JP6611159B2 - Method for measuring skin releasability of water absorbent fabric - Google Patents

Description

  The present invention relates to a measurement method for determining whether or not a fabric has good skin separation when the fabric absorbs a large amount of sweat.

  When a sport accompanied by long-time exercise such as marathon or soccer is performed, the cloth constituting the clothes is wet by a large amount of sweat, and the cloth is in close contact with the skin, resulting in a sticky feeling. This sticky feeling is unpleasant and adversely affects the competition. In order to alleviate such a feeling of stickiness, the athletes and the like unconsciously perform the operation of forcibly sending air between the clothing and the skin by repeatedly holding the clothing and releasing it from the skin. Such an operation is aimed at heat dissipation or sweat transpiration due to the “fluffy action”, and conforms to the laws of nature. Therefore, if the fabric constituting the clothes is easily separated from the skin, it is considered that a “fringing action” is generated during exercise and the sticky feeling is unlikely to occur without grasping the clothes. Therefore, it is self-evident that clothing with less stickiness can be obtained by using a fabric that is easily separated from the skin when a large amount of water is absorbed.

  For this reason, various methods for evaluating the adhesion between the water-absorbed fabric and the skin have been proposed for the purpose of obtaining clothes with little stickiness. Patent Document 1 describes that the adhesion between the water-absorbing fabric and the skin is evaluated by measuring the increase rate of the friction coefficient of the fabric when moisture is applied to the friction coefficient of the fabric when drying. Patent Document 2 relates to a water-repellent fabric that hardly absorbs water, and measures wet friction force by injecting water between a metal roller and the fabric to evaluate the adhesion between the water-repellent fabric and the skin. Is described. Patent document 3 also relates to a fabric partially water-repellent processed, but by measuring the coefficient of friction between a fabric to which a predetermined amount of water is applied and a film to which artificial sebum is applied, the adhesion between the fabric and the skin is improved. It is described to be evaluated

  However, all of the measurement methods described in Patent Documents 1 to 3 measure the friction coefficient when wet or when moisture is applied, and are easy to move when the fabric moves in a horizontal direction with respect to the skin. However, it does not evaluate the ease with which the above-mentioned “fluffing action” that moves in the direction perpendicular to the skin occurs.

JP 2010-236131 A (Claim 3 and paragraph 0028) JP-A-9-195172 (Claim 4 and paragraphs 0046 to 0048) Japanese Patent No. 5371110 (claim 3 and paragraph 0038)

  An object of the present invention is to provide a measurement method capable of determining whether or not a “fringing action” in which the absorbed fabric moves in a direction perpendicular to the skin is likely to occur.

In order for the “fluffy action” to be effectively achieved, it is whether or not the absorbed fabric is easy to move in a direction perpendicular to the skin. The present inventor pays attention to this point and intends to measure skin separation by measuring the load when the water absorbent fabric moves in the vertical direction, not the coefficient of friction when the water absorbent fabric moves in the horizontal direction. . That is, in the present invention, a lifting tool is attached to the center of gravity, and the water absorbing cloth placed on a flat plate in a state where water is applied is pulled up in the vertical direction with the lifting tool to measure the lifting load. A method for measuring the skin-removability of a water-absorbent fabric , wherein the lifting tool has a stretchable member and a non-stretchable member connected in the longitudinal direction. It relates to a measurement method .

  The fabric used in the measurement method according to the present invention is a water absorbent fabric. Examples of the water-absorbing fabric include a knitted fabric that has been subjected to water absorption processing and a knitted fabric composed of hydrophilic fibers such as rayon or cotton fibers. In the measurement method according to the present invention, a knitted fabric that has been subjected to a water repellent treatment on the entire surface is inappropriate. This is because a sufficient amount of water cannot be applied to the fabric. Since the present invention evaluates the separation of the skin when a large amount of sweat is absorbed, the knitted fabric subjected to water-repellent finish that cannot absorb sweat is not intended.

  The shape of the water-absorbent fabric is arbitrary, but is generally preferably a square or a circle. In the measuring method according to the present invention, the lifting load depends on the weight of the water absorbent fabric and the surface tension due to water existing between the water absorbent fabric and the flat plate, so that the center of gravity is easily determined and the length from the center of gravity to the edge. Are preferably the same square or circular.

