a pressure of about 4 pounds per square inch, gage. The meltblown fibers thus formed were blown toward a forming screen which was approximately 11 inches from the die tip.
Utilizîng the conventional coforming technlques as 15 illustrated in Figure 2, bleach~d cotton fibers obtained from Cotton Incorporated of N.Y. State and having a length o about one and one~half inches were incorporated into the stream of meltblown microfibers prior to their deposition upon the forming screen. The cotton fibers were first 20 formed, by a Rando Webber mat fo~ning apparatus, into a mat having an approximate basis weight of about 75 grams per square meter. The mat was fed to the picXer roll by a picker roll feed roll which was positioned about 0.005 inches from the surface of the picker roll. The picke~
25 roll was rotating at a rate of about 3,000 revolutions per minute and fiber transporting air was supplied to the picker roll at a pr~ssure of about 4 pounds per square inch, gage. Actual measurement of the position o~ the~
nozzle of the coform apparatus with respect to the stream 30 of meltblown microfibers was not made. However, it is believed that the nozzle o~ ~he coforming apparatus was positioned about 2 inches below the die tip of the meltblowing die and about 2 inches back from the die tip of the meltblowing die. This procedure provided a fibrous 35 nonwoven elastomeric web having a width (cross-machine direction) of about twenty (20) inches which was composed ., .
,i _ 43 - ~ 3~ 3 of a blend of about 70 percent, by weight, of the elastomeric meltblown microfibers and about 30 percent, by weight, of the cotton fibexs.
A three inch wide by five inch long sample of the fibrous nonwoven web formed by the procedure of Example I was tested for elongation in both the machine direction and the cross-machine direction. The machine direction tests were conducted on a sample which was cut from the 20 inch wide web and measured three inches in the cross-machine direction and five inches in the machine direction. The cross-machine direction tests were conducted on a sample which was cut from the 20 inch wide web and measured three inches in the machine direction and five inches in the cross machine direction. Each sample was placed lengthwise in a testing apparatus sold under the trade-mark Instron Model 1122 having an initial jaw setting of about three (3) inches and which stretched the samples at a rate of about ten (10) inches per minute to a length which was 150 percent, that is one and one-half times, the length of the unstretched sample, i.e. 50 percent elongation.
The load, in grams, necessary to achieve the 150 percent length was measured and the sample wa~ maintained at the 150 percent length (50 percent elongation) for one (1) minute~ At the end of the one minute period, the load, in grams, necessary to maintain tha length of the sample at the 150 length (50 percent elongation) was measured and the length of the sample was increased from 150 percent to 200 percent of thP original unstretched length of the sample, that is twice the original length of the unstretched sample, iOe. 100 percent elongation.
The load, in grams, necessary to achieve the 200 percent length was mPasured and the sample was then maintained at the 200 percent length for a one minute period. At the end o~ the second one minute period the load t in grams, necessary to maintain the length of the sample at 200 percent (100 percent elongation) was measured.
Thereafter, all load was removed from the sample and the ~ ~4 ~

percent of permanent deformation of the sample was measured. (For hypothetical illu5tration only, if a three inch sample returned to 3.3 inches the percent of permanent deformation would be 10 percent, i.e., 0.3/3Ø) After S measurement of the percent of permanent deformation, the sample was elongated to break (i.e., rupture) and the peak load, in grams, encountered during elongation of the sample to break and the percent of elongation of the sample at break was measured. The percent of elongation at break is 10 reported as a percent of the unstretched length of the sample. For example, if a sample having an unstretched length of 3 inches broke at 9 inches its elongation at break value would be 200 percent.
The results are indicated in the following Table IV, 15 below, where it can be seen that the load reduction aft~r the one (l) minute waiting period decreased in each case and that the peak load was about that of the initial load at 100 percent elongation. These results demonstrate the elastomeric properties of the samples since to obtain a 20 meaningful understanding of the elastomeric properties of material it is ~aluable to know both the percent of stretch to which the sample was subjected and the amount of permanent set which the material retained.

.

1 3 ~
TABLE IV

Cross-Machine Machine Di ection Directlon Initial Load at the 150~ length 411 grams 209 grams (50% elongation) Load at 150~ length after 1 minute214 grams 113 grams ~50% elongation) 15 Initial Load at the 200~ length420 grams ?58 grams (100~ elongation) 20 Load at the 200%
length ater 1 minute 240 grams 143 grams (100~ elongation) ~ Permanent Deformation 16~ 21%

Peak Load Encountered393 grams 266 ~rams % Elongation at Break 171~ 225%

~.

A fibrous nonwoven elastic web was formed by meltblowing a blend of 90 percen~, by weight, of an A-B-A' - ~6 -bloc~ copolymer having polys~yrene "A" and "A"' endblocks and a poly ~e~hylene-butylene) l'Bl1 mldblock (obtained from the Shell Chemical Company under the trade designation XRATON GX 1657) and 10 percent, by weight, of a 5 polyethylene (obtained from U.S.I. Chemical Company under the trade desiqnation PE Na601).
Meltblowing of the fibrous nonwoven elastic web was accomplished by extruding the blend of materials through a 0.75 inch diameter Brabender extruder and throuyh a 10 meltblowing die having nine extrusion capillaries per lineal inch of die tip. That is, extruder/die arrangement B4 as defined herein, was utilized. The capillaries each had a diameter of about 0.014S inches and a length of about 0.113 inches. The blend was extruded through the 15 capillaries at a rate of about 0.36 grams per capillary per minute at a temperature of about 322.8 degrees Centigrade.
The extrusion pressure exerted upon the blend in the die tip was measured as 450 pounds per square inch, gage. The die tip configuration was adjusted so that it extended 20 about 0.010 inches (0.010 inch die tip stick-out) beyond the plane of the external surface of the lips of the air plates which form the forming air passageways on either side of the capillaries. The air plates were adjusted so that the two forming air passageways, one on each side of 2S the extrusion capillaries, formed air passageways of a width or gap o~ about 0.060 inches. Forming air for meltblowing the blend was supplied to the air passageways at a temperature o about 335.6 degrees Centigrade and at a pressure of about 1.5 pounds per square inch, gage. The 30 viscoslty of the blend was calculated at 651 poise in the capillaries. The meltblown ibers thus formed were blown onto a forming screen which, while not ac~ually measured, is believed to have been approximately 12 inches from the die tip.

EXAMPLE III
._ A fibrous nonwoven elastic web was formed by meltblowing a blend of 80 percent, by weight, of an A-3-A' 5 block copolymer having polystyrene "A" and ".~"' endbloc~s and a poly ~ethylene-butylene) n3" midblock (obtained from the Shell Chemical Company under the trade designation ~RATON GX 1657) and 20 percent, by weight, of a polyethylene (obtained from U.S.I. ChemicaL Company under 10 the trade designation PE Na601).
Meltblowing of the fibrous nonwoven elastic web was accomplished by extruding the blend of materials through a 0.75 inch Brabender extruder and through a meltblowing die having nine extrusion capillaries per lineal inch of die lS tip. That is, extruder/die arrangement B4 as defined herein, was utilized. The capillaries each had a diameter of about 0.0145 inches and a length of about 0.113 inches.
The blend was extruded throu~h the capillaries at a rate of about 0.43 grams per capillary per minute at a temperature 20 of about 322.8 degrees Centigrade~ The extrusion pressure exerted upon the blend in the die tip was measured as 472 pounds per square inch, gage. The die tip configuration was adjusted so that it extended about 0.010 inches (0.010 inch die tip stickoout) beyond the plane of the external ~5 surface of the lips of the air plates which form the air passages on either side of the capillaries. The air plates were adjusted so that the two air passages, one on each side of the extrusion capillaries, ~ormed air passageways of a width or gap of about 0.060 inches~ Forming air for 30 meltblowing the blend was supplied to the air passageways at a temperature of about 325.0 degrees Centigrade and at a pressure o~ about 2.0 pounds per square inch, gage. The viscosity of the blend was calculated at 572 poise in the capillaries. The meltblown fibers thus formed were blown 35 onto a forming screen which, while not actually measured, '7 ~

- ~8 -is believed to have been approximately 12 inches from the die tip.

A fibrous nonwoven elastic web was formed by meltblowing a blend of 70 percent, by weight, of an A-B-A' block copolymer having polystyrene "Al' and "A"' endblocks and a poly (ethylene-butylene) "~" midblock (obtained from the Shell Chemical Company under the trade-mark KRATON GX
1657) and 30 percent, by weight, o~ a polyethylene ~obtained from U.S.I. Chemical Company under the trade designation PE Na601~.
Meltblowillg of the fibrous nonwoven elastic web was accomplished by extruding the blend of materials through a 0.75 inch extruder sold under the trade-mark Brabender and through a meltblowing die having nine extrusion capillaries per lineal inch o~ die tip. That is, extruder/die arrangement B4, as defined herein, was utilized. The capillaries each hacl a diameter of about 0.0145 inche~ and a length o-f about: 0.113 inches. The blend was extruded through the capillaries at a rate of about 0.43 grams per capillary per minute at a temperature of about 322.~ degrees Cen~igrade. The extrusion pressure exerted upon the blend in the die tip was measured as 375 pounds per square inch, gage. The die tip configuration was ad~usted so that it extended about 0.010 inches (0.010 inch die tip stick-out) beyond th~ plane of the external surface of the lips of the air plates which form the air ~0 passageways on either side of the capillaries. The air plates were adjusted so that the two air passageways, one on each side of the extrusion capillaries, formed air passageways of a width or gap of about 0.060 inches.
Forming air ~or meltblowing the blend was supplied to the air passageways at a temperature of about 325.0 degrees Centigrade and a pressure of about 2.0 pounds per square inch, gage. The viscosity o~ the blend was calculated at .

- 49 ~

454 poise in the capillaries- l'he meltblown fibers thus formed were blown onto a forming screen which, whiie not actually measured, is believed to have been approximately 12 inches from the die tip.

EXAMPLE V

A fibrous nonwoven elastic web was foxmed by meltblowing a blend of 70 percent, by weight, o~ an A~B-A' lO block copolymer having polystyrene "A" and 'iA"' endbloc~s and a poly ~ethylene-butylene~ "~" midblock (obtained from the Shell Chemical Company under the trade designation XRATON GX 1657) and 30 percent, by weight, of a polyethylene (obtained from U.S.I~ Chemical Company under 15 the trade designation PE Na601).
~ eltblowing of the fibrous nonwoven elastic web was accomplished by extruding the blend of matsrials through a 0.75 inch Brabender extruder and through a meltblowing die having nine extrusion capillaries per lineal inch of die 20 tip. That is~ extruder/die arran~ement B4, as defined herein, was utilized. The capillaries each had a diameter of about 0.0145 inches and a length of about 0.113 inches.
The blend was extruded through the capillaries at a ra~e of about 0.64 grams per capillary per minute at a temperature 25 of about 322.2 degrees Centigrade. ~he extrusion pressure exerted upon the blend in the die tip was measured as 480 pounds per square inch, gage. The die tip configuration was adjusted it extended about 0.010 inches (0.010 inch die tip stick-out) beyond the plane of the external surface of 30 the lip5 of the air plates which form the air passageways on either side of the capillaries. The air plates were adjusted so that the two air passageways, one on each side of tha extrusion capillaries, formed air passageways of a width or qap of about 0.060 inches. Forming air for 35 meltblowing the blend was supplied to the air passaqeways at a temperature of about 3~4.4 degrees Centigrade and at a - 50 ~

pressure of about 4.5 pounds per square inch, gage. The viscosity of the blend was calculated at 391 poise in the capillaries. The meltblown fi~ers thus formed were blown onto a forming screen which, while not actually measured, 5 is believed to have been approximately 12 inches from the die tip.
EXAMPLE VI

A fibrcus nonwoven elastic web was formed by meltblowing a blend of 60 percent, by weight, of an A-B-A' block copolymer having polystyxene "A" and "A' n endblocks and a poly (ethylene-butylene) "B" midblock (obtained from the Shell Chemical Company under the trade designation 15 KRATON GX 1657) and 40 percent, by weight, of a polyethylene (obtained from U.S.I. Chemical Company under the trade designation PE Na601).
Meltblowing of the fibrous nonwoven elastic web was accomplished ~y extruding the blend of materials through a 20 0.75 inch Brabender extruder and through a meltblowing die having nine extrusion capillaries per lineal inch of die tip. That is, extruder/die arrangement B4, as defined herein, was utilized. The capillaries each had a diameter of about 0.0145 inches and a lenqkh of about 0.113 inches.
2~ The blend was extruded thxough the capillaries at a rate of about 0.36 grams per capillary per minute at a temperature of about 323.9 degrees Centigrade. The extrusion pressure exerted upon the blend in the die tip was measured as 240 pounds per square inch, gage. The die tip configuration 30 was adjusted so that it extended about 0.010 inches tO.O10 inch die tip stick-out) beyond the plane of the external surface of the lips of the air plates which ~orm the air passageways on ei~her side of the capillaries. The air plates were adjusted so that the two air passageways, one 35 on each side of the extrusion capillaries, formed air passageways of a width or gap of about 0.060 inches.

