CA2079365C

CA2079365C - Check valve for fluid bladders

Info

Publication number: CA2079365C
Application number: CA 2079365
Authority: CA
Inventors: Robert W. Pekar
Original assignee: Dielectrics Industries Inc
Current assignee: Dielectrics Industries Inc
Priority date: 1991-09-30
Filing date: 1992-09-29
Publication date: 2002-07-30
Anticipated expiration: 2012-09-29
Also published as: CA2079365A1; EP0535904B1; DE69213377D1; DE69213377T2; JP3276999B2; AU658904B2; US5144708A; KR930006352A; JPH05240362A; KR100243442B1; EP0535904A1; AU2043392A

Abstract

A check valve provides a one-way fluid passage from without to within a fluid bladder formed by a pair of plastic sheets sealed together about their periphery. The check valve is formed by a pair of superimposed films of thermo-plastic material, generally equal in length, thermally bonded together at predetermined areas to define the fluid passage throughout the length of the valve. Each of the films, adjacent one end thereof, is sealed to one of the outer sheets where the valve enters the bladder by a seal line of wedge shape. Each of the films has a high-gloss, cohesive inner surface and a matte, non-cohesive, outer surface. At least one of the films includes, on its inner surface, a release material disposed at a location which corresponds to the area at the inlet end of the fluid passage through the peripheral seal of the bladder to prevent the fusing together of the films at that area of the seal. The seal in that area has a V-shape with apex pointing in a direction opposite the one-way fluid flow. The terminal ends of the superimposed films extend in surface-to-surface relation-into the bladder to provide a "duck-bill" type check valve.

Description

JJD:pak CHECK VALVE FOR FLUID BLADDERS
BACKGROUND OF THE INVENTION
This invention relates to check valves associated with fluid chambers or inflatable bladders and, more particularly, such valves as are formed of thermoplastic film material and which are adapted to be used in combination with a fluid pump or other bladder inflation device.
U.S. Patent No. 3,133,696 to Mirando, discloses a plastic foam pump in an air-tight bladder for inflating the bladder and includes a flapper type inlet check valve 23 and duck-bill type outlet check valve 22.
U.S. Patent No. 3,583,008 to Edwards, discloses a bulb-shaped, self-contained pump 36 connected to each of the inflatable compartments of an air mattress. The bulb relies upon a U-shaped spring and a coil spring 54 to expand the bulb after it has been compressed in each stroke of the pump.

~E~'~'i U. S. Patent No. 4,674,532 to Koyanagi, discloses a check valve for a balloon formed of a plurality of plastic film, including a pipe and at least one valve body formed as a pouch, laterally closed at one end.
U. S, Patent No. 4,917,646 to Kieves, discloses a self-sealing air valve for a balloon formed by two sheets of plastic. One of. the sheets is of substantially greater length than the other to provide a tab 62 for securing the valve in the stem of the balloon. The sheets are fitted together in such a waj- as to form an offset section 74 or throat .
It is the princip~.l object of this invention to pro-vide a wholly thermoalastic check valve and inflatable bladder combination of simpler, less inexpensive and more compact construction t~:an the valves disclosed in the prior art and can be used for liquids as well as gases while, at the same time, being reliab'e in operation.
It is another object of this invention to provide a check valve of the above type which, because of its soft and pliable construction, lends itself to ease o~ co-assembly in various types of inflatable~bladder applications.
It is a further abject of this invention to provide a combination check valve and fluid pump of very low pro-a S ~ ~1 n ;~~
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file, especially adapted to be used in inflatable body sup-port applications such as, inflatable athletic shoe liners, medical splints, intravenous needle holders for pediatric applications, athletic gloves, brassieres, back support belts and the like where compactness, flexability, comfort, convenience, durability and reliability are important.
It is still a further object of this invention to provide a check valve to prevent very high "spike" pres-sures from bleeding fluid from one bladder chamber to another chamber, The above and other objects and advantages of this invention will be more readily apparent from the following description read in conjunction with the accompanying drawings in which:
Fig. 1 is a perspective view of a thermoplastic valued, fluid pump and inflatable bladder combination of the type embodying this invention;
Fig. 2 is a section taken along line 2-2 of Fig. Z;
Fig. 3 is a section taken along line 3-3 of Fig. 1;
Fig. 4 is an exploded perspective view illustrative of the method of fabrication of the pump and bladder com-bination of Fig. 1;

