JP2015096662A - Side double system cloth - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a side double system cloth which is suitable for clothing application and is superior in water absorptivity of moisture such as sweat and quick-drying only by a cloth construction structure without using special fiber or giving special processing.SOLUTION: In a side double system cloth, back side crossover points of weft and warp are fewer than front side crossover points of the weft and the warp, "points" that the weft is arranged for a cloth external layer is not less than 2.0 times of "points" that the warp is arranged for the cloth external layer, groups of convex parts caused by the weft being arranged for the external layer consecutively and concave parts except the convex parts are formed in the back side, and the configuration of the back side is not flat.

Description

  The present invention relates to a weft double-tissue woven fabric suitable for apparel that is excellent in water absorption and quick-drying of moisture such as sweat.

  Conventionally, a fabric having a function of quickly drying moisture such as sweat has been demanded particularly for use in clothing for spring and summer. In general, clothing is often worn in contact with the skin, and when sweating due to exercise or environmental atmosphere, it absorbs sweat and quickly releases the moisture to the outside air, so that it has good drying properties. How it affects the comfort of wearing.

  For the purpose of providing such a quick-drying function, different fabric structures are provided on the skin surface and the outside air surface of the fabric, and moisture contacting the skin surface is quickly moved to the outside air surface by utilizing capillary action. A fabric is generally used, and its performance can be judged by the water absorption front / back diffusion area ratio.

  A specific method for improving the water absorption front / back diffusion area ratio is to use a knitted fabric that is easy to form a structural difference between the front and back surfaces of the fabric and has a large number of voids between fibers to retain moisture. As a constituent material, use a fiber with a large single fiber fineness on the skin surface and a thin fiber with a single fiber fineness on the outside air surface, so that moisture can be absorbed from a large gap on the skin surface to a small gap on the outside air surface. It has been proposed to use the capillary action to move. Furthermore, there is a method to assist the movement of moisture from the skin surface to the outside air surface by using fibers with a special cross-sectional shape, water repellent finish on the skin surface, and water absorption treatment on the outside air surface. (See Patent Documents 1 and 2).

  However, although such a fabric is excellent in function, the use of the fabric is limited because the fabric is a knitted fabric and is inferior in the smoothness and firmness of the fabric. However, it is not a suitable material for applications such as slacks, blouses, and uniforms that require tailoring and a sense of elasticity, and there are problems in adopting these applications.

  In woven fabrics, as with knitted fabrics, it is conceivable to use the same capillary phenomenon by increasing the fineness of weft yarns that are easily exposed to the skin surface and thinning the warp yarns that are easily exposed to the outside air surface. In this case, the warp and the weft are in close contact with each other, and there are few gaps between the fibers. Since the skin surface and the outside air surface are integrated, the effect of the capillary phenomenon is small only by the difference in the fineness of the fibers.

  Therefore, in order to further increase the difference in fineness, additional means are required which are expensive, such as using ultrafine fibers having a sea-island structure or imparting hydrophilicity to the fibers (see Patent Document 3). ). Also, in this proposal, in order to increase the difference in the fineness between the skin surface and the outside air surface, the outside air surface is extremely thinned so that the surface of the outside air surface can be easily deteriorated due to friction. There are major issues.

  Also, when designing the woven fabric, if the weaving density is too high, the air permeability deteriorates, leading to discomfort during wearing, and conversely, if the weaving density is too low, misalignment occurs. It is extremely difficult to determine an optimum design that achieves both characteristics.

JP-A-2005-105441 JP-A-9-143842 Japanese Patent Laid-Open No. 52-25168

  Therefore, in view of the above-described conventional background art, the object of the present invention is that it is not necessary to use special fibers or perform special processing in the woven fabric, and to absorb moisture such as sweat only by the woven tissue structure. Another object of the present invention is to provide a weft double-tissue fabric suitable for apparel with excellent quick-drying properties.

The present invention is to solve the above-mentioned problem, and the weft double structure fabric of the present invention is a weft double structure fabric, and the intersection of the weft and the warp on the back surface is It is less than the intersection of the weft and the warp, and on the back side, the “point” at which the weft is arranged on the outer fabric layer is 2.0 times or more than the “point” at which the warp is arranged on the outer fabric layer. In addition, an uneven structure is formed on the back surface by a convex portion that is formed as a lump by continuously arranging the weft yarn on the outer layer, and the other concave portion, and the back surface is not a flat structure. This is a double-tissue fabric.
(Here, the above "point" refers to a portion where the same warp and the same weft overlap, and the portion corresponding to "1 square" in the fabric structure diagram is referred to as "1 point").

