USRE28563E

USRE28563E - Method for fabrication of plastic footwear

Info

Publication number: USRE28563E
Authority: US
Priority date: 1962-11-13
Filing date: 1973-11-27
Publication date: 1975-09-30

Abstract

A method for manufacturing slippers comprising forming an elongated foot opening in a first sheet of a synthetic polymeric sheeting material; then bringing the first sheet together with a second sheet of synthetic polymeric sheeting material in face-toface relationship; exerting firm pressure on the exposed faces of the sheet in at least one narrow region surrounding the foot opening; raising the temperature of the sheets within the region to unite the sheets with one another within the region; and separating a slipper from the material lying outside of the region.

Description

United States Patent 1191 Mitchell et a1.

[ METHOD FOR FABRICATION OF PLASTIC FOOTWEAR [76] Inventors: Winalee G. Mitchell; James G.

Mitchell, both of 26920 W. River Road, Perrysburg, Ohio 43551 [22] Filed: Nov. 27, 1973 [21] Appl. No.: 419,462

Related U.S. Patent Documents Reissue of:

[64] Patent No.: 3,238,079

Issued: Mar. 1, 1966 Appl. No.: 236,882 Filed: Nov. 13, 1962 [52] U.S. Cl. 156/252; 12/142 R [51] Int. CI. B32B 31/00; A43D 9/00 [58] Field of Search 156/250-253, 156/258, 263, 264, 265, 267; 12/142 R, 142 E, 142 EV [56] References Cited UNITED STATES PATENTS 637,136 11/1899 Lemrnermann 156/251 1,388,762 8/1921 Riley 156/251 1,830,471 11/193] Le Dorf t 1 36/10 Reiss ued Sept. 30, 1975 2,002,527 5/1935 Dorogi et al 1. 156 251 2,076,079 4/1937 Gammeter 156/251 2,153,351 4/1939 Steinberger.. 156/251 2,288,199 6/1942 Levy ..36/10 3,026,233 3/1962 SchoII et a1. 156/251 3,149,355 9/1964 Greene 156;12/251;142 R FOREIGN PATENTS OR APPLICATIONS 129,014 4/1932 Austria 156 251 Primary Examiner-Douglas J. Drummond Attorney, Agent, or Firm-Robert R. Priddy; Burton A. Amernick [57] ABSTRACT A method for manufacturing slippers comprising forming an elongated foot opening in a first sheet of a synthetic polymeric sheeting material; then bringing the first sheet together with a second sheet of synthetic polymeric sheeting material in face-to-fac'e relationship; exerting firm pressure on the exposed faces of the sheet in at least one narrow region surrounding the foot opening; raising the temperature of the sheets within the region to unite the sheets with one another within the region; and separating a, slipper from the material lying outside of the region.

34 Claims, 11 Drawing Figures Reis sued Sept. 30,1975 Sheet 1 of 3 Re. 28,563

FIGZ

FIGS

7| 5 5s s9 E 52 z z) z z 1/ 66 2 8| g 8| 75 39 5 77 5a \51 I 77 64 4a 7 67 E 8 i 4 3 7 r IN VEN TORS ao WINALEE e. MITCHELL I z JAMES 5. MITCHELL 53 53 53 BY 0 Q w FIG. 9

THEIR AGENT Reissued Sept. 30,1975

Sheet 2 0f 3 Re. 28,563

FIG.4

INVENTORS WINALEE G MITCHELL JAMES G. MITCHELL THEIR AGENT Raissued Sept. 30,1975 Sheet 3 of3 Re. 28,563

m L m FIG 5 INVENTORS WINALEE G- MITCHELL JAMES G.- MITCHELL BYQLM GZQMZ/ THEIR Matter enclosed in hea'vybrackets appears in the original patent but forms no part of this reissue specification; matter printed in italics indicates thqadditions made by reissue.

There appears be :no widespread availability of I disposable" footwear at present, despitethe many advantages which can be realized from the use of such footwear. This is indeed :unfortunate, since persons often find themselves in situations in which conventional foot apparel offers something less than idea comfort or utility.. a i Some early attempts were made at fabricating crude foot'coverings of paper for use in public places where people commonly go barefoot, such as in the lockerroom areas of public swimming pools, for example. These attempts, however, met with little success, due to the well-known effectsof water on paper. The advent of plastic material in cellular and non-cellular sheets made available a water-resistant substitute for paper. in view of the availability of better demonstrable and the demonost'rable benefits to be obtained through the utilization of strong sanitary plastic footwear, it may seem surprising that such footwe ar has not become a standard household item, i

One explanation for' this rather surprising'state of affairs is an apparently co'mplete'la'ck of knowledge as to how these new materials should'be employed in the fulfillment of the need for products of this type. Should the article be made from a single piece of material or from several? How should the one or morepieces be shaped to produce'an article that will not tear or split apart prematurely? What methods should be used for manufacturing such articles? Clearly, there is an existing need for strong, sanitary and inexpensive footwear and for efficient methods of making such footwear.

It is a principal object of this invention to'fill this need. Other objects and advantages of the invention are discernible from the following description of preferred embodiments of the novel footwear and method of the present invention. The invention will 'be 'described in conjunction with the accompanying draw J als having cells tructure polyurethane foam, a poly- FIGS. 6, l0 and 11 are fragmentary views of the material under treatment in the FIG. 5 method.

FIGS. 7 and 8 are plan views of parts of the apparatus shown in FIG. 5, the sectionlines in these figures indieating the plane through which the:- FIG: 5 view is taken.

