This invention relates to handcovering or handwear, such as gloves or mittens, comprising an outer protective layer and a waterproof inner insert layer.
Attempts have been made to waterproof handcoverings, for gloves made of leather or fabric which are not waterproof. Gloves can be waterproofed by providing a waterproof lining or insert inside the outer shell layer of the glove. Frequently, for added comfort, the waterproof lining is usually also permeable to water vapor, i.e., it is breathable. This waterproof insert is sometimes referred to as a functional layer or material, it can be made a) of functional layer alone or b) made of a two-layer laminate comprised of a functional layer material and a cloth lining or textile backing or c) made of a three-layer material which is made of the functional layer material, the inner textile layer end a textile backing. For a comfortable feeling on the skin either there is a stitched together cloth lining inside the insert, or the inner textile layer of t he laminate is made of lining material. For easy and cost efficient production, these inserts usually consist of two counter equal, flat pieces of the functional layer or laminate which are sealed along the edge. The pattern has the shape of a two dimensional oversized hand.
Gloves comprising a shell and an insert that contains a functional layer are known. The said two dimensional pattern of the insert can not be brought into the three-dimensional shape of the glove shell without being folded somehow. In insulated gloves this is a minor problem since the additional insulation between the functional insert and the in this case thick cloth lining prevents the wearer from perceiving the folds.
In thin, non-insulated gloves which are tailored close to the shape of the hand the folds of the insert lead to substantial disadvantages. They can disturbingly be perceived by the wearer. The folds are not attached to each other thus giving the hand some slip within the glove which may be dangerous for the wearer in activities needing a good grip. Furthermore, they reduce the tactility by the added thickness what is crucial for activities needing a fine sensation. Furthermore, they increase the resistance of the glove to heat and moisture transfer, which is not wanted in gloves worn in warmer ambient conditions. Examples for such gloves are gloves for working, for motorcycling, and for golf.
A lot of attempts have been made to overcome these deficiencies. An example is U.S. Pat. No. 5,442,818 in which a three-dimensional shaped lining inside and a two dimensional, folded up insert made out of a laminate are joined in a “slip-proof” fashion with an adhesive thus leading to a three-dimensional inner glove. The folds of the two dimensional insert between the cloth lining and the shell are tolerated by covering them behind a three-dimensional shaped sewn lining. However, the system does not solve the problem of bulkiness and of high resistances for heat and moisture transfer. This is due to the many layers which are created by the still existing insert folds.
U.S. Pat. No. 5,255,716 is another patent that describes a two-layered material, namely a puckered functional or barrier layer adhered to a second extendable fabric layer, which two-layered material is then secured to an outer extendable fabric layer with an adhesive. In U.S. Pat. No. 5,255,716, the fabric layer is stretchable and is adhered in a manner that results in bunching up of the functional layer. This results in unnecessary thickness of the compounded layers. Hence, the resistance to heat and moisture transfere is not minimized. The added insulation value has even been mentioned by U.S. Pat. No. 5,255,716 as benefit which is only true when insulation is a wished property of the glove (page 13 line 28ff). Also, the elasticity of the wrinkles combined with the thickness of the wrinkled layer reduces the tactility perceivably.
Furthermore, U.S. Pat. No. 5,255,716 claims non elastic glove shells made e.g. from leather. However, with the described process it is not possible to make such a glove since the shell has to be drawn over a flat two dimensional former, which is formed in a way that requires extreme elasticity of the shell since the opening of the glove needs to stretched to fit over the wider fingerpart (page 47 line 3 ff). This is an inherent problem of the procedure and can not be solved by a change of the flat two dimensional former since the added circumferences of the fingers are larger than the circumference of the hand in the palm area and, therefore, the former has always to be wider at the fingers than at the palm area to completely stretch the whole glove, which is in the described procedure necessary to be able to adhere the glove over the complete surface.
This invention overcomes the deficiencies described in the prior art, especially with respect to minimizing the thickness of the complete assembled glove in order to optimize tactility, grip, breathability, heat transfer, and softness by providing in a broad aspect, a handcovering comprising: an outer material part or outer shell that is substantially non-elastic, e.g. made from such materials as leather or woven fabrics, and an inner part or inner glove insert adhered to the shell. The inner glove insert comprises a functional layer that is water vapor permeable and waterproof, the inner glove insert being substantially free of folds in the whole glove and having substantially no bunching of the functional layer, preferably no bunching at all.
