US3856599A

US3856599A - Sealed edge cutting method

Info

Publication number: US3856599A
Application number: US00390986A
Authority: US
Inventors: D Bylund
Original assignee: Milliken Research Corp
Current assignee: Milliken Research Corp
Priority date: 1969-06-19
Filing date: 1973-08-23
Publication date: 1974-12-24
Anticipated expiration: 1991-12-24

Abstract

A method of automatically providing individual sealed edge products from a roll of material without moving the material during the sealing and severing stage of manufacture.

Description

[4 Dec. 24, 1974 United States Patent Bylund 2,619,089 11/1952 Swartz 156/88 3,367,810 2/1968 3,385,747

[ 4] SEALED EDGE CUTTING METHOD Wasserstein Inventor: Don M. Bylund, Spartanburg, SC.

Deering Milliken Research 5/1968 Klein et a1.

[73] Assignee:

Corporation, Spartanburg, SC.

Aug. 23, 1973 Primary Examiner-Douglas J. .Drurnmond [22] Filed:

Attorney, Agent, or Firm-Earle R. Marden; H. William Petty 211 Appl. No.: 390,986

Related US. Application Data Continuation of Scr. No. 834,641, June 19, 1969, abandoned.

ABSTRACT A method of automatically providing individual sealed edge, products from a roll of material without moving the material during the sealing and severing stage of manufacture.

000 a 5mm Q15 3 1 1%5 2 4 6 0 11 ,5 om 57% 8 W 8M5 M 5D" 1 .m mmh .0 Hr N& L TI C s im UIF lll. 2 00 555 rlrltl [56] References Cited UNITED STATES PATENTS 7 Claims, 11 Drawing Figures SEALED EDGE CUTTING METHOD This is a continuation of application Ser. No. 834,641, filed June 19, I969, now abandoned.

This invention relates generally to methods and apparatus for forming a thermoplastic type selvage in a textile material and more particularly to methods and apparatus for continuously forming from a roll of material such items as diapers, handkerchiefs, etc., which are automatically sealed with a thermoplastic film and cut from the roll to provide sealed selvedges to prevent unraveling.

Prior to this invention it was known to heat seal a strip of thermoplastic material transverse to the longitudinal direction of a roll of fabric and cut such seal substantially in the center thereof to form individual sealed edge products. An example of such a machine is'shown in US. Pat. No. 3,385,747 wherein a roll of fabric is sealed in the weft direction. This machine takes single width fabric with woven selvedges in the warp direction and provides a product with only two sealed edges. Economically, it is desirable to take wide widths of fabric and seal longitudinal portions thereof and then sever the sealed portions substantially in the center thereof to provide a plurality of longitudinal extending sealed separated strips of fabric. These portions can then be automatically supplied to a machine which simultaneously transversely seals all the separated strips in the weftdirection and then simultaneously severs the separated strips substantially in the center of the transverse seals to provide a plurality of individual textile products with edges sealed to prevent unraveling of the selvedges. I

Therefore, it is an object of the invention to provide a method and apparatus which automatically provides a plurality of sealed edge products from a single width of fabric.

Another object of the invention is to provide a method of and apparatus to apply a thermoplastic material in the longitudinal and transverse direction of a fabric to prduce a produce which has all the edges thereof sealed.

Other objects and advantages will become readily apparent as the specification proceeds to describe the invention in which:

FIG. 1 is a schematic representation of the preferred method and apparatus to produce a sealed edge product;

FIGS. 2 and 3 show products produced by the apparatus shown in FIGS. 1 and 4; 7

FIG. 4 is a perspective blown-up view of the transverse sealing portion of the machine;

FIG. 5 is an enlarged end view of the apron system shown inFIG. 4;

FIG. 6 is an enlarged end view of the output nip rolls and conveyor shown in FIG. 4; and

FIGS. 7-11 show schematically the sequence of sealing and cutting the fabric.

