This is a National Phase Application in the United States of International Patent Application No. PCT/JP2010/064529 filed Aug. 26, 2010, the entire disclosure of which is hereby incorporated by reference.
The present invention relates to a method for integrating multi-layer sheet fabric pieces for use in a chemical protective suit
As shown in
In the aforementioned method, air tightness and chemical permeability resistance are achieved by sticking the synthetic rubber tape 16 on the outside surface of the stacked portion of the multi-layer sheet fabric pieces 12, 13 and the folding line 12b, welding the synthetic rubber tape 16, and sticking the rubber coated sheet fabric piece 17 on the inside surface of the stacked portion of the multi-layer sheet fabric pieces 12, 13 and the peripheral edges 12a, 13a so as to shut the spaces among the stacked sheet fabric pieces 12, 13 off from the internal air and the external air.
The conventional method for integrating multi-layer sheet fabric pieces for use in a chemical protective suit has a problem in that the method causes an increase in fabrication man-hours because it requires the five steps of producing the seam line 14, producing the seam line 15, sticking the synthetic rubber tape 16 on the multi-layer sheet fabric pieces, welding the synthetic rubber tape 16 using an external heat source, and sticking the rubber coated sheet fabric 17 on the multi-layer sheet fabric pieces.
Therefore, an object of the present invention is to provide a method for integrating multi-layer sheet fabric pieces for use in a chemical protective suit, wherein fewer fabrication man-hours are required than in the conventional method.
In accordance with the present invention, there is provided a method for integrating multi-layer sheet fabric pieces for use in a chemical protective suit comprising the steps of (a) stacking one of a pair of multi-layer sheet fabric pieces for use in a chemical protective suit, each of which comprises a front surface layer of thermoplastic resin film, a rear surface layer of thermoplastic resin film, and at least one middle layer of chemical permeability resistant resin film, on the other of the pair of multi-layer sheet fabric pieces, with a part of a peripheral edge of one multi-layer sheet fabric piece opposed to a part of a peripheral edge of the other multi-layer sheet fabric piece, (b) seaming the stacked multi-layer sheet fabric pieces at a portion close to the peripheral edges opposed to each other along the peripheral edges opposed to each other so as to form a seam line, and (c) high frequency dielectric heating the stacked multi-layer sheet fabric pieces at a band portion of predetermined breadth close to the seam line along the seam line, wherein the peripheral edges opposed to each other and the band portion are disposed to face opposite sides of the seam line, thereby welding and integrating the stacked multi-layer sheet fabric pieces with each other at the band portion.
In accordance with a preferred aspect of the present invention, the method further comprises, between the steps (b) and (c), the step of (d) folding one of the stacked multi-layer sheet fabric pieces toward the seam line at a portion away from the seam line beyond a band portion of predetermined breadth close to the seam line, wherein the peripheral edges opposed to each other and the band portion are disposed to face opposite sides of the seam line, and wherein the high frequency dielectric heating is carried out on triply stacked multi-layer sheet fabric pieces in the step (c).
In the method of the present invention, the stacked multi-layer sheet fabric pieces are heated and welded at a band portion of predetermined breadth close to the seam line, wherein the band portion and the peripheral edges opposed to each other are disposed to face opposite sides of the seam line, so as to drive out the spaces between or among the stacked sheet fabric pieces at the band portion of predetermined breadth. Air tightness and chemical permeability resistance of the integrated portion of the stacked sheet fabric pieces are secured by driving out the spaces between or among the stacked sheet fabric pieces at the band portion of predetermined breadth.
When the present invention is applied to the integrated portion of the stacked sheet fabric pieces including a folded portion as shown in
In accordance with a preferred aspect of the present invention, the thermoplastic resin film forming the front surface layer and the rear surface layer is polyurethane resin film.
In accordance with a preferred aspect of the present invention, the thermoplastic resin film forming the front surface layer and the rear surface layer is polyvinyl chloride resin film.
The polyurethane resin film or the polyvinyl chloride resin film is suitably welded by high frequency dielectric heating.
In accordance with a preferred aspect of the present invention, each of the multi-layer sheet fabric pieces further comprises a middle layer of lattice fabric.