FIG..9 is an enlarged'sectional 'detailed 'view of parts m'eric material which is ordinarilyproduced by blowirig a polyester resin with the aid of a diisocyanate compound. i l I i The. upper andlower should have similar shapes, preferably the same shape. That shape should conform closely enough toithat of the human foot so that the elasticity of the material will be sufficient to compen sate for differences between'theoutline of the slipper and that of the foot, if any. ln this embodiment, an ir regular oval shape used because it will fit either the left or right foot eciually well. I

The upper 20 and lower 21 lie one on top of the other and are joined to one another about their peripheries along aseam 22. It should be noted that this seam will be hidden fromview to a substantial extent when the slipper is turned inside out. I

Any effectivernethod ofjoinder can be utilized. Sew

ing, cementing, thermal sealing and induction sealing.

are a fewexamples. Wi th polyurethane foams, we prefer to use .the thermal sealing method, which will be explained further below. i V I As can be seen in FIG. 1, the slipper disclosed herein has a foot-opening 23. in the upper, a rounded front edge 24, two side edges 25 and 26 diverging from one another towards the heel of the slipper and meeting in a rounded trailing edge 27.

Although thereis no intention to limit the invention to slippers of particular dimensions, some dimensions willbe giyen for illustrative purposeslna mans large 7 (sizes 10-12) .slippergorresponding in shape to then FIGS-1-3 embodiment, havinga lower of stretchy onefourth inch thick polyurethanefoam and an upper of the same material three-sixteenths inch thick, the overall length. of the slipper is about 10 inches; width, aboutv 4ii1ches; length, of the foot. opening about 4%inches- (set back 3 inches from the toe),-th e foot opening-haw.

gentially .withsaid front and rear-ends. It is possible to ,vary the above. radii, widths, lengths and set back 1 within agiven foot size to:whatever extent is desired, I so long asthe' final productwill serve its intended pur pose. Obviouslythese dimensions will also vary widely throughout the range of sizes'needed to fit the feet of any child or adult. Therefore, the above dimensions are notto be construed aslir'niting the invention in any sense, but only as an'illustration of 'aisingle embodiment thereof; i

We have discovered some novel methods use'ful'for making a-widevariety ofslippersfThey will be illustrated in connection with the fabrication of two differv ent'slippers. 1

Generally speaking, the first method we have invented involves a series of steps, including; forming a footopening in a first sheet of plastic material; bringing said first sheet and a second sheet of said material into face to face contact with one another; uniting said sheets in any suitable manner in a narrow region spaced outwardly from said foot-opening, said region having an outline generally conformable to the human foot; and separating a slipper from the material lying outside the region. By forming" is meant any effective step or steps capable of producing a sheet with an opening in it, such as cutting, molding, shearing, punching and the like. Although the literal terms first sheet and second sheet may connote the presence of two separate sheets in some contexts, those terms are used herein to refer also to separate portions of a single sheet. Thus, bringing said first sheet and a second sheet of said material into face to face contact is intended to embrace not only the idea of bringing separate sheets together but also the idea of folding over a double-sized single sheet to produce the same result. By uniting is meant any fastening, sealing, sewing, cementing or other joining technique. The term separating includes any method of parting the completed slipper from the excess material.

The above described method is illustrated in FIG. 4. In FIG. 4 a first sheet of thermoplastic foam 30 is punched to remove a generally oval piece 31 from the central portion thereof. The resultant aperture will eventually be the foot-opening 32 inthe finished slipper. It is preferable, though not essential, that the periphery of the foot-opening be seared. This is accomplished by collapsing a narrow portion 33 of the material surrounding the opening and heating it while other compression. When the pressure and heat are removed, this narrow portion remains in a collapsed condition. It is believed to contribute to the appearance and strength of the finished article.

After the footopening is formed, a second sheet 34 of the thermoplastic material is broughtface to face with the first sheet 30. The second sheet may be'foam material or noncellular plastic sheeting, although foam material is definitely preferred, since a more comfortable slipper will result. Alternatively, the first sheet may be non-cellular material and the second cellular.

Still another possible modification would be to provide a' double sole in the slipper. For instance, the upper would be either cellular or non-cellular material and the lower would be in two layers, one of foam, the other of non-cellular material. There would be no departure from the present invention .in making such modifications, since the substitution of cellular material for non-cellular material or the replacement of a single sheet of one kind or the other with two sheets, one of each kind, would not alter the sequence or relationship of the essential steps in our process. Therefore, although the description will proceed with a description in which both the first and second sheets are of foam material, no intention to exclude any of the above modifications or others should be inferred.

As can readily be observed from the drawings, the second sheet 34 completely covers the foot opening 32 when properly in place. Proper placement having been achieved the sheets are ready to be squeezed together in a narrow region 35 which is spaced outwardly from and surrounds the foot opening. This region should have an outline that is conformable to the human'foot.

This does not require that the aforesaid outline must look exactly like that of a foot. It means that the shape of the outline need only be close enough to that of a foot so that the finished product will fit the wearers foot smoothly.

While the sheets of thermoplastic material are being squeezed together in the above-described region, heat is applied to the compressed material. The temperature is increased to the extent necessary to bring the material into a condition of coalescence or incipient melting, whereupon thereis a blending together of the facing portions of the

sheets

30 and 34 within region 35. Heating is continued for a period of time sufficiently long to insure the formation of a permanent bond between the sheets. Usually the time required is measured in seconds or fractions thereof.

The one remaining essential operation in the method is the separation of a complete slipper 36 from the waste material 37. Separation may occur at any time during or subsequent to compression of the material. It is accomplished by cutting, shearing, slicing or tearing away all of the material outward of the region in which sealing takes place, leaving all or at least a substantial portion of the seal intact and firmly attached to the material inward thereof. That portion of the first sheet 30 which remains in the slipper thus produced comprises the upper. The remaining portion of the second sheet 34 comprises the lower.