In the preferred form of the invention sealed edge fabrics are being produced continuously from a roll of material. A roll of fabric of sufficient width to produce two of a desired product such as diapers, towels, etc., has a strip of thermoplastic film such as polyvinyl chloride, nylon-6, etc., heat sealed thereto in the longitudinal. direction of the fabric. Then the fabric is slit in the middle of the seal to provide two lengths of fabric and preferably supplied continuously to a machine which heats seals another strip of thermoplastic film across the whole width of each the lengths of fabric. As with the above-mentioned longitudinal seal, the film material can be polyvinyl chloride, nylon-6, or any other suitable material. Each of the lengths of fabric are then cut approximately in the center of the seal across the width thereof to provide a sealed edge product. Normally the longitudinal direction of the fabric is the warp direction and the width of the roll of fabric is the fill or weft direction.

FIG. 2 and 3 represent products obtained from the herein-disclosed invention. FIG. 2 shows a prduct 10 which has all four edges sealed with a thermoplastic seal 11. The product of FIG..3 is obtained when the roll of fabric slit longitudinally has a selvedge 12 finished on the loom so it is only necessary to provide thermoplastic seals 11 on three edges thereof.

Looking now to FIG. 1, the machine schematically represented shows an arrangement wherein one of each of the products of FIGS. 2 and 3 are obtained on each cycle of the machine. It is obvious that two products like FIGS. 2 or 3 can be obtained depending on Whether none, one or two of the selvedges of the roll of fabric 14 arefinished or hemmed prior to introduction into the machine.

In FIG. 1 the overall machine to produce the products of FIGS. 2 and 3 is schematically shown. The roll of fabric 14 to be sealed is supported on a dolly 16, the transverse position of which is controlled by a conventional edge guide device. Briefly, the edge guide device consists of a sensing element 18 which senses the edge of the fabric 14 and if the edge of the fabric 14 is not properly positioned a signal will be relayed to the control member 20 to move the dolly in one direction or the other. In the preferred form of the invention, the system employed is hydraulic and the dolly 16 is moved back and forth by a hydraulic piston. Such a system is a conventional and per se is not part of the invention.

In the preferred form of the invention, the fabric 14 passes under

idler rolls

22 and 24 into the nip of

feed rolls

26 and 28 from whence it is supplied under dancer roll 30 and idler roll 32 into the nip of sealing rolls, generally designated 34 and 36. Preferably, the

rolls

34 and 36 are driven at a speed slightly faster than the

nip rolls

26 and 28 in order to maintain a pre-determined tension in the fabric between the two pairs of rolls. Dancer roll 30 automatically controls the speed of roll 26 depending on the vertical position of the dancer roll in a manner such as that disclosed in US. Pat. No. 3,385,747.

As discussed briefly before, it is preferred to provide seals on the fabric made from suitable thermoplastic polymer film such as polyvinyl chlorine, nylon-6, etc. In the use of such films certain variables have to be taken into consideration such as the pressure exerted on the film-fabric sandwich in the sealing nip, the temperature of the hot surfaces of the nip, the temperature of the fabric entering the nip, the temperature of the film entering the nip, thickness and construction of the fabric, thickness and constituency of the film, the speed at which the fabric passes through, thetension 'of the fabric and the tension of the film entering the nip. Also it is felt that the temperature of the film in the hot nip must be at least at the softening point to allow the polymers to flow into the fabric. As an example the softening temperature of a 3.5 mil thick polyvinyl chloride plasticized polymer film is about 350F. To provide the best means to maintain such temperature it is felt that the temperature and speed of the fabric and film coming together at the nip of

rolls

34 and 36 should be controlled. If these variables are not controlled, various defects in the seal will occur depending on the type of variance. For example, if the film is not sufficiently warm, the flow into the fabric may be insufficient and poor seal adherence may result. If the fabric temperature is not sufficiently high, or if the hot surfaces of the pressure nip, are not at a sufficiently high temperature, the fabric and film will be quenched at some temperature below the softening point and again poor seal adherence will result. conversely, if the fbric temperature exceeds the desired temperature to an extent that the fabric becomes dehydrated discoloration of the fabric can result. In the use of polyvinyl chloride the film temperature prior to entering the nip must be such that it does not approach the softening temperature to prevent loss of dimensional stability and consequently the production of irregular seals. Further, the pressure at the nip has to be sufficient to cause the softened film to adequately penetrate the fabric.

