JP2011127265A - Rubber glove - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a pair of rubber gloves by joining to the inside of the rubber gloves, an ultrathin fiber sheet demonstrating combined effects of heat insulation effect, moisture absorption effect, and deodorant effect in cold-water work. <P>SOLUTION: The pair of rubber gloves 10 is such that an ultrathin fiber sheet 30 made of a stretch material of hollow spun yarn 30A and cation dyeable atypical cross section polyester 30B is joined or stuck to the inside 10A of the rubber gloves 10. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a rubber glove, and more particularly to a rubber glove in which an ultra-thin fiber sheet that exhibits a combined effect of a heat retaining effect, a moisture absorbing effect, and a deodorizing effect is bonded or adhered to the inner surface of the rubber glove.

  Conventional rubber gloves, for example, have a rubber odor, cause a decrease in the temperature of the entire hand, including cold hands during cold water work in winter, cause blood circulation failure, and lack moisture absorption in the gloves. It is generally known that the hand skin is softened by wearing for a long time and is torn by the fingernail during use.

  Accordingly, various rubber gloves that have improved the above-described drawbacks and problems have been provided. Specifically, examples of known examples are: First, in the beauty and medical treatment of the human body, silicone rubber is mixed with a powder of a natural mineral that emits negative ions and far-infrared rays, and shaped into a glove shape. A silicone rubber glove for medical use for beauty and medical use is provided. Its composition is glove-like that has an effect on the surface of the human body and skin by mixing mineral powder that emits negative ions such as germanium and tourmaline and far-infrared rays into resin such as silicone rubber as a beauty and medical base material. A silicone rubber glove for beauty and medical use that produces negative ions and far-infrared rays on the base of the silicone rubber glove that can be combined with germanium, tourmaline, and silicone rubber, and has an effect on the human skin. Yes, it can also be used for massage (for example, see Patent Document 1).

  In addition, even if you sweat inside rubber and vinyl gloves, there is no sticky feeling even if water enters, inner gloves that can be taken off and put on smoothly and can be disposable are provided. . Its structure is flexible and strong, and is made of a non-woven fabric made of polypropylene, etc. that has high hydrophobicity and little moisture absorption, and is cut into a hand shape that is the same size as rubber and vinyl gloves. Are bonded by heat sealing (for example, see Patent Document 2).

  Furthermore, by wearing it inside a poorly breathable glove made of vinyl, rubber, etc., even if it is used for a long time, sweating and stickiness due to sweating can be suppressed, and fluffing and falling off due to repeated use and washing An inner glove that can be used in a clean room such as a sterile room is provided. The composition is that 50% by weight or more of the yarns constituting the glove has a moisture absorption rate of 8.0% or more in an environment of 20 ° C. and a relative humidity of 65% and a wet strength of 2.5 g / d or more. An inner glove made of fiber multifilament yarn is used (see, for example, Patent Document 3).

  JP 2009-221644 A   Japanese Patent Laid-Open No. 10-325007   Japanese Utility Model Publication No. 6-61917

  The cosmetic / medical silicone rubber glove disclosed in JP-A-2009-221644 generates negative ions and far-infrared rays on a base material that can be combined with germanium, tourmaline, and silicone rubber, and has a beauty effect on the human skin. Although it provides a medical effect, it does not provide a hygroscopic effect and a deodorizing effect, and the problem of lack of moisture hygroscopicity in the gloves and the tendency to soften the hand skin by wearing for a long time has not been solved.

  The inner glove disclosed in JP-A-10-325007 has no feeling of stickiness even when sweating inside the rubber or vinyl glove or water enters, and it can be taken off and put on smoothly. Also, it can be disposable. However, it does not bring about a heat retaining effect and a deodorizing effect, and the problem of lack of heat retaining properties and deodorizing properties in gloves and a problem that a hand is not warmed and becomes a rubber odor due to wearing for a long time has not been solved.

  Furthermore, the inner glove disclosed in Japanese Utility Model Publication No. 6-61917 is worn inside a rubber or other poorly breathable glove, so that even when used for a long time, sweating and stickiness due to sweating can be suppressed. It can be used in clean rooms such as an aseptic room. However, it does not bring about a heat retention effect and a deodorization effect, and during cold water work in winter, it causes a decrease in the temperature of the entire hand, including the cooling of the fingertips, resulting in blood circulation failure, as well as heat retention and deodorization in the gloves. The problem of lack of heat and lack of rubber odor due to lack of wear for a long time has not been solved.

  The present invention has been made in view of the problems in the rubber gloves, and in particular, an ultra-thin fiber sheet that exhibits a combined effect of a heat retaining effect, a moisture absorbing effect, and a deodorizing effect during cold water work is bonded to the inner surface of the rubber glove. Rubber gloves are provided.

  In order to achieve the above object, the rubber glove according to claim 1 of the present invention is characterized in that an ultra-thin fiber sheet exhibiting heat retention, moisture absorption and deodorization is bonded or adhered to the inner surface of the rubber glove.

