JP2017148422A - Knitted fabric for footwear - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a knitted fabric for footwear which can prevent the occurrence of foot stuffiness in the footwear more and reduce the occurrence of odor more.SOLUTION: The invented fabric is two-layer knitted fabric consisting of yarn A and yarn B, the yarn A is twisted union yarn of paper yarn or the paper yarn and synthetic fiber yarn, among two surfaces S1 and S2, knit loops are formed with the yarn A on the surface S1 and the knit loops are formed with the yarn B on the surface S2, on the surface s1, the knitted fabric having parts where two or more knit loops consisting of the yarn A in the condition inclining in the thickness direction is used so that the surface S1 is located in the side contacting the foot.SELECTED DRAWING: Figure 3

Description

  The present disclosure relates to a knitted fabric suitable for constituting an insole, an upper and the like of footwear.

  In athletic shoes such as walking shoes, running shoes, and sports shoes, foot stuffiness is likely to occur due to sweating during wearer's exercise. As a measure against foot stuffiness, an athletic shoe in which a part or all of a shoe is made of a mesh material is known. Such sports shoes can reduce the discomfort caused by the steam remaining in the shoes by discharging the steam generated by perspiration from the opening of the mesh part to the outside, but rainwater and dirt penetrate into the shoes. It has the disadvantage of being easy. Foot stuffiness is a problem that occurs not only in sports shoes, but also in other shoes and footwear. Foot stuffing can also cause odors. This is because when the shoes are taken off in a state where foot stuffiness has occurred, vapor generated by sweating rises, and odors diffuse along with this.

  Various proposals for reducing foot stuffiness and bad odor in shoes have been made. For example, Patent Document 1 discloses an insole for footwear made of Japanese paper strip fabric. This insole is lightweight and has a deodorizing and antibacterial action. Patent Document 2 discloses a fabric using a thread containing Japanese paper, and discloses that this fabric can be suitably used for an upper or an insole. This fabric combines hygroscopicity, durability and good tactile sensation. Patent Document 3 discloses a shoe using a woven or knitted fabric using a yarn containing Japanese paper as at least a part of the shoe upper. These shoes have little stuffiness and a refreshing feeling.

JP 2001-353004 A Japanese Patent Laying-Open No. 2015-098668 JP 2005-192724 A

  The present embodiment is made for the purpose of providing a knitted fabric for footwear that can further suppress foot stuffiness in the footwear and thereby reduce the generation of malodor.

The present disclosure, in one aspect,
A two-layer knitted fabric composed of yarn A and yarn B,
Yarn A is a paper yarn or an intertwisted yarn of a paper yarn and a synthetic fiber yarn,
Of the two surfaces S1 and S2, on the surface S1, the knit loop is composed of the yarn A, and on the surface S2, the knit loop is composed of the yarn B,
The surface S1 has a portion in which two or more knit loops composed of the yarn A are gathered in a state inclined in the thickness direction.
Providing knitted footwear.

  Since the knitted fabric for footwear of the present disclosure can absorb more steam due to sweating of the foot and can give the user a light touch, the interior material for footwear such as an upper lining material and an insole As well as the upper itself.

It is an example of the knitting | organization organization chart of the knitted fabric of this embodiment. It is an example of the knitting | organization organization chart of the knitted fabric of this embodiment. 4 is an optical micrograph showing an uneven surface (surface S1) of a knitted fabric produced in Example 2. 6 is an optical micrograph of a surface of the insole of Comparative Example 2 that is in contact with the foot (corresponding to the flat surface (surface S2) of the knitted fabric produced in Example 1). It is a top view which shows typically the distance between intersections in a knitted fabric, the distance between knit loops, and the knit loop width. It is a top view which shows typically the distance between intersections in a knitted fabric, the distance between knit loops, and the knit loop width.

[Reason for reaching this embodiment]
When the present inventor constructs an interior material (a member in contact with the user's foot and not generally appearing on the shoe surface) such as an insole or upper of the footwear by woven fabric and knitted fabric, sweat from the foot, In detail, the structure which can absorb more sweat discharged from the foot in the form of vapor was examined. Specifically, among yarns with high hygroscopicity, paper yarn is selected from the viewpoint of having a dry touch feeling (sharp feeling) and a light touch feeling, and not only using paper yarn but also woven and knitted fabrics. The possibility of reducing foot stuffiness by adjusting was examined. On the other hand, the interior material does not generally appear on the front of the shoe, and is used by being joined to another member. Therefore, it may be necessary to ensure good jointability with the other member.

