JP2005102933A - Shoe - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a shoe constantly holding the shoe inside in a comfortable state by changing a ventilation rate between an air inside the shoe and an outside air according to a change in a humidity in the shoe inside. <P>SOLUTION: This shoe 1 comprises an upper 2 and a sole 3. A fiber 5, when the humidity is 95% or more, shows a crimp contraction of less than 10%, when the humidity is 65%, a crimp contraction of 15-20% and a crimp number of 25/in. or more and, when the humidity is 45% or less, the crimp contraction of 20% or more; or a fabric 4 including the fiber 5 is used for an upper material of a part or the whole of the shoe. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a shoe using, as an upper material of a shoe, only a fiber in which the crimp rate reversibly changes due to a change in humidity and the surface form changes or a fabric containing the fiber.

  Conventionally, knitted fabrics, woven fabrics, artificial leathers and the like have been used as upper materials in order to obtain the breathability of shoes.

For example, as disclosed in JP-A-10-103, in a knitted fabric having a three-layer structure, the compression ratio is 20% or more, the bulk density is 0.3 g / cm ³ , and the surface layer is water-repellent and the back layer is A method of obtaining air permeability by using a water-absorbed material as an upper material has been taken.
JP-A-10-103

  However, in this case, although good ventilation is obtained, the air inside the shoe and the air outside the shoe are always ventilated, especially in winter when the temperature is low, and the cold air outside the shoe gets inside the shoe. As a result, there was a problem that the temperature inside the shoes decreased and the feet became cold.

  In order to solve the above-described conventional problems, the present invention is to keep the inside of a shoe in a comfortable state by changing the air permeability of the air inside the shoe and the air outside the shoe according to the humidity change inside the shoe. Objective.

In order to achieve the object, the invention described in claim 1
In upper and sole shoes, as the upper material, the crimp rate is less than 10% when the humidity is 95% or more, the crimp rate is 15 to 20% and the number of crimps is 25 / inch when the humidity is 65%. Further, the present invention relates to a shoe characterized in that only a fiber showing a crimp rate of 20% or more when the humidity is 45% or less, or a part or all of a fabric containing the fiber is used.

The invention according to claim 2
When the humidity is 95% or more, the crimp rate is less than 10%, when the humidity is 65%, the crimp rate is 15 to 20%, the number of crimps is 25 pieces / inch or more, and the humidity is 45% or less. The present invention relates to a shoe characterized in that a fiber having a crimp rate of 20% or more is a cellulose acetate fiber.

The invention according to claim 3
The cloth is a double raschel mesh, and one surface is composed of only the fiber according to claim 1 or 2 or a fiber containing the fiber, and the other surface and the connecting yarn are according to claim 1 or 2. It is related with the shoes characterized by being comprised with the fiber which does not contain the described fiber.

The invention according to claim 4
The present invention relates to a shoe, wherein the other surface of the double raschel mesh and the connecting yarn are made of polyester fiber.

The invention according to claim 5
The present invention relates to a shoe characterized in that at least a tongue portion of the upper is made of the fabric according to any one of claims 1 to 4.

The invention according to claim 6
At least the upper part of the upper is made of the fabric according to any one of claims 1 to 4.

  The present invention changes the air permeability of the air inside the shoe and the air outside the shoe according to the humidity change, and can keep the inside of the shoe always in a comfortable state.

  Embodiments of the present invention will be described below with reference to the accompanying drawings.

FIG. 1 is a perspective view of a shoe according to an embodiment of the present invention.
The present invention relates to a shoe 1 comprising an upper 2 and a sole 3, wherein the crimp rate is less than 10% when the humidity is 95% or more, the crimp rate is 15 to 20% and the number of crimps is 65% when the humidity is 65%. Only fiber 5 showing a crimp rate of 20% or more when the humidity is 45% or less and the humidity is 45% or less (hereinafter referred to as fiber 5 whose crimp rate changes depending on humidity) or fabric 4 containing the fiber Is used as the material of the upper 2.

FIG. 4 is an enlarged view of the fiber 5 in which the crimp rate changes according to the humidity in an atmosphere of 65% humidity. In an atmosphere with a humidity of 65%, the crimp rate of the fibers 5 whose crimp rate changes with humidity is 15 to 20%, and is in a crimped state as shown in FIG.
FIG. 2 is an enlarged view of the knitted fabric 41 including the fiber 5 whose crimping rate changes depending on humidity in an atmosphere of 65% humidity. Since the fibers 5 whose crimping rate changes with humidity are shrunk, the stitches of the stitches 42 increase, and the gaps 43 between the stitches become relatively small as shown in FIG. The air permeability of the knitted fabric 41 in this state is 110 cm ³ / cm ² · sec.