  According to a preferred aspect of the weft double-tissue fabric of the present invention, in one convex part formed on the back surface of the above-mentioned weft double-tissue fabric, the warp direction is 3 points or more and the weft direction is 3 points continuously. There is at least one portion where the weft is arranged in the outer layer of the fabric in the above range, and the weft is arranged in the outer layer of the fabric in a total of 20 points or more in one convex portion.

  According to a preferred embodiment of the weft double structure fabric of the present invention, a false twisted yarn is arranged as the weft of the weft double structure fabric.

  According to a preferred aspect of the weft double tissue fabric of the present invention, the water absorption front / back diffusion area ratio of the weft double tissue fabric is 6 or more.

  According to the present invention, a weft duplex having a water-absorbing and quick-drying property, that is, a quick-drying function, such as excellent sweat, which is required as a fabric material for clothing, more preferably as a clothing material for spring-summer uniforms. A tissue fabric is obtained.

  The weft double-tissue fabric of the present invention is a comfortable and comfortable material that does not become sticky even when sweating, and allows sweat to move quickly from the inside to the outside of the clothing and diffuse widely on the outside of the clothing. As a result, the contact area of the sweat with the outside air is increased and the effect of drying quickly is produced.

FIG. 1 is a drawing-substituting photograph for illustrating the uneven structure of the weft double-tissue fabric of the present invention. FIG. 2 is a drawing-substituting photograph for illustrating and explaining the flat structure of the weft double-tissue fabric of the present invention. FIG. 3 is a structural diagram of the weft double-tissue fabric obtained in Example 1 of the present invention. FIG. 4 is a structure diagram of the weft double-tissue fabric obtained in Example 2 of the present invention. FIG. 5 is a structure diagram of the weft double-tissue fabric obtained in Example 3 of the present invention. FIG. 6 is a structural diagram of the weft double-tissue fabric obtained in Example 4 of the present invention. FIG. 7 is a structure diagram of the weft double-tissue fabric obtained in Comparative Example 2 of the present invention.

  The weft double structure woven fabric of the present invention is a weft double structure woven fabric in which the number of intersections between the weft and the warp on the back surface is less than the intersection between the weft and the warp on the front surface, and the weft on the back surface. The “point” at which the weft yarn is arranged on the outer layer of the fabric is 2.0 times or more of the “point” at which the warp yarn is arranged on the outer layer of the fabric, and the weft yarn is continuously arranged on the outer layer. The concavo-convex structure by the convex part which became and the concave part other than that is formed in the back surface, and is a weft double structure | tissue fabric which the back surface is not a flat structure.

  In the double-tissue fabric of the present invention, the design of the weave is important, and this requirement will be described next.

  First, in the present invention, it is important that the woven structure is a weft double structure. It is possible to obtain a structure similar to that of a weft double-tissue fabric in a warp double-tissue fabric, but it is easy to change the type of weft yarn between the front and back surfaces on a loom. Yes, the weft double structure is compared with the warp double structure in increasing the variation or changing the design, such as easily changing the weft shape by changing the finishing width in the dyeing process. This has the advantage of greatly facilitating manufacture.

  On the other hand, in the case of a warp double woven fabric, in order to change the type of warp between the front and back surfaces, warp two different warps on the loom beam, or use a double beam loom, etc. Requires special skills. In the case of a warp double structure, shrinkage in the warp direction and adjustment of density in the dyeing process are not easy, and it is difficult to change the form of the warp.

  In the present invention, in view of the advantages of the above-mentioned weft double structure, a weft double structure fabric is adopted.

  Next, in the weft double structure woven fabric of the present invention, the number of intersections between the weft and the warp on the back surface is less than the intersection between the weft and the warp on the front surface, and the weft is arranged on the outer layer of the fabric on the back surface. It is important that the “point” is 2.0 times or more the “point” at which the warp is arranged on the outer layer of the fabric.

  Here, the above “point” refers to a portion where the same warp and the same weft overlap, and the portion corresponding to “1 square” in the fabric structure diagram is referred to as “1 point”.

  In the weft double structure fabric of the present invention, it is important that the number of intersections between the weft and the warp on the back surface is smaller than the intersection between the weft and the warp on the front surface. The ratio between the two is preferably 1.3 times, more preferably 1.5 times, and even more preferably 1.8 times or more. The greater the number of intersections between the warp and the weft, the more the fibers are constrained and the smaller the gap between the fibers and the fibers or between the single fibers and the single fibers. Therefore, the greater the ratio, the greater the difference in the gap between the front and back surfaces of the fabric. It becomes easier to move moisture from the back surface to the front surface by capillary action.

