JP3208614U - Multiple gauze fabric - Google Patents

Abstract

Provided is a multiple gauze fabric that maintains the air permeability and light weight, which are the characteristics of a gauze fabric, has a good touch (soft) and is excellent in heat retention. A multiple gauze fabric is composed of a plurality of gauze tissues including a first gauze tissue G1 corresponding to the front surface, a second gauze tissue G2 corresponding to the back surface, and a third gauze tissue G3 corresponding to the intermediate layer. The first gauze tissue G1 and the second gauze tissue G2 are connected directly and / or indirectly. The first gauze structure G1 is formed using the first twisted yarn having a twist coefficient of 3.0 or less for the warps 1 and 2 and the second twisted yarn having a twist coefficient of 3.0 or less for the wefts A and B. . The second gauze structure G2 is formed using a third twisted yarn having a twist coefficient of 3.3 or more for the warps 3 and 4, and a fourth twisted yarn having a twist coefficient of 3.3 or more for the wefts C and D. . The third gauze structure G3 is formed using the fifth twisted yarn having a twist coefficient of 3.3 or more for the warps 5 and 6 and the sixth twisted yarn having a twist coefficient of 3.3 or more for the wefts E and F. . [Selection] Figure 1

Description

  The present invention relates to a multiple gauze fabric.

  A gauze fabric is a plain fabric woven roughly by relatively thin yarns. Generally, a solid (not hollow) cotton twisted yarn is used.

  Cotton gauze fabric includes single fabric, double fabric, and triple fabric. Single gauze fabrics are used for medical purposes and cloths, for example. Double gauze fabric is used for clothes, handkerchiefs, and the like. Cotton yarn (mainly single yarn of 40 English count) is used. Triple gauze fabric is used for towels and bedding, for example. Cotton yarn is used. In a single structure, the total number of vertical yarns per inch is generally 50 to 120. If the density is less than 50, gauze is not formed. A high density of more than 120 is not generally called gauze.

  FIG. 8 is a cross-sectional view of a typical double gauze fabric. The double gauze fabric includes a front surface gauze structure and a back surface gauze structure. The gauze structure is composed of warp (warp) and weft (weft). A gauze structure having a plain weave structure is formed by driving wefts in accordance with the warp supply. Along with the formation of the surface gauze structure and the formation of the back surface gauze structure, the surface gauze structure and the back surface gauze structure are appropriately connected. As shown in the figure, the connecting portion may be formed by warp, or the connecting portion may be formed by weft.

JP2004-107824

  Gauze is a coarse woven fabric (with a large gap between yarns). Since gauze is a coarse plain fabric, it has excellent breathability and outstanding lightness.

  On the other hand, gauze fabric has poor heat retention. Even as a multiple gauze, the thickness is thin and heat retention cannot be expected. If the number of sheets to be stacked is increased so as to ensure sufficient heat retention, the lightness is remarkably impaired.

  Since gauze is a coarse fabric, it has poor elasticity and softness.

  As a result of the fact that gauze is a coarse woven fabric, for example, when used as clothes, the skin is transparent. In addition, when the thickness of the thread is increased or the density is increased, the permeability is improved, but the air permeability and light weight, which are the characteristics of gauze, are significantly impaired.

  For the above reasons, it was considered that the performance of conventional gauze fabrics was insufficient for application to clothing and bedding fabrics and there was room for improvement.

  The present invention solves the above-mentioned problems, and aims to provide a multiple gauze fabric that maintains the breathability and light weight, which are the characteristics of a gauze fabric, and that is soft to the touch and excellent in heat retention. To do.

  One aspect of the device for solving the above problems is a multi-gauze fabric including a first gauze structure corresponding to a surface layer and a second gauze structure corresponding to a back layer. The first gauze tissue and the second gauze tissue are connected directly and / or indirectly. The first gauze structure is formed using at least one of warp or weft using a first twist yarn having a twist coefficient of 3.0 or less, and the second gauze structure is a warp yarn having a twist coefficient of 3.3 or more. The third twisted yarn is used, and the weft yarn is formed using a fourth twisted yarn having a twist coefficient of 3.3 or more.

  In the above aspect of the invention, preferably, the first gauze structure is formed using a second twisted yarn having a twist coefficient of 3.0 or less on the other side of the warp or the weft.

  In the above aspect of the invention, preferably, the first gauze structure is formed using a second twisted yarn having a twist coefficient of 3.3 or more on the other side of the warp or the weft.