So far as the basic steps are concerned, the second method is similar to the first. The second however, is particularly adapted to substantially completely automatic mechanized production operations. Generally speaking, the second method involves: advancing an elongated strip of thermoplastic material in a longitudinal direction through a means for forming footopenings; forming foot-openings in said strip at equally spaced intervals of length along said strip; subsequently bringing said first strip and a second strip of thermoplastic material into face to face contact with one another; advancing said first and second strips through a sealing operation; exerting firm pressure during said sealing operation on the exposed faces of both of said strips in a narrow region spaced outwardly from said foot-opening, said region having an outline generally conformable to the human foot; raising the temperature of said strips within said region to the temperature at which said strips will adhere to one another within said region; maintaining said temperature for sufficient time to insure the formation of a permanent bond between said strips in said region; and separating a slipper from the material lying outside of said region.

Those skilled in the art will readily recognize that the above method may be practised with a variety of equipment and in different modes. Thus, the material may be advanced relatively continuously with the various fabricating steps being performed by flying punches, cutters and dies. Or, in a preferred embodiment, the material may be advanced incrementally through equipment of the sort shown in FIGS. 5 and 9.

In the FIG. 5 embodiment, the first strip 40 unwinds from a feed roll 38 and is guided through

rolls

62 and 65 which may be idler rolls or which may be driven in a manner to be explained hereafter. From the aforementioned rolls, the material proceeds to a punching station 42. At the punching station is a punch 43, powered by any suitable reciprocating motor means, such as a hydraulic press cylinder 45. In cooperation with a female die 44, situated below the material, the punch 43 is able to cut pieces 41 from the strip 40.

The strip 40 is advanced through punching station 42 incrementally. That is, its advancement occurs in a series of successive left to right longitudinal movements of equal length, each movement being followed by a short period in which the strip is stationary. The punch 43 functions each time the material comes to rest, resulting in the formation of a series of foot-openings 39 spaced apart from one another along the length of strip 40 as shown in FIGS. 5 and 6.

In the present embodiment, the foot-openings are disposed transversely of strip 40. It isapparent, however, that the foot-openings can also be formed'lengthwise along said strip, although it would thus become necessary to increase the distance the strip would have to be advanced between each successive actuation of the punch 43. It is also apparent that whether the footopenings are to be disposed longitudinally or transversely on said strip they may be punched in gangs, that is, several at a time, with the aid of multiple punches.

Optionally, when using foam material, as is the case in the present embodiment, the punch may be provided with a heating element 46 and a shoulder portion 65 for searing the edge of the foot-opening 39. The punch and integral shoulder 65 are heated to the fusion temperature of the thermoplastic foam with the aid of the heater 46. Each time the punch functions, it is driven downwards until the foam material immediately adjacent the punch is crushed between shoulder 65 and the upper face of female die 44. The material is kept under hot compression for a sufficiently long period of time to insure permanent collapse of the crushed material. Then the punch is withdrawn. The result is that the foot opening is formed with an edge comprising a narrow ribbon of non-cellular material of reduced thickness into which the top and bottom surfaces of strip 40 blend. For the sake of simplicity, and because the sear ing of the edge of the foot-opening is not an essential step in the method, the seared edge is not shown in FIGS. 5-7.

Subsequent to the formation of the foot-openings, with or without searing, the strip 40 and a second strip 48 of thermoplastic material are brought together. The strip 48 is preferably devoid of holes, other than the natural voids in the cell structure of the plastic foam material. It unwinds from a supply roll 47 and is brought into face to face contact with strip 40 so that the footopenings 39 are covered. The

strips

40 and 48 are then moved together through a cutting and sealing station 49 where the strips are bonded together in a manner to be described.

At cutting and sealing station 49 there is a stationary lower sealing die 67 having an upwardly disposed horizontal die face 51, as shown in FIGS. 5 and 7. This die is provided with a heating element 53 by means of which the die face 51 can be raised to the fusion temperature of the thermoplastic foam material in

strips

40 and 48. Directly above die face 51 and in registry therewith is the substantially identical, downwardly disposed horizontal die face 50 of upper sealing die 66, as shown in FIG. 8. Die 66 is provided with a heating element 52, similar to heating element 53. I

Unlike lower die 67, upper die 66 reciprocates vertically. By means of any suitable reciprocating motor contact with the strip 40 each time it comes to rest and is retracted before the material begins to move again. Thus, during those periods when the

strips

40 and 48 are stationary, they are compressed for a time between the dies 66 and 67.

A shearing type cutter 56 is associated with the upper die 66. As will be noted from FIG. 8, the cutter is fitted closely about the entire periphery of die 66. Because the dies 66 and 67 have vertical walls and meet in substantially perfect registry, the cutter 56 can separate material clenched in the die from that lying outside of it. In order to more fully disclose how the cutting and sealing operation may be carried out, reference is now made to an enlarged view, FIG. 9, showing additional details of the dies schematically represented in FIG. 5.

As shown in FIG. 9, the cutter 56 is generally in the shape of an inverted box which partially enclosed upper die 66. The cutter includes a base portion 70, attached to motor means 57 in the manner disclosed in FIG. 5, side walls 69 dependent from base 70 and a hardened cutting insert 68 secured in the lower edge of side walls 69. The insert 68 conforms to the exterior surface of the side walls and 76 of the upper and lower dies 66 and 67 and rings the upper die. The upper die is suspended within the cutter assembly with the aid of bolts 71 which pass through holes 72 in cutter base 70 and threadably engage the upper die backing member 73. The bolts-'71 have heads 74 which hang on the upper surface of the backing member. Springs 55 are wound about the bolts between base 70 and upper die backing member. The function of these springs will be come apparent as the description unfolds.