  Further, in the weft double structure woven fabric of the present invention, on the back side, it is important that the “point” at which the weft yarn is arranged on the outer fabric layer is 2.0 times or more than the “point” at which the warp yarn is arranged on the outer fabric layer. It is preferably 2.5 times or more, more preferably 3.0 times or more, and the upper limit is preferably 8 times or less. When the upper limit is 8 times or more, a large amount of wefts having no crossing points are arranged in the outer layer, so that it becomes easy to cause a problem as a basic physical property of the fabric, for example, a single fiber is cut by friction.

  In the present invention, when the arrangement of the warp and the weft is in such a range (structure), a structural difference between the back surface and the surface of the fabric is formed, and the capillary phenomenon from the back surface to the surface is facilitated.

  Here, the back surface corresponds to the skin surface side when the weft double-tissue fabric of the present invention becomes a garment, and the surface corresponds to the outside air surface side, in order to cause capillary action from the back surface to the surface. For this, it is necessary that the number of intersections between the warp and the weft on the back surface be smaller than the intersection between the warp and the weft on the surface so that the interfiber space on the back surface is larger than the interfiber space on the surface. By reducing the number of crossing points on the back surface, the binding force of the wefts is reduced, gaps are easily formed between adjacent wefts, and the single fibers constituting the wefts are more likely to be separated, thereby constituting the wefts. Gaps are easily formed between the single fibers, and moisture can be easily retained. As a result, the retained moisture is not diffused on the back surface.

  On the other hand, the surface has more intersections between the warp and the weft than the intersection between the warp and the weft on the back surface, so the inter-fiber gap is smaller than the back surface, and the moisture once retained on the back surface is caused by capillary action. And will diffuse on the surface.

  At this time, in the case of warp double-tissue fabric, the binding force of the warp is similarly reduced. However, since the tension of the warp is generally higher than the tension of the weft in the dyeing process, the warp is loose. It is difficult to form voids. This is one of the reasons why the weft double-tissue fabric is preferable.

  In order to form more interfiber spaces on the back side, the number of “points” at which the wefts are arranged on the outer layer of the woven fabric should be larger than the “points” at which the warp yarns are arranged on the outer layer of the woven fabric, and more than 2.0 times. is important. If the “point” is less than 2.0 times, the gap difference between the fibers on the front surface and the back surface is insufficient, and it becomes difficult to develop the capillary phenomenon.

  Furthermore, in the weft double structure woven fabric of the present invention, the above-mentioned weft is continuously formed in the outer layer, and a convex and concave structure formed by a lump and other concave portions are formed on the back surface. It is important that the back surface has a woven structure that is not a flat structure.

  On the back side of the woven fabric, for example, when the wefts are uniformly distributed over the entire surface of the fabric, such as a satin texture, the wefts and the single fibers constituting the wefts are likely to be loose and are sufficient to retain moisture on the back side. It is possible to form a gap between fibers, but the back surface, that is, the skin surface side is flat, and the entire surface of the fabric (woven fabric) is easy to come into contact with the skin when worn as clothes. It is high and the weft and the single fibers constituting the weft are loose, so that the touch is bad, especially when sweating is accompanied, the fabric (woven fabric) sticks to the skin due to the moisture retained, etc. Comfort will be very bad.

  Therefore, in order to form an inter-fiber gap sufficient to hold moisture on the back surface of the fabric and to obtain wearing comfort, it is extremely important to form a concavo-convex structure on the back surface.

  By forming the concavo-convex structure, the fabric (woven fabric) and the skin are in point contact where only the convex portions are in contact with each other, the frictional resistance is low, the skin is well separated, and wearing comfort can be obtained.

  Since the weft yarns are continuously arranged in the outer layer, the convex portion has bulges because the weft yarns and the single fibers constituting the weft yarns are separated, and a convex structure is formed on the back surface of the fabric. On the other hand, since the concave portion has more intersecting points between the warp and the weft than the convex portion, the bulge due to the weft yarn variation such as the convex portion is suppressed and a concave structure is formed.

  The convex part has a structure capable of holding moisture in the weft and the fiber space where the wefts are scattered, and suppresses the diffusion of moisture on the back surface as if the convex part becomes a bank. A small part of the water that cannot be held by the convex part flows into the concave part, but the concave part does not directly contact the skin, so it does not impair wearing comfort, and it is comfortable compared to a fabric with a flat back surface It is extremely advantageous in terms of sex.

