KR200301420Y1 - Cut-Resistance Glove - Google Patents

Abstract

The present invention relates to an anti-cutting glove, comprising: an outer layer woven from a first composite yarn; And an inner layer woven from the second composite yarn. The first composite yarn includes two strands of stainless steel and one strand of dyinima spun yarn twisted in the form of twisted yarns with the stainless steel yarn in the middle, and the second composite yarn is a strand of spandex and one strand surrounding the spandex yarn. Includes Inimasa. Cutting prevention gloves of the present invention is characterized in that the first composite yarn and the second composite yarn is woven using a double rain system.

Description

Cut-resistant gloves {Cut-Resistance Glove}

The present invention relates to an anti-cutting glove, and more particularly, a composite yarn composed of stainless steel and Dyneema spun yarn and a composite yarn composed of spandex yarn and Dyneema yarn are woven into an outer layer and an inner layer, respectively, to improve cutting resistance and elasticity. It relates to a protective glove.

Cut-resistant gloves are used to protect the hands of users who are susceptible to trauma by dangerous work or by sharp or sharp means. In order to prevent the trauma glove from being easily cut, the glove is generally woven with a yarn made of a material having cutting resistance and abrasion resistance even by a sharp instrument such as a knife.

Cutting prevention gloves according to the prior art is woven from Dyneema Yarn (a kind of cut resistant yarn). This Dyneema yarn has a size of about 400 Denier. The term denier is one of the bowel number, and refers to an international unit mainly used to express the thickness of yarn or fibers such as raw silk, silk, or synthetic fiber. Denier is denoted by the customary code d or D, and the standard weight is 450 m and the unit weight is 0.05 g. That is, denier D is calculated by the following equation.

Therefore, the larger the denier value, the greater the density, and the smaller the denier value, the thinner and smaller the density.

Cut-resistant gloves woven in Dyneema Yarn meet a performance level in the range of cutting strength 0-5. Dyneema is a polyethylene-based fiber that has a specific strength and inelasticity of 3 GPa or more in tensile strength and 172 GPa in tensile modulus, excellent absorption of impact energy, and low density, making it lightweight. It is a kind. Dyneema is used to manufacture cut-resistant gloves, body armor, bulletproof helmets, ropes, fishing lines and fishing nets.

Another type of cut protection glove is woven from a composite yarn, in which Dyneema yarn is twisted on a stainless steel yarn having a diameter of about 60 μm.

Another type of cut resistant glove is woven from two strands of stainless steel and two or more strands of polyester yarn with a thickness of about 150 deniers.

According to the European standard (EN388), the aforementioned cut-protective gloves have a blade cut resistance in the range of 0-5.

However, the cut prevention glove woven by the above-described prior art has a disadvantage in that the cut resistance and the wear resistance are good, but the elasticity is not good and the texture felt by the user wearing the cut prevention glove is not good.

Therefore, it is an object of the present invention to provide elastic cut protection gloves as well as cut resistance and wear resistance.

Another object of the present invention is to provide a cut-proof glove with good fit and free hand movement when worn.

1 is a view showing the configuration of a cut preventing glove having a double layer structure according to the present invention,

2 is a view showing the configuration of a composite yarn constituting the outer layer of the cut-proof gloves shown in FIG.

3 is a view showing the configuration of a composite yarn constituting the inner layer of the cut-proof gloves shown in FIG.

4A and 4B illustrate enlarged photographs of the knitting tissue of the outer and inner layers of the cut resistant glove, respectively, knitted in a double storm knitting manner.

<Description of the symbols for the main parts of the drawings>

100: cut protection glove 110: outer layer

120: inner layer 210, 310: composite yarn

220: stainless steel 230: Dyneema spun yarn

320: Dyneema company 330: spandex yarn

According to a preferred embodiment of the present invention for achieving the above object, it characterized by a double layer structure cut-resistant gloves comprising an outer layer woven with a first composite yarn and an inner layer woven with a second composite yarn.

The first composite yarn includes two strands of stainless steel and one strand of Dyneema spun yarn twisted in the form of a yarn with the stainless steel yarn in the middle, and the second composite yarn wraps the core yarn composed of one strand of spandex yarn and the core yarn. It includes a cover yarn composed of strand Dainima yarn.

According to another embodiment of the present invention, the Dyneema yarn of the second composite yarn is wound around the spandex yarn while the spandex yarn is pulled.

According to another embodiment of the present invention, the stainless steel yarn of the first composite yarn has a diameter of about 60 μm, and the Dynema spun yarn of the first composite yarn is composed of two strands composed of 50% of dyneema and 50% of polyamide. It is characterized by the plywood.

According to another embodiment of the present invention, the spandex yarn of the second composite yarn has a size of about 140 denier, and the Dyneema yarn of the second composite yarn has a size of about 400 denier.