FIG. 5 is an enlarged view of the fiber 5 in which the crimp rate changes depending on the humidity in an atmosphere of 95% humidity. In an atmosphere with a humidity of 95%, the crimp ratio of the fiber 5 whose crimp ratio changes depending on the humidity is less than 10%, and as shown in FIG. It becomes a state.
FIG. 3 is an enlarged view of the knitted fabric 41 including the fibers 5 whose crimping rate changes depending on the humidity in an atmosphere with a humidity of 95%. When the fibers 5 whose crimping rate changes depending on the humidity are stretched, the stitches of the stitches 42 are reduced, and the gaps 43 between the stitches become larger than those in an atmosphere of 65% humidity as shown in FIG. The air permeability in this state is 150 cm ³ / cm ² · sec, and an air permeability of about 1.4 times can be obtained as compared with the state in an atmosphere of 65% humidity.

  Although not shown, the crimp ratio of the fiber 5 whose crimp ratio changes depending on the humidity is 20% or more in an atmosphere with a humidity of 45% or less. It becomes a state. As a result, the stitches 42 are further crushed than the state shown in FIG. 2, and the gaps 43 between the stitches are further reduced.

  Although not shown, even when the fabric 4 of the present invention is made of a woven fabric, the crimp rate of the fibers 5 whose crimp rate changes depending on the humidity becomes small in an atmosphere with a humidity of 95%, so By increasing the gap, it is possible to obtain a higher air permeability as compared with a state in an atmosphere of 45% humidity and 65% humidity.

  Now, the humidity inside the shoe is usually the same as the outside of the shoe before wearing, and is about 45% when it is in the most dry state in winter, and about 50% to 75% in other seasons. In addition, when worn, it increases to about 95% by walking for about 30 minutes regardless of the season.

Therefore, by using only the fibers 5 whose crimping rate changes according to the humidity or the fabric 4 containing the fibers as the material of the upper 2, the size of the gap 43 in the fabric 4 can be changed according to the change in the humidity inside the shoe 1. By changing, the air permeability of the fabric 4 changes, and the air inside the shoe 1 can be vented to the outside of the shoe 1.
That is, immediately after wearing in winter, the humidity inside the shoe 1 is low and the gap 43 is small, so that the air outside the shoe 1 does not ventilate the inside of the shoe 1 and can prevent the inside of the shoe 1 from cooling. Further, when the humidity inside the shoe 1 is increased after wearing and in the summer, the air inside the shoe 1 can be vented to the outside of the shoe 1 by increasing the gap 43.

  It is preferable that the fiber whose crimping rate changes with humidity is composed of cellulose acetate fiber.

  Considering the effect, the proportion of cellulose acetate fibers contained in the fabric 4 is desirably 20% or more. Further, considering strength, 80% or less is desirable.

  FIG. 6 is a schematic diagram of a double Russell mesh 6 in which the fabric 4 has a three-layer structure and one surface 61 is composed of fibers 5 whose crimping rate changes with humidity.

As the humidity increases, the crimp rate of the fibers 5 whose crimp rate changes due to the humidity in the surface 61 of the double Russell mesh 6 decreases, and the gap 43 increases. On the other hand, when the humidity rises, the fibers 5 whose crimping rate changes due to the humidity are stretched. As a result, the entire stitch 42 in the surface 61 is stretched, and the fibers 5 whose crimping rate changes due to the humidity are shrunk. Compared with the case where it exists, the area of the whole surface 61 will increase.
Therefore, as shown in FIG. 6, the connecting yarn 62 and the other surface 63 are made of fibers that do not include the fiber 5 whose crimping rate changes depending on the humidity, and a three-layer structure is used. Even when the fiber 5 whose crimping rate changes due to the humidity of the surface 61 is stretched, the connecting yarn 62 and the other surface 63 are not stretched. Therefore, the area of the entire double raschel mesh 6 does not change and has a certain size. I can keep it.

  The connecting yarn 62 and the other surface 63 of the double raschel mesh 6 are preferably made of polyester fibers.

  Since the polyester fiber has high tensile strength, the rupture strength of the double raschel mesh 6 can be improved and the durability can be improved by forming the connecting yarn 62 and the other surface 63 of the polyester fiber. In addition, since the polyester fiber is very quick-drying, the moist air inside the shoe can be more effectively vented to the outside of the shoe.

  In addition to polyester fibers, other fibers having the same effect such as nylon fibers, covered yarn fibers obtained by wrapping polyester elastic fibers or nylon fibers around polyurethane elastic fibers, and the like can be considered.

  FIG. 7 is a perspective view of a shoe according to an embodiment of the present invention. As shown in FIG. 7, the hatched portion, that is, the upper bevel portion 22 may be formed of the fabric 4 and / or the double raschel mesh 6.

  Usually, the area that sweats most with the foot is near the upper finger. Therefore, by constituting the tongue portion 22 with the fabric 4 and / or the double raschel 6, the air inside the shoe can be vented to the outside more efficiently.

  FIG. 8 is a perspective view of a shoe according to an embodiment of the present invention. As shown in FIG. 8, the upper portion 21 of the upper 2 may be composed of the fabric 4 and / or the double raschel mesh 6.

