JP2021014677A - Heat insulating sock - Google Patents

Abstract

To provide a sock made of a fiber cloth with high heat insulation property and heat retaining property.SOLUTION: In a heat insulating sock 26 made of a fiber cloth, the sock is folded inside from a tip, a tip part is fixed to the fiber cloth from an inner side at a position of a heel part or an instep part. One of a surface or a rear face of the sock 26 is a treble fiber cloth and the other is a single fiber cloth. It is preferable that a Japanese sock portion is formed to be long, a depression part is formed in an intermediate part of a Japanese sock, and the tip to the depression part of the Japanese sock are folded to thin a toe portion and fit the sock to the toes in the sock 26.SELECTED DRAWING: Figure 7

Description

The present invention relates to heat insulating socks made of fiber fabric.

Heat-resistant gloves are required from the viewpoint of safety for welding work such as arc welding, pre-furnace work such as a blast furnace, and work handling high-temperature objects such as cooking. Animal skin is generally used as the material for heat-resistant gloves in thermally demanding work. Applicants make heat-resistant gloves using design twisted yarns containing heat-resistant fibers such as aramid fiber, polybenzimidazole fiber, polybenzoxazole fiber, polybenzazole fiber, polyamide-imide fiber, melamine fiber and polyimide fiber. It was proposed (Patent Document 1). Further, Patent Document 2 proposes that a glove is knitted using a single aramid fiber yarn and a synthetic resin is heat-sealed to a palm portion. Further, Patent Document 3 proposes a sock made of a fiber fabric having a double structure.

JP-A-2007-023463 Utility model registration No. 3048633 Japanese Unexamined Patent Publication No. 11-323608

However, conventional socks have problems in heat insulation and heat retention, and higher heat insulation is required.

The present invention provides socks made of fiber fabric having high heat insulation and heat retention in order to solve the above-mentioned conventional problems.

The heat insulating sock of the present invention is a heat insulating sock made of a fiber fabric, and the sock is folded inward from the tip, and the tip is inside the fiber fabric at either the heel or the instep. It is characterized in that either the front surface or the back surface of the sock is a triple fiber fabric and the other is a single fiber fabric.

In the heat insulating sock of the present invention, since either the front surface or the back surface is a triple fiber fabric and the other is a single fiber fabric, the heat insulating property can be exhibited in the triple fiber fabric portion. The single fiber fabric portion of the sock can satisfactorily retain the motion function of the foot.

FIG. 1 is a back view showing a state before folding of a knitted heat insulating glove of a reference example of the present invention. FIG. 2 is a back view showing a state after folding. FIG. 3 is a cross-sectional view taken along the line II of FIG. FIG. 4 is a back view showing a state before folding of the knitted heat insulating gloves of another reference example of the present invention. FIG. 5 is a cross-sectional view showing a state after the heat insulating gloves of FIG. 4 are folded. FIG. 6 is a back view showing a state before folding of the knitted heat insulating socks according to the embodiment of the present invention. FIG. 7 is a cross-sectional view showing a state after the tip of the heat insulating sock of FIG. 6 is folded inward and fixed on the upper side (instep side). FIG. 8 is a cross-sectional view showing a state after the tip of the heat insulating sock of FIG. 6 is folded inward and fixed on the lower side (sole side). FIG. 9 is a cross-sectional view showing a state in which the heat insulating sheet is inserted into the triple portion on the lower side (sole side) of the heat insulating sock of FIG.

The heat insulating glove made of the fiber cloth of the present invention is folded inward from the tip of the finger bag, and the tip is fixed to the fiber cloth from the inside at a position above the wrist or below the base of the finger bag. When inserted, either the palm or the instep of the finger becomes a triple fiber fabric and the other becomes a single fiber fabric. As a result, heat can be blocked from external heat by arranging the triple fiber fabric portion on the instep side and wearing it. Further, when gripping a hot object, the heat can be blocked by arranging the triple fiber fabric portion on the palm side and wearing it. In this specification, the example of gloves is a reference example.