  When the paper yarn absorbs the vapor, the paper yarn takes in the vapor inside the yarn and holds it. For this reason, in order to increase the absorption speed of the vapor, it is necessary to create a sufficient gap around the paper yarn so that the area where the paper yarn and sweat contact is increased. However, for example, in the woven fabrics shown in Patent Documents 1 and 2, the yarns are in relatively close contact with each other, and the paper yarn cannot absorb sweat immediately, and in addition, the surface of the woven fabric after moisture absorption has a sticky feeling. I found out that As a result of studies by the present inventors, it has been found that a relatively large gap can be secured between yarns by forming the knitted fabric into a two-layer structure. After further investigation, the two-layer knitted fabric is knitted so that the surface including the paper yarn has two or more portions where the knit loops are inclined in the thickness direction, and the paper yarn is arranged three-dimensionally. In addition, it has been found that a knitted fabric suitable as an interior material for footwear can be obtained by providing, on the surface, a sparse region where the proportion of yarn is relatively small and a dense region where the proportion of yarn is relatively large. It was.

That is, when a two-layer knitted fabric is configured by selecting a knitting structure so that irregularities are formed by paper yarn on one surface, the exposed area of the paper yarn becomes larger on this surface (contact area between yarns). We found that the paper thread can absorb more vapor more quickly. In addition, when unevenness is provided by a knitted structure, it is possible to form a convex portion having a high yarn density and not easily deformed by pressure, and a concave portion having a small yarn density and a large gap. It has also been found that the contact area between the foot and the knitted fabric becomes smaller and gives the user a lighter feeling.
This embodiment will be described below.

[Thread A and thread B]
The knitted fabric for footwear of the present embodiment is a two-layer knitted fabric composed of yarn A and yarn B, and the knit loop is composed of yarn A on the surface S1 of the two surfaces S1 and S2. A knitted fabric for footwear (hereinafter, also simply referred to as “knitted fabric”) in which the knit loop is formed of the yarn B on the surface S2. Here, first, two types of yarn constituting the knitted fabric of this embodiment will be described.
In the present specification, “knit loop” refers to a loop formed by passing through a previously formed loop.

  The yarn A is a paper yarn or a twisted yarn of a paper yarn and a synthetic fiber yarn. Especially, it is preferable that the thread | yarn A is a twisted yarn (henceforth "paper yarn twisted yarn") of a paper yarn and a synthetic fiber yarn. Paper yarns are less flexible than synthetic fiber yarns such as polyester yarns, so folds (the lines that stick to where they are folded) are easily maintained (hard to disappear). Due to this feature, when the yarn is unwound from a state where the yarn is wound around the bobbin (cone, cheese, etc.), the yarn may not be smoothly bent and unwound smoothly. By twisting the synthetic fiber yarn on the paper yarn, the flexibility is increased and the crease hardly remains, so that the knitting workability is improved.

The paper yarn is obtained by slitting a paper obtained by making one or a plurality of paper raw materials selected from hemp, wood pulp, gutter, mitsumata, and cocoon into narrow widths with a slitter and twisting. It may be a thing. Paper having a basis weight for the production of paper yarn may be ^{5g / m 2 ~30g / m 2} , preferably ^{10g / m 2 ~20g / m 2} , the width of the slit in 0.5mm~3mm It may be, and is preferably 10 mm to 20 mm. The number of twists may be 500-1500 per meter. For example, paper yarn is sold by Oji Fiber Co., Ltd. under the trade name OJO +.

As the paper yarn, a paper yarn having an apparent density of 0.8 g / cm ³ or less is preferably used, and a paper yarn having 0.6 g / cm ³ or less is more preferably used. A paper yarn having an apparent density of 0.8 g / cm ³ or less has a large amount of moisture absorption because it has many voids inside the yarn. The lower limit is not particularly limited, but may be 0.2 g / cm ³ .

  Synthetic fiber yarns that are twisted with paper yarn are, for example, polyester fibers made of polyester resins such as polyethylene terephthalate, polybutylene terephthalate, polytrimethylene terephthalate and polybutylene succinate, and polyamide resins such as nylon 6 and nylon 66. A monofilament yarn, a multifilament yarn or a spun yarn (mixed yarn, twisted yarn consisting of one or more synthetic fibers selected from polyamide fibers, polyolefin fibers consisting of polyolefin resins such as polyethylene and polypropylene, and acrylic fibers) May be included).

  Synthetic fiber yarns that are twisted with paper yarn are single fibers or composite fibers in which a low melting point resin (for example, polyethylene, low melting point polyethylene terephthalate, etc.) having a melting point of about 80 ° C. to 220 ° C. occupies a part or all of the fiber surface. (Hereinafter also referred to as “adhesive synthetic fiber yarn”). When such a yarn is used, the low melting point resin can be melted or softened by heat treatment or the like, and the yarns can be bonded to each other at the intersection.

  In the twisted yarn of the paper yarn and the synthetic fiber yarn, the paper yarn preferably occupies 50% by mass to 90% by mass of the entire paper yarn intertwisted yarn. If the ratio of the paper thread is too small, the hygroscopicity is small and sweat from the foot may not be sufficiently absorbed. If the ratio of the paper yarn is too large, the knitting workability may be insufficient and knitting with a knitting machine may be difficult.