  In the above aspect of the invention, a double gauze fabric is preferable.

  In the above aspect of the invention, the gauze fabric is preferably a triple or more gauze fabric, and includes a third gauze structure corresponding to an intermediate layer, and the third gauze structure includes a warp and a twist coefficient of 3.3 or more. 5 twisted yarns are used, and a weft yarn is formed using a 6th twisted yarn having a twist coefficient of 3.3 or more.

    One aspect of the device for solving the above problems is a garment formed by sewing with the multiple gauze fabric.

    One aspect of the device that solves the above-described problems is bedding that is sewn with the multiple gauze fabric.

  The multi-gauze fabric of the present invention maintains the breathability and light weight that are characteristic of a gauze fabric, has a good touch (soft), and is excellent in heat retention.

Sectional drawing of the multiple gauze fabric based on 1st Embodiment Sectional drawing of the multiple gauze fabric based on 2nd Embodiment Sectional drawing of the multiple gauze fabric based on 3rd Embodiment Sectional drawing of the multiple gauze fabric based on 4th Embodiment Sectional drawing of the multiple gauze fabric based on 5th Embodiment Sectional drawing of the multiple gauze fabric based on 6th Embodiment Sectional view of a triple gauze fabric according to the prior art Sectional view of a double gauze fabric according to the prior art

<First Embodiment>
~Constitution~
FIG. 1 is a cross-sectional view of a multiple gauze fabric according to the first embodiment. Although the present invention is an N (N is an integer of 2 or more) heavy gauze fabric, the triple gauze fabric will be described for easy understanding of the device.

  The gauze fabric includes a surface layer gauze G1, a back surface layer gauze G2, and an intermediate layer gauze G3.

  The surface layer gauze G1 and the back surface layer gauze G2 may be directly joined through the intermediate layer gauze G3, or the surface layer gauze G1 and the back surface layer gauze G2 are indirectly connected via the intermediate layer gauze G3. It may be connected to.

  Further, as shown in the figure, the connecting portion may be formed by warp, or the connecting portion may be formed by weft.

  Further, as shown in the figure, the connecting portion may be formed by the yarn of the intermediate layer gauze G3, or the connecting portion may be formed by the yarns of the surface layer gauze G1 and the back surface layer gauze G2.

  The surface layer gauze G1 is composed of warps (warps) 1 and 2 and wefts (wefts) A and B. A plain weave structure is formed in which the wefts A and B are supplied to the warp yarns 1 and 2 and intersect.

  For the warps 1 and 2, a twisted yarn (first twisted yarn) having a twist coefficient of 3.0 or less is used. For the wefts A and B, a twisted yarn (second twisted yarn) having a twist coefficient of 3.0 or less is used.

  The back surface layer gauze G2 is composed of warps 3, 4 and wefts C, D. A plain weave structure is formed in which the wefts C and D are supplied to the warps 3 and 4 and intersect.

  For the warps 3 and 4, a twisted yarn (third twisted yarn) having a twist coefficient of 3.3 or more is used. For the wefts C and D, a twisted yarn (fourth twisted yarn) having a twist coefficient of 3.3 or more is used.

  The intermediate layer gauze G3 is composed of warps 5, 6 and wefts E, F. A plain weave structure is formed in which the wefts E and F are supplied to the warps 5 and 6 and intersect.

  For the warps 5 and 6, a twisted yarn (fifth twisted yarn) having a twist coefficient of 3.3 or more is used. For the wefts E and F, a twisted yarn (sixth twisted yarn) having a twist coefficient of 3.3 or more is used.

  That is, in the surface layer gauze G1, both the warp and the weft are formed by weak twist yarns (or non-twist yarn), and in the back layer gauze G2 and the intermediate layer gauze G3, both the warp and weft are formed by general twist yarns. The back layer gauze G2 and the intermediate layer gauze G3 are gauze tissues generally used conventionally.

  A twisted yarn having a twist coefficient of 3.3 or more is a commonly used twisted yarn. A twisted yarn having a twist coefficient of 3.0 or less is called a weakly twisted yarn. Furthermore, a twisted yarn having a twist coefficient of 1.0 or less is included in the non-twisted yarn.

  When a twisted yarn having a twist coefficient of 3.5 or more is used as a general twisted yarn, and a twisted yarn having a twist coefficient of 2.5 or less is used as a weak twisted yarn, the effects described later become more remarkable.