~ 3 ~ 3 Forming air for meltbloWing the blen~ was supplied to the air passageways at a temperature of about 334.4 degrees Centigrade and at a pressure of about 1.5 pounds per square inch, gage. The viscosity of the blend was calculated at 5 347 poise in the capillaries. rrhe meltblown flbers thus formed were blown onto a forming screen which, while not actually measured, is believed to have been approximately 12 inches from the die tip.

EXAMP~E VII

A fibrous nonwoven elastic web was formed by meltblowing a blend of 60 percent, by weight, of an A-B-A' block copolymer having polystyrene "A" and "A"' endbloc~s 15 and a poly (ethylene~butylene~ ~B" midblock (obtained from the Shell Chemical Company under the trade designation KRATON G 1652) and 40 percent, by weight, of a polyethylene (obtained from ~oS~I~ Chemical Company under the trade designation PE Na601)~
Meltblowing of the fibrous nonwoven elastic web was accomplished by extruding the bl~nd of materials through a 0.75 Brabender extruder a~d through a meltblowing die having nine extrusion capillaries per lineal inch of die tip. That is, extruder/die arrangement B4, as defined 25 herein, was utilized. The capil:Laries each had a diameter of about 0.0145 inches and a length of about 0.113 inches.
The blend was ex~ruded through the capillaries at a rate of about 0.36 grams per capillary per minute at a tempexature of about 323.9 degrees Centigrade. The extrusion pressure 30 exerted upon the blend in the die tip was measured as 220 pounds per square inch, gage. The die tip configuration was adjusted so that it extended about 0.010 inches ~0.010 inch die tip stick-out) beyo~d the plane of the external surface of the lips of the air plates which form the air 35 passageways on either side of the capillaries. The air plates were adjusted so that the two air passageways, one - ~2 ~ 3 ~ 3 on each side of the extrusion capillaries, formed alr passageways of a width or gap of about 0.060 inches.
Forming air for meltblowing the blend was supplied to the air passageways at a temperature of about 335.0 degrees 5 Centigrade and at a pressure of about 1.5 pounds per square inch, sage. The viscosity of the blend was calculated at 318 poise in the capillaries. The meltblown fibers thus formed were blown onto a forming screen which, while not actually measured, is believed to have been approximately 10 12 inches from the die tip.

EXAMPLE VIII
_ A fibrous nonwoven elastic web was formed by 15 meltblowing a blend of 60 percent, by weight, of an A~B-A' block copolymer having polystyrene "A" and "A"' endblocks and a poly (ethylene-butylene) "B" midblock (obtained from the Shell Chemical Company under the trade designation KRATON GX 1657) and 40 percent, by weight, of a 20 polypropylene (obtained from The Himont Company under the trade designation PC-973).
Meltblowing of the fibrous nonwoven elastic web was accomplished by extruding the blend of materials through a 0.75 inch Brabender extruder through a meltblowing die 25 having nine extrusion capillaries per lineal inch of die tip. That is, extrudertdie arrangement B4, as defined herein, was utilized. The capillaries each had a diameter of about 0.0145 inches and a length of about 0.113 inches.
The blend was extruded through the capillaries at a rate of - 30 about 0.32 grams per capillary per minute at a temperature of abou~ 324.4 degrees Centigrade. Th~ extrusion pressure exerted upon the blend in the die tip was measured as 380 pounds per square inch, gage. The die tip configuration was adjusted so that it extended about 0.010 inches l0.010 35 inch die tip stick-out) beyond the plane of he external surface of the lips of the air plates which ~orm the air ~31~l7~
passageways on either side of the capillaries. The air plates were adjusted so that the two air passayewa~s, one on each side of the extrusion caplllaries, for~ed ai~
passageways of a width or gap of about 0.060 ir.ches.
S Forming air for meltblowing the blend was supplied to the air passageways at a temperature of about 337.8 degrees Centigrade and at a pressure of about 2.0 pounds per square inch, gage. The viscosity of the blend was calculated at 619 poise in the capillaries. The meltblown fibers thus 10 formed were blown onto a forming screen which, while not actually measured, is believed to have been approximately 12 inches from the die tip.

l S COMPARATIVE EXAMPLE :I:X
A fibrous nonwoven elastic web was formed by meltblowing a composition of 100 percent, by weigh~, of an A-8-AI block copolymer having polystyrene ~A" and "A"' endblocks and a poly ~ethylene-butylene) "B" midblock 20 (obtained from the Shell Chemical Company under the trade designation KRATON GX 1657~.
Meltblowing of the fibrous nonwoven elastic web was accomplishe~ by extruding the composition through a 0.75 inch Brabender extruder and through a meltblowing die 25 having nine extrusion capillaries per lineal inch of die tip. That is, extruder/die arran~ement B4, as defined herein, was utilized. The capillaries each had a diameter of about 0.0145 inches and a length of about 0.113 inches.
The compasition was extruded through the capillaries at a 30 rate of about 0.32 grams per capillary per minute at a temperature of about 324.4 degrees Centigrade. The extrusion pressure exerted upon the composition in the die tip was measured as yxeater than 505 (off scale of the pressure probe) pounds per s~uare inch, gage. The die tip 35 configuration was adjusted so that it extended about 0.010 inches ~0.010 inch die tip stic~ out) beyond the plane of - 54 - ~3~7~

the external surface of the l-ps cf the air plates which form the air passagewayS on either side of the capillaries.
The air plates were adjusted so that the two air passageways, one on each side of the extrusion capillaries, 5 formed air passageways of a width or gap of about 0.060 inches. Forming air for meltblowing the composition was supplied to the air passageways at a temperature of about 337.8 degrees Centigrade and at a pressure of about 2.0 pounds per square inch, gage. The viscosity of the 10 composition was calculated as greater than 823 (off scale) poise in the capillaries because the pressure prcbe was off scale. The meltblown fibers thus formed were blown onto a forming screen which, while not actually measured, is believed to have been approximately 12 inches from the die 15 tip.
Table V summarizes the variables utilized in examples 2 through 9.

-~ 3 ~ ~ ~ r~ 3 o o ~ ~ oc~c~ o a~ O O er u~ o c: r ~ + ~J

Q o o o ~ ~ O Ocl~ o c~ ~ ~ o ~ o o o ~ o o O
. o o o u~
~r . , , , , , o ~ o o ou~
~D ~ ~ r~7 a: o o ~ ~ cr~ o o ~ ~n o: ~ o ~ o o o a:~ o o ep' ~ ~
o~r ut ~ ~ m ~ o N O O O r r ~ ~
~ t~
Ln ~
~ ~4 ~ o o ~ ~ co o o ~ o ~ m ~ o ~ u~ o O u~

c~ o o r~ ~ ~r co o o o o ~ o o o ~ O
C o ~ o o O U~

, 0 0 I c~ E ~ e e O ~ E ~ ~ c I E

% x x x x . .

. ~6 - ~3~ 7~

The followin~ footnotes apply to Table IV:

1 = as defined herein 2 = A = KRATON GX 1657 (Shell) B = Polyethylene PE ~a601 (U.S.I.) C - KRATO~ G 1652 (Shell) D = Polypropylene PC-973 (Himont) 90A/lOB = 90 pexcent~ by weight, A blended with 10 percent, by weight, of ~
3 = in grams per capillary per minute 4 = in degrees Centigrade 5 = in pounds per square inch, gage in ~he capillaries 6 = negative values indicate recessed die tip arrangement, in inches 7 = in ir.che~
= in degrees Centigrade 9 = in pounds per square inch, gage = in poise 11 = in inches, not actually measured The elastomeric characteristics of the fibrous nonwoven webs formed in examples 2, 3, and 6 through 9 were measured. Data was also obtained for one of ~he ~0 percent KRATON GX 1657/30 percent polyet~lylene blends (examples 4 25 or 5) but it is not absolutely certain with which example the data is to be associated. It is believed that the data is to be associated with Example 4 and it i5 50 reported.
If this assumption were incorrect, the data should be associa~ed with Example 5. The testing was accomplished by 30 utilization of an Instron tensile tester model 1122, which elongated each sample, at a rate of five (5) inches per minute, 100 percent, that is 200 percent of t~e ori~inal unstretched machine direction length and then allowed the sample to return to an unstretched condition. This 35 procedure was repeated four (4~ times and then each sa~ple was elongated to break or tear. Each sample was two (2) ~ 3 1 8 4 7 3 inches wide (transVerSe machlne direction) ~y five (5) inches long (machine direction) and the initial jaw separation on the tester was set at one (1) inch. The samples were placed lengthwise in the tester. The data 5 which was obtained is tabulated in Table VI below.

TABLE VI

Percent MD Strip Permanent Example Stretch Number Tensile ~ Set_ 2 1 366 0.4983.3 2 2 355 0.4373.7 2 3 353 0.4304.1 15 2 4 351 0.4234.7 Z 5 3~8 0.~164.9 2to break 1,76b 12.9 N/A
~758%) 20 3 1 400 0.5373.95 3 2 388 0.4615.5 3 3 381 0.4426.1 3 4 378 0.4316.2 3 5 375 0.4206.7 25 34to break 1,590 14.7 N/A
(833%) 4 1 515 0.7462.8 4 Z 510 0.6553.9 30 4 3 505 0.6334.1 4 4 498 0.6224.5 4 5 495 0.6154.5 44to break 2,058 18.7 N/A
(746~) -~ 3 ~

6 1 670 0.98~ 4.3 6 2 656 0.797 5.1 6 3 649 0.763 5.;
6 4 638 0.742 6. l 6 5 635 0. ~29 6.1 64to break 1,916 16.8 N/A
(689~) 7 1 565 0.795 2.8 7 2 550 0.652 3.9 7 3 542 0.623 4.1 7 4 534 0.605 4.1 7 5 530 0.594 4.3 74to break 1,996 15.3 N/A
(670 % ) 8 1 1,907 3.20 11.5 8 2 1,865 1.63 14.5 8 3 1,824 1.47 15.0 8 4 1,812 1.41 17.0 8 5 1,792 1.40 ~7.0 8to break 4,929 41.0 N/A
(699~ ) .

9 1 513 0.682 3.7 9 2 50~ 0.585 4.1 9 3 504 0.569 5.9 9 4 497 0.559 4.5 9 5 496 0.554 5.9 9to ~reak 4,365 23.8 N/A
(661~) Footnotes for Table VI

1 in grams per two inch wlde sample and reported as an average of two replicate measureme~ts with the average then being normalized to a 100 gram per square meter material according to the formula reported value =
(average value) x ~ _ l0~
(actual basis weight) 10 2 in inch-pounds and reported as an average of two replicate measurements with the average then being normalized to a 100 gram per square meter material according to the formula of the i~mediately preceding footnote 1.
3 as a percent of the unstretched length of the sample and reported as an average of two replicate measurements unless otherwise noted.

20 4 as a percentage increase of the length of the original unstretched sample and reported as an average of two replicate measurements. For example, 100 percent would e~ual twice the length of the original unstretched sample.
one measurement only.
-EXAMPLE X

A fibrous nonwoven elas~ic web was formed by meltblowing a blend of 70 percent~ by weight, of an A-B~A' block copolymer having polys~yrene "A" and "A"' endblocks and a poly ~ethylene-butylene) "B" midblock (obta~ned from the Shell Chemical Company under the trade designation 35 KRATON GX 1657) and 30 percent, by weight, of a polyethylene (obtained from U-S-:[- Chemical Company under the trade designation PE Na601).
Meltblowing c~ the fibrous nonwoven elastic web was accomplished by extruding the blend of materials through a 5 1.5 inch diameter Johnson extruder and through a melthlowing die having thirty extrusion capillaries per lineal inch of die tip. That is, extruder/die arrangement A2, as defined herein, was utilized. The capillaries each had a diameter of a~out 0.0145 inches and a length of about 10 0.113 inches. The blend was extruded through the capillaries at a rate of about 0.302 grams per capillary per minute at a temperature of about 299.0 degrees Centigrade. The extrusion pressure exerted upon the blend in the die tip was measured as 155 pounds per square inch, 15 gage. The ~ie tip configuration was adjusted so that it was recessed about 0.080 inches (-0.080 die tip stick-out) from the plane of the external surface of the lips of the air plates which,form the air passageways on either side of the capillaries. The air plates were adjusted so that the 20 two air passageways, one on each side of the extrusion capillaries, formed air passageways of a width or gap of about 0.067 inches. Forming air for meltblowing the blend was supplied to the air passageways at a temperature of about 316.7 degrees Centigrade and at a pressure of about 25 7.0 pounds per square inch, gage. The viscosity of the blend was calculated at 267 poise in the capillaries. The meltblown fibers thus formed were blown onto a forming screen which was approximately 8 inches from the die tip.