The yarn B is not particularly limited, and may be a paper yarn, a paper yarn twisted yarn described in connection with the yarn A, or a synthetic fiber yarn, a recycled fiber yarn (rayon, copper ammonia rayon, solvent-spun cellulose fiber, etc.) or Natural fiber yarn (cotton, hemp, wool, etc.) may be used. When the yarn B is a synthetic fiber yarn, the yarn B may be a synthetic fiber yarn that is twisted with the paper yarn described above.
The yarn B preferably has a smaller water absorption or moisture absorption than the yarn A. The magnitude of water absorption is compared, for example, by immersing the yarn A and the yarn B in water for the same amount of time and taking out the yarn for a certain time (for example, 30 minutes) and then measuring the water absorption rate. Can do. The hygroscopicity can be compared by measuring the moisture absorption rate immediately after the yarn A and the yarn B are exposed to the steam atmosphere for the same time, or after a certain period of time.

Such a yarn B may be exemplified as a synthetic fiber yarn to be twisted with the paper yarn. The yarn B may be, in particular, a monofilament yarn or a multifilament yarn (hereinafter collectively referred to as “filament yarn”) made of a polyester resin, particularly polyethylene terephthalate. Filament yarn made of polyester resin itself is difficult to absorb water. When a knitted fabric is formed using this yarn, moisture is retained between filament yarns, but such moisture evaporates in a relatively short time. The knitted fabric tends to have quick drying properties.
The yarn B may also be the above-mentioned adhesive synthetic fiber yarn.

The diameter of the yarn A is preferably 100 μm to 500 μm, and more preferably 150 μm to 300 μm. When the diameter of the yarn A is 100 μm or more, the thickness of the knitted layer composed of the yarn A is increased, so that the moisture retention amount is increased. Furthermore, the yarn A having a diameter of 100 μm or more tends to give a dry touch feeling (also referred to as a sharp feeling to those skilled in the art) to the surface S1. When the diameter of the yarn is 500 μm or less, the surface S1 does not become too hard to feel, and when used as an interior material such as an insole or an upper lining, shoe rubs are unlikely to occur.
The yarn diameter can be calculated from the yarn weight per yarn length and the apparent yarn density. When the cross section of the yarn is not a circle, the cross sectional area of the yarn is calculated as a circle equal to the cross sectional area. Alternatively, when the apparent density of the yarn is not known, the yarn diameter may be obtained by directly observing the cross section of the yarn with a microscope or the like and performing image processing as necessary.

  When the yarn A is a twisted yarn of paper yarn and synthetic fiber yarn, the diameter of the paper yarn is preferably larger than the diameter of the synthetic fiber yarn. With this configuration, the characteristics (for example, suppleness) of the synthetic fiber yarn can be imparted while maintaining the characteristics (for example, hygroscopicity) of the paper thread. From the viewpoint of facilitating the exposure of the paper yarn on the surface of the yarn A and / or increasing the surface where the paper yarn constituting the yarn A comes into contact with the steam, the diameter of the paper yarn is 1.5 times that of the synthetic fiber yarn. It is more preferably twice or more, and particularly preferably two or more times. In addition, from a viewpoint of providing the characteristics of the synthetic fiber yarn, the upper limit may be 10 times or less.

  The diameter of the yarn B is preferably 30 μm to 150 μm, and more preferably 50 μm to 100 μm. If the diameter of the yarn B is 30 μm or more, the loop shape constituted by the yarn B may be deformed by the tack of the yarn A. When the diameter of the yarn B is 150 μm or less, the surface S2 tends to be flat.

  The diameter of the thread A is preferably larger than the diameter of the thread B. The diameter of the yarn A is more preferably 1.2 times or more than the diameter of the yarn B, and particularly preferably 1.5 times or more. When the diameter of the yarn A is larger than the diameter of the yarn B, the angle at which the knit loop is inclined in the thickness direction at the portion where the knit loops are gathered close to each other on the surface S1 (the angle formed between the knitted surface and the surface surrounded by the loop) Becomes more vertical and / or more loops are inclined in the thickness direction. As a result, the part where two or more knit loops gathered together becomes a part where the loops inclined in the thickness direction are densely gathered in a narrower region, and the yarn occupies a larger proportion in the part, so the surface of the knitted fabric It becomes a convex part which is hard to be crushed with respect to the pressure applied perpendicularly to the direction. The upper limit may be 5 times or less from the viewpoint of knitting workability in the knitting process.

[Composition of knitted fabric]
In the knitted fabric for footwear of the present embodiment, the knit loop is composed of the yarn A on the surface S1 of the two surfaces S1 and S2, the knit loop is composed of the yarn B on the surface S2, and the surface S1. However, the knit loop composed of the yarn A is knitted so as to have two or more gathered portions inclined in the thickness direction. Further, the two knitted layers are tucked together by the yarn A and integrated. Therefore, the yarn A used for tacking is exposed to the surface S2 at the tucked portion, but does not constitute a knit loop.