The sheet fabric piece for use in a chemical protective suit is desirably provided with a middle layer of lattice fabric so as to protect the middle layer of the chemical permeability resistant resin film.
Methods for integrating multi-layer sheet fabric pieces for use in a chemical protective suit in accordance with preferred embodiments of the present invention will be described.
As shown in
The sheet fabric 1 is cut into a plurality of pieces of predetermined shapes. The plurality pieces of the sheet fabric 1 are integrated into a unitary body to form a chemical protective suit.
As shown in
The stacked sheet fabric pieces 2 and 3 can be welded and integrated with each other by the high frequency dielectric heating because the sheet fabric 1 comprises the front surface layer made of thermoplastic polyurethane resin film and the rear surface layer made of thermoplastic polyurethane resin film.
The portion to be welded and integrated desirably includes the folding line.
When the sheet fabric pieces are integrated and a chemical protective suit is completed, the folded portion of the sheet fabric piece 2 is exposed to the external air.
The folded sheet fabric piece 2 and the sheet fabric piece 3 are welded and integrated with each other at the portion of predetermined breadth L along the seam line 4 so as to drive out the spaces among the triply stacked sheet fabric pieces 2 and 3 at the portion of predetermined breadth L. Thus, air tightness and chemical permeability resistance of the integrated portion between the sheet fabric pieces 2 and 3 are achieved.
In the first integrating method, the three steps of seaming triply stacked portion close to the folding line, sticking the synthetic rubber tape on the sheet fabric pieces, and sticking the rubber coated sheet fabric piece on the sheet fabric pieces, which are necessary steps in the conventional method shown in
The portion to be welded and integrated includes the folding line of the sheet fabric piece 2. Thus, foreign substances are prevented from getting in the space between the folded portion of the sheet fabric piece 2 and the sheet fabric piece 3 and gradual peeling with age of the sheet fabric piece 2 off the sheet fabric piece 3 at the welded and integrated portion is prevented.
The lattice fabric middle layer 1b is located closer to the external air than the EVOH film middle layer 1c. Thus, the EVOH film middle layer 1c is protected from damage due to external force.
The first integrating method can be used in forming the leg portion, the body portion, the arm portion and the head portion of a chemical protective suit.
As shown in
The sheet fabric pieces 2 and 3 are welded and integrated with each other at the band portion of predetermined breadth L along the seam line 4 so as to drive out the spaces between the stacked sheet fabric pieces 2 and 3 at the band portion of predetermined breadth L. Spaces between the stacked sheet fabric pieces 2 and 3 are driven out at the band portion closer to the internal air than the seam line 4. Thus, air tightness and chemical permeability resistance of the integrated portion between the sheet fabric pieces 2 and 3 are achieved.
Also in the second integrating method, the three steps of seaming triply stacked portion close to the folding line, sticking the synthetic rubber tape on the sheet fabric pieces, and sticking the rubber coated sheet fabric piece on the sheet fabric pieces, which are necessary steps in the conventional method shown in
The second integrating method can be used in forming the foot portions of a chemical protective suit provided with foot portions extending from the calves to the toes.
Polyurethane resin film is used for the front surface layer and the rear surface layer of the sheet fabric in the aforementioned preferred embodiments. However, not only polyurethane resin film but also any other type of thermal plastic resin film which can be welded by high frequency dielectric heating can be used for the front surface layer and the rear surface layer of the sheet fabric. Polyvinyl chloride resin film can preferably used for the front surface layer and the rear surface layer of the sheet fabric.
The breadth L of the welded and integrated portion is suitably decided for the particular type of resin film used.
The present invention can be widely used for production of a chemical protective suit.
1 Sheet fabric for use in a chemical protective suit
2, 3 Sheet fabric piece
4 Seam line
L Predetermined breadth of welded and integrated portion
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2010/064529 | 8/26/2010 | WO | 00 | 2/26/2013 |
Publishing Document | Publishing Date | Country | Kind |
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WO2012/026029 | 3/1/2012 | WO | A |
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Entry |
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Number | Date | Country | |
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20130153131 A1 | Jun 2013 | US |