It can be readily seen from the above that. certain conditions must be met once the fabric and film have been selected. As previously discussed, the fabric 14 is delivered from the nip rolls 26 and 28 to the nip of

roll members

34 and 36 at a pre-determined tension and speed. Depending on the speed selected the fabric can be pre-heated in the area of the longitudinal seal by pre-heaters 38 above and below the fabric. Pre-heaters 38, preferably, are infrared lamps which provide radiant energy for pre-heating of the fabric. Schematically shown are pneumatically actuated pistons 40 which are actuated by a fabric temperature sensing device, not shown, to actuate members 41 to open and close shutters on the pre-heaters 38 in response to the temperature sensed to control the heat supplied to the fabric. At slow fabric delivery speeds such as 12-14 yards/minute, pre-heaters 38 normally would not be actuated since the fabric has sufficient time to be heated by the hot portion of the

roll members

34 and 36.

Rolls members

34 and 36 consists of rubber covered carrier rolls 42 and cast iron heated rolls 44 and 45 to heat seal the film 46 into the fabric 14. Preferably, the cast iron rolls are heated by electrical cartridge heaters (not shown Cast iron rolls 44 and 45 are preferably treated with a release agent such as silicone to provide the hot roll surfaces with improved release properties. The number of cast iron rolls employed is dependent upon the number of longitudinal seals laid upon the fabric. In the preferred embodiment, since it is desired to lay down two seals 49 two pairs of cast iron rolls 44 and 45 employed. To provide controlled nip pressure to the

rolls

42, 44 and 45

yoke members

48 and 50 are pivotally secured at 52 and held in nip forming relationship with the lower rolls by the application of pressure from the pneumatically actuated cylinders 54. Semicircular fabric lifter members 56 actuated by pneumatically actuated cylinder 58 are provided to lift the fabric 14 off the lower hot rolls 44 when the

upper rolls

42 and 45 have been automatically pivoted away from the lower rolls when the machine is stopped.

The film 46 to be sealed to the fabric is provided in roll form on film carriers 60 mounted on the machine. Preferably, the carriers 60 contain more than one film roll 62 so that the application of film to the fabric can be continuous so that one roll of film can be automatically threaded up as another roll is running out. The

film 46 is supplied over an adjustable mounted roll 64 onto the hot surface of the upper hot roll 45 prior to entrance into the nip of the rolls 44. The amount of wrap of the film 46 around the upper roll 45 is dependent on the amount of pre-heat necessary for the film to be heated to a molten state without it losing its form or continuity and is a function fo roll speed, hot roll temperature and film properties. This amount of wrap is controlled by the position of the driven roll 64 relative to the peripheral surface of the upper hot roll 45.

As pointed out before, the lower roll member 34 is driven so that the fabric 14 is drawn into the nip of rolls 42, 44 and 45 s the molten film 46 is applied thereto and penetrates the fabric 14 due to the pressure between the upper and lower hot rolls 44. In the preferred form of the invention the fabric from the longitudinal sealing machine is supplied to another mechanism which also places a transverse seal upon the fabric but it is within the scope of the invention .to take up the fabric on a suitable take-up roll after it has been sealed longitudinally and cut. It has been found that when the fabric is supplied to a transverse sealing mechanism there is sufficient time for the longitudinal seal to set so additional cooling is not necessary since the production rate of the transverse sealing mechanism is comparatively slow. If it is desired to take up the fabric immediately after longitudinal sealing and cutting cooling cans or rolls should be used in order to set the seal before take-up.