  In the weft double-tissue fabric of the present invention, with regard to the shape of the concavo-convex portion, when the back surface of the woven fabric is visually observed, when the pattern appears to be a triangle, quadrangle, rhombus, hexagon, or circle, the convex portion or the concave portion is It corresponds to this pattern. When a convex part is used as a handle (Examples 1, 2 and 3 are applicable), the dimension of the handle is preferably 1 mm or more and 10 mm or less in the warp direction and the weft direction of the fabric. The dimension of the handle is more preferably 2 mm or more and 5 mm or less. When the pattern dimension is less than 1 mm, it is difficult to develop a difference in unevenness, which is the same as that of a woven fabric having a flat structure, and it is difficult to retain moisture on the back surface of the woven fabric. Moreover, when the dimension of the handle exceeds 10 mm, it becomes difficult to obtain wearing comfort by point contact because the contact area between the skin and clothes increases.

  In addition, when the concave portion is a handle (Example 4 corresponds), the convex portion is formed in a stitch shape and becomes one continuous convex portion. Similarly, it is preferably 1 mm or more and 10 mm or less.

  FIG. 1 is a drawing-substituting photograph for illustrating the uneven structure of the weft double-tissue fabric of the present invention. In FIG. 1A, a concavo-convex structure is formed by a concave portion 1 positioned outside the dotted line and a convex portion 2 positioned inside the dotted line in which wefts are continuously arranged on the outer layer surface. The concavo-convex structure shown in FIG. 1A is a structure of a weft double-tissue woven fabric obtained in Example 1 of the present invention.

  Further, in FIG. 1B, the concave portion 3 located inside the dotted line and the convex portion 4 (knitted pattern) in which the wefts located outside the dotted line are continuously arranged on the outer layer surface. The concavo-convex structure is formed by. The concavo-convex structure of FIG. 1B is a structure of a weft double-tissue woven fabric obtained in Example 4 of the present invention.

  Further, in the weft double-tissue fabric of the present invention, the flat structure refers to a surface structure that is uniform over the entire surface of the fabric, including special textures such as plain weave, oblique weave, satin weave, matte weave, or pear weave, The warp yarn or the weft yarn is not formed from two types of structures of a portion (convex portion) continuously arranged on the outer fabric layer and a portion (concave portion) that is not.

  FIG. 2 is a drawing-substituting photograph for illustrating and explaining the flat structure of the weft double-tissue fabric of the present invention. Each of (c), (d), (e), and (f) in FIG. 2 has an uneven surface due to the warp and the weft itself, but has a uniform surface structure over the entire surface of the fabric including the structure.

  In the present invention, in forming such a concavo-convex structure, the warp direction is continuous three or more and the weft direction is continuous in one convex portion formed on the back surface of the weft double-tissue fabric. It is preferable that there are at least one portion where the weft is arranged in the outer layer of the fabric in the range of 3 or more, and in the contents of one convex portion, the weft is arranged in the outer layer of the fabric in a total of 20 points or more. It is an aspect.

  The greater the number of consecutive “points” at which the wefts are arranged on the outer layer of the fabric, the more easily the wefts and the single fibers constituting the wefts are scattered, and an interfiber gap sufficient to hold moisture on the back surface can be formed. Easy. Specifically, if there are at least three continuous lines in the warp direction and no more than three continuous lines in the weft direction, the formation of convex portions due to weft swell is insufficient, and moisture retention becomes difficult. On the contrary, it is preferable that it is 20 or less continuous in the warp direction and 20 or less continuous in the weft direction. When these are more than 20, the number of intersections between the warp and the weft is small, so that the basic property of the fabric is not satisfied, for example, the fabric is caught by protrusions and the yarn is broken. In addition, the weft yarn is arranged in the outer fabric layer in one convex portion formed by combining portions in which the weft yarn is arranged in the warp direction and three or more continuous yarns in the weft direction and the weft yarn is arranged in the outer fabric layer. The optimum value of the number of “points” varies depending on the woven structure and the type of yarn to be used. However, when the total number of points is 20 or more, it is easy to form a sufficient gap.

  One convex part can be formed only by “points” where wefts are arranged on the outer layer of the fabric. However, the convex part is formed by three or more continuous parts in the warp direction and three or more continuous parts in the weft direction. It is also possible to form a plurality of parts arranged continuously. This is because when the number of continuous “points” that are arranged on the outer layer of the weft yarn is too large, the yarn tends to slip, and there is a concern of causing problems in terms of physical properties. effective.