  The knitted fabric of this embodiment is realized by, for example, the knitting structure shown in FIG. 1 or FIG. According to these knitted structures, it is easy to obtain a two-layer knitted fabric in which the surface S2 is flatter than the surface S1 (that is, the degree of unevenness of the surface S1 is larger than that of the surface S2). In the knitting structure of FIG. 1, in one row (course) of the wale direction constituted by the yarn A, tucking is performed every two loops, and the tack positions are the same for the two courses (rows 1 and 3 in FIG. 1). After the position, the next two courses (columns 5 and 7 in FIG. 1) are shifted by one loop. In FIG. 2, in the course constituted by the yarn A, the tack position is the same for the three courses, and then the next three courses are shifted by one loop.

  According to these knitted structures, the loop adjacent to the tack portion in one course on the surface S1 is inclined in the thickness direction (that is, the surface surrounded by the loop is more parallel to the thickness direction). In the portion where the loop is inclined in the thickness direction, the yarns A are three-dimensionally overlapped to increase the thickness, and a convex portion is formed. Moreover, in the said part, the distance between two adjacent loops is smaller, and the part where the thread | yarn gathered together was formed. Further, the knitted structure is formed of yarn B on the surface S2, and has loops that are equally spaced in the wale direction, and the yarn A is tucked into the loop of the surface S2. Therefore, the length of one tack portion and the distance between two adjacent loops on the surface S1 are both limited by the width of the equally spaced loops knitted on the surface S2, and they are approximately equal. For this reason, two adjacent knit loops located between the two tack portions in one course on the surface S1 are brought close to each other toward the other knit loop (in a direction away from the tack portion) It can be inferred that the two knitted loops that do not fit in the width limited by the knitted loop width of the surface S2 are inclined in the thickness direction.

  In addition, a relatively large gap is formed between a pair of two or more loops gathered together in a state inclined in the thickness direction in the wale direction. This is when the point where the knit loop and the previous loop overlap is the intersection, and the shortest of the line segments connecting the intersections between the two adjacent knit loops in one course is the distance between the intersections. In addition, in the surface S1, the distance between one or more intersections is larger than the knit loop width of the surface S2. Here, the “previous loop” is a loop of a course immediately below the course to which the knit loop of interest belongs, and is also called an old loop. A space is formed in the surface S1 at a location where the distance between the intersections is large. The “void” here refers to a state on the surface S1 side of a portion where the yarn A is tucked and exposed to the surface S2. In the portion where the void is formed (void portion), since the yarn A does not exist on the surface S1, the proportion of the yarn is small.

  5 and 6 schematically show the distance between the intersections, the distance between the knit loops, and the knit loop width. FIG. 5 illustrates the distance between the intersections on the surface S1 of the present embodiment, and FIG. 6 illustrates the distance between the intersections using a general flat knitting structure for easy understanding. In the figure, the intersections located between two adjacent knit loops are indicated by K1 to K4. The length of the shortest line segment (the line segment connecting the intersections K3 and K4 in the drawing) between the two adjacent knit loops is the distance between the intersections. The distance between the knit loops is a line segment connecting any two points on the outer edges of two adjacent knit loops, and the length of the shortest line segment among the line segments parallel to the wale direction is the distance between the knit loops. It becomes. The knit loop width is a line segment connecting any two points on the outer edge of one knit loop, and is the length of the longest line segment among the line segments parallel to the wale direction.

  According to these knitting structures, in the course where the tack position changed from the previous course (column 3 in FIG. 1) (column 5 in FIG. 1), the knit loop becomes thick due to the change in tack position. Since the direction of inclination in the vertical direction changes, the two directions in the thickness direction when two adjacent loops in the wale direction pass through the loop of the next course (row 7 in FIG. 1) are two or three courses. It changes every time. Thereby, even if it receives a pressure in the direction perpendicular | vertical with respect to the surface of a knitted fabric, the part inclined in the thickness direction becomes difficult to deform | transform.

  As shown in FIGS. 1 and 2, the position of the tack may be changed every two to three courses, or may be changed every four or more courses, and may not be changed. However, as the number of courses having the same tack position increases, the interval between the portions where the thickness of the knitted fabric increases (the interval in the knit loop (course) direction) increases, and the effect of making the surface S1 uneven. Is difficult to obtain. Therefore, in the present embodiment, it is most preferable that the tack position is changed every two courses as shown in FIG.

  As shown in FIGS. 1 and 2, the tack is preferably formed every two loops. Thereby, the number of convex parts in a transverse (wel) direction can be increased. Alternatively, a tack may be provided for every 3 loops or more. In that case, since the loop not adjacent to the tack portion is difficult to tilt in the thickness direction, the number of the knit loops inclined by the loop surface formed by the tack is reduced, and the number of convex portions on the surface S1 is reduced. Therefore, if the interval between the tack positions is increased, it may be difficult to give the user a light touch.

  On the other hand, on the surface S2, the yarn B forms a knit loop. In this embodiment, since the yarn B is not tucked, the knit loop constituting the surface S2 is not inclined in the thickness direction, and the surface surrounded by the loop of the knit loop is parallel to the surface S2. With this configuration, the surface S2 is a flat surface. As a knitting structure for obtaining such a surface S2, there is a tengu structure.