As shown in FIG. 1 the fabric 14 with the longitudinal seals 49 thereon passes over a pair of fixed

bars

66 and 68 to a pair of

score cutters

70 and 72, the cutting pressure of which is controlled by

pneumatic pistons

74 and 76. As is well known in the art, score cutting, a cutting edge bearing on a hardened surface 78, has a squeezing type separation, which when applied to a still plastic seal forces the seal around the severed yarns. The fixed bars 66 and 68 tend to squeeze out and smooth out the surface of the longitudinal seal 48 so that the

cutters

70 and 72 do not pick up portions of the still tacky' seal. Thusly, it is an advantage to slit the longitudinal seals 49 by score cutting immediately downstream of the seal application zone because of easy registry of the cutter to the seal and quality of thesealed edge.

The tension is maintained on the fabric 14 after passage through the nip of

roll members

34 and 36 by a pair of nip rolls 78 and 80 driven at a speed slightly higher than the speed. of the

roll members

34 and 36. Nip rolls 78 and 80 and

roll members

34 and 36 preferably are driven continuously by the same motor as rolls 34. 36, 78 and 80 and the dancer roll 30 can then be eliminated since the dancer roll 82 which controls the speed of the above-mentioned in a manner similar to that disclosed in U.S. Pat. No. 3,385,747 will then also control the speed of rolls 26. and 28. Dancer roll 82 within a narrow range also acts as an accumulator since the transverse sealing mechanism operates intermittently while the longitudinal sealing portion of the machine operates continuously. The dancer roll 82, when the transverse sealing mechanism is not taking fabric, moves downwardly as the longitudinal sealing portion of the machine continues to supply longitudinally sealed fabric.

From the dancer roll 82 the longitudinally sealed fabric R4 is supplied under an idler roll 84 to the nip of the intermittenly driven input rolls 86 and 83 of the transverse sealing mechanism of the machine. The input nip rolls 86 and 88 and the output nip

rolls

90 and 92 are driven by pneumatically actuated piston 93 which, when actuated, pulls the chain 94 to the left against the bias of spring 96 torotate sprocket 98 which in turn through suitable mechanical linkage rotates the bottom rolls 86 and 90 a pre-determined distance in one direction only. The predetermined distance of rotation of the

rolls

86 and 90 determines the length of fabric between transverse seals and can be adjusted to obtain various length products by adjusting the stroke of the piston 93. Located under the fabric 14 between the input and output rolls is a continuously rotating apron system 100 for reasons hereinafter explained. To prevent the fabric 14 from engaging the upper surface of the apron system 100 when the fabric 14 is held between the nips of the input and output rolls the nip of the output rolls 90 and 92 is located slightly higher than the nip of the input rolls 86 and 88. To provide tension in the fabric between the input and output rolls the output rolls 90 and 929 are driven at a speed greater than the input rolls 86 and 88. This differential speed between the rolls also tends to keep wrinkles out of the fabric and expedites the passage of a cut product onto the endless conveyor I02.