  Examples of the warp and weft used in the present invention include polyester synthetic fibers such as fibers made of polyethylene terephthalate, polytrimethylene terephthalate and polybutylene terephthalate, and polyamide synthetic fibers such as fibers made of nylon 6 and nylon 66. Synthetic fibers such as multifilaments, recycled fibers such as rayon, natural fibers such as cotton and wool, drawn yarns, air-processed yarns, composite yarns, spun yarns, and twisted yarns obtained by adding twists to these yarns. However, false twisted yarn is preferably used. The false twisted yarn has crimps in the single fiber, and when the warp and weft have few intersections and the binding force is lost, the single fiber is likely to be loosened, and it is extremely difficult to form a void that retains moisture. It becomes easy.

  The total fineness of the warp and weft constituting the weft double structure woven fabric of the present invention is preferably 50 denier or more and 200 or more in the case of multifilament fiber yarns in order to obtain a thickness and texture suitable as a woven fabric for clothing. In the case of spun yarn, it is preferable to combine fiber yarns of 50th to 20th. In the case of multifilament fibers, the total fineness is more preferably 75 deniers or more and 150 deniers or less, and in the case of spun yarns, more preferably 40 yarns or more and 30 yarns or less are combined.

  Moreover, about the false twisted yarn used, what was processed with the normal draw ratio suitable for the fiber to be used, such as a polyester fiber and a polyamide fiber, the number of false twists, and heat set temperature can be used.

  The weft double structure used in the present invention is a structure in which the warp is a single layer and the weft is composed of two layers, the front and the back, and when used as a clothing for spring and summer that easily sweats, It is preferable to use a drawn yarn or a twisted yarn as the warp so as not to generate a fukuroki. In addition, as the weft on the back side, false twisted yarn and air mixed yarn that easily form voids between single fibers, or spun yarn blended with natural fibers to obtain a comfortable touch, in order to retain moisture, can be used. It is preferable to use it. The front weft is the same as the back weft.

  Further, the warp density and the weft density of the woven fabric vary depending on the total fineness of the fibers used and the structure employed. In addition, the weft density between the front and back surfaces is that the surface has many surfaces, the back surfaces are many, or even if the front and back surfaces are the same, if the above uneven structure is formed, the desired water absorption front and back diffusion areas can be obtained. Is possible.

  When the weft yarn on the back side is partially arranged and the concavo-convex structure is formed on the back side of the woven fabric, the weft density on the front surface is larger than the weft density on the back surface, but it is arranged with the portion where the back weft yarn is arranged. The difference in the warp in the warp direction of the woven fabric tends to be different from the unexposed portion, and the woven fabric tends to be uneven as a texture. On the contrary, when the surface wefts are partially arranged and a concavo-convex structure is formed on the back side of the fabric, the weft density on the back side is larger than the weft density on the surface, but the physical properties that are particularly important on the surface There is a tendency for pilling and snag to get worse. Therefore, it is more preferable that the weft densities on the front surface and the back surface are the same in order to obtain a fabric having a texture and physical properties as a clothing material.

  The weft double-tissue fabric of the present invention is subjected to dyeing or resin processing. In the dyeing process, a usual dyeing method such as liquid flow dyeing or continuous dyeing is employed. Also, the resin processing can be subjected to water absorption processing or antistatic processing.

  According to the above design, in the present invention, it is possible to obtain a weft double-tissue fabric suitable for clothing having a water absorption front / back diffusion area ratio of preferably 6 or more. The water absorption front / back diffusion area ratio is more preferably 8 or more.

  In addition, the large water absorption front / back diffusion area ratio means that after the sweat from the skin is absorbed by the fabric, it does not diffuse on the skin surface of the fabric, but quickly penetrates into the outside air surface of the fabric and diffuses greatly on the outside air surface. This means that it diffuses greatly on the outside air surface, increasing the area that touches the outside air and drying quickly. Therefore, the larger the water absorption front / back diffusion area ratio, the better.

  The double-tissue fabric of the present invention includes jackets and slacks, skirts, shirts worn as office uniforms, jackets and slacks, skirts, shirts worn as working uniforms, sports clothing, casual wear, outer clothing, etc. It is suitably used for clothing applications.

  Next, the weft double-tissue fabric of the present invention will be described in detail with reference to examples. The characteristic values shown in the examples are measured by the following methods.