  In the present embodiment, the surface S2 is likely to be flatter than the surface S1, and such a shape is preferable from the viewpoint of ease of joining to other members. Whether the surface S2 is flatter than the surface S1 can be easily determined by observing the side surface of the knitted fabric, and may be determined by measuring the surface roughness using, for example, KES. The surface roughness corresponds to SMD in KES.

  On the surface S2, the thread A may be exposed to a part thereof. In the portion where the thread A is tucked to the surface S2, the thread A is exposed to the surface S2. The knit loop on the surface S2 preferably has a knit loop width of 0.8 to 1.2 times the knit loop distance in the yarn direction. The knit loop width and the distance between the knit loops are as described above with reference to FIG. When the knit loop width is 0.8 to 1.2 times the distance between the knit loops, the yarn A is formed of the yarn B by forming a gentle curve in the portion where the yarn A is exposed on the surface S2. Since the knit loop is tacked, the surface S2 tends to be a flat surface.

  3 and 4 show enlarged photographs of the surface S1 and the surface S2 of the two-layer knitted fabric produced in the examples described later. In FIG. 3, the portion surrounded by the dotted square frame is the knitted fabric obtained in the example, in which the knit loop composed of the yarn A is gathered closer to two or more in a state of being inclined in the thickness direction. It is a large part. In FIG. 3, a portion surrounded by a dotted ellipse frame is a void formed by the yarn A being tucked in the knitted fabric obtained in the example. Note that the horizontal (lateral) yarn in the dotted ellipse frame is the yarn A that is tucked to the surface S2 side, and is only visible in the depth direction of the paper surface through the gap on the surface S1, and the surface S1. Does not appear on the side of The tack position in the course including the part enclosed by the dotted square frame is different from the course under the course, so the surface surrounded by the loop is inclined in the thickness direction in that part, and the thickness of the knitted fabric Is getting bigger.

  In the knitted fabric of the present embodiment, two or more pairs of knitted loops composed of the yarn A gathered together in a state where the knit loop is inclined in the thickness direction are connected in the course direction to form a convex portion. The knitting structure of the present embodiment provides unevenness in which the yarn is closer to the convex portion and the density is higher, and in the concave portion that is the void portion, the yarn density is small and the void ratio is large. When the surface S1 having such a concavo-convex structure is brought into contact with the foot of a user who is perspiring, the concave portion serves as an entrance for sweat (steam) and quickly receives the sweat, and the contact between the convex portion and the sweat. It plays a role in increasing the area. Thereafter, the sweat moves from the concave portion to the yarn A located on the peripheral convex portion (the portion having a high yarn density), and is absorbed by the yarn A of the convex portion.

The yarn A that has absorbed the sweat retains the sweat in the void formed inside the yarn A (particularly, the inside of the paper yarn). Alternatively, the sweat is held in the space between the threads A. Sweat is first absorbed and retained in the form of vapor, but is retained in liquid form when cooled. The knitted fabric of the present embodiment has a two-layer structure, and the gap is large and bulky in the thickness direction, and the periphery of the convex portion is a portion having a relatively large gap, so that it is easy to absorb sweat. Further, since the yarns A are in contact with each other at the convex portion or are present in the vicinity of each other, sweat can be held between the yarns A. Therefore, according to this embodiment, more sweat (steam) can be absorbed.
In addition, when the surface S1 of the knitted fabric of the present embodiment is brought into contact with the user's foot, the convex portion exclusively comes into contact with the foot, and the contact area between the knitted fabric and the foot is reduced. As a result, a smooth feel can be given to the user.

  In this embodiment, since the convex part in the surface S1 is a part where the density of the yarn A is high, it is not easily crushed even if pressure is applied. Therefore, even when the knitted fabric for footwear of this embodiment is used as a member to which pressure is applied during use, such as an insole, unevenness on the surface S1 is easily maintained, and sweat is quickly absorbed by the yarn A by the above mechanism. Makes it possible to In addition, when the knitted fabric of this embodiment is used, the contact area with the user's foot can be kept small even in a state where pressure is applied, so even under conditions where pressure is applied during standing or during walking / exercising. It is possible to give the user a light feeling.

  In the knitted fabric of the present embodiment, for example, a loop composed of the yarn A has a yarn length (Yarn Length) of 20 cm / 100w to 40 cm / 100w, and a loop composed of the yarn B has a yarn length of 10 cm / 100w to You may knit so that it may become 25cm / 100w. The yarn length is the length of a yarn constituting 100 wales (100 loops). The knitted product is cut into a width of 100 wales, the yarn is unwound, and the length is measured and obtained.

  The knitted fabric of this embodiment may have a density of, for example, 15 courses / inch to 50 courses / inch, and 10 wales / inch to 40 wales / inch, in particular 25 courses / inch to 40 courses / inch, and It may have a density of 20 wal / inch to 30 wal / inch.

