TH23577B - Can pack gas and how to make - Google Patents

Abstract

Light, multilayer construction with high tensile strength that holds gas inside. There is an outer envelope that is a semi-permeable elastic material. for use as an anti-shock mechanism The outer barrier is bonded at several points to the surface of the interlayer fabric with links. The long fibers have a crystalline molecular structure facing the long and highly distorted chain axis. It has low gas permeability conditions. The bond between the barrier layer and the front of the fabric is greatly increased if there are tiny fibers or a patterned surface. The thread, which has the same patterned surface, serves as the stress average. to maintain the composite structure to be flat or convex without bonding at the load-bearing area This light product can withstand high internal inflatable pressure. under ultra-flexibility and compression cycles Consistently intense for a long time The product is inflated. is compressed gas and sealed and maintains the internal inflatable pressure for a long time generally exceeds the service life of the product. By using the diffusion pump phenomenon of self-inflating The cushioning mechanism can optionally control the rate of diffusion pumping phenomenon by varying the density relationship between the envelope's semi-permeable elastic material and the long fiber material into highly distorted crystals and gas permeable fabrics. Therefore, it helps to improve the working time and durability. and reduce costs and eliminate some disadvantages of previous cushioning products. In limited cases, the mechanism can be permanently inflated using liquid nitrogen or liquid air.

Claims (5)

1. Envelopes that can be pressurized internally with spaced internal and external surfaces, which include The first and second textile layers are positioned in such an envelope so that one surface of each layer is The textiles are facing the inner surface of the envelope. The envelope is a flexible material. Each of these textile surfaces is connected to the inner surface facing the envelope. The textile layer is combined with yarn material, which is textured or fur, or puffed to add a connection to the facing layer of the envelope. A flexible path between such textile layers for curbing the movement of the fabric layer beyond a predetermined distance from one another; and Gas in the inside of the envelope to pressurize the envelope 2. An internally pressurized envelope with internal and external surfaces spaced for use in footwear where the envelope is subjected to a specific cyclical load. That and when compared, it is high which includes A textile material with a first and second textile layer positioned in the envelope so that each of its surfaces faces the inner surface of the envelope. The envelope is a flexible material and is combined with at least the part which creates a sealed seam. Each of these textile surfaces is connected to the inner surface facing the envelope. A flexible path between these textile layers for curbing the movement of the fabric layer beyond a predetermined distance from one another. The elastic path is combined by a number of fibrous bundles that extend between the layers of the fabric and are connected to it. The sealed seams are basically free of the fibrous material of the said textile layer and the binding of the fibers; and Gas in the inside of the envelope to pressurize the envelope where the fibrous binding line is tightened to maintain the opposite surface of the envelope in a plane configuration, and the gas acts as a 3. An internal pressurized envelope consisting of A hermetically sealed envelope that defines at least one compression chamber, the envelope contains an elastic material which, in conjunction with the rest of the structure, is somewhat impervious to large molecular gases and permits oxygen. Little A compressed textile structure inside such a chamber. Textiles with such a compressed textile structure that is combined with yarn material that is textured, patterned, or feathered or inflated. The compressed textile structure is somewhat of the same boundary as that of the chamber and consists of the first textile layer, the second textile layer that is normally spaced from the first layer. An elastic path, which is also positioned to be compressed between such layers, and creates a section of the fabric for holding that textile layer from separating more than a predetermined distance. The path to establish a relatively continuous connection between the said outer covering and the first and second textile layers. The textile layer, at least, is at least partially embedded within the said outer covering to reduce the transmission of the covering. The envelope, which includes at least one seam. Such seams are free from the fibrous material of the textile structure. The non-polar gas of large molecules in such a chamber, the envelope is compressed to a pressure of at least two psi where the relatively total resistance of the envelope to compression is provided by. 4. The internal pressure-able envelope specified above in any of Clause 1, 2 or 3 by such flexible means to restrain the textile layer. As mentioned in a defined and pre-restricted spaced relationship from the other; 5. The internally compressed air-tight envelope specified above in either of Claim No. 1, 2 or 3. 