  The rubber glove according to claim 2 of the present invention is the rubber glove according to claim 1, wherein the ultra-thin fiber sheet is a stretch material of hollow spun yarn and cationic dyeable atypical cross-section polyester.

  The rubber glove according to claim 3 of the present invention is the rubber glove according to claim 1, wherein the ultra-thin fiber sheet is obtained by micronizing (1.0 dtex) the fineness of acrylic fiber.

  The rubber glove according to claim 4 of the present invention is the rubber glove according to claim 1 or 2, wherein the ultra-thin fiber sheet is obtained by applying a fragrance to the surface thereof.

  According to the rubber glove of the present invention, the hollow spun yarn and the ultra-thin fiber sheet made of the cationic dyeable atypical cross-section polyester stretch material are bonded or adhered to the inner surface of the rubber glove. Drying and thinning quickly absorbs, diffuses, and evaporates sweat to provide moisture absorption and deodorization, and provides a combined function of keeping the body cool with an optimal fit with stretch material. In particular, during cold water work in winter, the temperature of the entire hand, including the cooling of the fingertips, is prevented and blood circulation failure does not occur, and comfortable workability is exhibited.

  According to the rubber glove of the present invention, since the ultra-thin fiber sheet having a micronized acrylic fiber (1.0 dtex) is bonded or adhered to the inner surface of the rubber glove, there are many soft feelings due to microacrylic and air pockets between the fibers. It is created to improve heat retention, and provides a moist wearing feeling with milk protein-containing rayon, as well as a combined function with a heat-retaining effect that prevents the body from cooling down with an optimal fit with stretch material. In particular, during cold water work in winter, the temperature of the entire hand, including the cooling of the fingertips, is prevented and blood circulation failure does not occur, and comfortable workability is exhibited.

  Further, according to the rubber glove, since the fragrance is applied to the ultra-thin fiber sheet on the inner surface of the rubber glove, the antibacterial effect by the high-order processing technique is also exhibited.

  In the 1st Embodiment of this invention, it is the perspective view and sectional drawing of a rubber glove.   It is sectional drawing of the ultra-thin fiber sheet joined or closely_contact | adhered in rubber gloves in the 1st Embodiment of this invention.   FIG. 3 is a cross-sectional view of an action of a rubber glove in the first embodiment of the present invention.   In the 2nd Embodiment of this invention, it is the perspective view and sectional drawing of a rubber glove.   It is sectional drawing of the ultra-thin fiber sheet joined or closely_contact | adhered in rubber gloves in the 2nd Embodiment of this invention.   In the 2nd Embodiment of this invention, it is an effect | action sectional view of a rubber glove.

  Hereinafter, embodiments of the present invention will be described sequentially with reference to FIGS. 1 to 6.

  The rubber glove which becomes the 1st Embodiment of this invention is shown in FIGS. 1-3. The rubber glove 10 is made of a synthetic resin material 20 such as a vinyl chloride resin or an acrylic resin, and is molded by applying various materials having appropriate elasticity when being attached to and detached from the hand 40. An ultrathin fiber sheet 30 that exhibits heat retention, moisture absorption, and deodorization is bonded or adhered to the inner surface 10 </ b> A of the rubber glove 10. The ultra-thin fiber sheet is a stretch material having stretch properties composed of hollow spun yarn 30A and cationic dyeable atypical cross-section polyester 30B. The cationic dyeable atypical cross-section polyester 30B has a star-shaped cross section, which is intertwined with the hollow spun yarn 30A to form an ultrathin fiber sheet 30 in which the surface area of the yarns is doubled. This large surface area quickly absorbs sweat from the hand skin 40A wearing rubber gloves and diffuses it to evaporate the moisture of the sweat A. Also, the body temperature at which the space closed by the large surface area is emitted from the hand skin It has a function that does not escape. Further, the ultrathin fiber sheet 30 is coated with a fragrance on the surface thereof.

  Next, the operation of the rubber glove 10 will be described with reference to FIG. An ultra-thin fiber sheet 30 that exhibits heat retention, moisture absorption, and deodorization is bonded or adhered to the inner surface of the rubber glove 10. When this rubber glove 10 is attached to the hand 40, the entire hand is wrapped by an ultrathin fiber sheet made of stretch material made of a stretchable material made of hollow spun yarn 30A and cationic dyeable atypical cross-section polyester 30B. High heat retention by the hollow spun yarn is realized. Further, the cationic dyeable atypical cross-section polyester 30B has a star-shaped cross section, and due to the wide surface area of the ultrathin fiber sheet 30 in which the surface area of the yarns is doubled, sweating from the hand skin 40A wearing rubber gloves is quickly performed. It absorbs and diffuses to evaporate the moisture of the sweat A, and the space S closed by the large surface area does not escape the body temperature emanating from the hand skin. Furthermore, the ultra-thin fiber sheet 30 blocks the cold water outside the rubber gloves 10 and the low temperature of the cold air from propagating to the hand skin.

