JP2005248345A - Knitted fabric having excellent cutting resistance, and utilization thereof - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a knitted fabric stably having cutting resistance at a prescribed level or more, and suitable for a protective material having light weight and rich elasticity. <P>SOLUTION: The knitted fabric having the cutting resistance comprises a composite yarn composed of an ultrahigh molecular weight polyethylene multifilament having ≥15 cN/dtex strength at break and ≤7% elongation at break, and a fiber such as a natural fiber and a cellulose fiber having ≤15 cN/dtex strength and ≥7% elongation, and has 0.05-0.20 cover factor shown by the formula (1): F=(0.00113/L)×√(D/ρ) [wherein, F is the cover factor; L is a loop length (cm); D is a size (dtex); and ρ is a fiber density (g/cm<SP>3</SP>)], ≥4.0 index value in an evaluation method of BS EN388:1994 6.2, and ≤500 g/m<SP>2</SP>weight. The glove and the protective clothing are composed of the knitted fabric. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention is intended to protect the body from sharp blades, and is intended to be worn by, for example, workers handling blades and sports athletes such as skis and skates to protect all or part of the body. In addition, the present invention provides a garment with excellent stretchability and excellent cut resistance.

Conventionally, many proposals have been made on protective articles using high-strength fibers, including gloves. There are proposals for yarns that use a combination of inorganic fibers such as metal fibers and glass and high-strength fibers, but if inorganic fibers such as metal or glass are used, the weight of the yarn or fabric becomes heavy and work is carried out. Or, when doing sports, it gives difficulty in movement. (For example, see Patent Documents 1, 2, and 3)
Japanese Patent Application Laid-Open No. 06-065830 JP 2002-054008 A JP-A-06-1992928

Then, the proposal which suppresses such a heavy feeling using only organic fiber is made | formed. However, these proposals are proposals related to yarns and composite yarns, and a part of the proposal includes a description of finishing on a fabric or the like, but no detailed explanation or limitation on the fabric is described. (For example, see Patent Documents 4 and 5)
JP 2000-303289 A JP 2001-131842 A

There are other proposals regarding fabrics with high protective performance using organic fibers, but no specific examples are given, and the protective effects of the proposed fabrics remain unconfirmed. (For example, refer to Patent Document 6).
JP 2000-129510 A

  The present invention is a weft knitted fabric for preventing cut accidents from sharp blades, metal pieces, glass, etc., especially for lightweight accidents that use organic high-strength fibers and are comfortable to use. Propose a knitted fabric with a high level of protection performance.

That is, the present invention has the following configuration.
1. A knitted fabric made of an organic fiber yarn having at least a part of a high strength multifilament yarn having a breaking strength of 15 cN / dtex or more and a breaking elongation of 7% or less, wherein the cover factor represented by Formula 1 of the knitted fabric is A knitted fabric excellent in cut resistance, characterized by being 0.05 to 0.20.
Formula 1 F = (0.00113 / L) × √ (D / ρ)
Where F is the cover factor, L is the loop length (cm), D is the fineness (dtex), and ρ is the fiber density (g / cm ³ ).
2. BS EN388: 1994 The knitted fabric excellent in cut resistance according to the first aspect, wherein the index value in the evaluation method of 6.2 is 4.0 or more and the basis weight is 500 g / m ² or less.
3. The first or second aspect described above, wherein the high-strength multifilament yarn is a multifilament made of ultrahigh molecular weight polyethylene fiber having a weight average molecular weight of 1 million or more and a fiber density of 0.95 to 0.98 g / cm ^3. Knitted fabric with excellent cut resistance.
4). The organic fiber yarn is formed by combining high-strength multifilament yarn and natural fiber or cellulose fiber, etc., fibers having physical properties of strength 15 cN / dtex or less and elongation of 7% or more. 3. A knitted fabric excellent in cut resistance according to any one of 3 above.
5). The knitted fabric excellent in cut resistance according to any one of the first to fourth aspects, wherein the content of the high-strength multifilament yarn in the organic fiber yarn is 50% or more.
6). The knitted fabric excellent in cut resistance according to any one of the first to fifth aspects, wherein the organic fiber yarn is any one of an interlace yarn, a taslan yarn, or a covering yarn.
7). A glove comprising the knitted fabric according to any one of the first to sixth aspects.
8). A protective garment comprising the knitted fabric according to any one of the first to sixth aspects.

  According to the present invention, it is possible to stably provide cut resistance of a certain level or more, and to provide a knitted fabric that is lightweight and rich in stretchability. Such a knitted fabric is suitable as a protective material for a part having a risk of cutting such as a work such as a work such as a hat or a sport, and a supporter that protects an inner material, elbows, knees and the like including gloves.