The heat is the same even if it is replaced with a cold one or a cold one. The triple fiber fabric portion contains a large amount of air in the structure of the fiber fabric, and the air has a high heat insulating property, so that the heat insulating property is high. Whether the triple fiber fabric portion is arranged on the palm side or the instep side can be selected by wearing it on the right hand or the left hand when wearing it. The heat blocking portion is effective for heat blocking on the palm side or the instep side of the finger.

The glove may be further folded in half with the palm portion upward, and the tip of the folded in half may be fixed to the fiber fabric from the inside at a position below the base of the finger bag. As a result, the heat insulating property can be improved at the portion folded in half. The heat blocking portion is effective for heat blocking the palm and the upper part of the instep.

The glove may be further folded in half with the wrist portion upward, and the tip of the folded in half may be fixed to the fiber cloth from the inside near the base of the thumb bag. As a result, the heat insulating property can be improved at the portion folded in half. The heat blocking portion is effective for heat blocking between the palm and the lower part of the instep.

A heat insulating sheet is provided inside at least one selected from a portion in which the finger bag is folded inward from the tip, a portion in which the palm portion is folded in half with the palm portion facing upward, and a portion in which the wrist portion is folded in half with the wrist portion facing upward. You may insert it. As the heat insulating sheet, a non-woven fabric, leather, resin, metal, ceramics, woven fabric, knitting, an inorganic sheet such as mica or silica fiber can be used. As a result, the heat insulating property can be further improved. A heater wire or a signal wire can also be inserted into the portion where the finger bag is folded inward from the tip. The heater wire is effective against the cold. The signal line is effective for, for example, car navigation, music selection, games, or switching between them.

The heat insulating sock of the present invention is made of a fibrous fabric, is folded inward from the tip, and the tip is fixed to the fibrous fabric from the inside at either the heel or the instep, and the sock. Either the front surface or the back surface of the fabric is a triple fiber fabric, and the other is a single fiber fabric. By arranging the triple fiber fabric part on the instep (sole) side, heat from the upper surface of the foot can be blocked, and the heat retention effect is high when it is cold. By arranging the triple fiber fabric part on the sole side, the heat from the back surface of the foot can be blocked, and the heat retention effect is high when it is cold. The heat from the back of the foot may cause the surface of metal or concrete at a construction site to become hot, for example, under summer sunlight, and is effective for heat insulation when working in such a place.

A heat insulating sheet may be inserted inside the sock in which either the front surface or the back surface is made of triple fiber fabric. When the fiber fabric on the back of the foot is tripled, an inner sole type heat insulating sheet can be inserted into the internal space. As the material of the heat insulating sheet, the same material as that described for the gloves can be used. When the inner sole type heat insulating sheet is made of metal or resin, the nail stepping prevention function can also be exhibited.

The fiber fabric of the heat insulating fabric is preferably knitted. Since the knit is stretchable, it is convenient to fix each folded portion from the inside by sewing with a sewing machine. Knitted gloves or socks can be switched between right and left. Besides, it can be washed.

The fiber fabric includes cellulose fibers such as cotton and linen, wool, polyester fibers, polypropylene fibers, polyamide fibers, acrylic fibers, aramid fibers, polybenzimidazole fibers, polybenzoxazole fibers, polybenzthiazole fibers, polyamideimide fibers, and melamine. It is preferably composed of at least one fiber selected from fibers, polyimide fibers, polyarylate fibers and polyphenylene sulfide fibers. Of these, heat-resistant fibers such as aramid fiber, polybenzimidazole fiber, polybenzoxazole fiber, polybenzthiazole fiber, polyamideimide fiber, melamine fiber, polyimide fiber, polyarylate fiber, and polyphenylene sulfide fiber are preferable for heat. For cold weather, ordinary fibers such as cotton, wool, polyester fiber, polypropylene fiber, polyamide fiber and acrylic fiber are preferable.