EXAMPLE XI

A fibrous nonwoven elastic web was formed by meltblowing a blend of 70 percent, by weight, of an A-B-A' block copolymer ha~ing polystyrene "A" and "A'~ endblocks 35 and a poly ~ethylene-butylene) "B" midblock (cbtained from the Shell Chemical Company under the trade designation - 61 ~

KRATON GX 1657) and 30 percent, by weight, of a polyethylene (obtained fro~ U.S.I. Chemical Company under the trade designation PE Na601~.
Meltblowing of the fibrous nonwoven elastic web was 5 accomplished ~y extruding the blend of materials through a 1.5 inch diameter Johnson extruder and through a meltblowing die having thirty extrusion capillaries per lineal inch of die tip. That is, extruder/die arrangement A2, as defined herein, was utilized. The capillaries each 10 had a diameter of about 0.0145 inches and a length of about 0~113 inches. The blend was extruded through the capillaries at a rate of about 0.302 grams per capillary per minute at a temperature of abou~ 299l0 degrees Centigrade. The extrusion pressure exer~ed upon the blend 15 in the die tip was measured as 156 pounds per square inch, gage. The die tip configuration was adjusted so that it was recessecl about 0.080 (-0.080 die tip stick-out) inches from the plane of the external surface of the lips of the air plates which form the air passageways on either side of 20 the capillaries. The air plates were adjusted so that the two air passageways, one on each side of the extrusion capillaries, formed air passageways of a width or gap of about 0.067 inches. Forming air for meltblowing the blend was supplied to the air passageways at a temperature of 25 about 316.7 degrees Centigrade and at a pressure of about 3.S pounds per square inch, gage. The viscosity of the blend was calculated as 269 poise in the capillaries. ~he meltblown fibers thus formed were blown onto a forming screen which was approximately 8 inches from the die tip.
EXAMPLE XII

A fibrous nonwoven elastic web was formed by meltblowing ~ blend of 60 percent, by weight, of an A-B-A' 3S block copolymer having polystyrene "AN and ~A"' endblocks and a poly (ethylene-butylene) "B" midblock (obtained from - 62 - 13~

the Shell Chemical Comp~ny under the trade designat on ~RATON GX 1657) and 40 percent, by weight, of a polyethylene (o~tained from U.S.I. Chemical Compan~ under the trade designation PE Na601).
Meltblowing of the fibrous nonwoven elastic web was accomplished by extruding the blend of materials throu~h a 1.5 inch diameter Johnson extruder and through a mPltblowing die havinq thirty extrusion capillaries per lineal inch of die tip. That is, extruder/die arrangement 10 A2, as defined herein, was utilized. The capillaries each had a diameter of about 0.0145 inches and a length of about 0.113 inches. The blend was extruded through the capillaries at a rate of about 0.302 yrams per capillary per minute at a temperature of about 295.0 degrees 15 Centigrade. The extrusion pressure exerted upon the blend in the die tip was measured as 93 pounds per s~uare inch, gage. The die tip configuration was adjusted so that it was recessed about 0.030 (-0.080 die tip stick-out) inches from the plane of ~he external surface of the lips of the 20 air plates which form the air passageways on ~ither side of the capillaries. The air plates were adjusted so that the two air passageways, one on each side of the extrusion capillaries, formed air passageways of a width or gap of about 0.067 inches. Forming air for meltblowing the blend 25 was supplied to the air passageways at a temperature of about 311.7 degrees Centigrade and at a pressure of about 3.5 pounds per square inch,- gage. The viscosity of the blend was calculated as 160 poise in the capillarles. The meltblown fibers thus formed were blown onto a forming 30 screen which was approximately 8 inches from the die tip.
.

EX~MPLE XIII

A fibrous nonwoven elastic web was formed by 35 meltblowing a blend of 60 percent, by weight, of an A-B-A' ~311 ~73 block copolymer havinq polystyrene "A" and "A"' endblocks and a poly (ethylene butylene) "B" midblock (cbtained fro~
the Shell Chemical Company under the trade designation K~ATON GX 1657~ and 40 percent, by weight, of a 5 polyethylene (obtained from U.S.I. Chernical Compan<~ under the trade desi~nation PE Na601).
Melt~lowing of the fibrous nonwoven elastic web was accomplished by extruding the blend of materials through a 1.5 inch diameter Johnson extruder and through a 10 meltblowing die having thirty extrusion capillaries per lineal inch of die tip. That is, extruder/die arrangement A~, as defined herein, was utilized. The capil~aries each had a diameter of about 0.0145 inches and a length of about 0.113 inches. The blend was extruded through the 15 capillaries at a rate of about 0.302 grams per capillary per minute at a temperatur~ of about 299.4 degrees Centlgrade. The extrusion pressure exerted upon the blend in the die tip was measured as 86 pounds per square inch, gage. The die tip configuratiotl was adjusted so that it 20 was recessed about 0.080 ~-0.080 die tip stic~-out) inches from the plane of the exter~al surface of the lips of the air plates which form the air passageways on either side of the capillaries. The air plates were adjusted so that the two air passa~eways, one on each side of the extrusion 25 capillaries, formed air passa~eways of a width or gap of about 0.067 inches. Forming air for meltblowi~g the blend was supplied to the air passageways at a temperature of about 316.1 degrees Centigrade and at a pressure of about 7.0 pounds per sqllare inch, gage. The viscosity of the 30 blend was calculated as 148 poise in the capillaries. Th~
meltblown fibers thus formed were blown onto a forming screen which was approximately 8 inches from the die tip.

. .

-- 6~ --~3~73 EXAMP LE X I V

A fibrous nonwoven elastic web was formed by meltblowing a blend of 60 percent, by weight, of an A-B-A' 5 block copolymer having polystyrene "A" and "A"' endblocks and a poly ~ethylene-butylene~ "~" midblock (obtained from the Shell Chemical Company under the trade designation KRATON GX 1657) and ~0 percent, by weight, of a polyethylene (obtained from U.S.I. Chemical Company under 10 the trade designation PE Na601).
Meltblowing of the fibrous nonwoven elastic web was accomplished by extruding the blend of materials through a 1.5 inch diameter Johnson extruder and through a meltblowing die having thirty extrusion capillaries per 15 lineal inch of die tip. That is, extruder/die arrangement A2, as defined herein, was utilized. The capillaries each had a diameter of about 0.0145 inches and a length of about 0.113 inches. The blend was extruded through th~
capillaries at a rate of about 0~504 grams per capillary 20 per minute at a temperature of about 293.3 degxees Centigrade The extrusion pressure exerted upon the blend in the die tip was measured as 170 pounds per square inch, gage. ~he die tip configuration was adjusted so that it was recessed about 0.080 (-0.080 die tip stick-out) inches 25 from ~he plane of the external surface of the lips of the air plates which form the air passageways on either side of the capillaries. The air plates w~re adjusted so that the two air passageways, one on each side of the extrusion capillaries, formed air passageways of a width or gap of 30 about 0.067 inches. Forming air for meltblowing the blènd was supplied to the air passageway5 at a temperature of about 310.0 degrees Centigrade and at a pressure of about 3.5 pounds per square inch, gage. The viscosity of the blend was calculated as 176 poise in the capillaries~ The 3S meltblown fibers thus formed were blown onto a forming screen which was approximately 12 inches from the die tip.

EXAMPLE XV

A fibrous nonwoven elastic web was formed by meltblowing a blend of 60 percent, by weight, of an A-B-A' 5 block copolymer having polystyrene "A" and "A"' endblocks and a poly (ethylene-butylene) "B" midblock (obtained from the Shell Chemical Company under the trade designation KRATON GX 1657) and 40 percent, by weight, of a polyethylene ~obtained from U.S.I. Chemical Company under 10 the trade designation PE Na601).
Meltblow ng of the fibrous nonwoven elastic web was accomplished by extruding the blend of materials through a 1.5 inch diameter Johnson extruder and through a meltblowing die having thirty extrusion capillaries per 15 lineal inch of die tip. That is, extruder/die arrangement A2, as defined herein, was utilized. The capillaries each had a diameter of about 0.0145 inches and a length of abGut 0.113 inches. The blend was extruded through the capillaries at a rate of about 0.504 grams per capillary 20 per minute at a temperature of about 295.0 desrees Centigrade. The extrusion pressure exerted upon the blend in the die tip was measured as 160 pounds per square inch, gage. The die tip configuration was adjusted so that it was recessed about 0.080 ~-0.080 die ~ip stick-out) inches 25 from the plane of the external surface of the lips of the air plates which form the air passageways on either side of the caplllaries. The air plates w~re adjusted so that the two air passageways, one on each side of the extrusion capillaries, formed air passageways of a width or gap of 30 about 0.067 inches. Forming air for meltblowing the blend was supplied to the aix passageways at a temperature of about 308.9 degrees Centigrade and at a pressure of about 10.0 pounds per square inch, gage. The viscosity of ~he blend was calculated as 165 poise in the capillaries. The 35 meltblown fibers thus formed were blown onto a forming screen which was approximately 12 inches from the die tip.

~ 66 -~ 3 ~
EXAMPLE XVI

A fibrous nonwoven elastlc web was formed b~
meltblowing a blend of 60 percent, by weight, of an A-B-A' 5 block copolymer having polystyrene "Al and "A"' endblocks and a poly (ethylene-butylene) "B" midblock (obtained from the Shell Chemical Company under the trade designation ~RATON GX 1657) and 40 percent, by weight, of a polyethylene ~obtained from U.S.I. Chemical Company under 10 the trade designation PE Na601).
Melthlowing of the fibrous nonwoven elastic web was accomplished by extruding the blend of materials through a 1.5 inch diameter Johnson extruder and through a meltblowing die having thirty extrusion capillaries per 15 lineal inch o die tip. That is, extruder/die tip arrangement A2, as defined herein, was utilized. The capillaries each had a diameter of about 0.0145 inches and a length of about 0.113 inches. The blend was extruded through the capillaries at a rate of about 0.504 grams per 20 capillary per minute at a temperature of about 294.4 degrees Centigrade. The extrusion pressure exerted upon the blend in the die tip was m~asured as 153 pounds per square inch, gage. The die tip configuration was adjusted so that it was recessed about 0.080 (-0.080 die tip 25 stick-out) inches from the plane of the external surface of the lips of the air plates which form the air passageways on either side o~ the capillaries. The air plates were adjusted so that the two air passageways, one on each side of the extrusion capillaries, formed air passa~eways o~ a 30 width or gap of about 0.067 inches. Forming air for meltblowing the blend was supplied to the air passageways at a temperature of about 307.2 de~rees Centigrade and at a pressure of about 7.0 pounds per square inch, gage. The viscosity of the blend was calculated as 158 poise in the 35 capillaries~ The meltblown fibers thus formed were blown - 6~ - ~31~3 onto a forming screen which W215 approximately 12 lnches from the die tip.
Table VII summarizes the variables utilized in examples 10 through 16.
s : .
.

131~'iL7~
a~ o oo ,~o r o o ~9 ~ ~
o ~r ~ O O
o ~ U~ , o ~er o ~
C~O CO~D
~rIn O O O C~ O
U~
o U~ o o o CO o U) ~~ o o o 2~~D
~U~ ~ o o o .
~P
~: O ~ O ~ O O ~ ~D ~
o a~ t~ I ~ r~ ~1 ~D ~ ~ ~ ,~

~~ o ~
o o Co W
~ ~ ~ o o ~ o ,. ~ ~o .o~ ~ o o ~o t C~ CO
o ~ co I ,, ~r ~ ~ ~ ~1 H .
o:~ ~ a~~ or~
~D ~ O O CO
m err~ o ~ ~
. . . .
o o ~ ~ o co o a~ ~ I ~ ~o ~ ~ o O O O~
~ ~ o O o 1 _~ . ~
~: ~: o ~ ~o o o ~ ~ 0 n I _, ~~ Or~
O O ~ ~
~ ~ o o o r~ o O ~
~: ~o a~ u~ o o w O ~ U~
r~

r~
o h ~ O U
E ~ ~ a 3 q) ~c ~: ~ c ~ o S~ O O ~,o ~ c a~ a~ E Q~ ~ O
~1 ~ h ~ a ~
E ~ ~h ~J h ~ O
X X ~ X X X ~
~ ~ a ~ 3 ~ 3 The following footnotes apply to Table VI:

1 _ as defined hPrein ~ = A - KRATON GX 1657 (Shell) B = Polyethylene PE Na601 (U.S.I.) 90A/lOB = 90 percent, by weight, A blended with 10 percent, by weight, of B
3 = in grams per capillary per minute 4 = in degrees Centigrade 5 = in pounds per square inch, gage in the capillaries 6 = negative values indicate recessed die tip arrangement, in inches 7 Y in inches 8 = in degrees Centigrade 9 = in pounds per square inch, gage 10 = in poise ll = in inches Comparison of examples 4 through 6 of Table V with 20 examples 10 through 16 of Ta~le VII reveals that different extrusion pressures and thus different polymer viscosities resulted from examples which were otherwise generally comparable. These ~iscosity dif:Eerences may have resulted from the fact that one lot, lot A, of KRATON GX 1657 block 25 copolymer was utilized ln examples 2-6, 8 and 9, and a different lot, lot B, of KRATON GX 1657 block copolymer was utilized in examples 10 through 16. In view of these re~ults, the meltflow rate (MFR) of lot A and lot B of the K~ATON GX 1657 block copolymer was tested in accorda~ce 30 with AST~ standard D-1238 at 320 degrees Centigrade and using a 2,160 gram load since, generally speaking, higher meltflow rates are associa ed with lower polymer viscosities The results of these tests are reported below in Table VIII.