The normal condition of the dies, that is their condition while the

strips

40 and 48 are advancing, is open. The dies normally have sufficient clearance between them to permit the full thickness of both

strips

40 and 48 to advance between them without catching. The stroke of the press actually exceeds the aforementioned clearance to the extent necessary to drive the cutter insert 68 at least partly below the surface of lower die face 51. However, since the springs 55 are interposed between the cutter base and the upper die, and because the cutter insert normally rides above upper die face 50, upper die 66. must come to rest and the springs 55 must be compressed to a significant extent before the cutter insert' 68fdrops below lower die face 51.

When the

strips

40 and 48 come to rest, the upper die closes down onto the lower die. The size and strength of the springs 55 is sufficiently great to insure that as the press closes, those portions of

strips

40 and 48 which are between die faces 50 and 51 will be substan tially completely crushed therebetween before the springs 55 yield toany significant extent under pressure from the motor 57. Thus effective operation of the cutter is prevented until the strips are thoroughly immobilized by being clenched between the die faces. FIG. 9

illustrates that point in the operation of the cutter-die assembly when the foam material has collapsed but just before the springs yield. Finally the cutter does function severing the material within the dies 66 and 67, while still clenched therein from the surrounding portions of the strips.

Not only does cutting occur while the press is closed, but the sealing operation also takes place then. Sealing takes place in a narrow region of both

strips

40 and 48 which corresponds in width to the width of die faces 50 and 51. The width of these faces is exaggerated slightly in FIG. 9 and even more so in FIGS. 5, 7 and 8 to facilitate their illustration.

FIG. 10 illustrates the condition of the material when it is clenched between the dies. The width of the aforesaid region, designated by numeral 64 in FIG. 10, corresponds in actual practice to that of the die faces 50 and 51, but is shown in FIG. 10 with a width more closely approximating its proper size.

Sealing takes place when the thermoplastic foam strips are crushed together in region 64 while absorbing sufficient heat from dies 66 and 67 to reach the temperature at which the collapsed strips coalesce with one.

another to form a bond. Coalescence is ideally carried to the point that so much of the cellular structure of the strips as is between the die faces is virtually destroyed, leaving behind a pliable, non-cellular seam 54 which remains in the final product. Bonding of the strip does not occur to any significant extent outside or region 54 because of the poor heat conductivity of the plastic foam.

It will be appreciated that it is not particularly critical whether the seam becomes completely developed before or after the cutter functions. However, it is necessary that the dies remain closed long enough to insure the formation of a good bond in the seam. This usually takes no more than a few seconds or fractions thereof.

Once both cutting and sealing have been accomplished, the upper die is again opened by reversal of motor 57. As the dies open, the strips of thermoplastic material again advance, and the completed slippers 63 leave the press and are separated from the remaining portions of

strips

40 and 48, which are illustrated in FIG. 11. These remaining portions constitute the waste products of the present method. When the

strips

40 and 48 again come to rest, the above described successive steps of closing the dies, forming a seal, cutting away waste material, opening the dies, further advancing the material and bringing the material to rest are repeated again and again on a continuous basis.

,An optional added feature of the cutter-die assembly depicted in FIG. 9 is a pair of spring-loaded plates 77, secured'inside the dies 66 and 67 respectively with the aid of bolts 78. The bolts 78 threadedly engage the aforesaid plates and pass through holes 79 in the dies 66 and 67 and in their

respective backing members

73 and 80. Between each of the dies and the respective plate members are secured coil springs 81, which are wound about the bolts 78 and which are slightly less compressible than the thermoplastic foam material.

When the dies are open, each of the plate members 77 protrudes slightly from its die. When the die closes down upon the

strips

40 and 48, the spring loaded plates exert pressure on the foam material encircled by the die faces 50 and 51, although not compressing'the latter material to the same extent as the material in region 64. As a consequence of their relatively light grip on the material, and their somewhat indirect and loose contact with the

heating elements

52 and 53 in

die backing members

73 and 80, the plates 77 do not cause any bonding between the strips of thermoplastic foam material. Consequently, their sole function when the In order to practice our method in apparatus of the character described above, it is necessary to utilize some form of automatic mechanism for advancing the material through punching, sealing and cutting stations. One essential characteristic of a suitable advance mechanism is that it must bring the

strips

40 and 48 to rest with the foot-openings 39 lying at the desired loca tion within the die. Although it is possible to make slippers with foot-openings offset slightly to one side or the other, more often than not, a well-centered footopening will be found most desirable. In such a case, the strip 40 must come to rest between the dies 66 and 67 with the foot-openings centered over the longitudi nal axes of the dies, or as close thereto as practicable.

This requirement is partially fulfilled by placing the punching station 42 and the cutting and sealing station 49 at a proper distance from one another, along the path followed by the plastic material. They should be separated from one another by a distance which is approximately equal to some whole number multiple of the length of each incremental movement of the material as it advances over said path. Thus, provided the material is not stretched to any substantial extent between the stations, the centers of the foot openings 39 should arrive at or about the centerline of the dies 50 and 51 each time the material comes to rest.

Not only is it necessary to carefully control the length of the path traversed by the punched strip 40 between stations, but also it is essential to control the length of the material itself. Polyurethane foam can be made in various gradations of elasticity from very little or none to very stretchy. The type of foam ordinarily used in making articles such as the slippers of the present invention is sufiiciently stretchy to change in shape and length when being pulled from one operation to another.