The invention provides a handcovering with an outer material part and with an inner part, wherein the inner part is composed of a stretchable laminate which comprises a waterproof functional layer permeable to water vapor and a textile layer and which comprises an outer face; the outer material part has a three-dimensional shape corresponding to a hand and a correspondingly three-dimensional inner face; the inner part is stretched into the three-dimensional inner face of the outer material part in such a way that essentially the entire outer face of the inner part rests against the inner face of the outer material part; essentially the entire outer face of the inner part is bonded essentially to the entire inner face of the outer material part; and the outer material part is composed of an essentially inelastic outer material which is capable of absorbing restoring forces of the laminate which are caused by the stretching of the inner part.
The invention also provides a method for producing handcovering with an outer material part and with an inner part, having the following method steps: production of the outer material part having a three-dimensional shape corresponding to a hand and with a correspondingly three-dimensional inner face; production of the inner part having a two-dimensional stretchable laminate which has a waterproof functional layer permeable to water vapor and a textile ply and which possesses an outer face; stretching of the inner part into the three-dimensional inner face of the outer material part in such a way that essentially the entire outer face of the inner part comes to rest against the inner face of the outer material part; and bonding of essentially the entire outer face of the inner part to essentially the entire inner face of the outer material part; wherein the outer material part is composed of an essentially inelastic outer material which is capable of absorbing restoring forces of the laminate which are caused by the stretching of the inner part.
The handcovering is prepared by providing a laminate of the functional layer, e.g., porous PTFE film, that has preferably been treated on one surface with a polyurethane that is nonporous but which allows passage through it of water molecules, and a cloth lining laminated on the film. The laminate can optionally have a protective textile backing. The laminate is stretchable to a greater size. The cloth lining and the protective backing can be any textile or foam, e.g. made of polyurethane or polyester. Preferably, the cloth lining and the protective textile backing will comprise a knit. The cloth lining and the protective textile backing may be made of a polyethylene terephthalate, polyamide, viscose, cotton or blends of one or more of these materials.
To form the insert, two such laminates are superimposed and then sealed at an outline that is in the shape of a mitten or glove and then cut around the periphery to form a hand covering insert. The shape can be undersized in certain hand areas.
An adhesive is then applied to each outer surface of the insert. The adhesive can be applied in dot fashion, as a web or continuously. The adhesive can alternatively be applied on the laminate before the insert is sealed.
The insert is then placed inside an outer shell and heat is applied to cause the adhesive to adhere the insert to the inside of the shell by the means of a heated thumb form and a heated four finger hand form. It is usually preferred to heat the thumb portions first in order to secure the insert and the shell in the right position to one another and to prevent slippage as the procedure is carried out. Due to the three-dimensional shape of the shell, the insert is stretched in some areas to conform to the three-dimensional shape of the shell, and the two dimensional insert is reshaped into the three-dimensional shape of the shell substantially without folds being formed, and then the insert is adhered in this shape to the glove shell. Once initial adherence is obtained on the whole inner surface, air can be supplied to the interior to a) to press the insert firmly against the shell, b) cool the adhesive and c) to remove the glove from the heated handform without much friction.
In embodiments of the invention, the handwear or handcovering is in the form of a glove or a mitten.
In embodiments of the invention, the handwear or handcovering is in the form of an insulated glove or mitten or in the form of a thin, non-insulated glove.
As described above, the outer material shell of the handwear and the insert containing the functional layer are directly adhered in a way that reshapes the two dimensional insert by stretching into the three-dimensional form of the shell and thus avoiding folds and bunching. This provides a handcovering which overcomes the deficiencies in the prior art described further above.
The described direct adherence of the shell and the outer side of the functional layer insert to form a glove or mitten prevents the presence of an air layer which can act as a water vapor barrier between the shell and the functional layer insert. Furthermore the minimization of the number of layers ensures a minimum of insulation and a maximum of dexterity. For that and for better stretchability or elongation the functional layer may be directly adhered to the shell material without a protective textile backing. A compounded layer of the whole glove according to the invention, comprising of the regular shell component layer, the adhesive, and the functional insert laminate layer, has a water vapor transmission resistance Ret of less than 35 (m2*Pa)/W or even, in the case of a preferred embodiment, of less than 15 (m2*Pa)/W, depending on the choice of material with regard to outer material and lining material.