  The twist coefficient is an index of twist strength in consideration of the thickness of the yarn. The higher the number, the stronger the twist. The value obtained by multiplying the square root of the yarn count by the twist coefficient is the number of twists per inch.

~ Modification ~
The first twisted yarn and the second twisted yarn may have the same twist coefficient (weakly twisted yarn or non-twisted yarn), or may be different within the range of weakly twisted yarn or untwisted yarn. The third to sixth twisted yarns may have the same twist coefficient (general twisted yarn) or may be different within a range that becomes a general twisted yarn.

  The first to sixth twisted yarns may be hollow yarns, but are more preferably solid yarns.

  The first to sixth twisted yarns are preferably cotton yarns, but plant-derived regenerated fibers such as rayon may be applied.

  The first to sixth twisted yarns may be the same number, but may be different.

  Moreover, in the illustration in FIG. 1, it is a premise that the first twisted yarn to the sixth twisted yarn have the same number. Weakly twisted yarn (or untwisted yarn) appears to swell and become thicker than twisted yarn of the same number. Therefore, the first twisted yarn and the second twisted yarn are shown thicker than the third to sixth twisted yarns.

  For simplification of explanation, the tissue G1 is a surface layer gauze and the tissue G2 is a back surface layer gauze, but the tissue G1 may be a back surface layer gauze and the tissue G2 may be a surface layer gauze. That is, the surface layer gauze and the intermediate layer gauze are formed from a general twisted yarn, and the back surface layer gauze is formed from a weakly twisted yarn (or non-twisted yarn).

~effect~
FIG. 7 is a cross-sectional view of a prior art triple gauze fabric. The effect of this embodiment will be described by comparing with the prior art.

  In the prior art, all three layers (G1 to G3) are formed of twisted yarns. On the other hand, in this embodiment, the surface layer gauze G1 is formed of weakly twisted yarn (or untwisted yarn), and the back surface layer gauze G2 and the intermediate layer gauze G3 are formed of twisted yarn.

  Therefore, the surface layer gauze G1 has the softness and bulkiness that are characteristic of weakly twisted yarn (or non-twisted yarn). Moreover, the weakly twisted yarn (or untwisted yarn) appears to swell and become thicker than the twisted yarn of the same number. Thereby, the permeability is improved.

  By the way, the gauze structure is formed by supplying wefts to warps. After the gauze tissue is formed, the gauze tissue contracts when dried through a process of adding moisture such as washing and staining. At that time, the shrinkage differs between the twisted yarn and the weakly twisted yarn (or the non-twisted yarn). That is, twisted yarns tend to shrink, while weakly twisted yarns (or untwisted yarns) are less likely to shrink.

  Therefore, in the prior art, the three layers shrink evenly and do not become wrinkles, whereas in the present embodiment, the surface layer gauze G1 hardly shrinks. As a result of the back layer gauze G2 and the intermediate layer gauze G3 contracting, the surface layer gauze G1 cannot follow and wrinkles are generated. Due to the irregularities of the heel, the bulkiness is improved, the touch is good (soft), and the heat retention is improved.

  On the other hand, since the back surface layer gauze G2 and the intermediate layer gauze G3 are gauze tissues generally used conventionally, they have the strength equivalent to that of the prior art. This can be applied to the sewing field of clothes and the like. It also maintains the breathability and light weight that are characteristic of gauze fabrics.

<Second and Third Embodiments>
FIG. 2 is a cross-sectional view of a multiple gauze fabric according to the second embodiment. The triple gauze fabric includes a surface layer gauze G1, a back surface layer gauze G2, and an intermediate layer gauze G3. The surface layer gauze G1 and the back surface layer gauze G2 are directly or indirectly connected.

  The surface layer gauze G1 is composed of warps (warps) 1 and 2 and wefts (wefts) A and B. A plain weave structure is formed in which the wefts A and B are supplied to the warp yarns 1 and 2 and intersect.

  For the warps 1 and 2, a twisted yarn (first twisted yarn) having a twist coefficient of 3.0 or less is used. For the wefts A and B, 3.3 or more twisted yarn (second twisted yarn) is used.

  The back surface layer gauze G2 is composed of warps 3, 4 and wefts C, D. A plain weave structure is formed in which the wefts C and D are supplied to the warps 3 and 4 and intersect.

  For the warps 3 and 4, a twisted yarn (third twisted yarn) having a twist coefficient of 3.3 or more is used. For the wefts C and D, a twisted yarn (fourth twisted yarn) having a twist coefficient of 3.3 or more is used.