According to another embodiment of the present invention, the dyneima spun yarn of the first composite yarn is wound at a turn ratio of about 100 to 500 times per meter of the stainless steel, and the dyneima yarn of the second composite yarn is It is wound at a span rate of about 300 to 600 turns per meter of spandex.

According to another embodiment of the present invention, the cut preventing glove is characterized in that the first composite yarn and the second composite yarn is woven in a double gauge method with a density of 10 gauge.

Hereinafter, with reference to the accompanying drawings a preferred embodiment of the present invention will be described in detail as follows.

1 illustrates a cut preventing glove 100 woven using a composite yarn according to the present invention. The cut protection glove 100 of the present invention shown in FIG. 1 has a double layer structure of an outer layer 110 and an inner layer 120, as can be seen in a partially enlarged cross-sectional view. The composite yarn constituting the outer layer 110 and the composite yarn constituting the inner layer 120 are double woven using a double rain knitting method to be made of cut-resistant gloves 100. The double storm system is a method in which the inside and the outside of the glove 100 are mechanically knitted simultaneously by a knitting machine instead of separately squeezing and attaching the outer layer 110 and the inner layer 120 of the cut protection glove 100 separately.

The term 'yarn' as used in the present invention means a continuous strand of woven fiber, filament or material that is suitable for knitting, weaving or weaving to form woven tissue.

The term 'composite yarn' means a yarn composed of one or more core yarns and a cover yarn surrounding the core yarns.

The term 'speaker' means to wind the thread twisted. Such yarn can increase the yarn's dead strength, impart proper round appearance, elasticity and focusing properties to the yarn, and in particular, it has the property of improving weaving during the weaving process.

FIG. 2 shows the configuration of the composite yarn constituting the outer layer 110 of the cut resistant glove 100 shown in FIG. 1.

The composite yarn 210 of the outer layer 110 shown in FIG. 2 is a single strand of dynama made by twisting two twisted strands of stainless steel 220 and 50% polyamide and 50% polyamide. Dyneema Spun Yarn 230. Each stainless steel 220 has a diameter of about 60 μm, and Dyneema spun yarn is 28 S ′ (28 male 1 strand) in size.

As illustrated in FIG. 2, the composite yarn 210 is made by twisting a Dyneema spun yarn 230 in the form of a twist yarn with two strands of stainless steel 220 in the center. At this time, the Dyneema yarn 230 is wound about 100 ~ 500 times (TM: Twist Per Meter) per meter of the two strands of stainless steel (220).

In the present invention, the same polyethylene-based Spectra ^™ , Kevlar ^™ , or Twaron ^™ may be included instead of the Dyneema constituting Dyneema spun yarn. The outer layer 110 of the cut resistant glove 100 woven from the composite yarn 210 having this configuration maintains the same performance level 5 as in the prior art.

FIG. 3 illustrates a configuration of the composite yarn 310 constituting the inner layer 120 of the cut preventing glove 100 shown in FIG. 1.

The composite yarn 310 of the inner layer 120 shown in FIG. 3 is composed of a core yarn 320 and a cover yarn 330 surrounding the core yarn 320.

The core yarn 320 includes one strand of Spandex Yarn, and the cover yarn 330 includes one strand of Dyneema yarn.

Spandex yarn used as the core yarn 320 is a synthetic yarn made of an elastic yarn of polyurethane fiber, and is melt-spun by polymerizing polyether and methylenedephenylisocynate. Spandex yarn is about 3 times stronger than ordinary rubber yarns, can be up to 5 to 8 times longer than its original length, and has higher quality than conventional rubber yarns such as lighter rubber and stronger aging resistance. have. In the present invention, a spandex yarn having a size of about 140 denier is used as the core yarn 320, and a dyneema yarn having a size of about 400 denier is used as the cover yarn 330.

In the present invention, when the cover yarn 330 is wound around the core yarn 320, the cover yarn 330 is wound around the core yarn 320 in a state where the core yarn 320 is tensioned at both sides in the longitudinal direction. . In this case, the cover yarn 330 is wound at a turn rate of about 300 to 600 times per meter of the core yarn 320. In FIG. 3, when the cover yarn 330 is wound around the core yarn 320, it is illustrated as being wound in the left edge direction, but may also be wound in the right direction.

Therefore, the inner layer 120 of the cut resistant glove 100 woven from the composite yarn 310 including spandex yarn provides a soft fit to the user wearing the cut resistant glove 100 and exhibits good elasticity.

4A and 4B show enlarged photographs of the knitted tissue of the outer layer 110 and the inner layer 120 of the anti-cut gloves 100 shown in FIGS. 2 and 3.

The outer layer 110 and the inner layer 120 of the cut resistant glove 100 are knitted simultaneously in a double storm fashion by a knitting machine. 4A and 4B illustrate knitted tissue of the outer layer 110 and the inner layer 120 of the cut resistant glove 100 woven in a double weave manner, but other knitted tissues such as plain, Reverse, Rib, Shobari, Hatchi, Liju, Gadda Fulan (Milano), Bungada Fu-Milano, SCSI, Sheephead, Links, Intarsia, Pretzel It may be knitted into any one of (Cable), Fisherman, Transfer Jaqd, Floating Jaqd, Normal Jaqd, and Valtex.