A lifting tool is attached to the center of gravity of the water absorbent fabric. As the lifting tool , one in which both the stretchable member and the non-stretchable member are connected in the longitudinal direction is used. Here, the elastic member is a member that expands when a lifting load, which is a relatively low load, is applied, and contracts when the lifting load is removed. Generally, rubber such as rubber band is used. The non-stretchable member is a member that does not substantially expand even when a lifting load that is a relatively low load is applied. Generally, spun yarn such as sewing yarn, multifilament yarn or monofilament yarn is used. A sewing needle is generally used to attach the lifting tool to the center of gravity. The lifting tool may be attached by passing it through the surface of the center of gravity using a sewing needle. At this time, it is preferable to attach the lifting tool only to the surface of the center of gravity so that the sewing needle does not reach the back surface. This is because the back surface of the center of gravity of the water-absorbent fabric is a surface that comes into contact with the flat plate, and if the lifting tool is exposed on this back surface, there is a risk of adversely affecting the measurement of the lifting load due to the influence of this exposure. . Both elastic members and non-stretchable member Specific examples of the connecting by lifting element in the longitudinal direction, for example, may connect the rubber band on one end of the thread. Further, a thread ring and a rubber band may be connected. And a thread | yarn is attached to the gravity center of a water absorbing cloth , and is used as a raising tool.

A tag pin may be used as the non-stretchable member . The tag pin is made of a synthetic resin in which a bulging head and an overhanging bar portion are connected by a filament, and is commercially available under the name “Bannock pin” from Japan Bannock. The tag pin is easily attached to the water-absorbing fabric by passing the protruding bar portion through the center of gravity of the water-absorbing fabric. Further, the stretchable member and / or other non-stretchable member may be connected to the bulged head, and the tag pin may be attached to the center of gravity of the water-absorbing fabric.

Water is applied to the water absorbent fabric. The amount of water applied is arbitrary, but generally it is preferably about 300 ml per 1 m ² . Moreover, you may provide water excessively. Here, “excess” means an amount by which the water-absorbing fabric cannot completely retain water and drops wrinkles. The water-absorbing fabric to which excess water has been applied is cut vertically along with the flat plate. In order to cut the cocoon, it is sufficient to keep it vertical for a certain time (for example, 60 to 120 seconds). As a result, the water-absorbing fabric is in a state similar to the state when a large amount of sweat is absorbed (the heel does not fall, but is wet and damp). After cutting the scissors, the absorbent fabric and flat plate are leveled.

  The application of water may be after the water-absorbing fabric is placed on the flat plate or before the water-absorbing fabric is placed on the flat plate. Although any plate can be used, generally, an acrylic plate, metal plate, stone plate or silicone resin plate (simulated skin plate) having a smooth surface can be used. The thickness and weight of the flat plate are such that they cannot be lifted together when the water absorbent fabric is pulled up. Needless to say, when the water-absorbing fabric is placed on the flat plate, the water-absorbing fabric is placed so that the back surface (the surface in contact with the skin) abuts the flat plate.

The other end of the lifting tool attached to the horizontal water-absorbing fabric is gripped by the upper gripping portion of the tensile tester, and the upper gripping portion is pulled up in the vertical direction. Then, the water absorbent fabric is also pulled up in the vertical direction, and finally leaves the flat plate. Since the maximum lifting load is applied when moving away from the flat plate, this load is read. As the lifting tool, a member in which the stretchable member and the non-stretchable member are connected in the longitudinal direction is adopted, but it is preferable that the stretchable member is gripped by the upper gripping portion of the tensile tester. If there is a stretchable member in the lifting tool, the stretchable member stretched when the water absorbent fabric leaves the flat plate shrinks, the water absorbent fabric jumps upward at a stretch, and the pulling load drops all at once. It becomes easy to distinguish the lifting load. The speed at which the lifting tool is pulled up by the tensile tester (pulling speed) is arbitrary, but generally it is preferably 50 to 500 mm / min, more preferably 200 to 500 mm / min. If the pulling speed is outside the range of 50 to 500 mm / min, the maximum pulling load value tends to fluctuate, and the error tends to increase. A conventionally known tensile tester can be arbitrarily used. For example, “TENSILON (product number: UCT-500)” manufactured by TS Engineering Co., Ltd. or “Autograph (model number: AGS-5kNX)” manufactured by Shimadzu Corporation can be used. In addition, you may measure using a spring balance simply, without using a tensile testing machine. That is, a lifting tool may be connected to the hook of the spring balance, the spring balance may be pulled up manually, and the load of the spring balance when the water absorbent fabric is separated from the flat plate may be read to measure the lifting load.