TABLE VI I I

Lot ALot B

1 = in grams per ten (lO) minutes The machine direction elongation characteristics of the fibrous nonwoven elastomeric webs formed by the 10 processes detailed in examples 10 through 16 were tested by obtaining a two ~2) inch wide (transverse direction) by five (5) inch long ~machine direction) sample of each material. Each sample was placed lengthwise in an Instron model 1122 tester with an initial jaw separation setting of 15 one (1) inch. The sample was then stretched at a rate of ten (10) inches per minute in the machine direction, i.e.
lengthwise, to determine the load, in grams, required to elongate each sample 100 percent in the ~achine direction ~L100). That is, the load, in grams, required to elongate 20 each sample to a machine direction length of twice its unstretched machine direction length. Thereafter, each sample was elongated ~o break in the machine direction and the percent elongation of the sample in the machine direction at break tEB) was measured as a percentage of the 25 unstretched machine direction length of the sample. The peak load ~PL)I in grams, encountered during elongation of the sample to break was also measured. The L100 and PL
results which are reported in Table IX, below, were normalized to a fibrous nonwoven web having a basis weight 30 of 100 grams per square meter by utilizing the following equa~ion Normalized Value = Actual Value x ( 100 _ ) (Actual Basis Weight) _ 7~ ~
~ 3 ~
TA~LE IX

Exa~ple 10 1_ 12 13 14 _ _ 15 16 EB2 579 645 509 42~ 524355 391 PL3 1,453 1,304 1,227 1,176 8981,031 1,04 Footnotes to Table VI
1 = in grams, for a two inch wide sample, normalized to 100 gram per ~quare meter sample 2 = in percent of unstretched machine direction length 3 = in grams, for a two inch wide sample, normalized to 100 gram per square meter sample Review of Table V generally reveals that the viscosity of the extrudable composition decreases as the polyolefin content of the composition increases. To further emphasize 20 this f~ct the viscosity data from Table V are reproduced in Table X, below.

TABLE X

% Tri-bloc~
Copolymer ~ Poly~thylene Viscoslt~
100 0 823+ poise 651 poise 572 poise 452 poise 347 poise The results of Table X and the other above-mentioned data clearly demonstrate tha~ the viscosity of the 35 extrudable composition decreases rapidly with increasing - polyolefin content. Fur~her and surprisingly, the data - 7~ --~3~7~
demonstrate that the el~stometrlc properties o~ the nonwoven webs formed from the extrudable composi~ion generally approximateS the elasticity of the nonwoven webs formed solely from the block copolymer. In fact, the 5 elasticity of the nonwoven materials formed from the extrudable composition remains quite satisfactory even at high polyolefin contents.

EXA~PLE XVII
A fibrous nonwoven elastic web was ~ormed by meltblowing a blend of 50 percent, by weight, of an A-B-A' bloc~ copolymer having polystyrene "A" and "A"' endblocks and a poly (ethylene-butylene) "B~ midblock (obtained from 15 the Shell Chemical Company under the trade designation XRATON G 1652) and 50 percent, by weight, of a polybutene (obtained from Amoco under the trade designation Indopol L-14).
Amoco litera~ure states that the Amoco 20 polybutenes are a series of isobutylene-butene copolymers composed predominantly of high molecular weight mono-olefin (95 percent-100 percent) with the balance being isoparafinsO Typical properties of the L-14 polybutene as stated by Amoco literature are reported in Table XI, below.

--., ~3~v73 TABLE XI
IN~OPOL - L - 14 Test MethodL-t~
_ _ _ _ _ Viscosity D445 cSt at 38C (100F) 27-33 cSt at 99C (210~F) __ 10 Flash Point COCC(~ in D92 138 (280) API Gravity at 16C ~60F) D287 36-39 Color APHA
Haze Free, Max. 70 Haze, Max. 15 15 Appearance Visual~o Foreign Material Viscosity, SUS at 38C (100F) 139 SUS at 99C (210F) 42 Average ~olecular Weight Vapor Phase 320 Osmometer Viscosity Index ASTM D56769 Fire Point COC, C (F) ASTM D92154 (310) Pour Polnt, C (F) ASTM D97-51 (-60) Specific Gravity 15.6/15.6 C
(60/60F) 0.8373 Density, Lb/Gal 6.97 Ref. Index, M~oD ASTM D1218 1.4680 Acidity, mg KO~/g AS~M D9740.03 Total sulfur~ ppm X-Ray 6 Meltblowing of the fibrous nonwoven elastic web was accomplished by extruding the blend of materials through a 0.75 inch diame~er Brabender extruder through a meltblo~ing die having twenty extrusion capillaries per lineal inch of 35 die tip. That is~ extruder/die arrangement B3, as defined herein, was utilized. The capillaries each had a diameter ~3 ~3~3 of about 0.0145 inches and a length of about 0.113 inches.
The blend was extruded through the capillaries at a rate or about 0.53 grams per capillary per minute at a temperature o about 204 degrees Centigrade. The extrusion pressure 5 exerted upon the blend in the die tip was measured as le,s than 40 pounds per square inch, gage. The die tip configuration was adjusted so that it extended about 0.010 inches beyond the plane of the external surface of the lips of the air plates which form the air passageways on either 10 side of the capillaries. The air plates were adjusted so that the two air passageways, one on each side of the extrusion capillaries, formed air passageways of a width or gap of about 0.060 inches. Forming air for meltblowing the blend was supplied to the air passageways at a temperature 15 of about 204 degrees Centigrade and at a very low, unmeasured, pressure of about 1 pound per square inch, gage. The viscosity of the blend was calculated at about 39 poise in the capillaries.
A considerable amount of smoke was produced during 20 Example XVII and it is believed that this was due to the vaporization of the L-14 material since the temperature of extrusion was higher than the flash point of the material as specified in Table XI. Due to the excessive smoking no material was collected in accordan~e with the procedures of 25 Example XVII.
Accordingly, the extrusion temperature was reduced to 160 degrees Centigrade and Example XVIII was conducted.

EXAMPLE X~III
A fibrous nonwoven elastic web was lormed by meltblowing a blend of 50 percent, by weight, of an A-B-A' block copolymer having polystyrene "A" and "A"' endblocks and a poly (ethylene-butylene) "B" midblock (ob~ained from 35 the Shell Chemical Company under the trade designation KRATON G 1652) and 50 percent, by weight, of a polybutene _ 7, - ~ 3~ 3 (obtained from Amoco under the trade desi~ation Indopol L-14).
Meltblowing of the flbrous nonwoven elast c ~eb was accomplished by e~truding the blend of materials thro~ah a 5 0.75 lnch diameter Brabender extruder anc thrcugh a meltblowing die havlng twenty extrusion capillaries per lineal inch of die tip. That is, extruder/die arrangement B3, as de ined herein, was utilized. The capillaries eacn had a diameter of about 0.0145 inches and a lenqth of about 10 0.113 inches. The blend was extruded through the capillaries at a rate of about 0.53 grams per capillar~i per minute at a temperature of about 160 degrees Centigrade.
The extrusion pressure exerted upon the blend in the die tip was not measured. The die tip configuration was 15 adjusted so that it extended about 0.010 inches beyond the plane of the external surface of the lips of the air plates which form the air passageways on either side of the capillaries. The air plates were adjusted so that the two air passageways, one on each slde of the extrusion 20 capillaries, formed air passageways of a width or gap of about 0.060 inches. Forming air for meltblowing the blend was supplied to the air passageways at a temperature of about 160 degrees Centigrade and at a very low, unmeasured, pressure of about 1 pound per square lnch, gage. The 25 viscosity of the blend could not be calculated because extrusion pressure was not measured. The meltblown fibers thus formed were blown onto a forming screen which while not actually measured is believed to have been approximately 12 inches from the die tip.
Reduction of the temperature of extrusiorl from 204 degrees Centigrade to 160 degrees Centigrade reduced the amount of smoke and a fibrous non~oven elastomeric web was successfully produced.
A two (2) inch wide ~ransverse direction by five (5) 35 inch long machine direction sample was placed len~thwise in an Instron Model 1122 tester having an initial jaw ~ 3 1 ~

separation of one (1) inch and elon~ated to break at a rate of five (5) inches per minute. The peak load enccun'ered in elongating the sample to break was measured as 328 grams. The energy at break was measured at 2.01 5 inch-pounds and the elongation at break, as a percent of the unstretched length of the sample, was measured as 406 percent~ The reported peak load and energy at break results were normalized to a 100 gram per square meter value by utilizing the formula identifled in footnote one 10 of Table VI.
A different two (2) inch wide, transverse direction, by five (5~ inch long, machine direction, sample of the materlal obtained in accordance with Example XVIII was then stretched to 75 percent of the elongation at break percent 15 of the prior sample. The sample was placed lengthwise in an Instron Model. 1122 tester having an initial jaw separation of one (1) inch and elongated at a rate of five (5) inches per minute. That is, the sample was stretched to 75 percent of 406 percent elongation or about 305 20 percent. Then the sample was relaxed to an unstretched condition and the procedure was repeated three (3~ times.
Thereafter, the sample was elongated to break. The results of this test are reported in Table XII, below.

TABLE XII

~ Stretch No. Load Energy 3 Stretch3 1 295 1.24 305%
2 259 0.92 305 3 236 0.82 305 4 219 0.75 305~
to break 253 1.29 420%

, . .

- 77 - ~ 3~ '73 Footnotes to Table XII
1 = in grams, normalized to a 100 gram per square meter sample 2 = in inch-pounds, normalized -to a 100 gram per square meter sample 3 = as a percent of the unstretched sample. For example, 100 percent means twice the unstretched length oE the sample.

Table XII indicates that the fibrous nonwoven elas-tomeric web of Example XVIII demonstrated satisfactory elongation characteristics but had generally lower tensile s-trength than comparable materials not containing the *Indopol L-14 polybutene.

As a short cut in determining an indication of the ranges over which commercially feasible throughput (extrusion rates) amounts of the KRATON G 1652/L-14 blends could be meltblown, blends of various amounts o~ the KRATON G 1652 and the L-14 materials were formulated and the meltflow charac-teristics of each of the bl~nds was determined. The meltflow value of a given blend is important because, generally speaking, meltflow values~ as determined by ASTM test procedure D-1238, condition E (190 degrees Centigrade and 2,160 gram load), in excess of 50 grams per capillary per ten (10) minutes tend to indicate that the blend can be meltblown on a commercial scale. The results of these meltflow tests are detailed in Table XIII below.

* - Trade-mark pl/mc Indopol2 ~ra~on_G_16521 L-14 Meltflow 6.753 15.63 132~

Footnotes for Table XIII.

15 1 = percent, by weight.
= percent:, by weight.
3 = ASTM D-1238, Condition E ~190C.; 2,160 gram load).
4 = same as preceding footnote3 except temperature maintained at 170C.
20 5 = same as preceding footno~e4 except temperature maintained at 150C.

The results of Table XIII t:end to indicate that the XRATON G 1652/Indopol L-14 blends may be meltblown at 2~ commercially feasible throughput rates at temperatures of about 170C when the blend contains 50 percent, by weight, of the Indopol L-14.