The instep portion 21 is a portion indicated by hatching in FIG. 8 and is a portion of the upper 2 that mainly covers the front foot portion excluding the bevel portion 22 and the mouth portion 23.
The upper part 21 does not directly hit the toes, but is a relatively sweaty part. By forming this part with the fabric 4 and / or the double raschel 6, the air inside the shoe 1 can be more efficiently exhausted. It can be vented to the outside.

  FIG. 9 is a perspective view of a shoe according to an embodiment of the present invention. As shown in FIG. 9, the upper finger portion 24 on the upper portion 21 of the upper 2 may be constituted by the fabric 4 and / or the double raschel mesh 6.

The upper finger portion 24 is a portion indicated by hatching in FIG.
Since the upper finger portion 24 is a portion where the humidity is particularly high in the upper portion 21, the air inside the shoe 1 is more efficiently externalized by configuring only the upper finger portion 24 with the fabric 4 and / or the double raschel 6. Can be ventilated.
Moreover, since the toe portion is a portion that requires wear resistance, the portion 25 other than the upper finger portion 24 can be made of artificial leather having excellent wear resistance.

It is preferable that the surface 61 composed of the fibers 5 whose crimping rate varies depending on the humidity is located inside the shoe 1.
By configuring the inner surface 61 of the shoe 1 with the fibers 5 whose crimping rate changes according to the humidity, the gap 43 becomes larger in response to the humidity change inside the shoe 1 and the air inside the shoe 1 more efficiently. Can be vented to the outside.

Moreover, you may comprise so that the surface 61 comprised with the fiber 5 from which a crimp rate changes with humidity may come in the outer side of the shoes 1. FIG.
By placing the fiber 5 whose crimp rate changes due to humidity in a part that does not directly touch the foot, it is possible to prevent a change in the area of the surface 61 due to the change in the crimp rate from being felt directly on the foot. A feeling of insertion can be obtained.

  The same effect can be obtained when a knitted fabric other than a double raschel or a woven fabric is used as the upper 2 of the shoe 1 including the fiber 5 whose crimping rate changes with humidity.

  As an example of use of the present invention, sports shoes for competitions such as tennis, baseball, basketball, soccer, golf, table tennis, etc., as well as use for shoes intended only for walking such as walking, men's shoes, women's shoes, etc. Is also suitable.

1 is an overall perspective view of a shoe 1 of the present invention. It is an enlarged view in the atmosphere of 65% of humidity of the fiber 5 whose crimping rate changes with humidity. It is an enlarged view in the atmosphere of 95% of the humidity of the fiber 5 whose crimping rate changes with humidity. It is an enlarged view in the atmosphere of 65% of humidity of the knitted fabric 41 containing the fiber 5 in which a crimping rate changes with humidity. It is an expansion schematic diagram in the atmosphere of 95% of humidity of the knitted fabric 41 containing the fiber 5 in which a crimping rate changes with humidity. It is a schematic diagram at the time of comprising the cloth | dye 4 by the double raschel mesh of a 3 layer structure. 1 is an overall perspective view of a shoe 1 according to an embodiment of the present invention. 1 is an overall perspective view of a shoe 1 according to an embodiment of the present invention. 1 is an overall perspective view of a shoe 1 according to an embodiment of the present invention.

Explanation of symbols

1: Shoes 2: Upper 21: Upper part 22: Velcro part 23: Wear mouth part 24: Upper part of finger 25: Toe part 3: Sole 4: Fabric 41: Knitted fabric 42: Knitted stitch 43: Gap 5; Humidity of 95% or more The crimp rate is less than 10%, the humidity is 65%, the crimp rate is 15 to 20% and the number of crimps is 25 pieces / inch or more, and when the humidity is 45% or less, the crimp rate is 20 % Fiber (fibers whose crimping rate changes with humidity)
6: Double Russell mesh 61: Surface 62: Connecting thread 63: The other surface

Claims (6)

In upper and sole shoes, as the upper material, the crimp rate is less than 10% when the humidity is 95% or more, the crimp rate is 15 to 20% and the number of crimps is 25 / inch when the humidity is 65%. A shoe characterized by using only a fiber showing a crimp rate of 20% or more when the humidity is 45% or less or a part or all of a fabric containing the fiber. In claim 1,
When the humidity is 95% or more, the crimp rate is less than 10%, when the humidity is 65%, the crimp rate is 15 to 20%, the number of crimps is 25 pieces / inch or more, and the humidity is 45% or less. A shoe characterized in that the fibers having a crimp rate of 20% or more are cellulose acetate fibers. In claim 1 or 2,
The cloth is a double raschel mesh, and one surface is composed of only the fiber according to claim 1 or 2 or a fiber containing the fiber, and the other surface and the connecting yarn are according to claim 1 or 2. A shoe characterized by being composed of fibers that do not contain the described fibers. The shoe according to claim 3, wherein the other surface of the double raschel mesh and the connecting yarn are made of polyester fiber. The shoe according to any one of claims 1 to 4, wherein at least a tongue portion of the upper is made of the fabric according to any one of claims 1 to 4. The shoe according to any one of claims 1 to 5, wherein at least an upper portion of the upper is made of the fabric according to any one of claims 1 to 4.

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