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kid. S is ti pozsl~oct:ive v2ow illustzating one step in the metlzod o~ pre~ormir>.b tl~e outlet check valve o~ the pump;
I~ig. G is a perspective view which depicts one problem overcome by ~..e tnGthud embodying this invention;
I~igs. 7-13 are hez-spective views wlzich depict Che preferred method oL fabricating plastic. check valves embodying this invention;
hig. 9 is a 1~1~.11 View ShOwl.rlg the clleCk valve o~
Pig. 8 associated rrith a Cluid bladder; and r~ ig . 1.U is a ~ragmernl.a:ry enlarged plan view of a det~a:i:1 staown :iti 1':i.c~.
A clxeck valve embradying this invention is s110Wn gen°
eral7,y at 3U izz Pigs. ~., 3 and 4 and is illustrated in com°
bina'I:iOIl w1t11 fluid purup G, including one fluid clzamber a, which may be a puuipi.y chamber, an inflatable bladder, ar second chamber 10, and a push-'uutton type exhaust valve 12.
It v,~,'~,'.1 be recol;ui.zed l:hat the check valve 'i0 may be used for providing one-way bas or liquid, hereinafter referred to as "fluid", flow into any type of inflatable bladder or betireen separate fluid chambers, especially wl>.ere it may be important to prevent Cluid bleeding from one chamber to another chamber as a result a~ a fluid pressure sl~i.ke occurring in tlxe one chamber . Such shilce pressures would, for example, likely be encountered in athletic shoe fluid -S- , , .
bladder applications where the foot impacts upon the sole chamber of the fluid bladders while, at the same time, much lower pressure would exist in one of the upper chambers of the fluid bladder.
The pump 6 comprises _n inner core of reticulated, open-cell elastomeric foam 14 encapsulated between two outer layers of superimposed, thermoplastic sheet material 16 and 18. The two sheets are adapted to be fused, bonded ox sealed together about their peripheral edges, as indi-cated at 20 in Fig. l, by heat-sealing, or radio°frequency (R. F.) energy technique, to form the inflatable bladder.
At the same time, seal ~1 also fuses the sheets together about the perimeter of the foam body 14, thereby forming the pumping chamber 8. The pump 6 may be of any suitable configuration, depending upon the application to which the pump will be adapted.
It is essential that the foam 14 consist of t:.~ open-cell, reticulated and resiliently flexible elastomeric material, such as a polyurethane foam having an uncompressed thickness of about one-half to one inch and volume of about one-half to one cubic inch. The upper sheet 16; best shown in Figs. 1 and 4, is provided caith two holes 22 and 24.
The former serves as an inlet check valve, while the hole 24 serves to receive therethrough the stem portion 2S of _ c- n r e~ c~ ~a 6 ~il ~zj~~e3 the exhaust valve 12. The elastomeric foam body 14 may be cubical, as shown in Fig. 1, or may be of cylindrical con-figuration with a circular outer periphery and is pre-ferably a reticulated, open-cell polyurethane foam which has 10 to 50 pores per inch and ~;iy be o~ any suitable size 9 and shape, depending upon the application. A 1-inch cube of such foam of .5 to 1-inch in thickness, or a cylinder of 1-inch in diameter by .5 to 1-inch in thickness, have been found to operate in a highly satisfactory manner. In any event, the open-cell foa;n is sealed within the pumping chamber of the device, except for hole 22 and the fluid passage provided by a check valve 30 (Figs, l, 3 and 4).
The check valve 30 is adapted to extend from without to within the inflatable bladder 10 through the peripheral seal line 21 and, as shov~n in Fig. 1, may extend from pump chamber 8 into the inflatable chamber 10. The check valve 30 is of the "duck-bill" variety which provides for one-way fluid flow to chamber 10 from the high pressure chamber 8 defined by the ~oam 1.~, upper and lower sheets 16 and 18 and the peripheral seals 20 aild 21. The valve 30 consists essentially ef two superposed layers of heat-sealable plastic film 32 and 3~ sealed together along laterally-spaced zones of their side edges, as at 36, so as to define a central channel 38 which serves for the one-way fluid ~, <, ~, ."
flow from the pumping chambex 8 into the fluid bladder 10.
The outer layers 16 and 18 may be thermoplastic sheet material, such as polyurethane or polyvinylchloride which may range in thickness from about .005 to .05O inch. The inner layers 32 and 34 consist of plastic files in the range of .001 to .015-inch in thickness, a subsantially lesser guage than that of the outer layers 16 and 18. The films 32 and 34 are preferably formed as the same material as the outer layers.