EXAMPLE XIX
A fibrous nonwoven elastic web was formed by mel~blowing a blend of 70 percent, by weight, of an A-B-A' block copolymer having po~ystyrene "A" and "A"' endblocks and a poly (ethylene-butylene) "B" midblock (obtained from 35 the Shell Chemical Company under the trade designation KRATON GX 16i7) and 30 percent, by weight, o~ a l9 '~ 3 ~ 3 polyethylene tobtained from U.S.I. Chemical Company ~ln~er the trade designation PE Na601), ~ eltblowing of the fi~rous nonwoven elastic web was accomplished by extruding the blend of materlals through a 5 0.75 Brabender extruder and through a meltblowins die having twenty extrusion capillarles per lineal inch of die tip. That is, extruder/die arrangement B3, as defined herein, was utili2ed. The capillaries each had a diameter of about 0.0145 inches and a length of about 0.113 inches.
10 The blend was ex~ruded through the capillaries at a rate of about 0.16 grams per capillary per minute at a temperature of abou~ 602 degrees Fahrenheit. The extrusian pressure exerted upon the blend in the diè tip was measured as 208 pounds per s~uare inch gage. The die tip configuration was 15 adjusted so that it extended about 0.010 inches beyond the plane of the external surface of the lips of the air plates which form the air passageways on either side of the capillariesO ~he air plates were adjusted so that the two air passageways, one on each side of the extrusion 20 capillaries, formed air passageways of a width or gap of about 0.060 inches. Forming air for meltblowing the blend was supplied to the air passageways at a temperature of abou~ 601 degrees Fahrenheit ancL at a pressure of about 2 pounds per square inch ga~e. The viscosity of the blend 25 was calculated as 677 poise in the capillaries. The mel~blown fibers thus formed were blown onto a forminq screen which, while not actually measured, is believed to have been approximately 12 inches from the die tip.

EXAMPLE XX

A fibrous nonwoven elastic web was formed by meltblowing a blend of 60 percent, by weight, of an A-B-A' block copolymer havinq polystyrene "A" and "A' n endblocks 35 and a poly (ethylene-butylene) "~" midblock (obtained from the Shell Chemical Company under the trade designation .

- 80 ~

KRATON GX 1651) and 40 pereent, by weight, cr a polyethylene (obtained from U.S.I Chemical Compan~ under the trade designation PE Na601).
Meltblowing of the fibrous nonwoven elastic web was 5 accomplished by extruding the blend of materials through a 0.75 inch dlameter Brabender extruder and through a meltblowing die having twenty extrusion capillaries per lineal inch of die tip. That is, extruder/die arrangement B3, as defined herein, was utilized. The capillaries each l0 had a diameter of about 0.0145 inches and a length of about 0.113 inches. The blend was extruded through the capillaries at a rate of about 0.3l grams per capillary per minute at a temperature of about 602 degrees Fahrenheit.
The extrusion pressure exerted upon the blend in the die 15 tip was measured as 200 pounds per square inch gage. The die tip configuration was adjusted so that it extended about 0.0l0 inches beyond the plane of the exter~al surface of the lips of the air plates which form the air passageways on either side of the capillaries. The air 20 plates were adjusted so that the two air passageways, one on each side of the extrusion capillaries, formed air passageways of a width or gap of about 0~060 inches.
Forming air for meltblowing the blend was supplied to the air passageways at a temperature of about 600 degrees 25 Fahrenheit and at a pressure of about 2 pounds per square inch gage. The viscosi~y of the blend was calculated as 336 poise in the capillaries. The meltblown fibers thus ormed were blown onto a forming screen which, while not actually measured, is believed to have been approximately 30 12 inches from the die tlp.

EXAMPL~ XXI

A ibrous nonwoven elastic web was formed by 35 meltblowiny a blend of 50 percent, by weight, of an A-B-A' block copolymer having polystyrene "A" and "A"' endblocks - 81 ~

and a poly ~ethylene-butYlene) 'B" midblock (obtai~.ed from the Shell ~hemical Company under the trade desi~nation KRATON GX 1657) and 50 percent, by weight, o~^ a polyethylene /obtained from U.S.I. Chemical Company under 5 the trade designation ~E Na601).
Meltblowing of the fibrous nonwoven elastic web was accomplished by extrudin~ the blend of materials through a 0.75 inch diameter Brabender extruder and through a meltblowing die having twenty extrusion capillaries per 10 lineal inch of die tip. That is, extruder/die arrangement B3, as defined herein, was utilized. The capillaries each had a diameter of about 0.0145 inches and a length of abou~
0.113 inches. The blend was extruded through the capillaries at a rate of about 0.56 grams per capillary per 15 minute at a temperature of about 603 degrees Fahrenheit.
The extrusion pressure exerted upon the blend in the die tip was measured as 201 pounds per square inch gage. The die tip configu~ation was adjusted ~o that it extended about 0.010 inches beyond the plane of the external surface 20 of the lips of the air plates which form the air passageways on either side of the capillaries. The air plates were adjusted so that the two air passageways, one on each side of the extru~ion capillaries, formed air passageways of a width or gap of about 0.060 inches.
25 Forming air for meltblowing the blend was supplied to the - air passageways at a temperature of about 600 degrees Fahrenheit and at a pressure of about 2 pounds per square inch gage. The viscosity of the blend was calculated as 187 poise in the die tip. The meltblown fibers`thus formed 30 were blown onto a forming screen whicn, while not actually measured, is believed to have been approximately 12 inches from the die tip.

- 82 - ~3~73 EXA~P~E

A fibrous nonwoven elastic web was formed h~
meltblowing a blend of 40 percent, by weight, o~ an A-B-A' 5 block copolymer havinq polystyrene "A" and "A"' endblocks and a poly (ethylene-butylene) "B" midblock (obtained from the Shell Chemical Company under the trade designation KR~TON GX 1657) and 60 percent, by weight, of a polyethylene (obtained from U.S~I. Chemical Company under 10 the trade designation PE Na601).
Meltblowing of the fibrous nonwoven elastic web was accomplished by extruding the blend of materials through a 0.75 inch diameter ~rabender extruder and through a meltblowing die having twenty extrusion capillaries per 15 lineal inch of die tip. That is, extruder/die arrangement ~3, as defined herein, was utilized. The capillaries each had a diameter of about 0.0145 inches and a length of abvut 0.113 inches. The blend was extruded through the capillaries at a rate of about 0.82 grams per capillary per 20 minute at a temperature of about 602 degrees Fahrenhelt.
The extrusion pressure exerted upon the blend in the die tip was measured as 198 pounds per square inch gage. The die tip configuration was adjusted so that it extended about 0.010 inches beyond the plane of the external surface 25 o~ the lips of the air plates which form the air passageways on either side of the capillaries. The air plates were adjusted so that the two air passageways, one on each side of the extrusion capillaries, formed air passageways of a width or gap of about 0.060 inches.
30 Forming air for meltblowing the blend was supplied to the air passageways at a temperature of about 600 degrees ~ahrenheit and at a pressure of about 2 pounds per square inch gage. The viscosity of the blend was calculated as 126 poise in the capillaries. The meltblown fibers thus 35 formed were blown onto a forming screen which~ while not - 83 ~ 3 actually measured, is belleved to have been approximatel~
12 inches from the dle tip.

EXAMPLE X~III

A fibrous nonwoven elastic web was formed bv meltblowing a blend of 30 percent, by weiyht, of an A-B-A' block copolymer having polystyrene "A" and "A"' endbloc~s and a poly (ethylene-butylene) "B~ mldblock (obtained from lO the Shell Chemical Company under the trade designation KR~TO~ GX 1657) and 70 percent, by weight, of a polyethylene (obtained from U.S.I. Chemical Company under the trade designation PE Na601).
Meltblowing of the fi~rous nonwoven elastic web was 15 accomplished by extruding the blend of materials through a 0.75 inch diameter Brabender extruder and through a meltblowing die having twenty extrusion capillaries per lineal inch of die tip. That is, extruder/die arrangemen~
B3, as defined herein, was utilized. The capillaries each 20 had a diameter of about 0.0145 inches and a length of about 0.113 inches. The blend was extruded through the capillaries at a rate of about 0.94 grams per capillary per minute at a temperature of about 594 degrees ~ahrenheit.
The extrusion pressure exerted upon the blend in the die 25 tip was measured as 166 pounds per square inch gage. The die tip configuration was adjusted 50 that it extended about 0.010 inches beyond the plane of the external surface of the lip5 of the air plates which form the air passageways on elther side of the capillaries. The air 30 plates were adjusted so that the two air passageways, one on each side of the ex~rusion capillaries, formed air passageways of a width or gap of about 0,060 inches.
Forming air for meltblowing the blend was supplied to the air passageways at a temperature of about 600 degrees 35 Fahrenheit and at a pressure of about 2 pounds per square inch. The viscosity of the blend was calculated as 92 ,..

poise in the die tip. The meltblow~ fibers thus formec were blown onto a forming screen which, while not actually measured, is believed to have been approximatel~l 12 inches .rom the die tip.
Table XIV summarizes the variables utilized in examples l9 ~hrough 23.

13~ 7~
~ o o o ~ o o m ~ o ~r ~o ~ U~

ct~ o O
CO O o ~c o ~ CO o o o O O ~ O

m O O
O ~ ~ ~D
~ ~ C~ o '' m ~ O ~ ~1 o o O ~ r~
U~ ~o I ~
~n ~ m o o G ~ O O
O ~ ~ O

~4 0 0 O
r~ o o ~ ~ O ~ O ~D

O o ~ _ C

X 'S n3 ~ X ~ . h~ :~a ~
"~

- ~6 -~ 3 ~

Footnotes for Table XIV:

1 = as deflned herein = A = ~RATON GX 1657 (Shell) B = Polyethylene PE Na601 ~.S.I.) 90A/103 = 90 percent, by weight, A blended with 10 percent, by weight, of B
3 - in grams per caplllary per minute 4 = in degrees Fahrenheit = in pounds per square inch, gage in the capillaries 6 = negative values lndicate recessed die tip arranqement, in inches 7 = in inches 8 = in degrees Fahrenheit 9 = in pounds per square inch, gage - in poise 11 = in inches, not actually measured In examples 19 through 23, which all utilized extruder/die configuration B3, as defined herein, the temperature of ex~rusion, extrusion pressure, air temperature, and air pre~sure were maintained as constant as practical. Accordingly, referring to Table XV the 25 dramatic decrease in the viscosity of blend in the capillaries and the accompanying increase in extrusion - (throughput) rates as the percent, by wei~ht, of the polyolefin material is increased is clear.
To further investigate the effects of increaslng 30 polyolefin content in the blends on the fibrous nonwoven elastomeric webs formed therefrom the elongation, peak load and energy at break characteristics of samples of the fibrous nonwoven webs formed in examples 19 through 23, were measured by obtaining five (5) samples of each web 35 having a cross machine direction width of two (2) inches and a machine direction length of five ~5) inches. Each of . .

the five samples was placed lengthwise in an Instron tensile tester model TM ~ith an i~itial ,a~ separation or one (1) inch. Each sample was then stretc~ed at a ra~e of inches per minu~e to determine the load, in grams, 5 required to elongate the sample to break. These results are reported below in Table XV, below.

TABLE XV

Percent4 Basis E1on-Example Sampleweight1 ~ensile~ Ener~y3 ~tion 19 1 116 1,470 4,940 663 15 19 2 166 1,460 6,605 525 19 3 15a 1,430 6,670 675 19 4 147 1,410 6,510 688 1 9 5 ' _ _ ~_ _ . _ .
20 19 Avg _ 146.86 1,343 6,181 638 19 SD5 18.6 158 719 66 19 N7 85.00 777 3,578 __ _ _ 1 63.5 650 2,965 550 25 20 2 63.5 560 2/260 525 3 63.5 590 2,390 538 4 66.6 660 2,635 488 58.9 540 2,080 500 , 30 20 Avg 63.24 ~oo 2,466 5.0 20 SD 3.1 48 308 23 20 N7 85.00 806 3,315 21 1 104 1,130 ~,~80 ~00 21 2 102 1,050 3,120 ~~5 21 3 113 1,340 4,755 ;13 21 4 112 1,040 3,005 311 21 5 110 1,180 3,970 '163 21 AvgS 108.19 1,148 3,826 428 21 SD _ 4.6 109 673 88 21 N _ 85.00 902 3,006 22 1 155 1,760 4,885 3;0 22 2 155 1,770 5,135 350 22 3 143 l,600 4,955 375 22 4 144 l,610 4,560 350 lS 22 5 146 1,650 4,500 358 _ _ _ _ 22 Avg5 _ 148.49 1,678 4,807 355 22 SD7 4.6 73 241 10 22 N7 85000 361 2,752 -- - - --- _ _ .
23 1 143 1,520 2,480 113 23 2 14~ 1,600 2,945 213 23 3 124 1,420 2,225 200 23 4 141 1,640 3,435 250 23 5 149 1,750 3,290 225 23 Avg5 ~_ 140.12 1,586 2,875 200 23 SD6 _ 7.7 111 462 47 23 N _ 85.00 962 1,744 F~otnotes for Table XV:

1 = in grams per square meter 2 = in grams per two (2) inch sample 35 3 = in inch-grams ~3~73 4 = as a percent of the length of the urstretched sam~le, that is 100 percent equals twice the lengt~ of the original sample 5 = average 5 6 = standard deviation 7 = values normalized to 85 grams per s~uare meter value These data generally indicate that the tensile strength of the material increases with increasing amounts l~ of Na601 polyethylene. Furthex, increasing amounts of polyethylene tend to decrease the elongation at break of the material. However, even at 70 percent, by weight, ~a601 polyethylene content is 200 percent elongation, at brea~ is obtained.
Another group of samples, that is the following Examples 24 through 30, was formed using a third lot, lot C, of XRATON GX 1657 blended with various amounts of polypropylene materials.