In the present invention, the heat-resistant fiber may be any inorganic fiber or organic fiber as long as it has a melting point or a decomposition point of about 350 ° C. or higher, preferably 400 ° C. or higher. Preferably, aramid fiber (melting point or decomposition point of para-aramid: 480 to 570 ° C., meta-type: 400 to 430 ° C.), polybenzimidazole fiber (glass transition temperature: 400 ° C. or higher, thermal decomposition temperature exceeding 600 ° C.), Polybenzoxazole fiber (melting point or decomposition temperature: 650 ° C), polybenzthiazole fiber (melting point or decomposition temperature: 650 ° C), polyamideimide fiber (melting point or decomposition temperature: 350 ° C or higher), melamine fiber (melting point or decomposition temperature:: (400 ° C. or higher), polyimide fiber (melting point or decomposition temperature: 350 ° C. or higher), polyallylate fiber (melting point or decomposition temperature: 400 ° C. or higher), polyphenylene sulfide fiber (melting point: about 280 ° C. or higher) and the like are preferable. These fibers are easy to process into knitted fabrics. The fineness is preferably about 118 to 5905 dtex (cotton count: 0.5 to 50). It can be used as a single yarn, multiple yarns can be aligned, or twisted and used.

In the present invention, the design twisted yarn described in Patent Document 1 may be used. As an example, the design twisted yarn is composed of a core yarn, a loop yarn (flower yarn) and a holding yarn, and the loop yarn (flower yarn) is preferably at least one selected from cotton, rayon, hemp, wool and acrylic fiber. .. For example, polyester filament yarn can be used as the core yarn and the pressing yarn. The heat-resistant fiber yarn can be used as a core yarn, a loop yarn (flower yarn), or a holding yarn. If the loop yarn is created by overfeeding the core yarn 2 to 6 times, loops can be randomly formed around the core yarn in all directions. The fineness of the design twisted yarn is preferably about 118 to 11811 dtex (cotton count: 0.5 to 50). It can be used as a single yarn, multiple yarns can be aligned, or twisted and used.

The fibrous fabric may have a multi-layer structure, and a knit may be formed so that a large amount of heat-resistant fiber yarns are present on one surface and a large amount of design twisted yarns are present on the other surface. The organization of such knits includes at least one organization selected from double knits, double jerseys, double-sided knits, double raschels, double knits, single jerseys and smooth knits.

In the above-mentioned structure, some loops of the loop yarn may protrude to the rich surface of the heat-resistant fiber yarn. In this case, the loops appearing on the outer surface are cut to form a cut pile. Is preferable. In this way, when the heat-resistant gloves are used as work gloves, the loops do not get caught in mechanical parts or the like, and the work safety is improved.

The thickness of the heat insulating glove of the present invention is preferably 0.3 mm or more and 3 mm or less, and more preferably 0.5 mm or more and 2 mm or less. The weight per unit area of the heat insulating gloves is preferably 0.09 g / cm ² or more, and more preferably 0.1 g / cm ² or more. When the thickness and the weight per unit area are in the above ranges, the combustion resistance is improved in addition to the heat blocking property.

The heat insulating gloves of the present invention are, for example, work gloves that handle high-temperature or low-temperature substances, welding work such as arc welding, gloves for pre-furnace work such as smelting furnaces, work gloves that handle high-temperature objects such as cooking, and sports gloves such as mountain climbing. It is useful for gloves and the like.

This will be described below with reference to the drawings. In the drawings below, the same reference numerals indicate the same products. FIG. 1 is a back view showing a state before folding of the knitted heat insulating gloves according to the embodiment of the present invention. The length of this glove 1 is 660 mm, which is 2 to 3 times longer than the length of a normal glove. The finger bag has five fingers, but two fingers (mittens), three fingers, etc. may be used. The length of the ring finger is 200 mm. If only the finger bag is folded back and fixed, make only the finger bag 2.1 to 2.3 times as long as a normal glove. The reason why it is slightly longer than twice as long as a normal glove is that the length of the folded part is required and that it is fixed to the fiber cloth from the inside at a position below the base of the finger bag.