It is essential chat the channel 38 remain "open"
from the chamber 8 to the chamber 10 through the area of the seal 21 along the perimeter of the foam, despite the fact that the outer surfaces of the plastic films 32 and 34 are simultaneously sealed to the inner surfaces of the upper and lower.sheets to and 18. This unsealed area or zone is provided by~ a bar rier material or coating 40 dis-posed between the opposed inner surfaces of the films 32 and 34, as shown in Fios. 3 and 4. The barrier material 40 is preferably applied to opposed areas on both films and is of sufficient area and thickness to prevent heat or R.F.
energy sealing together of the so-coated area of the films 32 and 34 when the sealing of sheets 16 and 18 is being carried out in the assembly process to form the two fluid chambers 8 and 10. Such sealing is prevented even though _g_ those areas of the films are disposed in abutting relationship and subjected to sufficient energy so that the outer surfaces of the films will be sealed to the inner surfaces of the bladder.
The one-way check valve 30 is biased "open" at one end by the sheets 16 and 18 and by the adjacent edge of foam 14 while the other ends of the films, disposed within the bladder, have an inherent tendency to remain in intimate surface-to-surface contact because of the construction of the valve and texture of the films.
The barrier coating 40 may be applied by conventional printing techniques, such as silk screening, rotogravure or flexographic process. Preferably, the coating is applied as a composition in a liquid dispersion medium of an organic solvent or water base with a dispersed phase of finely divided microscopic particles, on the order of five (5) microns in diameter, of a polyethylene, a polytetrafluoroethylene (Teflon') or silicone. It is essential, in any case, that the dispersion medium selected be one that which will condition the surface of the plastic film to cause the microscopic particles to adhere, or be anchored to the surface of the film, to prevent heat-sealing at the coated area of the two plastic films 32 and 34.
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As best shown in Fig, 7, a thermoplastic film 60 used to fabricate the layers of film 32 and 34 which make up the valve 30, has a high gloss, cohesive surface S4 on one side and on the opposite side, a dull or matte surface 55. These surface characteristics of the film are important since they contribute to the one-way flow characteristics of the valve 30. In that connection, the inner surfaces of the films, when placed in contact, will exhibit substantial cohesion, blocking or surface-to-surface affinity which results in the two layers having a marked tendency to stick together. While usually considered a drawback, this property is utilized so, that the channel 38 of the valve 30 will remain closed unless pressurized fluid is flowing through the channel from outside the bladder 10. As soon as the incoming fluid ceases to flow, 'the channel 38 will, because of its internal blocking characteristic, close and be held closed by the fluid pressure within the bladder 10. Con-vers°ly, the matte outer surfaces 55 0.r the films are essentially non-adherent to the inner surfaces 56 of the outer layers 16 and 18 which form the bladder 10 whereby there will be no tendency to compete with the inherent surface-to-surface affinity of the inner glossy surfaces.
It is another preferred feature of the invention that the portion of the sealing area corresponding to the p;~~~,s,.,p..
3u r.~ 5.~ il location at which the valve and sheets 16 and 18 of the bladder 10 are fused together, and as illustrated in Fig. 9, is preferably in the form of a chevron or V-shape S8 with the apex of the "V" disposed in a direction toward the pump 8, or the inlet end of the valve. This seal configuration , facilitates the opening of channel 38 should there be inci-dental sticking together of the release layers in the seal area which may occur before the first use of the valve.