6. Envelopes that can be compressed internally as described above in either of Claim No. 1, 2 or 3, where the inner pressure envelope is specified above. Such first and second weaves are combined with yarns where up to approximately 30% of the fibrous composition are discrete to increase the connection with the inside facing surface of the envelope. 7. Pressure-able envelopes. Can within any of the above, in any of the claims 1, 2 or 3, where the strength of The displacement between that inner surface and the matching surface of such textiles is approximately 18 psi linearly greater than approximately 18 psi. One of claim 1, 2 or 3 where the textile layer is joined by a long fiber consisting of a molecular structure that is mostly natural crystalline and acts as a barrier to diffusion of gas through it. Which can be internally compressed as described above in any of Clause 1 or Clause 3, where such textured, patterned or feathered or inflated thread material is Heat stabilization 1 0. The internally compressed sachet specified above in any of Claim No. 1, 2 or 3 where the textile layer consists of yarn material which has been Processed to prevent the formation of any direct and unobstructed passageways. Passed to the core of the textile layer 1 1. The internally compressed envelope specified above in either of Claim No. 1, 2 or 3, where such an elastic path is for restraining the The movement of the textile layer is strong enough to hold the said layer at a predetermined distance when the gas pressure in the room exceeds approximately 150 psi. The intrinsic pressure-capable method is set forth above in any of Clause 1, 2 or 3, where such a flexible path to restrain the movement of such textile layers is made up of long fibers. 1 3. Envelopes that can be pressurized inside, as indicated above, in any of the claims 1, 2 or 3 where the flexible path is The longitudinal and textile layers are different from that of the longitudinal material 1 4. The internal pressure-able envelope is described above in Clause 12, whereby the long fibers are composed of materials which Has good gas barrier properties. 1. 5. Envelopes that can be compressed inside as mentioned above in the section. Clause 12, where the longitudinal fibers are composed of shiny long-chain high molecular weight polymers 1 6. The internally pressurized sachet, as described above in the Claims Clause. 15, where the polymer It was selected from a group consisting of Dacron 56, Nylon 66 and Cordura Nylon 1 7. The internal pressure-able envelopes described above in claim No. 15. Has a semi-matt or matt surface. 8. Internal pressure-able envelope, as described above in Clause 15, where such long fibers are composed of textured, patterned or feathered threads. Or inflated and heat stabilized, and where the yarn is of very uniform thickness 1 9. Envelopes that can be compressed inside as specified above in any of the claims. Points 1, 2 or 3, where the fabric layer is saturated with coupling binders to a depth which is less than approximate their thickness, such coupling is welded to the facing surface. 2 0. The internally compressed air-tight envelope is described above in Clause 19 where the coupling is a flexible and semi-oxygen-permeable material. That can be compressed internally as described above in any of the claims 1, 2 or 3, where the gas includes Super gas 2 2. The internally compressed sachet specified above in any of Clause 1, 2 or 3 where the elastic material is incorporated with a polyurethane elastic compound. Retain 2 3. The internally compressed envelope as described above in any of Claim No. 1, 2 or 3 where the envelope incorporates an external surface, such an external surface is included. The fabric material is connected to it. 2. 4. The internal pressure-able envelope, as indicated above, in any of the claims 1, 2 or 3 where the gas is gas. 5. Envelopes that can be compressed internally as described above in either Claim No. 1, 2 or 3, provided that they are the inside of the full length of the shoe for Used in shoes 2. 6. Internal pressure-able sachet as described above in any of Claim No. 1, 2 or 3 where the sachet is the shoe heel 2. 7. Envelope that can be Pressurized internally as described above in any of Claim No. 1, 2 or 3 where the envelope is the cobra-type heel part and the heel part has a leg section 2 8. fiddle The internal pressure-able envelope is described above in claim 27, where one leg is longer than the other. Rights No. 28, where the legs are spaced and separated from each other 3. 0. The internal pressure-able envelope is specified above in claim No. 29, where the chamber is also inflated. The gas is between the legs. 3 1. The internally compressed air envelope, as stated above, in any of the claims 1, 2 or 3 where the envelope includes at least chamber two. Chamber 3. 2. Internal pressure-able envelope as described above in Clause 31 where the chamber is interconnected. 3 3. The internal pressure-able envelope as described above. Clause 31, where one chamber is above the other 3. 