Knitting is to make loops out of thread and thread them to form new loops (or noses) that intertwine to form knits. Such knitted fabrics are also referred to as meriyas, and are classified as upper meriyas and light meriyas according to their knitting structure and the direction of supplying the yarn for forming the loop of the knitted fabric, and are fundamentally different from woven or nonwoven fabrics. In other words, the knitted fabric is a generic term for a product made by wrought iron rings formed by a string of strings of a string or a string. Woven knitted yarns form left and right loops as they move from side to side or round to form a circle, and knitting and knitting a warp thread arranged like a fabric is called a knit knitted fabric. have.

In general, the knitting machine used to manufacture gloves can be divided into circular knitting machine and flat knitting machine according to its structural form. A circular knitting machine is a machine for knitting a fabric while the needles are arranged in a circular shape, and a horizontal knitting machine is a machine for knitting a needle while the needles are arranged in a straight line. Such knitting machines are further divided into knitting machines, automatic knitting machines, and computer knitting machines, depending on the type of operation. At present, most knitting machines have been replaced by automated computer knitting machines.

Referring to the process of manufacturing the cut prevention glove 100 of the present invention is one of the knitted fabrics woven by such a knitting machine as follows.

First, one strand of the first composite yarn 210 and one strand of the second composite yarn 310 are provided to the knitting machine, and the knitting pattern of the cut prevention glove 100 is set in the knitting machine. The knitting machine used in the present invention uses, for example, a glove knitting machine made by Shima Seiki of Japan having a 10 gauge.

Herein, the term gauge is a unit representing the number of needles disposed within one inch of the knitting machine, and the density of the ten gauges means that the needle is densely knit with ten needles disposed within one inch.

Then, the pinky portion is knitted first, and then in the order of the ring finger, middle finger, index finger, palm, thumb, and wrist portion in the same manner as in the conventional manufacturing method of gloves.

When the shape of the glove is completed, one strand of rubber yarn to the first composite yarn 210 and the second composite yarn 310 in order to the glove 100 to tighten the wrist portion without coming out of the operator's hand Each of them is spliced and knitted on the wrist portion of the glove 100.

Then, the supply of the first composite yarn 210, the second composite yarn 310 and the rubber yarn is stopped, and a part of the adhesive yarn (Melting Yarn) is used at the end of the wrist portion of the glove 100. This adhesive yarn is completely knitted the glove 100, and then heated to a temperature of about 50 to 60 ℃ to melt so that the knitted yarn is not loosened.

Finally, by overlocking the adhesive yarn part with the sewing machine, the glove 100 of the present invention illustrated in FIG. 1 is manufactured.

The above description is merely illustrative of the technical idea of the present invention, and those skilled in the art to which the present invention pertains may make various modifications and variations without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but to explain, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be interpreted by the following claims, and all technical ideas within the scope of the present invention should be interpreted as being included in the scope of the present invention.

Therefore, the cut protection gloves constructed in accordance with the present invention described above exhibit the advantage of having good elasticity as well as cut resistance and wear resistance.

In addition, the cut prevention glove configured in accordance with the present invention has the advantage that the user feels a good texture.

Claims (7)

In the cut prevention gloves, An outer layer woven of the first composite yarn; And An inner layer woven from a second composite yarn, The first composite yarn includes two strands of stainless steel yarn and one strand of Dyneema spun yarn twisted in a twisted shape with the stainless steel yarn in the middle, And said second composite yarn comprises a core yarn composed of one strand of spandex yarn and a cover yarn composed of one strand of dynima yarn surrounding said core yarn. The method of claim 1, Dyneema yarn of the second composite yarn is wound around the spandex yarn in the state that the spandex yarn is pulled. The method of claim 1, The stainless steel yarn of the first composite yarn has a diameter of about 60 ㎛, Dyneema spun yarn of the first composite yarn is cut resistant gloves, characterized in that the two strands composed of 50% and 50% polyamide (Polyamide) is spliced together. The method of claim 1, And said spandex yarn of said second composite yarn has a size of about 140 denier, and said Dyneema yarn of said second composite yarn has a size of about 400 denier. The method of claim 1, And said Dyneema spun yarn of said first composite yarn is wound at a turn ratio of about 100 to 500 times per meter of said stainless steel. The method of claim 1, Dyneema yarn of the second composite yarn wound at a rate of about 300 to 600 turns per meter of the spandex yarn. The method according to any one of claims 1 to 6, The cut preventing glove is a cut preventing glove, characterized in that the first composite yarn and the second composite yarn is woven using a double rain system at a density of 10 gauge.