  The surface S2 of the knitted fabric of this embodiment is relatively flat because the yarn B constitutes a knit loop and the yarn B is not tacked. Therefore, for example, when the knitted fabric for footwear of the present embodiment is used as a surface material of an insole (a member that forms a surface in contact with a foot), and this is integrated with, for example, an elastic sheet having good cushioning properties (for example, a polyurethane sheet) or the like. The surface S2 can be easily applied with an adhesive or the like and can be satisfactorily bonded to the elastic sheet. Similarly, when the knitted fabric of the present embodiment is joined to other members in the footwear, the surface S2 functions as a joining surface.

  Further, when the yarn A includes an adhesive synthetic fiber yarn and / or the yarn B is an adhesive synthetic fiber yarn, after the knitted fabric is manufactured, the adhesive synthetic fiber yarn is heated, for example, by an electron beam It may be melted or softened by irradiation or the like, and the knitting intersection point may be bonded with an adhesive synthetic fiber yarn. By adhering the knitting intersections, the strength and form retention of the knitted fabric can be increased, and fuzzing (fraying of yarn) can be suppressed.

  In the above description, the mode in which only the yarn A is tacked and the yarn B is not tackled has been described. In another embodiment, thread B may also be tacked to surface S2. In that case, the surface S2 also has a portion where two or more gathered together with the knit loop formed of the yarn B inclined in the thickness direction. In such a form, if the yarn B is also a paper yarn or a paper yarn twisted yarn, the surface S2 is also highly hygroscopic and both surfaces can be used as surfaces that contribute to moisture absorption.

[Application to footwear]
The knitted fabric of the present embodiment may be used as a member constituting the footwear, an article independent of the footwear, and an article placed between the footwear and the foot when used, or a member constituting the article. Specifically, the members constituting the footwear are, for example, an upper, an upper lining material, an insole and a slip fixed to the footwear, and a tongue. Articles independent of footwear include insole and slip sold separately from footwear. The knitted fabric of the present embodiment is preferably used as a member or article in contact with the foot. If the knitted fabric of the present embodiment is used in such an application, sweat from the foot is absorbed well by the knitted fabric and foot stuffiness is prevented. Can be suppressed. When foot stuffiness is suppressed, the odor of various bacteria adhering to the feet together with the sweat vapor from the feet is also suppressed, and it becomes difficult to feel bad odors. Therefore, when the knitted fabric of this embodiment is used as a member or article for footwear, various discomfort caused by foot stuffiness can be reduced.

  The type of footwear to which the knitted fabric of this embodiment is applied is not particularly limited, and any of athletic shoes, sneakers, business shoes, pumps, boots, rain shoes, safety shoes, walking shoes, sandals, slippers, sandals, etc. Good. The knitted fabric of the present embodiment is appropriately cut according to the type of footwear and the member used. If necessary, apply adhesive to the cut surface, or if the yarn B is a synthetic fiber yarn, melt or soften it on the cut surface to prevent the yarn from fraying from the cut surface. You may do it. Alternatively, fraying may be stopped by sewing or gluing a narrow tape.

  The knitted fabric of this embodiment is preferably used as an insole (including one fixed to footwear and one sold separately from footwear) or as a member constituting the insole. Since the sole of the foot is a site with a large amount of sweating, foot stuffiness can be effectively suppressed by arranging the knitted fabric of the present embodiment on the part in contact with the foot. When the insole is configured with the knitted fabric of the present embodiment, the knitted fabric may be cut according to the type of footwear and used as it is as an insole, or may be used by being joined to another member constituting the insole, for example, a cushioning material. When the knitted fabric is joined to another member, the surface S2 is used as a bonding surface, and an adhesive is applied to the surface S2 and / or the other member to integrate them.

  The knitted fabric of this embodiment may be used as the upper itself or as an upper lining material. Since the upper and the lining material thereof are also members in contact with the foot, it is possible to suppress foot stuffiness by configuring them with the knitted fabric of this embodiment. Further, when the upper itself is the knitted fabric of the present embodiment, the knitted fabric has a relatively high air permeability, so that the air permeability of the footwear can be enhanced. When the knitted fabric of the present embodiment is used as an upper, the yarn A includes an adhesive synthetic fiber yarn, and / or the yarn B is an adhesive synthetic fiber yarn, thereby bonding the knitting intersections, thereby providing strength and form. It is preferable to improve retention and durability (fluff suppression). When the knitted fabric of the present embodiment is exposed as the outer side surface of the footwear, the knitted fabric may be subjected to water repellency or waterproofing as necessary. In particular, when two knitted fabrics of the present embodiment are stacked to form an upper of a shoe, such as footwear produced in the examples described later, only the knitted fabric located on the outer side may be subjected to water repellency or waterproofing.

  When the knitted fabric of the present embodiment is used as an upper, two knitted fabrics of the present embodiment may be prepared and stacked so that the surfaces S2 face each other. When such an upper is used, the uneven surface S1 is exposed as an outer surface of the footwear, and the design effect due to the unevenness is exhibited.