Hereinafter, the present invention will be described in detail.
It is important that the knitted fabric according to the present invention has a cover factor of 0.05 or more and 0.20 or less. Here, the cover factor is an index indicating the degree of voids in the woven fabric or knitted fabric.
F = K × d ÷ L (where F: cover factor, K: proportionality constant, d: yarn diameter, L: loop length). Since spun yarn is generally used for knitted fabrics, it is assumed that the thickness d of the yarn is inversely proportional to the square root of the yarn count S using a constant count, and F ′ = 1 / (L × √S ). However, since the present invention is a knitted fabric using organic multifilaments, it is necessary to calculate the cover factor from the constant length fineness. Therefore, with respect to the yarn diameter d, the following relationship holds between the fineness D, the specific gravity ρ of the yarn, and the diameter d of the filament.
D = π × (d / 2) ² × 1000000 × ρ
By substituting d obtained from this into F = K × d ÷ L, Equation 1 is obtained.
Formula 1 F = (0.00113 / L) × √ (D / ρ)
Here, K is set to 1, and Formula 1 is obtained. The cover factor obtained from this formula 1 is 0.1 to 0.3, preferably 0.55 to 0.15, and more preferably 0.06 to 0.1. When the cover factor is less than 0.1, there is a high possibility that the cut resistance performance is lowered and the index value cannot satisfy 4.0. On the other hand, when the cover factor is 0.2 or more, the cut-resistant performance is satisfactory, but the flexibility of the knitted fabric is deteriorated, which causes problems in wearing feeling and operability during use.
Although the proposal of the invention which specified the cover factor regarding protective clothing has already been made, this uses metal fiber, and furthermore, since the structure is a woven fabric, this proposal is intended to be elastic. I think that performance such as flexibility, lightness, etc. cannot be satisfied. (For example, see Patent Document 7)
JP 2000-198159 A

  High strength organic multifilament fibers need to be used at least in part. Since organic fibers are superior in lightness and flexibility as compared with inorganic fibers and metal fibers, it is thought that the ease of use is the best. Among organic fibers, high-strength fibers are excellent in cut resistance against blades and have a specific gravity of 2 or less, so that a very light knitted fabric can be obtained. Here, as a fiber physical property of the high strength fiber, the tensile strength is 15 cN / dtex or more, preferably 20 cN / dtex or more. The elongation is 7% or less, preferably 5% or less. Examples of such high strength fibers include ultra high molecular weight polyethylene fibers, high strength vinylon fibers, aramid fibers, polyarylate fibers, and polyparabenzobisoxazole (PBO) fibers. Among these, the ultra-high molecular weight polyethylene fiber is mentioned as the most preferable fiber. Since the ultrahigh molecular weight polyethylene fiber has a specific gravity of 1 or less, the area of the high-strength fiber per unit area of the knitted fabric becomes larger even if the same weight of fiber is used as compared with other high-strength fibers. As explained above, it has been found that the higher the ratio of fibers with excellent cut resistance to the unit area of the knitted fabric, the higher the cut resistance will be. Use such high strength fibers with low specific gravity. It can be said that it is suitable for obtaining a knitted fabric that is lightweight and has high cut resistance.

There are several methods for evaluating the cut resistance, but the blade cut resistance method described in 6.2 of BS EN388: 1994 in the British Standard is used. This is a comparative comparison of the cut resistance of the fabric of the present invention, based on a cotton canvas fabric (weight per unit of 540 g / m ² , thickness 1.2 mm) running on a fabric with a tungsten steel circular blade. In this test method, a circular blade with a load of 5N is run on the sample, the count value until penetrating is measured, and the Index value is calculated from a certain formula. Here, the Index value indicated by the knitted fabric of the present invention is at least 4.0 or more, preferably 4.5 or more, more preferably 5.0 or more.

  The high-strength organic fiber described above is indispensable for the fiber used in the present invention, but it is a composite of natural fiber or artificial cellulose fiber, organic fiber having a strength of 15 cN / dtex or less and an elongation of 7% or more. May be. In this case, it is important that the content of the high strength organic fiber is 50% or more, preferably 70% or more. Combining with these natural fibers or artificial cellulose fibers, organic fibers with a strength of less than 15 cN / dtex, and an elongation of 7% or more can reduce the stickiness caused by sweat, color, and reduce costs. The said effect can be considered.