EXAMPLE XXIV
-A fibrous nonwoven elastic web was formed by meltblowing a blend of 60 percent, by weight, of an A-B-AI
bloc~ copolymer having polystyrene "A" and "A"' endblocks 25 and a poly (ethylene butylene) "B" midblock (obtained from the Shell Chemical Company under the trade designation KRA~ON GX 1657) and 40 percent, by weight, of a polypropylene (obtained from The Himont Chemical Company under the trade designation PC-973).
Meltblowing of the fibrous nonwoven elastic web was accomplished by extruding the blend of materials through a 0.75 inch Brabender extruder and through a meltblowing die having nine extrusion capillaries per lineal inch of die tip. That is, extruder/die arrangement B4, as defined 35 herein, was utilized. The capillaries each had a diameter of about 0.0145 inches and a length of about 0.113 inches.

go ~ 3~ $~ 73 The blend was extruded through the capillaries at a rate of about 0.33 gra~s per capillary per minute at a temperature oE
about 322 degrees Cen-tigrade. The extrusion pressure exerted upon the blend in the die tip was measured at 265 pounds per square inch! gage. The die tip configuration was adjusted so that it exterlded about 0.010 inches (0.010 inch die tip stick-out) beyond the plane of the external surface of the lips of the air plates which form the air passageways on either side of the capillaries. The air plates were adjusted so that the two air passageways~ one on each side of the extrusion capillaries, formed air passageways of a width or gap of about 0.060 inches. Forming air for meltblowing the blend was supplied to the air passageways at a temperature of about 337 degrees Centigrade and at a pressure of about 2.0 pounds per square inch, gage. The viscosity of the blend was calculated at Al9 poise in the capillaries. The meltblown fibers thus formed were blown onto a forming screen which was approximately 12 inches from the die tip.

EXAMPLE XXV

A fibrous nonwoven elastic web was formed by meltblowing a blend of 60 percent, by weightr oE an A-B-A' block copoly-mer having polystyrene "A" and "A"' endblocks and a poly (ethylene-butylene) "B" midblock (obtained from the Shell Chemical Company under the trade designation KRATON GX 1657) and 40 percent, by weight, of a polypropylene (obtained from Eastman Chemical Products, Inc. under the trade-mark Epolene N-15 wax).

Data available from Eastman states that the Epolene N-15 has a polyolefin content of approximately 100 percent, a specific gravity of about 0.86 at 25 degrees Centigrade (water = 1) and a softening point of about 163 degrees Centigrade (325 degrees Fahrenheit) Ring and Ball (ASTM

pl/mc "
.

- 91 - ~L3i~3 D-36 26). The molecular weight of the Epolene N-15 is believed to be low.
Meltblowing of the fibrous nonwoven elastic web was accomplished by extruding the blend of materials througil a 5 0.75 inch Brabender extruder and through a meltblowing die having nine extrusion capillaries per lineal inch of die tip. That is, extruder/die arrangement B4, as defined herein, was utilized. The capillaries each had a diameter of about 0.0145 inches and a length of about 0.113 inches.
lO The blend was extruded through the capillaries at a rate of about 0.33 grams per capillary per minute at a temperature of about 322 degrees Centigrade. The extrusion pressure exerted upon the blend in the die tip was measured as 20 pounds per square inch, gage. The die tip configuration 15 was adjusted so that it extended about 0.010 inches (0.010 inch die tip stick-out) beyond the plane of the external surface of the lips of the air plates which form the air passageways on either side of the capillaries. The air plates were adjusted so that the two air passaqeways, one 20 on each side of the extrusion capillaries, formed air passageways of a width or gap of about 0.060 inches.
~orming air for meltblowing the blend was supplied to the air passageways at a temperature of about 337 degrees Centigrade and at a pressure of about 2.0 pounds per square 25 inch, gage. The viscosity of the blend was calculated at 32 poise in the capillaries. ~he meltblown fibers thus formed were blown onto a forming screen which was approximately 12 inches from the die tip.

A fibrous nonwoven elastic web was formed by meltblowing a blend of 60 percent, by weight, of an A-B-A' block copolymer having polystyrene "A" and "A"' endblocks 35 and a poly (ethylene-butylene) "B" midblock (obtained from the Shell Chemical Company under the - 92 - ~31~

trade-mark KRATON GX 1657), 20 percent, by weight, o~ a polypropylene ~obtained from the Himont Chemical Company under the trade designation PC 973) and 20 percent, by weight, of a polypropylene (obtained ~rom Eastman Chemical Products, Inc. under the trade-mark Epolene N-15 wax).
Meltblowing of the fibrous nonwoven elastic web was accomplished by extruding the blend of materials through a 0.75 inch Brabender extruder and through a meltblowing die having nine extrusion capillaries per lineal inch of die tip. That is, extruder/die arrangement B4, as defined herein, was utilized. The capillaries each had a diameter o~ about 0.0145 inches and a length of about 0.113 inches.
The blend was extruded through the capillaries at a rate of about 0.33 grams per capillary per minute at a temperature of about 323 degrees Centigrade. The extrusion pressure exerted upon the blend in the die tip was measured as 101 pounds per square inch, gage. The die tip configuration was adjusted so that it extended about 0.010 inches (0.010 inch die tip stick out) beyond the plane of the external surface of the lips of the air plates which ~orm the air passageways on either side of the capillaries. The air plates were adjusted so that the two air passageways, one on each side of the extrusion capi:Llaries, formed air passageways of a width or gap of about 0.060 inches.
Forming air for meltblowing the blend was supplied to the air passageways at a temperature of about 337 degrees Centigrade and at a pressure of about 2.0 pounds per square inch, gage. The viscosity of tha blend was calculated at 159 poise in the capillaries. The meltblown ~ibers thus formed were blown onto a forming screen which was approximately 12 inches from the die tip.

EXAMPLE XXVII
A fibrous nonwoven elastic web was formed by meltblowing a blend of 60 percent, by weight, of an A-B-A' ~ 3 ~ 7 3 block copolymer having polystyrene "A" and "A"' endblocks and a poly (ethylene-bUtylene) "B" midblock (obtalned ~rom the Shell Chemical Company under the trade designation KRATON GX 1657), 20 percent, by weight, of a pol~prop~lene 5 (obtained from The Himont Chemical Company under the trade designation PC 973) and 20 percent, by weight, of a polypropylene (obtalned from Eastman Chemical Products, Inc. under the trade designation Epolene N-15 wax) Meltblowing of the fibrous nonwoven elastic web was 10 accomplished by extruding the blend of materials through a 0.75 inch Brabender extruder and through a meltblowing die having nine extrusion capillaries per lineal inch of die tip. That is, extruder/die arrangement B4, as defined herein, was utilized. The capillaries each had a diameter 15 of about 0.0145 inches and a length of about 0.113 inches.
The blend was extruded through the capillaries at a rate of about 0.33 grams per capillary per minute at a temperature of about 230 degrees Centigrade. The extrusion pressure exerted upon the blend in the die tip was measured as 190 20 pounds pex square inch, gage. The die tip configuration was adjusted so that it extended about 0.010 inches (0.010 inch die tip stick-out) beyond the plane of the external surface of the lip5 of the air plates which form the air passageways on either side of the capillaries. The air 25 plates were adjusted so that the two air passag~ways, one on each side of the extrusion capillaries, formed air passageways of a width or gap of about 0.060 inches~
Forming air or meltblowing the blend was supplied to the air passageways at a temperature of about 337 degrees 30 Centigrade and at a pressure of about 2.0 pounds per square inch, gage. The viscosity of the blend was calculated at 300 poise in the capillaries. The meltblown fibers thus formed were blown onto a forming screen which was approximately 12 inches from the die tip.

~ 3 ~ S~

E~AMPLE XXVII_ A fibrous nonwcven elastic web was formed by meltblowing a blend of 60 percent, by weight, of an A-B-A' 5 block copolymer ha~ing polystyrene "A" and "A"' endblocks and a poly ~ethylene-butylene) "~" midblock (obtained from the Shell Chemical Company under the trade designation KRATON GX 1657), 20 percent, by weight, of a polypropylene (obtained from The Himont Chemical Company under the trade 10 designation PC 973) and 20 percent, by weight, of a polypropylene (obtained from Eastman Chemical Products, Inc. under the trade designation Epolene ~-15 wax).
Meltblowing of the fibrous nonwoven elastic web was accomplished by extruding the blend of materials through a 15 0.75 inch ~rabender extruder and through a meltblowiny die having nine extruslon capillaries per lineal inch of die tip. That is, extruder/die arrangement B4, as defined herein, was utilized. The capillaries each had a diameter of about 0.0145 inches and a length of abou~ 0.113 inches.
20 The blend was extruded through the capillaries at a rate of about 0.33 grams per capillary per minute at a temperature of about 221 degrees Centigrade. ~he extrusion pressure exerted upon the blend in the die tip was rapidly rising when it was measured as 300 pounds per square inch, gage.
25 Accordingly, the example was aborted and sample material was not gathered. The die tip configuration was adjusted so that it extended about 0.010 inches (0.010 inch die tip stick-out) beyond the plane of the external surface of-the lips of the air plates which form the air passageways on 30 either side of the capillaries. The air plates were adjusted so that the two air passageways, one on each side of the extrusion capillaries, formed air passageways of a width or gap of about 0.060 inches. Forming air for meltblowing the blend was supplied to the air passageways 35 at a temperature of about 337 degrees Centigrade and at a pressure of about 2.0 pounds per square inch, ga~e. The 1 3 ~

viscosity of the blend was calculated at being in excess of 4~ poise in the capillaries.

EXAMPLE XXIX
S - _ A fibrous nonwoven elastic web was formed by meltblowing a blend of 60 percent, by weight, of an A-a-A' block copolymer having polystyrene "A" and "A"' endblocks and a poly ~ethylene-butylene) "~" midblock ~obtained from 10 the Shell Chemical Company under the trade designation KRATON GX 1657), and 40 percent, by weight, of a polypropylene ~obtained xom Eastman Chemical Products, Inc. under the trade designation Epolene N~15 wax).
Meltblowing of the fibrous nonwoven elastic web was 15 accomplished by extruding the blend of materials through a 0~75 inch ~rabender extruder and through a mel~blowing die having nine extrusion capillaries per lineal inch of die tip. That is, extruder/die arrangement B4, as defined herein, was utilized. The capillaries each had a diameter 20 of about 0.0145 inches and a length of about 0.113 inches.
The blend was extruded through the capillaries at a rate o~
about 0.31 grams per capillary per minute at a temperature of about 161 degrees Centigrade. The extrusion pressure exerted upon the blend in the die tip was measured as 25 fluctuating between about 295 and 451 pounds per square inch, gage. The die tip configuration was adjusted so that it extended about 0.010 inches (0.010 inch die tip stick-out) beyond the plane of the external surface of the lips of the air plates which for~ the air passagewavs on 30 ei~her side of the capillaries. The air plates were adjusted so that the two air passageways, one on each side of the extrusion capillaries, formed air passageways of a width or gap of about 0.060 inches. Forming air for meltblowing the blend was supplied to the air passageways 35 at a temperature of about 210 degrees Centigrade and at a pressure o~ about 2.0 pounds per square inch, gage. The 7 ~

viscosity of the blend was calculated as ~luctuatinq between about 260 and 550 poise in the capilla~-es. The meltblown fibers thus formed were blown orto a for~irg screen which was approximately 12 inches from the die tip.

EXAM_LE XXX

A fibrous nonwoven elastic web was 'ormed ~y meltblowing a blend of 60 percent, by weight, of an A-B-A' 10 block copolymer having polystyrene "A" and "A"' endblocks and a poly (ethylene-butylene) "B~ midblock lobtained from the Shell Chemical Company under the trade designation KRATON GX 1657), and 40 percent, by weight, of a polypropylene (obtained from Eastman Chemical Products 15 Inc. under the trade dPsignation Epolene N-15 wax).
Meltblowing of the fibrous nonwoven elastic web was accomplished by extruding the blend of materials ~hrough a 0.75 inch Brabender extruder and through a meltblowing die having nine extrusion capillaries per lineal inch of die 20 tip. That is, extruder/die arrangernent B4, as defined herein, was utilized. The capillaries each had a diameter of about 0.0145 inches and a length of about 0.113 inches.
The blend was extruded through the capillaries at a rate of about 0.31 grams per capillary per minute at a temperature 25 of about 172 degrees Centigrade. The extrusion pressure exerted upon the blend in the die tip was measured as fluctuating between about 155 and 327 pounds per square inch, gage. Accordingly, the example was aborted and sample material was not gathered. The dle tip 30 configuration was adjusted so that it extended about 0.010 inches l0.010 inch die tip stick-out) beyond the plane of the external surface of the lips of the air plates which form the air passageways on either side of the capillaries.
The air plates were adjusted so that the two air 35 passageways, one on each side of the extrusion capillaries, formed air passageways of a width or gap of abou~ 0.060 13 L8~73 inches. Forming air for meltblowing t~e blend was su??liea to the air passagewayS at a temperature of abcul ~'3 degrees Centigrade and at a pressure o' about 2.0 -e~r.ds per s~uare inch, gage. The viscosit~ of the blenc was 5 calculated as fluctuating between about 496 and 7;8 poise in the capillaries.