[Water diffusion front / back diffusion area ratio]
On the glass plate, 0.1 cc of an ink solution obtained by diluting commercially available ink twice with water was dropped, and the back surface of the sample fabric (woven fabric) was placed on the bottom, that is, on the side in contact with the ink solution. Then, after being left for 60 seconds to absorb the ink liquid, this was moved onto another glass plate, and again left for 3 minutes with the back side down. It carried out similarly about three fabrics. The diffusion area of the ink liquid on the front and back surfaces of the sample fabric thus obtained was measured, and the area ratio (surface diffusion area / back surface diffusion) calculated from the measured values was shown as the water absorption front / back diffusion area ratio. It was.

  The size of the diffusion area indicates the absorption state of the ink liquid, and the surface diffusion area is large and the area ratio is large, so that the dropped ink liquid efficiently moves to the surface side. This means that the water permeability and diffusion capacity are excellent. In addition, a large diffusion area on the surface side indicates that the contact efficiency with the air is improved, so that the drying property is also excellent.

[Example 1]
Polyethylene terephthalate multifilament non-crimp drawn yarn (84 dtex-36f) is used as warp, polyethylene terephthalate multifilament false twist yarn (84 dtex-36f) is used as the surface weft, and polyethylene terephthalate multifilament false twist yarn (167dtex-48f) is used as the weft on the back surface, and according to the fabric structure of FIG. 3, using a normal air jet loom, the warp density is 135 / 2.54 cm, and the weft density is 129 / 2.54 cm. A weft double weave fabric was woven.

  The organization chart of FIG. 3 is for weaving with a back weave (on the loom, the side of the organization chart is down). An organization chart in which the organization chart is divided into a front surface (the warp is common and the weft is the front weft) and the back surface (the warp is common and the weft is the back weft) is a. Backside, b. A surface, a. A portion surrounded by a dotted line (red line) on the back surface is one convex portion in which wefts are continuously arranged on the outer layer portion on the back surface of the fabric, and the other portion is a concave portion. In this case, the convex portion forms a square pattern. The surface has a flat structure without a portion where wefts are continuously arranged on the outer layer of the fabric.

  At this time, there are 224 crossing points with the warp of the weft on the back surface, and 464 cross points with the warp of the weft on the front surface, and the ratio is 2.1 times. The number of “points” placed on the woven fabric was 432, and the number of “points” on which the warp was placed on the outer layer of the fabric was 144, and the ratio was 3.0 times.

  Further, on the back surface, the warp direction is 12 continuous, the weft direction is 12 continuous, and the wefts are arranged on the outer layer of the woven fabric to form one convex portion with 144 “points” in total. It became a structure.

  Next, the obtained weft double-tissue fabric was subjected to normal liquid dyeing finishing to obtain a fabric having a warp density of 151 / 2.54 cm and a weft density of 138 / 2.54 cm. The woven fabric had a water absorption front / back diffusion area of 17.6, and as a result of being worn as a shirt for a work uniform, it was a comfortable material that did not stick to the skin even when sweating and did not feel stuffy. The results are shown in Table 1.

[Example 2]
Polyethylene terephthalate multifilament non-crimp-drawn yarn (84 dtex-36f) is used as warp yarn, spun yarn of 34th single yarn consisting of 65% polyester fiber and 35% cotton by weight as surface weft, and polyethylene terephthalate multifilament 4 using the normal twisted yarn (84 dtex-36f) as the weft on the back surface and using a normal air jet loom according to the fabric structure of FIG. 4, the warp density is 135 / 2.54 cm, and the weft density is 132 /2.54 cm weft double-tissue fabric was woven.

  The organization chart in FIG. 4 is for weaving with a back weave (on the loom, with the organization chart side down). An organization chart in which the organization chart is divided into a front surface (the warp is common and the weft is the front weft) and the back surface (the warp is common and the weft is the back weft) is a. Backside, b. A surface, a. A portion surrounded by a dotted line (red line) on the back surface is one convex portion in which wefts are continuously arranged on the outer layer portion on the back surface of the fabric, and the other portion is a concave portion. In this case, the convex part forms a rhombus pattern. The surface has a flat structure without a portion where wefts are continuously arranged on the outer layer of the fabric.

  At this time, there are 124 intersections with the warp of the weft on the back surface, and 264 intersections with the warp of the weft on the front surface, and the ratio is 2.1 times. The number of “points” arranged on the outer layer of the fabric was 208 points, and the number of “points” arranged on the outer layer of the fabric was 64, and the ratio thereof was 3.3 times.