  FIG. 1 shows a schematic diagram when a measuring method according to an example of the present invention is used. 1 is a flat plate, 2 is a water absorbent fabric, 3 is a non-stretchable member, 4 is a stretchable member, and 5 is an upper gripping portion of a tensile tester. Then, the upper gripping portion 5 is pulled up in the vertical direction and the lifting load f is measured. When various water-absorbing fabrics were measured by the measurement method according to the present invention, it was found that the lower the lifting load, the better the skin separation when sweating in large quantities. The specific value of the lifting load varies depending on the amount of water applied to the water absorbent fabric. In the case of an applied amount of water of about 300 ml per 1 m <2> of the water-absorbent fabric, it has been confirmed that those having a lifting load f of 8 cN or less have excellent skin separation. Moreover, when excess water is provided to the water-absorbent fabric, it has been confirmed that those having a lifting load f of 100 cN or less are excellent in skin separation.

  The skin-peeling property measuring method of the water-absorbing fabric according to the present invention does not measure the friction coefficient when the water-absorbing fabric moves in the horizontal direction, but measures the lifting load when the water-absorbing fabric moves in the vertical direction. Therefore, it correlates with the ease with which the “absorbent action” of the water-absorbing fabric moves in the direction perpendicular to the skin, and is suitable for evaluating the separation of the skin and the feeling of stickiness.

[Water Absorbent Fabric 1]
A double circular knitted fabric was knitted based on the organization chart shown in FIG. 2 using a Fukuhara Seiki circular knitting machine (LPJ type, hook diameter 33 inches, needle density 28 G). That is, in FIG. 2, a polyester false twisted yarn (78 dtex48f) is introduced into the yarn feeders F1 and F5 to knit the back of the circular knitted fabric, a polyester false twisted yarn (73 dtex44f) is set as F2, F3, and F6, and a round cross-section polyester multifilament is set as F4. Each yarn (84 dtex 36f) was introduced to knit the surface of the circular knitted fabric. The knitting rate of each yarn was 39.8 mass% for the 78 dtex48f yarn, 45.1 mass% for the 73 dtex44f yarn, and 15.1 mass% for the 84 dtex36f yarn.
After the knitting, the circular knitted fabric was scoured at 80 ° C. for 30 minutes using a bath containing a scouring agent “Sanmor FL (trade name)” manufactured by Nikka Chemical Co., Ltd. using a liquid dyeing machine. Then, after removing the above bath from the dyeing machine, disperse dye “Dianix Blue UN-SE (trade name)” manufactured by Dystar Co., Ltd. was added at 1.0% o. m. f, acetic acid 0.2 cc / L, dispersion leveling agent “Nikkasan Salt SN-130 (trade name)” manufactured by Nikka Chemical Co., Ltd. 0.5 g / L and water-absorbing agent “SR1800 (trade name) manufactured by Takamatsu Oil & Fats ) "2.0% o. m. The bath containing f was poured, and the circular knitted fabric was dyed at 130 ° C. for 30 minutes. After dyeing, a circular knitted fabric was finished and set using a pin tenter to obtain a water absorbent fabric 1.
The density of the water absorbent fabric 1 was 64 courses / inch and 46 wales / inch on the front surface and 42 courses / inch and 24 wales / inch on the back surface. The basis weight was 134 g / m ² .