Because of the V-shape seal 58, pressurized fluid entering the channel 38 will initially contact the apex of the chevron seal SS and, in effect, start to open-up or peel apart any incidental fusion in the seal area. Once the fluid pressure has opened a narrow channel through the apex of the seal 58, the opening will rapidly expand across the full width of the chevron seal. This action is similar to removing an adhesive strip from another surface by first peeling up a corner of th a strip. The valve sealed in this manner will thereby permit easy fluid flow thr~.7;;fg h the channel 38 and into the bladder, despite the fact that prior to first using the valve, there may have been some sticking together at the inlet end thereof.
The outlet check valve 30 embodying this invention, is a subassembly which is preformed in a separate operation by sealing two plastic films disposed in superposed edge-9 t ~ 'J ::9 to-edge relation, as shown in Fig. 5. The films 32 and 34 placed on platen 5S are sealed along their side edges 36 by die 53 having a filled non-heating center portion 52 and a pair of edge sealing portions 54. This construction pre-vents the formation of extrusion beads 56 Fig. 6), such as 1 would be formed along the side edges of a channel 60 between such films edge-sealed together as a result of using a con-ventional die and could provide escape channels for the high pressure fluid in the bladder. It is important to avoid the formation of such beads, because otherwise the glossy sides of the two films would not, after each compression stroke of the pump, resume their intimate surface-to-surface contact to block effectively the reverse flow of fluid from the bladder to the pumping chamber. Once closed, fluid pressure in the bladder 10 will act to hold the channel 38 closed.
Figs. 7 and 8 show the preferred method of manufac-turing the valve 30. In Fig. 7, is shown a film 60 adapted for fitting onto a fixture having registration pins (not shown) disposed to extend through holes 61 in the film which is placed with its glossy side 54 facing upwardly.
The glossy side of the film 60 may be coated at a plurality of spaced locations with rectangular strips or patches 40' of release material. Each patch has a length ,~ approxi-'a -lz" ~a~~~z3aic~
mately 1/2 inch which is twice that of the 1/4 inch length of the release coating used in each valve 30 and a width w equal to or preferably somewhat greater than the spacing between adjacent seal lines 36 to ensure that the inlet end of the valve will remain open. After coatinu, the film 60 i may be folded along a crease line 62 so that each release patch 40', on one side of fold line 62, will be disposed in registered superposed relationship with each patch on the other side, as depicted in Fig. 8. The two layers of film are then sealed together along a plurality of parallel seal lines 36' using a die of the type shown in Fig. 5, but which has multiple sealing heads. Seal bands 36' are laterally spaced apart a distance approximately equal to or slightly less than the width of the strips 40' to form a fluid flow channel 38 therebetween, as depicted in Figs, 8 and 9. After sealing, a cutting die may be used to sever the two layers along mutually perpendicular lines. As at 63, the release striry :~0' on the superposed film layers are bisected and other cutting edges will cut the films, as at 65, a distance spaced approximately one-inch from the bisected edge. At the same time, the two layers are cut transversely, as at 67, thereby forming a plurality of discrete rectangular valves 30, which for the illustrated embodiment, would be sixteen in number. The die may also include means to cutout registration holes 69 and 70 for " 13 - ~ ~l ~~ ';,'. .., ., ,, ,~ :l ~% ~e~
use in positioning each of the valves 30 when fabricating the bladder and valve assembly (Fig. 9) and for cutting off the outer edge portions of the films along line 71 (Fig. 7).
It has been found that in applications where a valve 30 is sealed in a narrow throat portion of a bladder, as depicted in Fig. 9, the bladder, when inflated, will have a tendency to separate the face-to-face, planar contact of the valve films 32 and 34 in the channel area 38. In such applications, leakage problems have been encountered in approximately two percent (20) of such valves. To overcome this problem, the valve forming die may include means to longitudinally sever or slit the outer end portions of the sealed areas 36 of the valve, as illustrated at 75 in the enlarged section of cig. 9. It is important that the inner end of the slits 75 be spaced from the inner end of the release material 40, extend to the outlet end of the valve and be located approximately one-half the width of the sealed areas. By this simple slitting step, the outlet end portions of the valves will remain free-floating and not be adversely affected by the inflation of the bladder. The slitting of the sealed areas of valves 30, as at 75, has resulted in such failures being reduced by approximately seventy-five percent (75Q).