FIG. 2 is a back view showing a state after being folded in the same manner, and FIG. 3 is a sectional view taken along line II of FIG. In the heat insulating glove 2 after being folded, the tip portion 4a-4e of the finger bag is folded in, and the tip portion is fixed to the fiber fabric from the inside at a position below the base of the finger bag by sewing. Reference numeral 5a-5e is a fixed portion by sewing. As a result, a finger bag 3a-3e having a hole 6a-6e in the center is formed, but when the finger 16 is inserted, either the palm or the instep of the finger 16 is triple as shown in FIG. The other is a single fiber fabric. The triple fiber fabric portion has more than three times the heat insulating property as that of the single fiber fabric. In addition, if a heat insulating sheet is inserted into the central hole 6a-6e, the heat insulating property is further improved.

The heat insulating glove 2 is further folded in half with the upper part 7 of the back of the hand and the upper part of the palm facing upward, and the tip of the double fold is fixed to the fiber fabric from the inside at a position below the base of the finger bag by sewing. , The heat insulation of the upper part of the back of the hand and the upper part of the palm can be improved. Reference numeral 8 is a portion in which the upper portion 7 of the back of the hand is folded in half with the upper portion 7 facing upward. 9a-9c and 10a-10c are fixed portions by sewing. Since a space is created between the upper portion 7 of the back of the hand and the portion 8 folded in half, if a heat insulating sheet is inserted into this space, the heat insulating property is further improved.

In this heat insulating glove 2, the wrist portion 15 is further folded in half upward, and the tip of the folded portion is fixed to the fiber cloth from the inside near the base of the thumb bag 3a to improve the heat insulating property of the palm portion. it can. Reference numeral 12 denotes a portion in which the lower portion 11 of the back of the hand is folded in half with the lower portion 11 facing upward. 13a-13d and 14a-14c are fixed portions by sewing. Since a space is created between the folded portion 12 and the lower portion 11 of the back of the hand, if a heat insulating sheet is inserted into this space, the heat insulating property is further improved. Reference numeral 15 denotes a wrist portion of the rubber knitting portion.

FIG. 4 is a back view showing a state before folding of a knitted heat insulating glove according to another embodiment of the present invention. In this glove 20, each finger bag is formed about three times longer than a normal glove. The cross-sectional view shown in FIG. 5 shows that each finger bag of the glove 20 is folded inward and the tip is fixed by sewing from the inside. The fixing portion 24 is preferably sewn with a sewing machine from the inside to the outside of the glove. As a result, the back side of the hand becomes the triple fabric portion 21, and the palm side becomes the single fabric portion 23. The triple fabric portion 21 has a heat insulating or heat retaining effect, and the single fabric portion 23 can retain the operating function. A heat insulating sheet can be inserted into the space 22 of the triple fabric portion 21. Reference numeral 25 denotes a wrist portion of the rubber knitting portion. The triple fabric portion 21 can also be on the palm side.

FIG. 6 is a back view showing a state before folding of the knitted heat insulating socks according to the embodiment of the present invention. The sock 26 has a sock portion that is about three times longer than a normal sock. There is a constricted portion 28 in the middle portion of the tabi 27 and 29, and when folded to this portion, the fingertip portion becomes thin and fits the toes. 30 is the heel and 31 is the ankle. If the tip of the tabi 27 has the same shape as the heel 30, it is easy to match when the tip of the tabi 27 is folded to the heel 30.

FIG. 7 shows a cross-sectional view showing a state after the tip of the sock is folded inward and fixed on the upper side (instep side). The fixing portion 32 is preferably sewn with a sewing machine from the inside to the outside of the sock. As a result, the upper side (instep side) of the foot becomes a triple fabric, which is effective for heat insulation or heat retention. A heat insulating sheet may be inserted in the triple fabric portion. Since the sole side is made of a single material, the movement function of the foot can be well maintained.

FIG. 8 is a cross-sectional view showing a state after the tip portion of the heat insulating sock of FIG. 6 is folded inward and fixed on the lower side (sole side). The fixing portion 33 is preferably sewn with a sewing machine from the inside to the outside of the sock. As a result, the sole side of the foot becomes a triple fabric, which is effective for heat insulation or heat retention. Further, as shown in FIG. 9, the heat insulating sheet 34 can be inserted into the triple portion on the lower side (sole side). By inserting a metal or resin inner sole, the nail stepping prevention function can also be exhibited.