In a system in which all operating forces are fairly constant and in which the tensile properties of the material under treatment are equally constant, the material can be fed by pulling it through the system from the downstream end with a constant pulling force. However, we have found that the above conditions constitute an ideal situation which is not always obtainable. Consequently, we have found that there is a need for a better method of feeding the foam material through the various process steps.

This need is satisfied in accordance with the invention by the adoption of a method of feeding which involves both pushing the foam material into and pulling it out of thesealing mechanism, thus relieving it of deforming tensions. The objects of the invention are attained in a measure by pushing and pulling the punched strip 40 while only pulling the lower strip 48. However, it is preferred that both the punched 40 and unpunched 48 strips be pushed as well as pulled. The pushing forces may be applied to the

strips

40 and 48 separately, that is, before they come together. However, it is preferred that the strips be brought together prior to or practically at the same time as they are pushed towards the sealing and severing operation.

Any effective means for engaging the strips and moving them incrementally at a controlled rate and over a controlled distance may be used to provide the pushing and pulling forces for advancing the material. The main desideratum is that force be applied directly to the strips both ahead of and beyond the sealing and severing operation. This result can be obtained with the aid of any transport means which acts-throughoutsome portion of the length of the strips which.portion;traverses the cutting and sealing operation. Alternatively, means actinguponfthestrips. at spaced points both ahead of and b eyoiid the cutting and sealing'station may be used; 1 r I For instance,'in the present embodiment, the fimeans acting upon the strips at spaced pointsbo th ahead of and beyond the cutting and sealing station is a set of rollers. The set includes two pairs of rollers, a first pair, 58 and 59, ahead of said station and a second pair, 60 and 61, beyond said station. All of the rollers are driven by one common or several synchronized driving means so that each pair acts at the same rate, with the same amount of force and moves the material through the same distance as the other. The

rollers

62 and 65 may also be tied into the same driving'system, if desired.

Acornplete system will also include suitable means for synchronizing the operation of the

motors

45 and 57 with thework advancing mechanism. The main objectiveis toinsure that'both the foot-opening punch and the cutter-sealer mechanism contact the material only when it is at rest; This objective can be easily attained through the use of electric rotary switch type timer clocks or electronic sequence timers, hydraulic pumps, solenoid valves, limit switches and other control apparatus with which those skilled in thisart are already quite familiar. Therefore, they have merely been indicated schematically in the drawings. This completes a description of a preferred embodiment of our second method. I I

.I.t will be readily apparent that the general description of our second methodis of sufficiently broad scope to cover many embodiments other than the preferred one described above. Although it is not necessary and would probably be impossible to adequately describe all the possible embodiments of this method in detail, a few particularly interesting ones will be mentioned briefly. a The above preferred embodiment illustrates how the invention may readily be practiced with thermal heat sealing apparatus. Our invention may also be practised with electronic sealing apparatus. These two types of apparatus, although they are both thermal in a sense, are distinguishable with regard to'the manner of applying the heat to the work. In thermal'sealing apparatus, the heat is transferred solely by direct conduction of heat units from a preheated die directly to the material which the die contacts under pressure. US. Pat. No. 2,425,388 is an example of this'type. i

In the so-called electronic type of apparatus, the heat is developed in the material at least in part by subjecting the material to a high frequency alternatingfield'.

squeezed down to a'fraction of its uncompressed thicle-r ness in the region where sealing takes place. Any effective means of compressing the material may 'belusedt In.

the case of thermal sealing equipmenhthe member that transmits both pressure and heat to the'material -is ordi.-.

narily a metal-faced die corresponding to the shape of the desired seam. In electronic equipment, the mem bers between which the sheets of foam are squeezed often comprise a die which is formed basically of metal,

but has a-facing of Fiberglas reinforced heat-resistant From the above description of our methods, it is clear that they are sufficiently versatile to be practised in a variety of types of equipment, only a few preferred representatives of which have been mentioned. Those skilled in the art will readily adapt our methods to types of apparatus not disclosed herein without departing from the steps of our methods. These methods have the advantages of producing articles with a minimum of handling of materials during and prior to production. They can be performed at a great rate of speed with a high degree of product uniformity and few rejects. They are readily adaptable to machinery in which ganged dies, sealing mechanisms andsevering means are used to turn out a plurality of objects for each cycle of machine operation g Y Having described not only our novel articles of manufacture and methods but also apparatus for carrying out said methods,,we wish it to beunderstood that our methods are not restricted to the particular apparatus disclosed herein nor'are our methods of manufacture restricted to the particular products disclosed herein, excepf to'the extent that such restrictions are clearly expressed in the appended claims. Therefore, it should be understood that where acertain step'is recited in the appended method claims, reference should not be made to the specification for the purpose of introducing limitations germaine to the products or exemplary apparatus disclosed herein. 3

What we desire to protect by United StatesLetters Patent is:

1. A method of manufacturing slippers of heatsealable synthetic polymeric sheeting material, comprising:

advan'cing a first elongated strip of said material in a lohgitudinalndirection through a foot-opening" forming operation;

forming foot-openings at equally spaced distances along said strip; subsequently bringing said strip of said material into face to face contact with .one another; I advancing said first and second strips together through a cutting and sealingoperation by pushing said strips toward said operation from one side 7 thereof and pulling or withdrawing said strips from the other side of said operation, said pushing and pulling being performed with equal force, over equal distances and at the same time; during said cutting and sealing operation, exerting firm pressure on the exposed faces of both of said strips in at least one narrow region surrounding one first strip and a second of said foot-openings, said region being spaced outwardly from said one foot-opening and having an outline generally conformable to the human foot; raising the temperature of said strips within said region to the temperature at which said strips will co alesce with one another within said region; maintaining said temperature until said strips are permanently bonded in said region; and

separating a completed slipper from the material lying outside of said region.