  As a method of combining high-strength fibers with natural fibers and artificial cellulose fibers, organic fibers with a strength of less than 15 cN / dtex and elongation of 7% or more, it is often taken up by composite yarn methods such as core yarn, manard processing, and covering processing. A processing method is mentioned. Further, as processing that can be used for both high-strength fibers 100% and composites with other fibers, there is a method of performing bulk processing such as interlace or taslan processing. By carrying out bulky processing, the orientation of the filament becomes random, and the effect of improving the cut-resistant performance can be mentioned. By applying these processes, the yarn can be swollen, the texture of the knitted fabric can be made mild, the moisture absorption / release property is improved, and the wear feeling is improved.

Proposals have been made to improve cut resistance by using high-strength fibers in part and performing bulky processing. (For example, see Patent Documents 8 and 9)
JP 2001-303324 A JP 2002-180355 A

  An example of using such a knitted fabric is a glove. In particular, there are many accidents involving cuts on hands and the like, such as working with blades and metal processing sites, and gloves with excellent cut resistance are used. Another requirement is ease of work. As a method of satisfying such a requirement, it is common to use a knitted fabric excellent in stretchability. As a method of making such a knitted fabric, there are three basic structures of flat knitting, rubber knitting, and pearl knitting using a round knitting machine or a flat knitting machine. Although weft insertion knitting etc. are mentioned, it is desirable to carry out with circular knitting which is easy to give stretchability. In addition, a method in which a plurality of these knitted fabrics are laminated or a knitted fabric is produced by using a knitting method having a multiple structure is also used.

  As another application example, it can be worn on the body and used as protective clothing. It can be used in the same form as a garment that is usually used, such as a tubular knitting form that supports the knees and elbows, and shirts and pants. In addition, hats, gloves and socks may be used to protect the head, hands, and feet, but basically it is recommended to wear them at places where cuts are likely to occur during work or sports competitions. These protective garments may be worn underneath work clothes or uniforms as inners, or the same protective effect can be obtained even when worn on work clothes or uniforms for easy attachment / detachment.

When used as protective clothing, especially when it is necessary to protect the body from cut accidents such as skating, flexibility and light weight are required. In order to increase the cut resistance, the basis weight may be increased. However, the size of the basis weight may be limited in the sports-related fields as described above. Therefore, the cover factor is important in order to efficiently impart light cut resistance. It was found that sufficient cut-resistant performance can be imparted with a basis weight of 500 g / m ² or less within the range of the cover factor this time.

  Hereinafter, the present invention will be described specifically by way of examples.

Each value for calculating the cover factor of the knitted fabric shown in Examples and Comparative Examples was obtained by the following method.
(Fineness)
In accordance with JIS L 1018: 1999 8.7.1a), a thread length of 1m is applied to a fineness of 1dtex, cut to a length of 1m, weighed, and weighed 10,000 times to obtain a fineness (dtex) Asked.
(Loop length measurement)
In accordance with JIS L 1018: 1999 8.10, unravel the knitted fabric, take out the yarn that corresponds to the number of stitches for 10 pieces, measure the length by applying a load of 1 / 11.1 g to the fineness of 1 dtex, 1 / of the obtained numerical value A value of 10 was taken as the loop length.
(specific gravity)
Regarding the specific gravity, 2 g of the chip was carefully evaluated, and helium gas was flowed in using a pycnometer (Micromeritics Accupyc 1330 manufactured by Shimadzu Corporation) to determine the volume, and the specific gravity was calculated.

The measuring method of the tensile strength and tensile elasticity modulus of the high strength fiber used in the Example is shown.
(Fineness measurement)
The high-strength fiber was allowed to stand in a room maintained at a temperature of 20 ° C. and a humidity of 65% for 24 hours. After the sample had a constant moisture content, the fineness was measured according to JIS L 1013 8.3.
(Measurement of tensile strength and elongation)
The sample was allowed to stand in a room maintained at a temperature of 20 ° C. and a humidity of 65% for 24 hours, and after the sample had a constant moisture content, the tensile strength was measured in accordance with JIS L 1013 8.5. Using 5t Tensilon manufactured by Orientec Co., Ltd., the measurement was performed at a strain rate of 1 (min ⁻¹ ). The number of repetitions was 5 times, and the average value was taken as the tensile strength of the high strength fiber. At the same time, the elongation when the maximum strength was shown was also measured, and the average value measured five times was defined as the elongation.