Accordingly, each valve consists essentially of two layers of plastic film, eaclx coated with a release layers .I c_ s: =.i J
40 of one-half the length of patches 40' and which extend exactly to the inlet edge of the valve. This precise result is assured because the bisected edges, per se, define the inlet ends of the valves. Thus, when the plastic valve is being sealed to the outer layers 16 and I8 of the bladder, as heretofore described, there will be no sealing of the valve channel 38 beyond the outer end of the release material 40. Moreaver, as shown in Fig. 9, the fluid flow channel 38, measured from the inner edge 77 of the release coating 40, should be on the order of 3/8 to 1/2 inch, but not less than 3/16 inch for effective one-way flow. From edge 77, the channel :,3 is preferably of generally uniform cross-section throughout its length. In addition to the channels 38 and the release material 40, each valve is die cut and includes an e:;tension along one side thereof with one or more registration holes 69 and 70 for use in fixing the position of the valve by using registration pins when sealing within a bladder, or bladder ;:~d pump combination, as depicted in Pig. 9.
The exhaust valve 12 includes a tubular base 4Z with a circular flange 44 of plastic material heat°sealable about the periphery of the hole 24 through sheet 16. The valve also includes reciprocally movable stem 2S and a coil spring 46 disposed about the stem, thereby biasing the valve stem to a normally "closed" position. By pressing the stem 25 downwardly, fluid will be exhausted from the bladder when not in use.
Among the advantages of this combination of a fluid bladder and check valve 30 a.~ its adapability for ease of assembly, as illustrated in Fig. .4. A sheet 18 is first laid on the platen 50 of a heat-sealing die and a foam block 14 and check valve 30 are placed in juxtaposition on the upper surface of the sheet 18. An upper sheet 16 with exhaust valve 12, having been fitted into and sealed to the surrounding edge of the hole 24, is superimposed in edge-to-edge relation over the sheet 18 with the foam block 14 and the check valve 30 interposed therebetween. A heat-sealing die (not shown) of suitable configuration is then lowered to seal together the sheets 16 and 18 about their marginal edges and about the perimeter of the foam block 14 to form the pumping chamber 8 and air bladdAr 10. As a consequence, the fluid bladder, inlet valve, outlet valve, and exhaust valve are all integrated or united in a single sealing operation, thereby forming on the valued unit of flexible, inexpensive, adaptable and reliable construction, OPERATION
In operation, it is only necessary for the user to place a finger or thumb over the fluid hole 22 provided in -16°
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the upper sheet 16 and alternately depress and release the finger pressure an the elastomeric foam a sufficient number of pulsations until the bladder 10 is properly inflated.
In this pumping action, the inlet valve is automatically opens and closes in response to the ~.ec~uential application of the finger aver the hole during the compression and expansion of the foam. When opening 22 is uncovered, ambient fluid is drawn through the hole 22 and fills the open cells of the foam as it expands. During the pressure stroke, the fluid is expelled from the foam and flows through the channel 38 of the check valve 30 which closes after each compression stroke. When the thumb is removed from the hole, the flui3 once again enters the pumping chamber. Should any spike pressures occur in chamber 10, the check valve 30 would block the flow of fluid into chamber 8. To deflate the bladder, such as in an athletic shoe liner or the like, it is merely necessary to depress the stem of w~.ive 12 and fluid will be released frowns the bladder when no longer in use.