  Footwear to which the knitted fabric of the present embodiment is applied is also included in the present disclosure. Specifically, for example, an insole is manufactured by joining the knitted fabric of the present embodiment to a cushioning material, and this is attached to the footwear body, and the footwear formed by sewing the knitted fabric of the present embodiment as an upper, this implementation Footwear formed by attaching the knitted fabric of the form to the upper as a lining material, and footwear formed by attaching the knitted fabric of the present embodiment as a slip are included in the present disclosure. The knitted fabric of the present embodiment may constitute two or more members in the footwear, for example, the footwear in which the upper and the insole are both composed of the knitted fabric of the present embodiment or include the knitted fabric of the present embodiment as a constituent member. Included in the disclosure.

Example 1
Paper yarn (manufactured by Oji Fiber Co., Ltd., trade name OJO +, 1/51 Nm, Z twist 620 T / m, diameter 224 μm, apparent specific gravity 0.5 g / cm ³ ) made from Manila hemp is prepared and 75 denier (diameter 88 μm) ) Polyethylene terephthalate monofilament yarn (hereinafter abbreviated as “PET yarn”).
Paper yarn and PET yarn are twisted to obtain a twisted yarn, which is used as yarn A, PET yarn is used as yarn B, and is knitted using the circular knitting machine so as to have the knitting structure of FIG. Got. Yarn density of the two-layer knitted fabric 2 4 courses / inch, was 32 wales / inch. The yarn A had a diameter of 240 μm and a yarn length of 27.5 cm / 100 w, and the yarn B had a diameter of 88 μm and a yarn length of 18.5 cm / 100 w.
A flatter surface (surface S2) in which the knitted yarn B constitutes a knit loop was bonded to polyurethane foam as a cushioning material and cut into the size of the foot to obtain an insole.

(Comparative Example 1)
Insole of Comparative Example 1 according to the procedure for producing the insole of Example 1 except that PET yarn was used in place of the yarn A (that is, the yarn constituting the knitted fabric was only the PET yarn (yarn B)). Got.

Ten panelists, both men and women, put the insoles of Example 1 and Comparative Example 1 into their shoes and each worn them for 4 to 25 days, and evaluated the following criteria for stuffiness and odor. Table 1 shows the results of evaluating the stuffiness and odor of Example 1 and Comparative Example 1.
(Steam evaluation)
A: There is little stuffiness when wearing the insole. B: There is no difference between when wearing the insole and when not wearing it.
C: Easily stuffy when wearing insole (odor evaluation)
A: The foot odor was reduced when the insole was worn.
B: There is no difference between when the insole is worn and when it is not worn.
C: The smell of the foot is tight when wearing the insole.

  Compared with the insole of Comparative Example 1, the insole of Example 1 was less likely to feel stuffiness. This is presumed to be due to the fact that in Example 1, the knit loop constituting the surface (surface S1) on the side in contact with the foot of the insole is composed of a yarn containing paper yarn having high hygroscopicity. Also, regarding the evaluation of odor, the number of panelists evaluated as “A” was larger in Example 1, and the number of panelists evaluated as “C” was zero for Example 1. 1 indicates that the insole effectively suppresses the stuffiness. The reason why the odor of the foot is felt is that the steam rises due to the stuffiness in the shoe and the odor diffuses accordingly.

(Comparative Example 2)
The insole of Example 1 was produced except that the knitted fabric obtained in Example 1 was bonded so that the surface (uneven surface) (surface S1) in which the yarn A constitutes the knit loop was in contact with the urethane foam. The insole of Comparative Example 2 was obtained according to the procedure. The insole of Comparative Example 2 was relatively flat because the surface on the side in contact with the foot had a knitted structure close to the top where the PET yarn formed a knit loop. In FIG. 4, the enlarged photograph which image | photographed the surface (surface bonded with a urethane foam in Example 1) of the side which contact | connects the leg | foot of the insole of the comparative example 2 is shown.

(Comparative Example 3)
The knitting structure was changed so that the knitting structure (single layer knitted fabric) in which the yarn A and the yarn B were alternately knitted in a tengu (32 course / inch, 24 wal / inch, yarn length 18.5cm / 100w) Except that, the insole of Comparative Example 3 was obtained according to the procedure for producing the insole of Example 1.

  As a result of putting the insoles of Example 1, Comparative Example 2 and Comparative Example 3 into shoes and wearing one panelist for 14 days, the insole of Example 1 was compared with the insoles of Comparative Example 2 and Comparative Example 3. It was evaluated that there was little feeling of stuffiness. This is because the insole of Example 1 has a part (convex part) where the hygroscopic yarn A is three-dimensionally overlapped and bulky, and a part having a relatively large gap (concave part), It was inferred that the exposed area of the yarn A was larger and it was easier to absorb the steam that caused the stuffiness.

(Example 2)
A core-sheath type polyethylene terephthalate monofilament yarn (hereinafter also referred to as “core-sheath PET yarn”) having a 75 denier core component of polyethylene terephthalate and a sheath component of copolymerized polyester is prepared, and this is twisted with paper yarn. A two-layer knitted fabric was obtained in accordance with the procedure for producing a knitted fabric in Example 1, except that the twisted yarn was changed to yarn A and the core-sheath PET yarn was changed to yarn B. By spraying hot air of 190 ° C. on the obtained knitted fabric for 8 minutes, the sheath component of the core sheath PET yarn constituting the yarn A and the yarn B was melted to bond the knitting intersections. FIG. 3 shows an enlarged photograph of a surface in which the yarn A of the knitted fabric forms a knit loop.