  The intermediate layer gauze G3 is composed of warps 5, 6 and wefts E, F. A plain weave structure is formed in which the wefts E and F are supplied to the warps 5 and 6 and intersect.

  For the warps 5 and 6, a twisted yarn (fifth twisted yarn) having a twist coefficient of 3.3 or more is used. For the wefts E and F, a twisted yarn (sixth twisted yarn) having a twist coefficient of 3.3 or more is used.

  That is, in the surface layer gauze G1, the warp is formed of weakly twisted yarn (or non-twisted yarn), and the weft is formed of general twisted yarn. In the back surface layer gauze G2 and the intermediate layer gauze G3, both the warp and the weft are formed by general twist yarns. The back layer gauze G2 and the intermediate layer gauze G3 are gauze tissues generally used conventionally.

  The inventor of the present application, when initially using weakly twisted yarn (or non-twisted yarn) as the warp of the surface layer gauze G1, wrinkles that repeat only in the warp direction (the wrinkles extending in the weft direction) are generated. I thought it would not happen.

  However, when a prototype of the triple gauze according to the second embodiment was made, it was found that wrinkles were generated in the weft direction following the warps in the warp direction.

  Therefore, the second embodiment can achieve the same effect as the first embodiment.

  FIG. 3 is a cross-sectional view of a multiple gauze fabric according to the third embodiment. The triple gauze fabric includes a surface layer gauze G1, a back surface layer gauze G2, and an intermediate layer gauze G3. The surface layer gauze G1 and the back surface layer gauze G2 are directly or indirectly connected.

  The surface layer gauze G1 is composed of warps (warps) 1 and 2 and wefts (wefts) A and B. A plain weave structure is formed in which the wefts A and B are supplied to the warp yarns 1 and 2 and intersect.

  For the warps 1 and 2, a twisted yarn (second twisted yarn) having a twist coefficient of 3.3 or more is used. For the wefts A and B, 3.0 or less twisted yarn (first twisted yarn) is used.

  The back surface layer gauze G2 is composed of warps 3, 4 and wefts C, D. A plain weave structure is formed in which the wefts C and D are supplied to the warps 3 and 4 and intersect.

  For the warps 3 and 4, a twisted yarn (third twisted yarn) having a twist coefficient of 3.3 or more is used. For the wefts C and D, a twisted yarn (fourth twisted yarn) having a twist coefficient of 3.3 or more is used.

  The intermediate layer gauze G3 is composed of warps 5, 6 and wefts E, F. A plain weave structure is formed in which the wefts E and F are supplied to the warps 5 and 6 and intersect.

  For the warps 5 and 6, a twisted yarn (fifth twisted yarn) having a twist coefficient of 3.3 or more is used. For the wefts E and F, a twisted yarn (sixth twisted yarn) having a twist coefficient of 3.3 or more is used.

  That is, in the surface layer gauze G1, the warp is formed of a general twist yarn, and the weft is formed of a weak twist yarn (or a non-twist yarn). In the back surface layer gauze G2 and the intermediate layer gauze G3, both the warp and the weft are formed by general twist yarns. The back layer gauze G2 and the intermediate layer gauze G3 are gauze tissues generally used conventionally.

  Thereby, in the surface layer gauze G1, wrinkles repeated in the weft direction are generated, and wrinkles are also generated in the warp direction following the wrinkles in the weft direction. Therefore, the third embodiment can obtain the same effect as the first embodiment.

<4-6 embodiment>
Although the multiple gauze fabric according to the first embodiment is triple, it can be a double gauze. FIG. 4 is a conceptual diagram of a multiple gauze fabric according to the fourth embodiment.

  The double gauze fabric includes a surface layer gauze G1 and a back surface layer gauze G2. The surface layer gauze G1 and the back surface layer gauze G2 are connected.

  The surface layer gauze G1 is composed of warps (warps) 1 and 2 and wefts (wefts) A and B. A plain weave structure is formed in which the wefts A and B are supplied to the warp yarns 1 and 2 and intersect.

  For the warps 1 and 2, a twisted yarn (first twisted yarn) having a twist coefficient of 3.0 or less is used. For the wefts A and B, a twisted yarn (second twisted yarn) having a twist coefficient of 3.0 or less is used.

  The back surface layer gauze G2 is composed of warps 3, 4 and wefts C, D. A plain weave structure is formed in which the wefts C and D are supplied to the warps 3 and 4 and intersect.