Hereinafter, the present invention will be described in detail with reference to Examples.

(Example 1, reference example)
Five single yarns (fineness 590decitex) of cotton yarn (cotton yarn) with a cotton count of 10 used for gloves that are said to be normal work gloves are used, and a fully automatic glove knitting machine manufactured by Shima Seiki Co., Ltd. is used. Then, the knit gloves shown in FIG. 1 were knitted. The length from the tip of the ring finger to the hem of the wrist of this glove was 660 mm in the stationary state, the length from the tip of the ring finger to the base was 200 mm, and the weight was 95 g on one side. The gloves were folded as shown in FIGS. 2 and 3, and the tips of the folded portions were fixed by a sewing machine from the inside to the outside. The heat insulating gloves thus obtained are as shown in FIGS. 2 and 3, and the finger portion has a high heat insulating or heat retaining effect on one side, and the palm and the back of the hand have a high heat insulating or heat retaining effect on both sides. It could be confirmed.

(Example 2, reference example)
(1) Manufacture of design twisted yarn Polyester multifilament processed yarn (manufactured by Toray), total fineness 83 dtex (75 denier), 48 filaments are used as core yarn and presser yarn, and cotton yarn 196.9 dtex (cotton count) is used as loop yarn. : No. 30) was used. Three single cotton yarns are used, and one core yarn is supplied with an overfeed rate of 5 to 7 times and entwined. At the same time as the entanglement, the presser yarn is twisted from above at about 1000 times / m. I applied a real twist. The average protruding length of the loops of the obtained design twisted yarn was 3 mm, and an average of 70 loops per inch were projected at various angles at an angle of 360 °. The fineness of this design twisted yarn was 2511 dtex (cotton count: 2.3530, 2260 denier).
(2) Preparation of heat-resistant fiber yarns 8 or 9 yarns of 295.3 dtex (cotton count: 20) of commercially available Teijin's trade name "Conex" (meta-based aramid fiber) were used.
(3) Knitting of gloves Knitted gloves were knitted using a fully automatic glove knitting machine manufactured by Shima Seiki Co., Ltd. The heat-resistant fiber yarn was knitted at a ratio of 60% by weight, and the design twisted yarn was knitted at a ratio of 40% by weight. The knitting structure is double-sided knitting. The heat-resistant fiber yarn is arranged on the front surface side (outside air side), the design twisted yarn is arranged on the back surface side (human body side), and the loop is mainly present on the back surface side, but a part is also exposed on the front surface side. It was. The weight of one of the obtained gloves was 95 g.
(4) Heat resistance test When the obtained heat resistant work gloves were put in the hand and the lighter was lit, the surface was slightly burnt, but no heat was felt inside. From this, flame retardancy and heat resistance could be confirmed.
Also, when used for arc welding work, it does not feel hot, it is not hot even if it is exposed to welding sparks (about 1200 ° C), it is thin and does not impair work operation, it has breathability, and workability is extremely good. It was. It could be washed after work and could be used repeatedly.
Also, when it was used for cooking work to bake a pizza pie in a combustion furnace, it also has high heat insulation, heat resistance, flame resistance, flame retardancy, breathability, good workability, and can be washed. The hygiene was also good.

(Example 3, reference example)
Five spun yarns (fineness 590decitex) of cotton yarn (cotton yarn) having a cotton count of 10 were used as single yarns, and a fully automatic glove knitting machine manufactured by Shima Seiki Co., Ltd. was used to knit the knit gloves shown in FIG. The length from the tip of the ring finger to the hem of the wrist of this glove was 420 mm in the stationary state, the length from the tip of the ring finger to the base was 300 mm, and the weight was 85 g on one side. Each finger bag of this glove was folded as shown in FIG. 5, and the tip of each folded portion was fixed by a sewing machine from the inside to the outside. The heat-insulating gloves thus obtained have a high heat-insulating or heat-retaining effect on the entire instep side including the fingers, and the palm side retains operation functions such as work.