  Prepare two sheets of knitted fabric with knitting points bonded together, stack the knitted fabrics so that the flatter surfaces (surface S2) of the knitted fabrics touch each other, cut this into the upper shape, and then sew to obtain sneakers It was. In this sneaker, the insole portion was also made of the same knitted fabric.

(Comparative Example 4)
Commercially available sneakers (Converse Japan, Canvas All Star Low Cut) were prepared.

  When one panelist wore the sneakers of Example 2 and Comparative Example 4 for 6 hours, it was evaluated that the stuffiness that occurred during wearing was less when the sneakers of Example 2 were worn. Also, the foot odor felt when the sneakers were taken off after wearing was evaluated to be less in the sneakers of Example 2.

The present disclosure includes the following aspects.
(Aspect 1)
A two-layer knitted fabric composed of yarn A and yarn B,
Yarn A is a paper yarn or an intertwisted yarn of a paper yarn and a synthetic fiber yarn,
Of the two surfaces S1 and S2, on the surface S1, the knit loop is composed of the yarn A, and on the surface S2, the knit loop is composed of the yarn B,
The surface S1 has a portion in which two or more knit loops composed of the yarn A are gathered in a state inclined in the thickness direction.
Knitting for footwear.
(Aspect 2)
The surface when the point where the knit loop and the previous loop overlap is the intersection, and the shortest line segment connecting the intersections between the two adjacent knit loops in one course is the distance between the intersections. The knitted article for footwear according to aspect 1, wherein the distance between one or more intersections is larger than the knit loop width of the surface S2 in S1.
(Aspect 3)
The knitted layer including the surface S1
In one course, the yarn A is tacked to a knitted layer composed of yarn B every two loops,
The tucked position is shifted by one loop for each of a plurality of courses.
The knitted fabric for footwear of the aspect 1 or 2 which is a knitted layer.
(Aspect 4)
The knitted fabric for footwear according to any one of aspects 1 to 3, wherein the knitted fabric is the knitted fabric shown in FIG.
(Aspect 5)
The knitted fabric for footwear according to any one of aspects 1 to 4, wherein the yarns are bonded together by a synthetic fiber yarn contained in the yarn A.
(Aspect 6)
The knitted fabric for footwear according to any one of aspects 1 to 5, wherein the yarn B is a synthetic fiber yarn, and the yarns are bonded together by the yarn B.
(Aspect 7)
An insole for footwear comprising the knitted footwear of any one of aspects 1 to 6 and a cushioning material.
(Aspect 8)
The footwear knitted fabric according to any one of aspects 1 to 6, wherein the footwear knitted fabric is an upper, and the surface S1 of the footwear knitted fabric is disposed inside the footwear.

  In the knitted fabric for footwear of the present embodiment, the paper yarn having high hygroscopicity or the paper yarn twisted yarn is exclusively exposed on one surface to form an uneven surface, so that it is easier to absorb sweat, and Since it gives a light touch, it can be used for footwear insoles, uppers, upper linings, and the like.

Claims (8)

A two-layer knitted fabric composed of yarn A and yarn B,
Yarn A is a paper yarn or an intertwisted yarn of a paper yarn and a synthetic fiber yarn,
Of the two surfaces S1 and S2, on the surface S1, the knit loop is composed of the yarn A, and on the surface S2, the knit loop is composed of the yarn B,
The surface S1 has a portion in which two or more knit loops composed of the yarn A are gathered in a state inclined in the thickness direction.
Knitting for footwear.   The surface when the point where the knit loop and the previous loop overlap is the intersection, and the shortest line segment connecting the intersections between the two adjacent knit loops in one course is the distance between the intersections. The knitted article for footwear according to claim 1, wherein the distance between one or more intersections is larger than the knit loop width of the surface S2 in S1. The knitted layer including the surface S1
In one course, the yarn A is tacked to a knitted layer composed of yarn B every two loops,
The tucked position is shifted by one loop for each of a plurality of courses.
The knitted fabric for footwear according to claim 1 or 2, which is a knitted layer.   The knitted fabric for footwear according to any one of claims 1 to 3, wherein the knitted fabric is the knitted fabric shown in Fig. 1.   The knitted fabric for footwear according to any one of claims 1 to 4, wherein the yarns are bonded together by a synthetic fiber yarn included in the yarn A.   The knitted fabric for footwear according to any one of claims 1 to 5, wherein the yarn B is a synthetic fiber yarn, and the yarns are bonded to each other by the yarn B.   The insole for footwear containing the knitted fabric for footwear of any one of Claims 1-6, and a shock absorbing material.   The footwear knitted fabric according to any one of claims 1 to 6, wherein the footwear knitted fabric is an upper, and a surface S1 of the footwear knitted fabric is disposed inside the footwear.