It shows about the evaluation method of cut resistance. Evaluation was performed in accordance with the test method of British Standard BS EN388.
The evaluation device runs the circular blade while rotating it on the test sample in the direction opposite to the running direction, cuts the test sample, and measures the count value until the blade penetrates the test sample.
As a blank, a cotton canvas fabric having a basis weight of 540 g / m ² is used as a blank, and the cut level with the test sample is evaluated. Start the test from the cotton canvas fabric, measure the count value alternately between the cotton canvas fabric and the test sample, and when you finish measuring the count value for 5 test samples, finally the 6th time of the cotton canvas fabric The count value is measured, one test is completed, and one index value can be calculated. In this evaluation, all test samples were set in a free state.
A value called Index value is calculated by the following equation.
A = (count value of cotton cloth before sample test + count value of cotton cloth before sample test) / 2
Index value = (sample count value + A) / A
The cutter used for the evaluation was φ45 mm for the rotary cutter L-type manufactured by OLFA. The material was SKS-7 tungsten steel, and the blade thickness was 0.3 mm.
Each sample measures two Index values, and the lower value is set as the Index value of the sample. Finally, the Level is obtained from the Index value. If the Index value is 5.0 or more, the Level is 3 or more.

(Example 1)
A high-molecular-weight polyethylene fiber (trade name Dyneema; manufactured by Toyobo Co., Ltd.) 1320dtex was supplied, and a cylindrical knitting was produced with a circular knitting machine having 100 needles.

(Example 2)
Ultra high molecular weight polyethylene fiber (trade name Dyneema; Toyobo Co., Ltd.) 330dtex and Ny70dtex were mixed by Taslan processing to obtain a yarn. Tube knitting was made with a circular knitting machine using 100 needles and 2 yarns.

(Example 3)
An ultra high molecular weight polyethylene fiber (trade name Dyneema; manufactured by Toyobo Co., Ltd.) 440dtex was used as a core yarn and covered with Ny140dtex sheath yarn to obtain a yarn. The number of covering turns was 200 t / m. The obtained yarn was used for 100 needles, and the number of yarns supplied was 2 to produce cylindrical knitting with a circular knitting machine.

Example 4
Ultra high molecular weight polyethylene fiber (trade name Dyneema; manufactured by Toyobo Co., Ltd.) 440dtex was covered with Ny140dtex core yarn to obtain a yarn. The number of covering turns was 200 t / m. The obtained yarn was used for 100 needles, and the number of yarns supplied was 2 to produce cylindrical knitting with a circular knitting machine.

(Example 5)
Ultra high molecular weight polyethylene fiber (trade name Dyneema; manufactured by Toyobo Co., Ltd.) 440dtex was used as a core yarn and covered with Pet150dtex sheath yarn to obtain a yarn. The number of covering turns was 200 t / m. The obtained yarn was used for 100 needles, and the number of yarns supplied was 2 to produce cylindrical knitting with a circular knitting machine.

(Example 6)
Ultra high molecular weight polyethylene fiber (trade name Dyneema; manufactured by Toyobo Co., Ltd.) 440dtex was covered with sheath yarn, and polyurethane fiber (trade name: ESPA; manufactured by Toyobo Co., Ltd.) was covered with core yarn to obtain a yarn. The number of covering turns was 400 t / m. The obtained yarn was used for 100 needles, and the number of yarns supplied was 2 to produce cylindrical knitting with a circular knitting machine.

(Example 7)
Ultra high molecular weight polyethylene fiber (trade name Dyneema; manufactured by Toyobo Co., Ltd.) 440dtex and cotton yarn 10.5 were mixed by manard processing to obtain a yarn. Tube knitting was made with a circular knitting machine using 100 needles and 2 yarns.

(Example 8)
Using 1690T polybenzobisoxazole (PBO) fiber (trade name: Zylon; manufactured by Toyobo Co., Ltd.), a single knitting machine was used to produce a cylindrical knitting with a circular knitting machine with 100 needles.

(Comparative Example 1)
High-molecular-weight polyethylene fiber (trade name Dyneema; manufactured by Toyobo Co., Ltd.) 1320dtex was supplied, and a cylindrical knitting was produced with a circular knitting machine having 50 needles.

(Comparative Example 2)
Ultra high molecular weight polyethylene fiber (trade name Dyneema; Toyobo Co., Ltd.) 330dtex and Ny70dtex were mixed by Taslan processing to obtain a yarn. Tube knitting was made with a circular knitting machine using 50 needles and 2 yarns.

(Comparative Example 3)
Ultra high molecular weight polyethylene fiber (trade name Dyneema; Toyobo Co., Ltd.) 330dtex and Ny70dtex were mixed by Taslan processing to obtain a yarn. The number of needles was 50, the number of yarns supplied was 3, and cylindrical knitting was made with a circular knitting machine.