Claims

1. Combination of a check valve and inflatable bladder defined by upper and lower sheets of synthetic plastic material having a seal forming one and another fluid chamber with a fluid passage therebetween, the check valve comprises two layers of plastic film of generally the same length which are sealed together at their side edges and to opposed inner surfaces of the sheets in said passage and having a channel throughout the length thereof for permitting the one-way flow of fluid from the one chamber of the bladder into the other chamber thereof, each of said layers being characterized by a matte non-blocking outer surface and a glossy inner surface having a blocking tendency, a barrier material disposed between said film to prevent the heat-sealing together of the film layers at the location where the check valve extends through the seal between said two sheets.

2. Combination of a check valve and inflatable bladder, as set forth in claim 1, in which said sheets and film are composed of the same thermoplastic material, said film material is of a thickness in the range of 0.001 to 0.015 inch and said barrier material is applied to at least one of said films as a coating.

3. Combination air pump and inflatable bladder comprising an open-cell, elastomeric foam disposed between an upper and a lower sheet of synthetic plastic material sealed about the periphery thereof and the perimeter of the foam form both a pumping chamber and the inflatable fluid bladder, the foam being inherently compressible and expansible to absorb and expel air from cells thereof, an inlet valve into the pumping chamber provided by a hole through one of the plastic sheets opening at generally the central portion of the foam, an outlet check valve extending through the perimeter seal of the foam communicating with the interior of the inflatable bladder, the outlet check valve comprises two layers of plastic film sealed together at their side edges and to opposed inner surfaces of the sheets and having a channel for permitting the one-way flow of air from the pumping chamber into the bladder contiguous thereto, each of said layers being characterized by a matte non-blocking outer surface and a glossy inner surface having a blocking tendency, a barrier material disposed between said film to prevent the heat-sealing together of the film layers at the location where the check valve extends through said perimeter seal.

4. A synthetic plastic check valve having an inlet end and outlet end for an inflatable bladder formed by upper and lower sheets of synthetic plastic material fused together by a peripheral seal, the check valve comprising two layers of plastic film sealed together in superposed, edge-to-edge relation to form a fluid flow channel therebetween, the inner surfaces of said layers of film being high gloss, cohesive surfaces, each of said layers being characterized by a matte non-blocking outer surface, said layers of film being of sufficient length to extend through said peripheral seal from without to within said bladder and having their outer surfaces, adjacent the inlet end of said valve, fused to the inner surfaces of said sheets, a release material interposed between said films at the inlet end of said valve and being of sufficient extent to prevent sealing together at that location.

5. A synthetic plastic check valve, as set forth in claim 4, in which the length of the fluid flow channel from the inner edge of said release material is of generally uniform cross-section.

6. A synthetic plastic check valve, as set forth in claim 5, in which the said length of the fluid flow channel from the inner edge of said release material is at least 3/8 inch.

7. A synthetic plastic check valve having an inlet end and outlet end for an inflatable bladder formed by upper and lower sheets of synthetic plastic material fused together by a peripheral seal, the check valve comprising two layers of plastic film sealed together in superposed, edge-to-edge relation to form a fluid flow channel therebetween, the inner surfaces of said layers of film being high gloss, cohesive surfaces, said layers being of sufficient length to extend through said peripheral seal from without to within said bladder and having their outer surfaces, adjacent the inlet end of the valve, fused to the inner surfaces of said sheets, the portion of said peripheral seal, which traverses the fluid channel of the valve having a generally V-shape with the apex end thereof disposed toward said inlet-end, and a release material interposed between said films at the inlet end of said valve and being of sufficient extent to prevent sealing together at that location.

8. A synthetic plastic check valve having an inlet end and outlet end for an inflatable bladder formed by upper and lower sheets of synthetic plastic material fused together by a peripheral seal, the check valve comprising two layers of plastic film sealed together in superposed, edge-to-edge relation to form a fluid flow channel therebetween, the sealed areas of the superposed plastic films, which define said fluid flow channel, each include a longitudinal slit disposed intermediate the width of the sealed area of the valve and at the outlet end of said valve, the inner surfaces of said layers of film being high gloss, cohesive surfaces, each of said layers being characterized by a matte non-blocking outer surface, said layers of film being of sufficient length to extend through said peripheral seal from without to within said bladder and having their outer surfaces, adjacent the inlet end of the valve, fused to the inner surfaces of said sheets, a release material interposed between said films at the inlet end of said valve and being of sufficient extent to prevent sealing together at that location.