2. A method according to claim 1 wherein said strips are advanced incrementally.

3. A method according to claim 1 wherein at least one of said strips is of stretchy plastic foam material.

4. A method according to claim 1 wherein the separating operation is performed while said strips are still under pressure.

5. A method of manufacturing slippers of heatsealable synthetic polymeric sheeting material, comprising:

advancing a first elongated strip of said material in longitudinal direction through a foot-opening forming operation;

forming elongated foot-openings at equally spaced distance along said strip;

subsequently bringing said first strip and a second gion to the temperature at which saidstrips will coalesce with one another within said region; maintaining said temperature until said strips are bonded within said region; and separating a completed slipper from the material lying outside of said region.

6. A method according to claim 5 wherein at least one of said strips has a cellular structure.

7. A method according to claim 5 wherein the application of heat is accomplished with the aid of a heated die, having a face corresponding to the shape of said region.

8. A method according to claim 7 wherein all of the heat required to unite said strips is applied thereto by direct conduction from said die.

[9. A method of manufacturing slippers of heatsealable synthetic polymeric sheeting material comprising:

forming an elongated foot-opening in a first sheet of said material;

subsequently bringing said first sheet together with a second sheet of said material in face to face relationship;

exerting firm pressure on the exposed faces of said sheets in at least one narrow region surrounding said foot-opening, said region being spaced outwardly from said foot-opening and having an elongated outline generally conformable to the human foot, said outline being elongated in generally the same direction as said foot-opening;

raising the temperature of said sheets within said region to unite said sheets with one another within said region; and

separating a slipper from the material lying outside of said region.

10. A method accordingto claim 9] I I wherein both of said sheets are of stretchy cellular material.

I 1. A method of manufacturing slippers of a heatsealable synthetic polymeric sheeting material comprising:

providing first and second'sheets of the synthetic polymeric sheeting material, at least one of which is stretchy cellular material;

forming an elongated foot opening in the first sheet of said material;

subsequently bringing the first sheet together with the second sheet of said material in face to face relationship;

exerting firm pressure on the exposed faces of the sheets in at least one narrow region surrounding the foot opening, said region being spaced outwardly from the foot opening and having an elongated outline generally conformable to the human foot, said outline being elongated in generally the same direction as said foot opening;

raising the temperature of the sheets within said region to unite said sheets with one another within said region; searing the periphery of the foot opening by collapsing a narrow portion of the material surrounding the opening and heating it while under compression; and

separating a slipper from the material lying outside of said region.

12. The method of claim I I wherein said slipper is separated from said material lying outside of said region by shearing.

1.3. The method of claim 1 1 wherein said foot-openings are formed by punching.

.14. The method of claim I I wherein the application of heat is accomplished with the aid of a heated die having a face corresponding to the shape of said region.

15. The method of claim 14 wherein all of the heat required to unite said sheets is applied thereto by direct conduction from said die.

V 16. The method of claim I I wherein the separating operation is performed while said sheets are still under pressure. i

1 7. The method of claim 1 I wherein at least one of said sheets is polyurethane foam. 7

18. The method of claim 6 wherein said slipper is separated fromsaid material lying outside of said region by shearing. I

19. The method of claim 6 wherein said foot-openings are formed by punching.

20. The method of claim 6 wherein the separating operation is performed while said strips are still under pressure.

21. The method of claim 6 which further includes searing the periphery of the foot-opening by collapsing a narrow portion of the material surrounding the opening and heating it while under compression.

22. The method of claim 5 wherein at least one of said strips is polyurethane foam.

23. The method of claim 5 wherein both of said strips are of stretchy cellular material.

24. The 'n'z'ethodof claim 3 wherein said sli'pp'er is'sepa rated from said material lying outside .olfsiiidregion by shearing. 1

25 The method of claim 3 wherein saidfoot-o penings ar eformed by punching.

26. The method of'claim3 wherei the application of heat is accomplishedgtwith theaid of a heated die'having aface corresponding to the shape'of sdid b 27. The method of claim 26 wherein the, heat required to unite said strips is applied the reto bydire'c'tconduction from said die. h l 1;

28. The method of claim 3 whichfurther includes searing the periphery of the foot-opening by collapsing a narrow portion of the material surrounding the opening and heating it while under compression.

29. The method of claim 1 wherein at least one of said strips is polyurethane foam.

30. The method of claim 1 wherein both of said strips are of stretchy cellular material.

31. A method of manufacturing slippers of heat sealable polyurethane foam material comprising:

punching an elongated foot-opening in afirst sheet of polyurethane foam;

subsequently bringing saidfirst sheet together with a second sheet of polyurethane foam in face to face relationship;

exerting firm pressure on the exposed faces of said sheets in at least one narrow region surrounding said foot-opening, said region being spaced outwardly from saidfoot-opening and having an elongated outline generally conformable to the human foot, said outline being elongated in generally the same direction as saidfoot-opening;

raising the temperature of said sheets within said region to unite said sheets with one another within said region; wherein, the application of heat is accomplished with the aid ofa heated die having aface corresponding to the shape of said region;

searing the periphery of thefoot-opening by collapsing a narrow portion of the material surrounding the opening and heating it while under compression; and separating a slipperfrom the material lying outside of said region while said sheets are still under pressure.