4. The internal pressure-able envelope, as described above in claim 31, where one of the chambers is placed above the other. Compressed to a different pressure from other chambers. 3. 5. Internal pressure-able envelope as specified above in any of the Clause 1, 2 or 3 by The surface of the object will be in a planar relationship. 3. 6. The internally compressed envelope specified above in any of the claims 1, 2 or 3, where the textile material The above is a two-needle rod-shaped knitting material 3. 7. Envelopes that can be pressurized internally as described above in either of the claims 1, 2 or 3. The slack yarn is comprised of approximately 50 to 1,000 strands per square inch of textile and where the total mass density of slack threads ranges from 5,000 to 150,000 fibers or strands per square inch. The internal pressure is stated above in any of Claim No. 1, 2 or 3 where the envelope is formatted as the inside of the shoe, which is relatively uniform in thickness and as follows. There will be no uncompressible areas throughout the loading portion of the inside of the shoe. 3 9. The internal pressure-able envelope as described above in Clause 38 by The inside of the shoe is shaped up to the shape of the loading surface in the foot plane 4 0. The internal pressure is specified above in any of Clause 1, 2 or 3 where the textile layers are correlated as predetermined heights spaced from each other. 1. The internally compressed envelope as described above in any of Claim No. 1, 2 or 3 where the envelope includes an inflated portion free of textile material 4. 2. The internally compressed envelope as described above in any of Clause 1, 2 or 3 where the envelope includes at least the Deformable Gas-Pressure Energy Storage. 4 3. The internally pressurized envelope as described above in any of Claim No. 1, 2 or 3, which also includes materials. The least resilient foam is in contact with at least part of the envelope. 4 4. The internally pressurized envelope as described above in any of Claim No. 1, 2 or 3 by The fabric is combined with elastic threads that are sewn into 4. 5. Envelopes that can be pressurized inside as stated above in any of the above. Holds No. 1, 2 or 3, which also includes the medial material that is buttoned in where the buttons or spokes touch at least the part of the envelope. Any one of claim 1, 2 or 3 where the elastic path is the fluff yarn perpendicular to the textile layer 4. 7. The internally compressed envelope as described above in Any one of claim 1, 2 or 3 where the elastic path is the slack yarn provided with an angular turn relative to the fabric layer. 4 8. Pressed envelope. In any of the clauses 1, 2 or 3, the envelope is made of film material 4. 9. The internally pressurized envelope mentioned above in any of the above. One of the claims 1, 2 or 3, where the envelope is pre-formed envelope 5 0. Process for fabricating internally compressed multicomponent envelopes, comprising a process. of Choosing a flexible, semi-permeable material in a slab form, which is relatively impervious to macromolecular non-polar gas and slightly permeable to oxygen. Selection of a compressible structure that includes the first textile layer, the second textile layer normally spaced from the first layer, and the path between the near sides of that textile layer. For curbing such a textile layer from separation over a predetermined distance and path to form a relatively uniformly distributed junction on the far side of the textile layer. Saturating the far sides of the first and second textile layers with coupled binders to a depth that is less than approximately the thickness of such layers. Connecting the elastic material to the far side to create a connection between the fabric layer and the elastic material. The connection extends fairly steadily, covering the far side. Sealing such elastic material around the area Around the aforementioned compressible structure to create a hermetically sealed envelope and Putting gas in the chamber to pressurize the envelope 5 1. The process for the internal pressurized multi-component envelope structure is described above in claim 50, where such gases consist of at least macromolecular non-polar gas 5. 2. The process for the internal pressurized multi-component envelope structure is described above in claim 50, where the selection of the aforementioned compressible structure is combined with the selection of textile materials in place. In which the fibers were haired or textured, or puffed and thermally stabilized 5 3. The process for the internal pressurized multi-component envelope structure is described above in Clause 50, where the bonding binder is reduced to at least the aforementioned textile layer before fitting. Solder the parties thereof. 5 4. The process for the internal pressurized multi-component envelope structure is described above in claim 50, where coupled binders have a molecular weight in the range 100,000 to 500,000 and where the elastic material consists of: At least polyurethane 5 5. The process for the internal pressurized multi-component envelope structure is described above in claim 50, where the modulus of elasticity of such elastic material is bonded to and relative to Push the inflation to provide a desired bounce feature and support the finished envelope.