The adhering of the shell to the insert can be effected either with adhesive which has been applied in continuous form, i.e., over the whole area, or with adhesive which has been applied discontinuously, i.e. with gaps of >50% of the surface area. In this connection, the adhesive can be applied most conveniently to the outer surfaces of the insert. Water-vapor-permeable adhesive is used in the case of a continuous adhesive layer being applied. For the use of a discontinuous adhesive layer, for example applied in powder, dot, grid or web form, it is possible to use an adhesive that is not water-vapor-permeable. Water vapor permeability is maintained through the area of the insert not covered by the adhesive.
The shell for the glove or mitten of the invention can suitably be, for example, leather or textile sheet materials. Textile sheet materials can be, for example, wovens, knits, nonwovens or felt. These textile sheet materials can be formed from natural fiber, for example cotton or viscose, or from synthetic fiber such as polyester, polyamides, polypropylene or polyolefins, or of blends of at least two of these materials. Such outer materials are normally water permeable and water vapor permeable. To render them water resistant they can be hydrophobicized by treating the shell with a water-repellent material in such a way that the pores of the outer material remain open for water vapor transport.
The adhesive is preferably heat activated and may be selected from a copolyamide, copolyester, polyester polyurethane, polyolefine, polyamide or a polyurethane adhesive, for example such as a reactive polyurethane adhesive, and also mixtures of polyester urethane and polyurethane. The adhesive may have a melting point in the range of 50 to 130° C.
The functional material can be any waterproof, breathable material such as porous polyethylene, polyurethane and the like. Preferably it will be a laminate of a porous polytetrafluoroethylene layer adhered to a cloth lining which feels comfortable on the skin. The porous polytetrafluoroethylene is preferably expanded polytetrafluoroethylene prepared as described in U.S. Pat. No. 3,953,566 and preferably will have a coating of polyurethane that is nonporous but which transports water vapor molecules by molecular transportation. Such a combination is described in U.S. Pat. No. 4,194,041. This combination is adhered to an appropriate textile layer which serves to protect the porous polytetrafluoroethylene layer.
The lamination of the insert into the shell is done in a way that prevents wrinkling and bunching of the functional layer. The resulting laminate must have a stretchability in at least one direction of at least 30% and preferably 40% in order to allow stretching of the laminate into a three-dimensional shape corresponding to the shape of a hand. Preferably the stretchabilityis in both directions and is mare than 40% The laminate must maintain its waterprootness and water vapor permeability in the stretched condition. To keep the forces for deformation during the stretching and adhering of the insert in the shell low a flat stress strain curve of the laminate (<30 N/5 cm (i.e. related to a sample having a width of 5 cm) for 30% elongation in at least one direction) is necessary. Them is preferably a low recovery of the laminate.
As stated before, the shell is composed of an essentially inelastic outer material which is capable of absorbing restoring forces of the laminate caused by the stretching of the insert. It can easily be tested whether the outer material of handcovering of the present invention had absorbed restoring forces: The finished handcovering is heated to such an extent that the adhesive bonding the insert to the shell liquefies. The shell has absorbed restoring forces if the insert separates from the shell upon liquefaction of the adhesive. Such separation will be detectable in particular in the regions of the finger roots and the thumb back of the handcovering where the three-dimensional shape of the handcovering mostly differs from the two-dimensional shape of a not stretched insert.
In practice, as seen in
The insert so formed can then be treated with adhesive on its two outer surfaces as described above, to ready the insert for insertion in a shell. As shown in
The adhesive is heat activatable and is activated either by direct heat, microwave or infra-red.
Shell 50 comprises a shell gauntlet 54, a shell thumb 56 and shell fingers 58. Shell 50 has a three-dimensional shape. Insert 52 oomprises an insert gauntlet 60, an insert thumb 62 and insert fingers 64. Before insertion into shell 50, insert 52 has a two-dimensional shape.
Insert gauntlet 60 is free of adhesive so that gauntlets 54 and 60 will not be bonded by adhesive to each other.
In a preferred embodiment of the invention, the heat for activating the adhesive is applied by the means of three dimensional heated forms, preferably rigid and most preferably made of metal. A first form 66 depicted in
In the first assembling step insert 52 is put into place in outer glove shell 50 in a manner that all insert fingers 64 are in the respective finger 58 of shell 50. Shell 50 and insert 52 together are then pulled on the two forms 66 and 70 subsequently, being a thumb form 66 and a four finger hand form 70. It is preferred to adhere and fix the thumb area first to anchor the insert 52 and shell 50 during subsequent steps. Heat is then applied to the rest of the combination to adhere insert 52 to shell 50. By pulling the undersized but stretchable insert 52 onto the form 66, 70, the two dimensional insert 52 is stretched into the three-dimensional shape of the form 66, 70 and in this shape is adhered to the glove shell 50. Since the glove shell 50 sits tight on the form 66, 70, the insert 52 is now in the basic shape of the glove 72 and fixed therein.