32. A method of manufacturing slippers of heatsealable polyurethane foam material, comprising:

advancing a first elongated strip of polyurethane foam in a longitudinal direction through a foot-opening forming operation;

punching elongated foot-openings at equally spaced distances along said strip;

subsequently bringing saidfirst strip and a second strip of polyurethane foam into face to face contact with one another;

exerting firm pressure on the exposed faces of said strips in at least one narrow region surrounding one of said foot-openings, said region being spaced outwardly from saidfoot-opening and having an elongated outline generally conformable to the human foot, said outline being elongated in generally the same direction as said foot-opening;

raising the temperature ofsaid strips within said region to the temperature at which said strips will coalesce with one another within said region; and wherein the application of heat is accomplished with the aid of a heated die having a face corresponding to the shape of said region;

":maintaining said temperature until said strips are bonded within said'regiony I Y searing the periphery ofthefoot-openingby collapsing a" narrow-"portion of'the material surrounding the opening and heating itwhile undercompression; and separating a c'ompletedslipper from the material lying outside of said region while said strips are still under pressure; y "3 3. '?=1 ""'method=*of manufacturing slippers of heatsetalable "stretchy cellular material comprising:

advancing afirs telongated strip ofsaid material in a longitudindl direction through a foot-opening forming operation; punching foot-openings at equally spaced distance along said strip; subsequently bringing said first strip and a second strip 'of said material into face to face contact with one another; advancing said first and second strips together through a cutting and sealing operation by pushing said strips toward said operation from one side thereof and pulling or withdrawing said stripsfrom the other side of said operation, said pushing and pulling being performed with equal force, over equal distances and at the same time; during said cutting and sealing operation, exertingfirm pressure on the exposed faces of both of said strips in at least one narrow region surrounding one of said foot-openings, said region being spaced outwardly from said one foot-opening and having an outline generally conformable to the human foot; raising the temperature ofsaid strips within said region to the temperature at which said strips will coalesce with one another within said region; wherein the ap plication of heat is accomplished with the aid of a heated die having a face corresponding to the shape of said region; maintaining said temperature until said strips are per manently bonded in said region; and separating a completed slipper from the material lying outside of said region while said sheets are still under pressure. 34. The method of claim 33 wherein the strips are advanced incrementally.

35. A method of manufacturing slippers of heatsealable stretchy cellular material comprising:

incrementally advancing afirst elongated strip of said material in a longitudinal direction through a footopening forming station; punching foot openings at equally spaced distances along said strip while it is at rest at said foot-opening forming station; advancing said first elongated strip from said footopening forming station along a path of advance ment extending to a cutting and sealing station, said punching station and said cutting and sealing station being separated by a distance along said path approximately equal to a whole number multiple of the length of each incremental movement of the material as it advances over said path; bringing saidfirst strip and a second strip of said material together along said path between said punching station and said cutting and sealing station; incrementally advancing said first and second strips together through said cutting and sealing station; performing the advancing of said first strip through said punching station and the advancing of saidfirst and second strips together through said cutting and sealing station by pushing said strips towards said stations from one side thereof and pulling or withdrawing said strips from the other side of said stations, said pushing and pulling being petformed with equal force, over equal distances and at the same time;

at said cutting and sealingstation, exerting firm pressure on the exposed faces of both of said strips while they are at rest in at least one narrow region surrounding one of said foot openings, said exerting of pressure being synchronized with the punching of outside of said region.

Claims

1. A method of manufacturing slippers of heat-sealable synthetic polymeric sheeting material, comprising: advancing a first elongated strip of said material in a longitudinal direction through a foot-opening forming operation; forming foot-openings at equally spaced distances along said strip; subsequently bringing said first strip and a second strip of said material into face to face contact with one another; advancing said first and second strips together through a cutting and sealing operation by pushing said strips toward said operation from one side thereof and pulling or withdrawing said strips from the other side of said operation, said pushing and pulling being performed with equal force, over equal distances and at the same time; during said cutting and sealing operation, exerting firm pressure on the exposed faces of both of said strips in at least one narrow region surrounding one of said foot-openings, said region being spaced outwardly from said one foot-opening and having an outline generally conformable to the human foot; raising the temperature of said strips within said region to the temperature at which saId strips will coalesce with one another within said region; maintaining said temperature until said strips are permanently bonded in said region; and separating a completed slipper from the material lying outside of said region.

5. A method of manufacturing slippers of heat-sealable synthetic polymeric sheeting material, comprising: advancing a first elongated strip of said material in a longitudinal direction through a foot-opening forming operation; forming elongated foot-openings at equally spaced distance along said strip; subsequently bringing said first strip and a second strip of said material into face to face contact with one another; exerting firm pressure on the exposed faces of said strips in at least one narrow region surrounding one of said foot-openings, said region being spaced outwardly from said foot-opening and having an elongated outline generally conformable to the human foot, said outline being elongated in generally the same direction as said foot-opening; raising the temperature of said strips within said region to the temperature at which said strips will coalesce with one another within said region; maintaining said temperature until said strips are bonded within said region; and separating a completed slipper from the material lying outside of said region.

10. A method according to claim (9) 11 wherein both of said sheets are of stretchy cellular material.

11. A method of manufacturing slippers of a heat-sealable synthetic polymeric sheeting material comprising: providing first and second sheets of the synthetic polymeric sheeting material, at least one of which is stretchy cellular material; forming an elongated foot opening in the first sheet of said material; subsequently bringing the first sheet together with the second sheet of said material in face to face relationship; exerting firm pressure on the exposed faces of the sheets in at least one narrow region surrounding the foot opening, said region being spaced outwardly from the foot opening and having an elongated outline generally conformable to the human foot, said outline being elongated in generally the same direction as said foot opening; raising the temperature of the sheets within said region to unite said sheets with one another within said region; searing the periphery of the foot opening by collapsing a narrow portion of the material surrounding the opening and heating it while under compression; and separating a slipper from the material lying outside of said region.