Assuming for the sake of discussion and looking at FIGS. l and 7-11 the transverse sealing mechanism has been indexed to feed completed sealed products onto the conveyor I02 and fabric M is held between the nip rolls 86 and 88 and 90 and 92 (FIGS. 1 and 7). The fabric Mis now in the position to have a transverse seal placed thereon. When the fabric M has been moved to the positioin shown or just before the fabric reaches this position the piston 104 is actuated to advance a strip of film material from the roll of film 106 on the film feeding mechanism generally designated 108. The film feed and upper platen assembly 109 are identical to and operate in the same manner as that shown in US. Pat. No. 3,385,747 to place the strip of advanced film onto the fabric and heat seal same thereto. In other words, the upper platen H0 is actuated to a downward position onto the film material and fabric and cooperates with the lower platen 1112 to heat seal the film to the fabric (FIG. 8). Then the piston 10d is actuated in the opposite direction to pivot the film feed mechanism back to its original position and the upper platen is lifted up off the newly formed sealed fabric portion (FIG. 9). It should be noted at this point that upper platen 110 is fixed relative to lower platen 112 and that upper blade 116 is fixed relative to the lower blade ll8 so that when the platen support member 120 is pivoted the platens and blades move together. When the upper platen 110 is retracted the piston 122 is actuated to pivot the platen support member 120 to move the platens and blades counterclockwise to a position where the knife blades I16 and 118 are over and under the previously formed transverse seal (FIG. 10). Then the piston 124 is actuated to bring the upper knife I16 blade downwardly to cooperate with the lower knife blade 118 to sever the fabric 14 substantially in the center of the seal (FIG. 111). Then the upper blade 118 is retracted and the platen support member 120 pivoted back by the piston 122 to the position shown in FIGS. 1 and 7. When the platen support member 120 has returned or almost returned to the position shown in FIG. l, the piston 93 is actuated to rotate the

rolls

86 and 88 and rolls 90 and 92. Actuation of output rolls 90 and 92 causes the completed sealed edge products 10 to be delivered to the endless conveyor which deposits them in a suitable container or stacking device. As discussed before, apron system is driven continuously but does not contact the fabric ll l in the position shown in FIG. I but the fabric 114, when severed by the blades, will tend to drop onto the aprons. Then when the

rolls

86 and 88 are actuated the aprons will guide the fabric 14 into the nip of

rolls

90 and 92 for the next operation. Then the herein described operation is successively repeated to provide a plurality of scaled edge products.

Looking now to the drawings in more detail. FIGS. 4 and 5 show more specifically the traverse sealing mechanism. In FIG. 4 the piston 93 has been reversed for the sake of illustration and the upper plate is shown in the heat sealing position. When the upper platen 110 has been raised by the pistons 126 the platen support member will be pivoted to the dotted line position shown in FIG. 5 to move the lower cutting blade under the newly made seal and the upper blade over the newly made seal for the purpose of severing the fabric 14 substantially in the center of the seal to provide substantially equal seals on both of the severed edges.

As discussed briefly before, the fabric 14 is held between the input nip

rolls

86 and 88 and the output nip

rolls

90 and 92 so that the cutting; blades U6 and 118 are mounted in a fixed position relative to each other, thereby eliminating the necessity of synchronizing the blades on each cut. In other words the blades move relative to the fabric rather than the fabric moving relative to the blades. Since this movement is desired the bottom apron roll 186 is spring loaded by spring 130 (FIG. 5) so that the lever. arm I32 pivotally mounted at 134 exerts a downward bias on the roll 186 so that when apron roll 136 is moved rearwardly by the platen support 120 the apron roll 186 will cause the apron system 100 to assume the dotted line position shown in FIG. 5 to maintain tension on the aprons. It should be noted that a stop member, consisting of a U-shaped bracket 138 connected to platen support member 120, a bolt I40 projecting through an opening; 142 in the machine frame 144 and a pair of nuts 146 threaded onto the bolt on opposite sides of the opening, is employed to limit the pivotal movement of the platen support member 120 relative to the frame 144. Obviously, nuts 146 can be adjusted to vary the pivotal movement of the platen support member I20 relative to the frame 144.

The nip pressure between the input nip

rolls

86 and 88 is controlled by an air cylinder 148 and the nip pressure between the output rolls 90 and 92 is controlled by an air cylinder 150. Preferably, the input nip roll pressure is considerably greater than the output roll pressure to ensure a positive feed of the fabric when in dexed. The output nip roll pressure under normal conditions is only high enough to take the wrinkles of the fabric without excessively increasing the tension therein.