(Comparative Example 4)
An ultra high molecular weight polyethylene fiber (trade name Dyneema; manufactured by Toyobo Co., Ltd.) 440dtex was used as a core yarn and covered with Ny140dtex sheath yarn to obtain a yarn. The number of covering turns was 200 t / m. The obtained yarn was used for 50 needles, and the number of yarns supplied was 2 to produce cylindrical knitting with a circular knitting machine.

(Comparative Example 5)
Ultra high molecular weight polyethylene fiber (trade name Dyneema; manufactured by Toyobo Co., Ltd.) 440dtex was covered with Ny140dtex core yarn to obtain a yarn. The number of covering turns was 200 t / m. The obtained yarn was used for 50 needles, and the number of yarns supplied was 2 to produce cylindrical knitting with a circular knitting machine.

(Comparative Example 6)
Ultra high molecular weight polyethylene fiber (trade name Dyneema; manufactured by Toyobo Co., Ltd.) 440dtex was used as a core yarn and covered with Pet150dtex sheath yarn to obtain a yarn. The number of covering turns was 200 t / m. The obtained yarn was used for 50 needles, and the number of yarns supplied was one, and cylindrical knitting was produced with a circular knitting machine.

(Comparative Example 7)
Ultra high molecular weight polyethylene fiber (trade name Dyneema; manufactured by Toyobo Co., Ltd.) 440dtex was used as a core yarn and covered with Pet150dtex sheath yarn to obtain a yarn. The number of covering turns was 200 t / m. The obtained yarn was used for 100 needles, and the number of yarns supplied was 1, and cylindrical knitting was made with a circular knitting machine.

(Comparative Example 8)
Ultra high molecular weight polyethylene fiber (trade name Dyneema; manufactured by Toyobo Co., Ltd.) 440dtex was used as a core yarn and covered with Pet150dtex sheath yarn to obtain a yarn. The number of covering turns was 200 t / m. The obtained yarn was used for 50 needles, and the number of yarns supplied was 2 to produce cylindrical knitting with a circular knitting machine.

(Comparative Example 9)
Ultra high molecular weight polyethylene fiber (trade name Dyneema; manufactured by Toyobo Co., Ltd.) 440dtex and cotton yarn 10.5 were mixed by manard processing to obtain a yarn. Tube knitting was made with a circular knitting machine using 50 needles and 2 yarns.

(Reference Example 10)
Commercial gloves (7 gauge product) made of commercially available cotton yarn were evaluated.

  The evaluation results of Examples 1 to 8 and Comparative Examples 1 to 10 are shown in Table 1.

  As is apparent from the examples and comparative examples, the knitted fabric using high-strength fibers having a cover factor of 0.05 or more is found to be a knitted fabric having high cut resistance.

  The present invention provides a knitted fabric that is lightweight and rich in elasticity and excellent in cut resistance, and the use of the product of the present invention includes gloves, sports inner materials, supporters and hats that protect elbows and knees, Etc. are useful.

Claims (8)

A knitted fabric made of an organic fiber yarn having at least a part of a high strength multifilament yarn having a breaking strength of 15 cN / dtex or more and a breaking elongation of 7% or less, wherein the cover factor represented by Formula 1 of the knitted fabric is A knitted fabric excellent in cut resistance, characterized by being 0.05 to 0.20.
Formula 1 F = (0.00113 / L) × √ (D / ρ)
Where F is the cover factor, L is the loop length (cm), D is the fineness (dtex), and ρ is the fiber density (g / cm ³ ). The knitted fabric excellent in cut resistance according to claim 1, wherein an index value in the evaluation method of BS EN388: 1994 6.2 is 4.0 or more and a basis weight is 500 g / m ² or less. High tenacity multifilament yarn, a weight average molecular weight of 1,000,000 or higher, according to claim 1 or 2, wherein the fiber density of multifilament consisting of ultra high molecular weight polyethylene fibers of 0.95~0.98g / cm ³ Knitted fabric with excellent cut resistance. The organic fiber yarn is formed by combining a high-strength multifilament yarn and a natural fiber or cellulose fiber with a fiber having a physical property of a strength of 15 cN / dtex or less and an elongation of 7% or more. 3. A knitted fabric excellent in cut resistance according to any one of 3 above.   The knitted fabric excellent in cut resistance according to any one of claims 1 to 4, wherein the content of the high-strength multifilament yarn in the organic fiber yarn is 50% or more.   The knitted fabric excellent in cut resistance according to any one of claims 1 to 5, wherein the organic fiber yarn is any one of an interlace yarn, a taslan yarn, or a covering yarn. A glove comprising the knitted fabric according to any one of claims 1 to 6. A protective garment comprising the knitted fabric according to any one of claims 1 to 6.