  In addition, on the back surface, one convex part is formed with a total of 25 “points” centered on the portion where the warp direction is continuous 5 and the weft direction is continuous 3 and the weft is arranged on the outer layer of the fabric. An uneven structure was obtained.

  Next, the obtained weft double-tissue fabric was subjected to normal liquid dyeing finishing to obtain a fabric having a warp density of 144 pieces / 2.54 cm and a weft density of 143 pieces / 2.54 cm. The woven fabric had a water absorption front / back diffusion area of 11.9, and as a result of being worn as a shirt for a work uniform, it was a comfortable material that did not stick to the skin even when sweating and did not feel stuffy. The results are shown in Table 1.

[Example 3]
A twisted yarn obtained by adding a twist of 800 times / m in the Z direction to a non-crimped drawn yarn (84 dtex-36f) of polyethylene terephthalate multifilament is used as a warp yarn, and a false twisted yarn (168 dtex-288f) of polyethylene terephthalate multifilament is used on the surface. Polyethylene terephthalate multifilament false-twisted yarn (84 dtex-36f) is used for the weft, and the warp density is 126 / 2.54 cm using a normal air jet loom according to the weave structure of FIG. A weft double-tissue fabric having a weft density of 144 / 2.54 cm was woven.

  The organization chart shown in FIG. 5 is a case where weaving is performed using a surface weaving (on the loom, the organization chart is facing upward). An organization chart in which the organization chart is divided into a front surface (the warp is common and the weft is the front weft) and the back surface (the warp is common and the weft is the back weft) is a. Backside, b. A surface, a. A portion surrounded by a dotted line (red line) on the back surface is one convex portion in which wefts are continuously arranged on the outer layer portion on the back surface of the fabric, and the other portion is a concave portion. In this case, the convex part forms a rhombus pattern. The surface has a flat structure without a portion where wefts are continuously arranged on the outer layer of the fabric.

  At this time, there are 192 crossing points with the warp of the weft on the back surface, 576 crossing points with the warp of the weft on the front surface, and the ratio is 3.0 times. The number of “points” arranged on the outer layer was 492, and the number of “points” arranged on the outer layer of the woven fabric was 96, and the ratio was 5.1 times.

  In addition, on the back surface, one convex portion is formed with a total of 60 “points” including a portion in which the warp direction is continuous three and the weft direction is continuous five and the wefts are arranged on the outer layer of the fabric. An uneven structure was obtained.

  The resulting weft double-tissue fabric was then subjected to normal liquid dyeing finishing to obtain a fabric having a warp density of 160 / 2.54 cm and a weft density of 156 / 2.54 cm. The woven fabric had a water absorption front / back diffusion area of 10.2, and as a result of being worn as a shirt for a work uniform, it was a comfortable material that did not stick to the skin even when sweating and did not feel stuffy. The results are shown in Table 1.

[Example 4]
A twisted yarn obtained by adding a twist of 800 times / m in the Z direction to a non-crimped drawn yarn of polyethylene terephthalate multifilament (84 dtex-36f) is used as a warp yarn, and a false twisted yarn (84 dtex-36f) of polyethylene terephthalate multifilament is used on the surface. For the weft, a spun yarn of 34th single yarn composed of 65% by mass of polyester fiber / 35% by mass of cotton is used as the weft on the surface, and according to the fabric structure of FIG. A weft double-tissue fabric with a /2.54 cm and a weft density of 131 / 2.54 cm was woven.

  The organization chart in FIG. 6 is for weaving with a back weave (on the loom, with the organization chart side down). An organization chart in which the organization chart is divided into a front surface (the warp is common and the weft is the front weft) and the back surface (the warp is common and the weft is the back weft) is a. Backside, b. A surface, a. A portion surrounded by a dotted line (red line) on the back surface is one convex portion in which wefts are continuously arranged on the outer layer portion on the back surface of the fabric, and the other portion is a concave portion. In this case, the concave portion forms a square pattern. The convex portions are arranged in a knitted pattern. The surface has a flat structure without a portion where wefts are continuously arranged on the outer layer of the fabric.

  At this time, the number of intersections between the wefts on the back surface and the warp yarns is 104, and the intersection points between the wefts on the front surface and the warp yarns is 256, and the ratio is 2.5 times. The number of “points” arranged on the outer layer of the woven fabric was 218, and the number of “points” arranged on the outer layer of the woven fabric was 54, and the ratio was 4.0 times.