TABLE XVI, below, summarizes the process conditions of Examples 24 through 30.

3 ~ 3 r c o o O ~ ~ ~ ~ L~l (~1 0 ;~ o L-) O e~
~7 ~ C C ~ U~ O
o r~ U~
~D

O O Ct~
O _I L~l r~
~t ~ O O O t`
~r I . . .
O ~ U~ O O O
o ~ c ._ O
O O
O t~ . O O O
3~ ~ + . . . +
o o o r~ ~ e ~ ~ o ~ r-O
~O
' O
O O
('~
C~ ~ O O O
O
Cl 1:'~ 0 ' O O O O ~-- ~`I O t`J
I¢
~-I O
~ ~D
X
~n ~ o o o m r~ o O o O o O
~ .
. O
~O
. ~ o o o ~
er ~ O O O
L'l ~r t`~ ~ I¢ Q C~ 'O O O 1` ~1 \~

C~ O O
O
C ~1 O O O
~ ~ ~ 1~ 1¢ 0 ~ 1~) 0 0 t~
~r ~- CO C
a ~ c c 1 J ~ 3~ o, Ul ,, ''~.~ s x I x 3 v E~ Q O
a ~
a . . . . .
.
.
.
.
; ,~ .

_ 99 - ~3~ 3 The following footnotes apply to Table XVI:
l = ~s defined herein 2 = A = KRATON GX 1657 (Shell), lot C
D = polypropylene PC-973 (Himont) E = polypropylene Epolene N-15 wax (Eastman) 90A/lOB = 90 percent, by weight, A blended with lO percent, by weight, of 3 3 = in grams per capillary per minute 4 = in degrees Centigrade 5 = in pounds per square inch, gage in the capillaries 6 = negative values indicate recessed die tip arrangement, in inches 7 = in inches a = in degrees Centigrade 9 = in pounds per square inch, gage lO = in pOise ll = in inches The elastomeric characteristics of the fibrous nonwoven webs formed in examples 24, 25, 26, 27 and 29 were measured. The testing was accomplished by utilization o an Instron tensile tester model 1122, which elongated each sample, at a rate of five t5~ inches per minute, 100 25 percent, that is 200 percent oE the original ~nstretched machine direction length and then allowed the sample to return to an unstretched condition. This procedure was repea~ed three t3) times and then each sample was elongated to break or tear. Each sample was two (2) inches wide 30 (transverse machine direction) by three (3~ inches long (machine direction) and the initial jaw separation on the tester was set at one (l) inch. The samples ~ere placed lengthwise in the tester. The data which was obtained is tabulated in Table XVII below~

~3~7~

TABLE ~VII

MD St_ip Exam~le St_etch Number Tenslle Enera~

24 1 4.0~8 1./2 24 2 3.168 0.73 24 3 3.15~ 0.73 24 4 3.223 0.50 24 3to break 6.670 19.23 (736~) 25 (all data example 25)4 1 2.35 1.05 2 2.13 0.39 3 2.05 0.35 4 2.00 0.32 3to break 2.73 2.78 (280~) 26 (all data example 26)4 1 2.67 1.20 26 2 2.57 0.54 26 . 3 2.52 0.49 26 4 2.47 0.46 26 3to break 5.17 14.67 ~775%) .
27 1 - 1.68 0.66 27 2 1.62 0.37 27 3 1.58 0.35 27 4 1.55 0.33 : 27 3to break 4.21 11.83 ~854%) 3 ~ 3 29 1 0.?0 G.23 29 2 0.6~ C.03 29 3 0.61 0.11 29 4 0.61 0.'1 5 29 3to break 0.70 0.19 ( 1 1 0 ~ ) Footnotes for Table XVII
1 in pounds per two inch wide sample and reported as an average of four (4) replicate measurements unless otherwise stated with the average then being normalized to a 100 gram per square meter material according to the formula reported value =
(average value) x ( 100 ).
(actual basis weight) 2 in inch-pounds and reported as an average of four (4) replicate measurements unless otherwise stated with the average then being normalized to a 100 gram per square meter material accorcling to the formula of the immediately preceding footnote 1.

25 3 as a percentage increase of the length of the original unstretched sample and reported as an average of four ~4) replicate measurements unless otherwise stated.
For example, 100 percent would equal twice the length of the original uns~retched sample.
4 average of five (5) replicate samples.

Examples 28, 29 and 30 exemplify the extreme lower limits of using polypropylene materials since the high 35 pressures encountered and the wide fluctuation in the pressures indicate that the polypropylene material was ,~.f~

probably be~inning to solidify. Thus surging of the blend which woulcl account for the pressure fluc-tuations would be expected.
Specific note should be made of the low viscosity of 32 poise encountered in Example 25.

The nonwoven elas-tomeric webs of the present inven-tion, whether comprising 100 percent elastomeric fibers or, for example coformed blends of elastomeric and other fibers, find widespreacl applica-tion in providing elasticized fabrics whether used by themselves or bonded to other materials. Potential uses include disposable garments and ar-ticles, by which is meant garments and articles designed to be discarded after one or a few uses rather -than being repeatedly laundered and reused.

This case is one of a group of related Canadian patent application cases. The group includes application Serial No.
514,680 filed July 25, 1986 in the name of M.T. Morman and entitled "Gathered Nonwoven Elastic Webll; Canadian Application Serial No. 514,456 filed July 23, 1986 in the name of M.T. Morman and T.J. Wisneski entitled "Elasticized Garment and Method of Making the Same"; Canadian Application Serial No. 514,457 filed July 23, 1986 in the name of M.T. Morman and T.J. Wisneski entitled "High Temperature Method of Making Elastomeric Materials and Materials Obtained Thereby"; Canadian Application Serial No.
514,423 filed July 22, 1986 in the name of M.~. Vander Wielen and J.D. Ta~lor entitled "Composite ~lastomeric Material and Process for Making the Same"; and Canadian Application Serial No. 514,957 filed July 30, 1986 in the name of William B. Haffner, Michael T.
Morman and T.J. Wisneski entitled "Block Copolymer - Polyolefin Elastomeric Films".

- 103 - ~ 3~

While the inventlon has been described in det~ th respect to specific prererred embodiments thereof, it ~
be appreciated that those skilled in the art, upon attaining an understand.ing of the Foregoing, may readily 5 conceive of alterations to and variations of the preferred embodiments. Such alterations and variations are believed to fall w~.thin the scope and spirit of the invention and the appended claims.

Claims (66)

1. A fibrous nonwoven elastomeric web comprising microfibers, said microfibers comprising:
at least about 10 percent, by weight, of an A-B A' block copolymer where "A" and "A'" are each a thermoplastic endblock which comprises a styrenic moiety, and where "B" is an elastomeric poly (ethylene-butylene) midblock, and from greater than 0 percent, by weight, up to about 90 percent, by weight, of a polyolefin which, when blended with the A-B-A' block copolymer and subjected to an effective combination of elevated temperature and elevated pressure conditions, is adapted to be extruded, in blended form, with the A-B-A' block copolymer.

2. The elastomeric web according to claim 1, wherein the "A" and "A"' endblocks of the block copolymer are selected from the group consisting of polystyrene and polystyrene homologs.

3. The elastomeric web according to claim 2, wherein the "A" and "A"' endblocks of the block copolymer are identical.

4. The elastomeric web according to claim 2, wherein the "A" and "A'" endblocks of the block copolymer are selected from the group consisting of polystyrene and poly (alpha-methylstyrene).

5. The elastomeric web according to claim 1, wherein the polyolefin is selected from the group consisting of at least one polymer selected from the group consisting of polyethylene, polypropylene, polybutene, ethylene copolymers, propylene copolymers and butene copolymers.

6. The elastomeric web according to claim 5, wherein the polyolefin is a blend of two or more polymers selected from the group consisting of polyethylene, polypropylene, polybutene, ethylene copolymers, propylene copolymers and butene copolymers.

7. The elastomeric web according to claim 1, wherein the polyolefin is polyethylene.

8. The elastomeric web according to claim 7, wherein the polyethylene has a density of about 0.903 grams per cubic centimeter.

9. The elastomeric web according to claim 8, wherein the polyethylene has a Brookfield Viscosity, cP at 150 degrees Centigrade of about 8500 and at 190 degrees Centigrade of about 3300 when measured in accordance with ASTM D 3236, a number average molecular weight (Mn) of about 4,600, a weight average molecular weight (Mw) of about 22,400, a Z average molecular weight (Mz) of about 83,300 and a polydispersity (Mw/Mn) of about 4.87.

10. The elastomeric web according to claim 1, wherein the polyolefin is polypropylene.

11. The elastomeric web according to claim 10, wherein the polypropylene has a density of about 0.900 grams per cubic centimeter when measured in accordance with ASTM D
792.

12. The elastomeric web according to claim 11, wherein the polypropylene has a meltflow rate obtained in accordance with ASTM D 1238, Condition L, of about 35 grams per ten minutes, a number average molecular weight (Mn) of about 40,100, a weight average molecular weight (Mw) of about 172,000, a Z average molecular weight of about 674,000 and a polydispersity (Mw/Mn) of about 4.29.

13. The elastomeric web according to claim 1, wherein the polyolefin is polybutene.

14. The elastomeric web according to claim 13, wherein the polybutene is an isobutylene-butene copolymer.

15. The elastomeric web according to claim 1, comprising from at least about 20 percent, by weight, to about 95 percent, by weight, of the A-B-A' block copolymer and from at least about 5 percent, by weight, to about 80 percent, by weight, of the polyolefin.

16. The elastomeric web according to claim 1, comprising from at least about 30 percent, by weight, to about 90, by weight, of the A-B-A' block copolymer and from at least about 10 percent, by weight, to about 70 percent, by weight, of the polyolefin.

17. The elastomeric web according to claim 1, comprising from at least 50 percent, by weight, to about 90 percent, by weight, of the A-B-A' block copolymer and from at least about 10 percent, by weight, to about 50 percent, by weight, of the polyolefin.

18. The elastomeric web according to claim 1, comprising from at least about 50 percent, by weight, to about 70 percent, by weight, of the A-B-A' block copolymer and from at least about 30 percent, by weight, to about 50 percent, by weight, of the polyolefin.

19. The elastomeric web according to claim 1, comprising about 60 percent, by weight, of the A-B-A' block copolymer and about 40 percent, by weight, of the polyolefin.

20. A fibrous nonwoven elastomeric web including microfibers, said microfibers comprising:

from at least about 10 percent, by weight, to about 90 percent, by weight, of an A-B-A' block copolymer where "A" and "A"' are each a thermoplastic polystyrene endblock, where "B" is an elastomeric poly (ethylene-butylene) midblock and where the sum of the molecular weight of the A endblock with the molecular weight of the A' endblock is about 14 percent of the molecular weight of the A-B-A' block copolymer, and from at least about 10 percent, by weight, to about 90 percent, by weight, of a polyethylene having a density of about 0.903 grams per cubic centimeter which, when blended with the A-B-A' block copolymer and subjected to an effective combination of elevated temperature and elevated pressure conditions, is adapted to be extruded, in blended form, with the A-B-A' block copolymer.

21. A fibrous nonwoven elastomeric web including microfibers, said microfibers comprising:
from at least about 50 percent, by weight, to about 90 percent, by weight, of an A-B-A' block copolymer where "A" and "A'" are each a thermoplastic polystyrene endblock and where "B" is an elastomeric poly (ethylene-butylene) midblock, and from at least about 10 percent, by weight, to about 50 percent, by weight, of a polyethylene having a Brookfield Viscosity, cP at 150 degrees Centigrade of about 8500 and at 190 degrees Centigrade of about 3300 when measured in accordance with ASTM D 3236 and a density of about 0.903 grams per cubic centimeter which, when blended with the A-B-A' block copolymer and subjected to an effective combination of elevated temperature and elevated pressure conditions, is adapted to be extruded, in blended form, with the A-B-A' block copolymer.

22. The elastomeric web according to claim 21 wherein the sum of the molecular weight of A with the molecular weight of A' is from about 14 percent to about 29 percent of the molecular weight of the A-B-A' block copolymer.