The forms have a switchable air supply at 75 and 77, respectively. The air is switched on after the adhesive 53 has been activated to cool the activated adhesive 53, to force the insert 52 firmly against the shell 50, which forms the insert exactly after the glove shell 50 and to remove the glove 72 from the form 66, 70 without friction. By using laminate with a flat stress strain curve, a special designed insert pattern and a pressure of up to 0.3 bar, a deformation of the insert 52 is reachable which allows a substantially foldfree fixation of the insert 52 inside the glove shell 50. The insert 52 keeps sustainingly the three-dimensional shape of the glove 72 finally since recovery forces, which tend to pull the insert 52 back into its original shape, are taken over by the glove shell 50.
In an embodiment of the invention, forms 66 and 70 comprise electrical connectors 78 and 80, respectively, for supplying electric heating power to electric heating elements 82 and 84, arranged on or within the respective one of forms 66 and 70.
By this means a unitary handwear is produced that is substantially free of folds or bunching of the insert 52 or the functional layer.
What is shown in
By the term waterproof is meant that the material under investigation and the welded or sealed area is able to withstand a water ingress pressure of more than 0.05 bar. Preferably, the material can withstand a water pressure of more than 1 bar. The measurement is carried out by exposing a 100 cm2 sample of the material under investigation to a rising water pressure. For this purpose, distilled water having a temperature of 20±2° C. is used. The rise in the water pressure is 60±3 cm H2O/min. The water ingress pressure of the sample is that pressure at which water passes through the opposite side of the sample. The exact method for carrying out this test is described in the 1981 ISO Standard No. 811.
Waterproof as used herein for the glove insert is meant having textile laminates with a water penetration resistance of 0.07 bar or more and whose seams have a penetration resistance of 0.07 bar or more. The waterproofness of the glove insert can be measured using the “Whole Glove Leak Tester” apparatus disclosed in U.S. Pat. No. 4,776,209 (Patchell) assigned to W. L. Gore & Associates, Inc., in which air at pressure of between 0.07 bar and 0.35 bar is admitted into the inside of a glove insert disposed in a water tank.
The term water vapor permeable as used herein is defined via the water vapor transmission resistance Ret of the material so designated. The Ret is a specific material property of sheet-like structures or composites, which determines the “latent” evaporation heat flux through a given area in consequence of an existing steady-state partial pressure gradient. The Ret is defined in German Standard DIN EN 31 092 of February 1994, corresponding to International Standard ISO 11 092, and is expressed in m2*Pa/W (square meters Pascal per watt). For measuring Ret, a measuring head is employed having a temperature of 35° C. at a relative humidity of air of 40%, with an air speed being adjusted to 1 m/s. The water vapor transmission resistance is measured using the Hohenstein skin model test, which is described in standard test method Ne. BPI 1.4 of September 1987 of Bekleidungsphysiologisches Institut e.V. Hohenstein.
Number | Date | Country | Kind |
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100 04 355 | Feb 2000 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP01/01124 | 2/2/2001 | WO | 00 | 11/25/2002 |
Publishing Document | Publishing Date | Country | Kind |
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WO01/56415 | 8/9/2001 | WO | A |
Number | Name | Date | Kind |
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3953566 | Gore | Apr 1976 | A |
4194041 | Gore et al. | Mar 1980 | A |
4430759 | Jackrel | Feb 1984 | A |
4776209 | Patchel | Oct 1988 | A |
4847918 | Sturm | Jul 1989 | A |
5255716 | Wilcox | Oct 1993 | A |
5349705 | Ragan | Sep 1994 | A |
5442818 | Loos | Aug 1995 | A |
5566405 | Masley | Oct 1996 | A |
5732413 | Williams | Mar 1998 | A |
5740551 | Walker | Apr 1998 | A |
5911313 | Gold | Jun 1999 | A |
5981019 | Goodwin et al. | Nov 1999 | A |
6154886 | Hottner | Dec 2000 | A |
6716778 | Hottner | Apr 2004 | B1 |
Number | Date | Country |
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G 87 15 686.4 | Feb 1988 | DE |
WO 9207480 | May 1992 | WO |
WO 9716082 | May 1997 | WO |
WO 9722385 | Jun 1997 | WO |
Number | Date | Country | |
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20040098786 A1 | May 2004 | US |