  According to the rubber glove 10 which becomes the 1st Embodiment of this invention, the following effect is acquired. First, high heat retention by the hollow spun yarn 30A becomes possible. That is, at the time of cold water work in winter, the temperature of the entire hand including the cooling of the fingertip is prevented and blood circulation failure does not occur, and comfortable workability is exhibited. In addition, quick drying and thinning can be achieved with the cationic dyeable atypical cross-section polyester 30B, and a feeling of fitting in which the entire hand is wrapped with an ultra-thin fiber sheet of stretch material is obtained. Furthermore, since the fragrance | flavor is apply | coated to the surface of the ultra-thin fiber sheet 30, there is no rubber odor and the deodorizing effect is acquired. And antibacterial property is also provided by the high-order processing technique of an ultra-thin fiber sheet.

  Next, the rubber glove 11 which becomes the 2nd Embodiment of this invention is shown in FIGS. The rubber glove 11 is made of a synthetic resin material 20 such as a vinyl chloride resin or an acrylic resin, and is formed by applying various materials having appropriate elasticity when attached to and detached from the hand. An ultrathin fiber sheet 33 that exhibits heat retention, moisture absorption, and deodorization is bonded or adhered to the inner surface 11A of the rubber glove 11. The ultra-thin fiber sheet is made of a micronized (1.0 dtex) fineness of acrylic fiber. As a result, the soft feeling is improved and many air pockets AP between the fibers are created to create a heat retaining function. With this wide air pocket AP, sweat from the hand skin 40A wearing rubber gloves is quickly absorbed and diffused to evaporate the moisture of the sweat A, and the space closed by the wide air pocket AP is emitted from the hand skin. It has a function that does not let the body temperature escape to the outside. Further, the ultrathin fiber sheet 33 is coated with a fragrance on its surface.

  Next, the operation of the rubber glove 11 will be described with reference to FIG. An ultrathin fiber sheet 33 that exhibits heat retention, moisture absorption, and deodorization is bonded or adhered to the inner surface 11A of the rubber glove 11. When the rubber glove 11 is attached to the hand 40, an ultra-thin fiber sheet with micronized acrylic fibers (1.0 dtex) is joined to the inner surface of the rubber glove. Blocks low temperature transmission to the hand skin. That is, in the ultra-thin fiber sheet 33, a lot of softness due to micro acrylic and air pocket AP between the fibers are created, and by this air pocket AP, the cold water outside the rubber gloves 11 and the low temperature of cold air propagate to the hand skin 40A. While blocking | blocking doing, while absorbing the sweat A spilling from a hand quickly, skin temperature is confined and heat retention property improves. In addition to the moist wearing feeling of milk protein-containing rayon, it also has a combined function with a heat-retaining effect that prevents the body from getting cold with an optimal fit feeling due to stretchable stretch material.

  According to the rubber glove 11 which becomes the 2nd Embodiment of this invention, the following effect is acquired. Ultra-thin fiber sheets with micronized acrylic fibers (1.0 dtex) are joined to the inner surface of rubber gloves, creating a soft feeling with microacrylic and a lot of air pockets between fibers, improving heat retention, and milk In addition to the moist wearing feeling of protein-containing rayon, the combined function with the heat-retaining effect that prevents the body from cooling down with the optimal fit of the stretch material is demonstrated. In particular, during cold water work in winter, the temperature of the entire hand, including the cooling of the fingertips, is prevented and blood circulation failure does not occur, and comfortable workability is exhibited.

  Furthermore, according to each of the rubber gloves 10 and 11, the antibacterial effect by the high-order processing technology is also exhibited, and by applying the fragrance to the ultra-thin fiber sheet on the inner surface of the rubber glove, the rubber odor and bad odor are eliminated, and the rubber is high. Gloves are obtained.

  In the present invention, the object is described in the example of the rubber glove. However, the present invention can be applied to various products including leather gloves.

DESCRIPTION OF SYMBOLS 10 Rubber gloves 10A Inner surface 11 Rubber gloves 11A Inner surface 20 Synthetic resin material 30 Super thin fiber sheet 30A Hollow spun yarn 30B Cationic dyeable atypical cross section polyester 33 Ultra thin fiber sheet 40 Hand 40A Hand skin A Sweat AP Air pocket S Space

Claims (4)

  A rubber glove wherein an ultra-thin fiber sheet exhibiting heat retention, moisture absorption and deodorization is bonded or adhered to the inner surface of the rubber glove.   2. The rubber glove according to claim 1, wherein the ultra-thin fiber sheet is a stretch material of hollow spun yarn and cationic dyeable atypical cross section polyester.   2. The rubber glove according to claim 1, wherein the ultra-thin fiber sheet is obtained by micronizing (1.0 dtex) the fineness of acrylic fiber.   3. The rubber glove according to claim 1, wherein the ultra-thin fiber sheet has a surface coated with a fragrance.

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