The herein disclosed apparatus. and method efficiently and automatically provides a roll of material with a longitudinal seal and a transverse seal and delivers a textile product which has all the edges sealed to prevent unraveling. The novel disclosed machine also provides a transverse sealing and cutting mechanism which eliminates the problem of synchronizing the cutter blades on each cycle since the cutter blades are fixed relative to each other and more as a unit relative to the fabric which is not moved during the sealing and cutting portion of the cycle.

Although the preferred embodiments of the invention have been described in detail, it is contemplated that many changes may be made without departing from the scope or spirit of the invention and it is desired to be limited only by the claims.

That which is claimed is:

1. A method to produce a sealed edge product comprising the steps of: providing a supply of textile material, putting a pre-selected length of material under tension in a pre-determined fixed position, placing a thermoplastic strip of material across the width of said textile material, applying heat and pressure to said thermoplastic strip of material to seal said thermoplastic strip to said textile material, moving a cutting means into registry with said thermoplastic seal while holding said textile material in said pre-determined fixed position, actuating said cutting means to sever said textile material through said thermoplastic seal, moving the severed textile material to a point of collection while putting another length of textile material in said predetermined position under tension and successively repeating the steps to provide successive textile material segments with the edges sealed across the width thereof.

2. The method of claim 1 wherein said textile material is automatically and continuously supplied from a roll of material.

3. The method of claim 1 wherein said thermoplastic seal is severed insubstantially the center thereof.

4. The method of claim 1 wherein said supply of textile material is sealed and severed longitudinally prior to sealing and severing across the width thereof.

5. The method of claim 4 wherein said textile material is sealed and severed across the width thereof while being maintained integral with the supply of material.

6. The method of claim 4 wherein said method is automatic and continuous.

7. The method of claim 6 wherein said seals are severed substantially in the center thereof.

UNTTTn STATES PATENT CERTIFECATE @F QQ RREQTION Patent No. 3,856,599 I Dated December 24, 1974 Inventor(s) D Bylund It is certified that error appears in the above-identified patent and that said Letters Patent are hereby corrected as shown below:

Column 1, line 40, the words "prduce a produce should read --produce a. produCt-.

Column 1, line 67, the word "heats" Should read --heat-.

Column 2 line 11, the word "prduct" should read --product--.

Column 2, lines 63 and 64, the word "polymers" should read --polymer--,

Column 3, line 12, the word 'conversely" should read --Conversely-- Column 3, line 12, the word "fbric should read --f abric--. Column 3, line 41, the word "Rolls" should read --Roll--. Column 3, line 52, after numeral "45" add --are--.

Column 4, line 1, the word "adjustable" should read --adjustably--. Column 4, line 7, the word "fo" should read -of--.

Column 4, line 13, the letter "s" should read --as--.

Column 4, line 51, "34." should be --34,--.

Column 5, line 20, numeral "929" should be --92--.

Column 5, line 32, the word "positioin" should read --poS'1'.ti0n--. Column 6, line 15, the word "plate" should read -platen--. Column 6, line 53, after the word "output" add --nip-.

Column 6, line 67, the word "more" should read --move-.

Signed and sealed this 11th day of March 1975..

(SEAL) Attest:

C. MARSHALL DANN RUTH C. MASON Commissioner of Patents Attesting Officer and Trademarks

Claims

1. A method to produce a sealed edge product comprising the steps of: providing a supply of textile material, putting a preselected length of material under tension in a pre-determined fixed position, placing a thermoplastic strip of material across the width of said textile material, applying heat and pressure to said thermoplastic strip of material to seal said thermoplastic strip to said textile material, moving a cutting means into registry with said thermoplastic seal while holding said textile material in said pre-determined fixed position, actuating said cutting means to sever said textile material through said thermoplastic seal, moving the severed textile material to a point of collection while putting another length of textile material in said pre-determined position under tension and successively repeating the steps to provide successive textile material segments with the edges sealed across the width thereof.

3. The method of claim 1 wherein said thermoplastic seal is severed in substantially the center thereof.

6. The method of claim 4 wherein said method is automatic and continuous.