23. A fibrous nonwoven elastomeric web consisting essentially of microfibers consisting essentially of:
from at least about 50 percent, by weight, to about 90 percent, by weight, of an A-B-A' block copolymer where "A" and "A'" are each a thermoplastic polystyrene endblock and where "B" is an elastomeric poly (ethylene-butylene) midblock and from about 10 percent, by weight, to about 50 percent, by weight, of a polyethylene having a Brookfield Viscosity, cP at 150 degrees Centigrade of about 8500 and at 190 degrees Centigrade of about 3300 when measured in accordance with ASTM D 3236 and a density of about 0.903 grams per cubic centimeter which, when blended with the A-B-A' block copolymer and subjected to an effective combination of elevated temperature and elevated pressure conditions, is adapted to be extruded, in blended form, with the A-B-A' block copolymer.

24. The elastomeric web according to claim 23, wherein the sum of the molecular weight of A with the molecular weight of A' is from about 14 percent to about 29 percent of the molecular weight of the A-B-A' block copolymer.

25. A process for forming a cohesive fibrous nonwoven elastomeric web from an extrudable composition comprising at least about 10 percent, by weight, of an A-B-A' block copolymer where "A" and "A'" are each a thermoplastic endblock which includes a styrenic moiety and where "B" is an elastomeric poly (ethylene-butylene) midblock, and from greater than 0 percent, by weight, to about 90 percent, by weight, of a polyolefin which, when blended with the A-B-A' block copolymer and subjected to an effective combination of elevated temperature and elevated pressure conditions, is adapted to be extruded, in blended form, with the A-B-A' block copolymer, said process including the steps of:
subjecting the extrudable composition to a combination of elevated temperature and elevated pressure conditions to effect extrusion of the extrudable composition from a meltblowing die as molten threads;
applying a heated, pressurized stream of an attenuating gas to the molten threads to attenuate the molten threads to microfibers;
collecting the microfibers as a cohesive fibrous nonwoven elastomeric web.

26. The process according to claim 25, wherein the polyolefin is polyethylene and the extrudable composition is subjected to an elevated temperature of at least about 125 degrees Centigrade to effect the extrusion of the extrudable composition from the meltblowing die.

27. The process according to claim 25, wherein the polyolefin is polypropylene and the extrudable composition is subjected to an elevated temperature of at least about 175 degrees Centigrade to effect the extrusion of the extrudable composition from the meltblowing die.

28. The process according to claim 25, wherein the extrudable composition is subjected to an elevated temperature of from at least about 290 degrees Centigrade to about 345 degrees Centigrade to effect extrusion of the extrudable composition from the meltblowing die.

29. The process according to claim 25, wherein the extrudable composition is subjected to an elevated temperature of from at least about 300 degrees Centigrade to about 335 degrees Centigrade to effect extrusion of the extrudable composition from the meltblowing die.

30. The process according to claim 25, wherein the extrudable composition is subjected to no more than 300 pounds per square inch, gage to effect extrusion of the extrudable composition from the meltblowing die.

31. The process according to claim 25, wherein the extrudable composition is subjected to an elevated pressure of from at least about 20 pounds per square inch, gage to about 250 pounds per square inch, gage to effect extrusion of the extrudable composition from the meltblowing die.

32. The process according to claim 25, wherein the extrudable composition is subjected to an elevated pressure of from at least about 50 pounds per square inch, gage to about 250 pounds per square inch, gage to effect extrusion of the extrudable composition from the meltblowing die.

33. The process according to claim 25, wherein the extrudable composition is subjected to an elevated pressure of from at least about 125 pounds per square inch, gage to about 225 pounds per square inch, gage to effect extrusion of the extrudable composition from the meltblowing die.

34. The process according to claim 25, wherein the attenuating gas is applied to the molten threads at a temperature of from at least about 100 degree.
Centigrade to about 400 degrees Centigrade.

35. The process according to claim 25, wherein the attenuating gas is applied to the molten threads at a temperature of from at least about 200 degrees Centigrade to about 350 degrees Centigrade.

36. The process according to claim 25, wherein the attenuating gas is applied to the molten threads at a pressure of from at least about 0.5 pounds per square inch, gage to about 20 pounds per square inch, gage.

37. The process according to claim 25, wherein the attenuating gas is applied to the molten threads at a pressure of from at least about 1 pound per square inch, gage to about 10 pounds per square inch, gage.

38. The process according to claim 25, wherein the extrudable composition is extruded through the meltblowing die at a rate of from at least about 0.00044 pounds per capillary per minute to about 0.00374 or more pounds per capillary per minute.

39. The process according to claim 25, wherein the extrudable composition is extruded through the meltblowing die at the rate of from at least about 0.00022 pounds per capillary per minute to about 0.00275 pounds per capillary per minute.

40. The process according to claim 25, wherein the extrudable composition is extruded from the meltblowing die at a rate of from at least about 0.00066 pounds per capillary per minute to about 0.00242 pounds per capillary per minute.

41. A coformed fibrous nonwoven elastomeric web including:
at least about 20 percent, by weight, of a fibrous nonwoven elastomeric web of microfibers, said microfibers comprising:

at least about 10 percent, by weight, of an A-B-A' block copolymer where "A" and "A'" are each a thermoplastic endblock which includes a styrenic moiety and where "B" is an elastomeric poly (ethylene-butylene) midblock; and from greater than 0 percent, by weight, up to about 90 percent, by weight, of a polyolefin which, when blended with the A-B-A' block copolymer and subjected to an effective combination of elevated temperature and elevated pressure conditions, is adapted to be extruded, in blended form, with the A-B-A' block copolymer; and from greater than 0 percent, by weight, to about 80 percent, by weight, of at least one secondary fiber generally uniformly distributed throughout the fibrous nonwoven elastomeric web.

42. The coformed elastomeric web according to claim 41, wherein the "A" and "A"' endblocks of the block copolymer are selected from the group consisting of polystyrene and polystyrene homologs.

43. The coformed elastomeric web according to claim 42, wherein the "A" and "A'" endblocks of the block copolymer are identical.

44. The coformed elastomeric web according to claim 41, wherein the "A" and "A'" endblocks of the block copolymer are selected from the group consisting of polystyrene and poly (alpha-methylstyrene).

45. The coformed elastomeric web according to claim 41, wherein the polyolefin is selected from the group consisting of at least one polymer selected from the group consisting of polyethylene, polypropylene, polybutene, ethylene copolymers, propylene copolymers and butene copolymers.

46. The coformed elastomeric web according to claim 45, wherein the polyolefin is a blend of two or more polymers selected from the group consisting of polyethylene, polypropylene, polybutene, ethylene copolymers, propylene copolymers and butene copolymers.

47. The coformed elastomeric web according to claim 41, wherein the polyolefin is polyethylene.

48. The coformed elastomeric web according to claim 47, wherein the polyethylene has a density of about 0.903 grams per cubic centimeter.

49. The coformed elastomeric web according to claim 48, wherein the polyethylene has a Brookfield Viscosity, cP
at 150 degrees Centigrade of about 8500 and at 190 degrees Centigrade of about 3300 when measured in accordance with ASTM D 3236, a number average molecular weight (Mn) of about 4,600, a weight average molecular weight (Mw) of about 22,400, a Z average molecular weight (Mz) of about 83,300 and a polydispersity (Mw/Mn) of about 4.87.

50. The coformed elastomeric web according to claim 41, wherein the polyolefin is polypropylene.

51. The coformed elastomeric web according to claim 50, wherein the polypropylene has a density of about 0.900 grams per cubic centimeter when measured in accordance with ASTM D 792.

52. The coformed elastomeric web according to claim 51, wherein the polypropylene has a meltflow value obtained in accordance with ASTM D 1233, Condition L, of about 35 grams per ten minutes, a number average molecular weight (Mn) of about 40,100, a weight average molecular weight (Mw) of about 172,000, a Z average molecular weight of about 674,000 and a polydispersity (Mw/Mn) of about 4.29.

53. The coformed elastomeric web according to claim 41, wherein the polyolefin is polybutene.

54. The coformed elastomeric web according to claim 53, wherein the polybutene is an isobutylene-butene copolymer.

55. The coformed elastomeric web according to claim 41, comprising from at least about 20 percent, by weight, to about 95 percent, by weight, of the A-B-A' block copolymer and from at least about 5 percent, by weight, to about 80 percent, by weight, of the polyolefin.

56. The coformed elastomeric web according to claim 41, comprising from at least about 30 percent, by weight, to about 90, by weight, of the A-B-A' block copolymer and from at least about 10 percent, by weight, to about 70 percent, by weight, of the polyolefin.

57. The coformed elastomeric web according to claim 41, comprising from at least 50 percent, by weight, to about 90 percent, by weight, of the A-B A' block copolymer and from at least about 10 percent, by weight, to about 50 percent, by weight, of the polyolefin.

58. The coformed elastomeric web according to claim 41, comprising from at least about 50 percent, by weight, to about 70 percent, by weight, of the A-B-A' block copolymer and from at least about 30 percent, by weight, to about 50 percent, by weight, of the polyolefin.

59. The coformed elastomeric web according to claim 41, comprising about 60 percent, by weight, of the A-B-A' block copolymer and about 40 percent, by weight, of the polyolefin.

60. The coformed elastomeric web according to claim 41, wherein the secondary fiber comprises from at least about 30 percent, by weight, to about 70 percent, by weight, of the coformed web.

61. The coformed elastomeric web according to claim 41, wherein the secondary fiber comprises from at least about 30 percent, by weight, to about 50 percent, by weight, of the coformed web.

62. A coformed fibrous nonwoven elastomeric web including:
from at least about 30 percent, by weight, to about 70 percent, by weight, of a cohesive fibrous nonwoven elastomeric web of microfibers comprising:
from at least about 10 percent, by weight, to about 90 percent, by weight, of an A-B-A' block copolymer where "A" and "A'" are each a thermoplastic polystyrene endblock, and where "B" is an elastomeric poly (ethylene-butylene) midblock: and where the sum of the molecular weight of the "A" endblock with molecular weight of the "A'" endblock is about 14 percent of the molecular weight of the A-B-A' block copolymer, and from at least about 10 percent, by weight, to about 90 percent, by weight, of a polyethylene having a density of about 0.903 grams per cubic centimeter which, when blended with the A-B-A' block copolymer and subjected to an effective combination of elevated temperature and elevated pressure conditions, is adapted to be extruded, in blended form, with the A-B-A' block copolymer; and from at least about 30 percent, by weight, to about 70 percent, by weight, of at least one secondary fiber generally uniformly distributed throughout the cohesive web.

63. A coformed fibrous nonwoven elastomeric web including:

from at least about 30 percent, by weight, to about 70 percent, by weight, of a cohesive fibrous nonwoven elastomeric web of microfibers comprising:
from at least about 50 percent, by weight, to about 90 percent, by weight, of an A-B-A' block copolymer where "A" and "A'" are each a thermoplastic polystyrene endblock and where "B" is an elastomeric poly (ethylene-butylene) midblock, and from at least about 10 percent, by weight, to about 50 percent, by weight, of a polyethylene having a Brookfield Viscosity, cP at 150 degrees Centigrade of about 8500 and at 190 degrees Centigrade of about 3300 when measured in accordance with ASTM D 3236 and a density of about 0.903 grams per cubic centimeter which, when blended with the A-B-A' block copolymer and subjected to an effective combination of elevated temperature and elevated pressure conditions, is adapted to be extruded, in blended form, with the A-B-A' block copolymer; and from at least about 30 percent, by weight, to about 70 percent, by weight, of at least one secondary fiber generally uniformly distributed throughout the cohesive web.

64. The coformed elastomeric web according to claim 63, wherein the sum of the molecular weight of A with the molecular weight of A' is from about 14 percent to about 29 percent of the molecular weight of the A-B-A' block copolymer.

65. A coformed fibrous nonwoven elastomeric web consisting essentially of:
from at least about 30 percent, by weight, to about 70 percent, by weight, of a cohesive fibrous nonwoven elastomeric web of microfibers comprising:

from at least about 50 percent, by weight, to about 90 percent, by weight, of an A-B-A' block copolymer where "A" and "A'" are each a thermoplastic polystyrene endblock and where "B" is an elastomeric poly (ethylene-butylene) midblock;
from about 10 percent, by weight, to about 50 percent, by weight, of a polyethylene having a Brookfield Viscosity, cP at 150 degrees Centigrade of about 8500 and at 190 degrees Centigrade of about 3300 when measured in accordance with ASTM D 3236 and a density of about 0.903 grams per cubic centimeter which, when blended with the A-B-A' block copolymer and subjected to an effective combination of elevated temperature and elevated pressure conditions, is adapted to be extruded, in blended form, with the A-B-A' block copolymer, and from at least about 30 percent, by weight, to about 70 percent, by weight, of at least one secondary fiber generally uniformly distributed throughout the cohesive web.

66. The elastomeric web according to claim 65, wherein the sum of the molecular weight of A with the molecular weight of A' is from about 14 percent to about 29 percent of the molecular weight of the A-B-A' block copolymer.