12. The method of claim 11 wherein said slipper is separated from said material lying outside of said region by shearing.

13. The method of claim 11 wherein said foot-openings are formed by punching.

14. The method of claim 11 wherein the application of heat is accomplished with the aid of a heated die having a face corresponding to the shape of said region.

16. The method of claim 11 wherein the separating operation is performed while said sheets are still under pressure.

17. The method of claim 11 wherein at least one of said sheets is polyurethane foam.

18. The method of claim 6 wherein said slipper is separated from said material lying outside of said region by shearing.

19. The method of claim 6 wherein said foot-openings are formed by punching.

24. The method of claim 3 wherein said slipper is separated from said material lying outside of said region by shearing.

25. The method of claim 3 wherein said foot-openings are formed by punching.

26. The method of claim 3 wherein the application of heat is accomplished with the aid of a heated die having a face corresponding to the shape of said region.

27. The method of claim 26 wherein all of the heat required to unite said strips is applied thereto by direct conduction from said die.

28. The method of claim 3 which further includes searing the periphery of the foot-opening by collapsing a narrow portion of the material surrounding the opening and heating it while under compression.

31. A method of manufacturing slippers of heat sealable polyurethane foam material comprising: punching an elongated foot-opening in a first sheet of polyurethane foam; subsequently bringing said first sheet together with a second sheet of polyurethane foam in face to face relationship; exerting firm pressure on the exposed faces of said sheets in at least one narrow region surrounding said foot-opening, said region being spaced outwardly from said foot-opening and having an elongated outline generally conformable to the human foot, said outline being elongated in generally the same direction as said foot-opening; raising the temperature of said sheets within said region to unite said sheets with one another within said region; wherein, the application of heat is accomplished with the aid of a heated die having a face corresponding to the shape of said region; searing the periphery of the foot-opening by collapsing a narrow portion of the material surrounding the opening and heating it while under compression; and separating a slipper from the material lying outside of said region while said sheets are still under pressure.

32. A method of manufActuring slippers of heat-sealable polyurethane foam material, comprising: advancing a first elongated strip of polyurethane foam in a longitudinal direction through a foot-opening forming operation; punching elongated foot-openings at equally spaced distances along said strip; subsequently bringing said first strip and a second strip of polyurethane foam into face to face contact with one another; exerting firm pressure on the exposed faces of said strips in at least one narrow region surrounding one of said foot-openings, said region being spaced outwardly from said foot-opening and having an elongated outline generally conformable to the human foot, said outline being elongated in generally the same direction as said foot-opening; raising the temperature of said strips within said region to the temperature at which said strips will coalesce with one another within said region; and wherein the application of heat is accomplished with the aid of a heated die having a face corresponding to the shape of said region; maintaining said temperature until said strips are bonded within said region; searing the periphery of the foot-opening by collapsing a narrow portion of the material surrounding the opening and heating it while under compression; and separating a completed slipper from the material lying outside of said region while said strips are still under pressure.

33. A method of manufacturing slippers of heat-sealable stretchy cellular material comprising: advancing a first elongated strip of said material in a longitudinal direction through a foot-opening forming operation; punching foot-openings at equally spaced distances along said strip; subsequently bringing said first strip and a second strip of said material into face to face contact with one another; advancing said first and second strips together through a cutting and sealing operation by pushing said strips toward said operation from one side thereof and pulling or withdrawing said strips from the other side of said operation, said pushing and pulling being performed with equal force, over equal distances and at the same time; during said cutting and sealing operation, exerting firm pressure on the exposed faces of both of said strips in at least one narrow region surrounding one of said foot-openings, said region being spaced outwardly from said one foot-opening and having an outline generally conformable to the human foot; raising the temperature of said strips within said region to the temperature at which said strips will coalesce with one another within said region; wherein the application of heat is accomplished with the aid of a heated die having a face corresponding to the shape of said region; maintaining said temperature until said strips are permanently bonded in said region; and separating a completed slipper from the material lying outside of said region while said sheets are still under pressure.

34. The method of claim 33 wherein the strips are advanced incrementally.

35. A method of manufacturing slippers of heat-sealable stretchy cellular material comprising: incrementally advancing a first elongated strip of said material in a longitudinal direction through a foot-opening forming station; punching foot openings at equally spaced distances along said strip while it is at rest at said foot-opening forming station; advancing said first elongated strip from said foot-opening forming station along a path of advancement extending to a cutting and sealing station, said punching station and said cutting and sealing station being separated by a distance along said path approximately equal to a whole number multiple of the length of each incremental movement of the material as it advances over said path; bringing said first strip and a second strip of said material together along said path between said pUnching station and said cutting and sealing station; incrementally advancing said first and second strips together through said cutting and sealing station; performing the advancing of said first strip through said punching station and the advancing of said first and second strips together through said cutting and sealing station by pushing said strips towards said stations from one side thereof and pulling or withdrawing said strips from the other side of said stations, said pushing and pulling being performed with equal force, over equal distances and at the same time; at said cutting and sealing station, exerting firm pressure on the exposed faces of both of said strips while they are at rest in at least one narrow region surrounding one of said foot openings, said exerting of pressure being synchronized with the punching of said foot openings in said first elongated strip, said region being spaced outwardly from said one foot opening and having an outline generally conformable to the human foot; raising the temperature of said strips within said region to the temperature at which said strips will coalesce with one another within said region; maintaining said temperature until said strips are permanently bonded in said region; and separating a completed slipper from the material lying outside of said region.