(Example 4)
Made by Shima Seiki Co., Ltd., using two spun yarn twin yarns (equivalent to 15th single yarn) and one nylon 77.8decitex twin yarn (155.6decitex) of cotton yarn (cotton yarn) with a cotton count of 30. The knit socks shown in FIG. 6 were knitted using a fully automatic glove knitting machine. The length from the tip of the sock to the hem of the heel was 380 mm in the stationary state, the total length was 500 mm, the width of the tabi was 110 mm, and the weight was 38 g on one side. The finger bag of this sock was folded as shown in FIG. 7, and the tip of the folded portion was fixed by a sewing machine from the inside to the outside. The heat-insulating socks obtained in this way had a high heat-insulating or heat-retaining effect on the instep side. The foot movement function was retained on the sole side of the foot.

(Example 5)
Made by Shima Seiki Co., Ltd., using two spun yarn twin yarns (equivalent to 15th single yarn) and one nylon 77.8decitex twin yarn (155.6decitex) of cotton yarn (cotton yarn) with a cotton count of 30. The knit socks shown in FIG. 6 were knitted using a fully automatic glove knitting machine. The length from the tip of the sock to the hem of the heel was 460 mm in the stationary state, the total length was 580 mm, the width of the sock was 110 mm, and the weight was 43 g on one side. The finger bag of this sock was folded as shown in FIG. 8, and the tip of the folded portion was fixed by a sewing machine from the inside to the outside. The heat-insulating socks obtained in this way had a high heat-insulating or heat-retaining effect on the sole side of the foot. The movement function was retained on the instep side.

The heat insulating gloves of the present invention are, for example, work gloves that handle high-temperature or low-temperature substances, welding work such as arc welding, gloves for front-end work such as a smelting furnace, work gloves that handle high-temperature objects such as cooking, and sports gloves such as mountain climbing. It is useful for gloves and the like. In addition, when metal or resin (including gel) is inserted into the hole and / or the folded portion of the finger bag, it is also useful as a glove with a blade-proof, vibration-proof, and pinch-injury cushioning material.
Further, the socks of the present invention are useful as work socks at a construction site, for example, and can also exhibit heat insulating properties, heat retaining properties, and nailing prevention functions.

1 Gloves before folding 2,20 Insulated gloves 3a-3e Finger bag 4a-4e Tip of finger bag 5a-5e, 9a-9c, 10a-10c, 13a-13d, 14a-14c Fixed part by sewing 6a-6e Hole 7 Upper part of the back of the hand 8,12 Folded part 11 Lower part of the back of the hand 15,25 Wrist 16 Finger 21 Triple fabric part 22 Space part 23 Single fabric part 24,32,33 Fixed part 26 Socks 27,29 Socks 28 Constriction of foot bag 30 Heel 31 Ankle 34 Insulation sheet

Claims (6)

Insulated socks made of fiber fabric
The sock is folded inward from the tip, and the tip is fixed to the fiber fabric from the inside at either the heel or the instep.
A heat insulating sock characterized in that either the front surface or the back surface of the sock is a triple fiber fabric and the other is a single fiber fabric. The heat-insulating sock according to claim 1, wherein a heat-insulating sheet is inserted inside the sock in which either the front surface or the back surface is made of a triple fiber fabric. The heat insulating sock according to claim 1 or 2, wherein the fiber fabric is knitted. The heat insulating socks include cellulose fibers, wool, polyester fibers, polypropylene fibers, polyamide fibers, acrylic fibers, aramid fibers, polybenzimidazole fibers, polybenzoxazole fibers, polybenzthiazole fibers, polyamideimide fibers, melamine fibers, and polyimide fibers. The heat insulating sock according to any one of claims 1 to 3, which is composed of at least one fiber selected from polyarylate fiber and polyphenylene sulfide fiber. The heat-insulating sock according to any one of claims 1 to 4, wherein the yarn constituting the fiber fabric of the heat-insulating sock is a design twisted yarn. The sock has a long sock portion, a constricted portion is provided in the middle portion of the tabi, and the sock is folded from the tip of the sock to the constricted portion to make the fingertip portion thin and fit the toes. Insulation socks described in either.