  For the warps 3 and 4, a twisted yarn (third twisted yarn) having a twist coefficient of 3.3 or more is used. For the wefts C and D, a twisted yarn (fourth twisted yarn) having a twist coefficient of 3.3 or more is used.

  That is, in the surface layer gauze G1, both the warp and the weft are formed by weak twisted yarn (or non-twisted yarn), and in the back surface layer gauze G2, the warp and the weft are formed by general twisted yarn. The back layer gauze G2 is a gauze tissue generally used conventionally.

  FIG. 8 is a cross-sectional view of a prior art double gauze fabric. The effect of this embodiment will be described by comparing with the prior art.

  If the fabric strength as in the first embodiment is not required, the intermediate layer gauze G3 can be omitted and a double gauze can be obtained. At this time, the same effect as the first embodiment can be obtained.

  In the surface layer gauze G1, softness and bulkiness are improved by the synergistic action of weakly twisted yarn (or untwisted yarn) and wrinkle formation. By improving the bulkiness, heat retention and permeation resistance are improved.

  On the other hand, since the back surface layer gauze G2 is a gauze structure generally used conventionally, it has the strength according to the prior art. This can be applied to the sewing field of clothes and the like. It also maintains the breathability and light weight that are characteristic of gauze fabrics.

  FIG. 5 is a cross-sectional view of a multiple gauze fabric according to the fifth embodiment. The double gauze fabric includes a surface layer gauze G1 and a back surface layer gauze G2. The surface layer gauze G1 and the back surface layer gauze G2 are connected.

  The surface layer gauze G1 is composed of warps (warps) 1 and 2 and wefts (wefts) A and B. A plain weave structure is formed in which the wefts A and B are supplied to the warp yarns 1 and 2 and intersect.

  For the warps 1 and 2, a twisted yarn (first twisted yarn) having a twist coefficient of 3.0 or less is used. For the wefts A and B, 3.3 or more twisted yarn (second twisted yarn) is used.

  The back surface layer gauze G2 is composed of warps 3, 4 and wefts C, D. A plain weave structure is formed in which the wefts C and D are supplied to the warps 3 and 4 and intersect.

  For the warps 3 and 4, a twisted yarn (third twisted yarn) having a twist coefficient of 3.3 or more is used. For the wefts C and D, a twisted yarn (fourth twisted yarn) having a twist coefficient of 3.3 or more is used.

  That is, in the surface layer gauze G1, the warp is formed of weakly twisted yarn (or non-twisted yarn), and the weft is formed of general twisted yarn. In the back surface layer gauze G2, both the warp and the weft are formed by general twist yarns. The back layer gauze G2 is a gauze tissue generally used conventionally.

  Thereby, in the surface layer gauze G1, wrinkles repeated in the warp direction are generated, and wrinkles are also generated in the weft direction following the wrinkles in the warp direction. Therefore, the fifth embodiment can achieve the same effect as the fourth embodiment.

  FIG. 6 is a cross-sectional view of a multiple gauze fabric according to the sixth embodiment. The double gauze fabric includes a surface layer gauze G1 and a back surface layer gauze G2. The surface layer gauze G1 and the back surface layer gauze G2 are connected.

  The surface layer gauze G1 is composed of warps (warps) 1 and 2 and wefts (wefts) A and B. A plain weave structure is formed in which the wefts A and B are supplied to the warp yarns 1 and 2 and intersect.

  For the warps 1 and 2, a twisted yarn (second twisted yarn) having a twist coefficient of 3.3 or more is used. For the wefts A and B, 3.0 or less twisted yarn (first twisted yarn) is used.

  The back surface layer gauze G2 is composed of warps 3, 4 and wefts C, D. A plain weave structure is formed in which the wefts C and D are supplied to the warps 3 and 4 and intersect.

  For the warps 3 and 4, a twisted yarn (third twisted yarn) having a twist coefficient of 3.3 or more is used. For the wefts C and D, a twisted yarn (fourth twisted yarn) having a twist coefficient of 3.3 or more is used.

  That is, in the surface layer gauze G1, the warp is formed of a general twist yarn, and the weft is formed of a weak twist yarn (or a non-twist yarn). In the back surface layer gauze G2, both the warp and the weft are formed by general twist yarns. The back layer gauze G2 is a gauze tissue generally used conventionally.

  Thereby, in the surface layer gauze G1, wrinkles repeated in the weft direction are generated, and wrinkles are also generated in the warp direction following the wrinkles in the weft direction. Therefore, the sixth embodiment can achieve the same effect as the fourth embodiment.