  In addition, on the back surface, a concavo-convex structure was formed in which one continuous convex portion was formed by combining a portion in which the warp direction was continuous seven and the weft direction was continuous seven.

  The resulting weft double-tissue fabric was then subjected to normal liquid dyeing finishing to obtain a fabric having a warp density of 144 / 2.54 cm and a weft density of 142 / 2.54 cm. The woven fabric had a water absorption front / back diffusion area of 13.5, and as a result of being worn as a shirt for a work uniform, it was a comfortable material that did not stick to the skin even when sweating and did not feel stuffy. The results are shown in Table 1.

[Comparative Example 1]
Polyethylene terephthalate multifilament crimped yarn (84dtex-36f) is used as warp, polyethylene terephthalate multifilament false twisted yarn (168T-48f) is used as weft, and normal air jet loom is used. A plain-textured fabric having 110 pieces / 2.54 cm and a weft density of 50 pieces / 2.54 cm was woven.

  Next, the obtained plain tissue woven fabric was subjected to a normal liquid dyeing finish to obtain a woven fabric having a warp density of 122 / 2.54 cm and a weft density of 53 / 2.54 cm. The woven fabric had a water absorption front / back diffusion area of 1.2, and was worn as a shirt for work uniforms. As a result, the fabric became sticky on the skin due to sweating, and was a material with poor touch. The results are shown in Table 1.

[Comparative Example 2]
Polyethylene terephthalate multifilament non-crimp drawn yarn (84 dtex-36f) is used as warp, polyethylene terephthalate multifilament false twist yarn (84 dtex-36f) as surface weft, and polyethylene terephthalate multifilament false twist yarn (167 dtex-48f) is used for the weft on the back surface, and according to the fabric structure of FIG. 7, using a normal air jet loom, the warp density is 135 / 2.54 cm, the weft density is 129 / 2.54 cm, Weaving a double-tissue fabric.

  The organization chart of FIG. 7 is a case of weaving with a back weave (on the loom, the side of the organization chart is down). An organization chart in which the organization chart is divided into a front surface (the warp is common and the weft is the front weft) and the back surface (the warp is common and the weft is the back weft) is a. Backside, b. There was no part where wefts were continuously arranged on the outer layer of the woven fabric on both the back and front surfaces, resulting in a flat structure.

  At this time, there are 112 intersections with the warp of the weft on the back side, and 128 intersections with the warp on the weft, and the ratio is 1.1 times. Since there are no portions arranged on the outer layer of the woven fabric and there are many intersections with the warp, there are 84 “points” where the wefts are arranged on the outer layer of the woven fabric, and 72 “dots” where the warps are arranged on the outer layer of the woven fabric. In that respect, the ratio was 1.7 times.

  In addition, the back surface has a portion in which the weft is arranged in the outer layer of the woven fabric only in the warp direction, or three in the weft direction. The warp direction is three or more and the weft direction is three or more. Since there is no portion where the weft is arranged on the outer layer of the fabric, the structure is flat without forming irregularities.

  Next, the obtained weft double-tissue fabric was subjected to normal liquid dyeing finishing to obtain a fabric having a warp density of 151 / 2.54 cm and a weft density of 138 / 2.54 cm. Even after finishing, the back surface did not form convex portions, and had a flat structure (a uniform surface structure on the entire surface of the fabric including the structure). The water absorption front and back diffusion area of this fabric was 2.4. The results are shown in Table 1.

1. Recessed portion 2. Convex part 3. 3. Recessed part Convex part

Claims (4)

  A “point” in which the weft and warp yarns on the back surface are less than the crossing points between the weft yarns and the warp yarns on the front surface, and the weft yarns are arranged on the outer fabric layer on the back surface. Are warps that are 2.0 times or more of the “points” placed on the outer layer of the fabric, and the wefts are continuously placed on the outer layer to form a group of convex portions, and other concave portions, A weft double-tissue woven fabric characterized in that an uneven structure is formed on the back surface.   In one convex part formed on the back surface of the weft double-structure fabric, at least a portion where the weft is arranged on the outer layer of the fabric within the range where the warp direction is 3 points or more and the weft direction is 3 points or more is at least The weft double-tissue fabric according to claim 1, wherein the weft yarn is arranged on the outer layer of the fabric in one place and within a total of 20 or more points in one convex portion.   The weft double-tissue fabric according to claim 1 or 2, wherein a false twisted yarn is arranged as the weft.   The weft double-tissue fabric according to any one of claims 1 to 3, wherein the water absorption front / back diffusion area ratio is 6 or more.