<Remarks>
By the way, in a pile towel, a non-twisted yarn pile or a weak twisted yarn pile may be used.

  Generally used twisted yarn is formed by twisting cotton fibers. On the other hand, the untwisted yarn is formed so that the twisted yarn is untwisted and untwisted.

  Untwisted yarns are soft and swell and contain a lot of air between the fibers. Therefore, the non-twisted yarn pile achieves heat retention and soft touch.

  The weakly twisted yarn is formed such that the twisted yarn is untwisted like the non-twisted yarn, but the twist remains. Weakly twisted yarns have properties similar to untwisted yarns.

  The inventor considered applying untwisted or weakly twisted yarn to the gauze fabric. A gauze structure made of non-twisted yarn or weakly twisted yarn has a volume feeling compared to a gauze structure made of twisted yarn while maintaining air permeability and lightness. As a result, heat retention, soft touch, and permeation resistance are improved.

  However, generally, untwisted yarn and weakly twisted yarn are inferior in strength to twisted yarn. Therefore, the gauze structure composed only of untwisted yarn is inferior in strength. The same applies to a gauze structure composed only of weakly twisted yarns. Even multiple gauze does not significantly improve strength.

  Then, it examined applying to the multi-gauze fabric which connects the gauze structure comprised by the twisted yarn, and the gauze structure comprised by the non-twisted yarn (or weak twisted yarn).

  While the gauze structure composed of twisted yarns maintains strength, the gauze structure composed of non-twisted yarns (or weakly twisted yarns) has heat retention, soft touch and permeation resistance. In other words, the combination has both advantages.

  As a related device, the inventor has proposed a multi-gauze fabric using non-twisted yarn (or weakly twisted yarn) for the surface layer and the back layer.

  However, while actually commercializing and selling related devices, we came up with the idea that even if only a part of untwisted yarn (or weakly twisted yarn) was used, an effect equivalent to the related devices could be obtained.

  In particular, when applied to clothes, the inventors have come up with the idea that non-twisted yarn (or weakly twisted yarn) may be used only on the surface that contacts the skin.

<Application example of multiple gauze fabric>
The multi-gauze fabric of the present invention has improved bulkiness, heat retention, soft touch and permeation resistance as compared with the prior art while maintaining breathability and lightness. Moreover, it has the strength according to a prior art, and can be applied to sewing fields, such as clothes. Manufacturing cost is low.

  As a result, it is suitable as a cloth for clothes (gowns, pajamas, shirts, pants, mufflers, infant supplies, etc.) and bedding (sheets, blankets, pillow covers, etc.) as well as gauze towels and handkerchiefs.

G1 surface layer gauze G2 back layer gauze G3 intermediate layer gauze 1, 2 surface layer gauze warp 3, 4 back layer gauze warp 5, 6 intermediate layer gauze warp A, B surface layer gauze weft C, D back layer gauze weft E, F Intermediate layer gauze weft

Claims (7)

Including a first gauze tissue corresponding to the front surface layer and a second gauze tissue corresponding to the back surface layer,
The first gauze tissue and the second gauze tissue are connected directly and / or indirectly,
The first gauze tissue is
At least one of warp or weft is formed using a first twisted yarn having a twist coefficient of 3.0 or less,
The second gauze tissue is
For the warp, use a third twisted yarn having a twist coefficient of 3.3 or more,
A multi-gauze woven fabric characterized in that the weft is formed by using a fourth twisted yarn having a twist coefficient of 3.3 or more. The first gauze tissue is
The multi-gauze woven fabric according to claim 1, wherein a second twisted yarn having a twist coefficient of 3.0 or less is formed on the other of the warp or the weft. The first gauze tissue is
The multi-gauze woven fabric according to claim 1, wherein a second twisted yarn having a twist coefficient of 3.3 or more is formed on the other of the warp or the weft. It is a double gauze fabric. The multiple gauze fabric according to any one of claims 1 to 3. 3 or more gauze fabrics,
Including a third gauze tissue corresponding to the intermediate layer,
The third gauze tissue is
For the warp, use a fifth twisted yarn with a twist coefficient of 3.3 or more,
The multi-gauze woven fabric according to any one of claims 1 to 3, wherein the weft is formed using a sixth twisted yarn having a twist coefficient of 3.3 or more. A garment characterized by being sewn with the multiple gauze fabric according to any one of claims 1 to 5. A bedcloth characterized by being sewn with the multiple gauze fabric according to any one of claims 1 to 5.