[Water Absorbing Fabric 2]
Using a Fukuhara Seiki circular knitting machine (LPJ type, hook diameter 33 inches, needle density 28G), a double circular knitted fabric was knitted based on the organization chart shown in FIGS. That is, in FIGS. 3 to 5, polyester false twist yarn (85 dtex 36f) is introduced into the yarn feeders F1, F3, F6, F8, F11, F13, F16, and F18, and the back of the circular knitted fabric is knitted, and F2, F4, F7, and F9 F, F12, F14, F17, F19 were introduced with a polyester false twist yarn (78 dtex48f), and F5, F10, F15, F20 were respectively introduced with a polyester yarn (73 dtex44f) to knit the surface of the circular knitted fabric. The knitting rate of each yarn was 52.6% by mass for 85 dtex36f, 27.7% by mass for 78dtex48f, and 19.7% by mass for 73dtex44f.
This circular knitted fabric was subjected to scouring, dyeing, and finishing set under the same conditions as in the case of the water-absorbent fabric 1 to obtain a water-absorbent fabric 2.
The density of the water-absorbent fabric 2 was 51 course / inch and 42 wal / inch on the front surface and 51 course / inch and 42 wal / inch on the back surface. The basis weight was 146 g / m ² .

[Water Absorbing Fabric 3]
A double circular knitted fabric was knitted based on the organization chart shown in FIG. 6 using a Fukuhara Seiki circular knitting machine (LPJ type, hook diameter 33 inches, needle density 28G). That is, in FIG. 6, the polyester false twist yarn (84 dtex 72f) is introduced into the yarn feeders F1, F3, F5, and F7 to knit the circular knitted surface, and the polyester false twist yarn (84 dtex 36f) is introduced into the F2, F4, F6, and F8. The back of the circular knitted fabric was knitted. The knitting rate of each yarn was 51.5 mass% for the 84 dtex72f yarn and 48.5 mass% for the 84 dtex36f yarn.
This circular knitted fabric was subjected to scouring, dyeing, and finishing set under the same conditions as in the case of the water-absorbent fabric 1 to obtain a water-absorbent fabric 3.
The density of the water-absorbent fabric 3 was 54 course / inch and 42 wal / inch on the front surface, and 54 course / inch and 42 wal / inch on the back surface. The basis weight was 134 g / m ² .

[Measurement example of skin releasability of water absorbent fabrics 1 to 3]
Each of the water absorbent fabrics 1 to 3 is cut into a circle having a diameter of 11 cm, and a thread [polyester sewing machine is used only on the surface of the center of gravity (that is, not to reach the back of the center of gravity of the water absorbent fabric). Thread (Kuraray Co., Ltd., Kuraray ester “Kraftel 20/4000 m (trade name)”)] was passed through. Then, the thread was removed from the sewing needle, and both ends of the thread were tied to make a ring with a total length of about 10 cm. Further, a rubber band (“Oband No. 16 (trade name)” manufactured by Kyowa Co., Ltd.) was connected in series using a zem clip to the yarn ring. Each water-absorbing fabric was placed on the acrylic plate so that the back surface (surface on the skin side) of each water-absorbing fabric was in contact with a 20 mm square acrylic plate having a thickness of 5 mm. And after giving 3 ml of water to the fabric center part to this water-absorbing fabric, it was left as it was for 1 minute. Thereafter, the rubber band is gripped by the upper grip portion of a tensile tester [TENSILON (Part No .: UCT-500) manufactured by TS Engineering Co., Ltd.], and is pulled up at a pulling speed of 500 mm / min in the vertical direction. I read it. This measurement was performed 5 times for each water-absorbing fabric, and the average value of the 5 lifting loads was determined. The results were as follows.
-Water-absorbing fabric 1 ... 3.9cN
・ Water absorbent fabric 2 ... 6.7 cN
-Water-absorbing fabric 3 ... 17.8 cN

  Sportswear was sewn using each of the water-absorbing fabrics 1 to 3, and the panelist performed a wearing test. The order was 3. Therefore, it was found that the measurement method according to the example correlated with the sticky feeling.

It is a schematic diagram at the time of using the measuring method which concerns on an example of this invention. It is a knitting | organization organization chart at the time of knitting the water-absorbent fabric 1 used in the Example. It is a knitting | organization organization chart at the time of knitting the water-absorbent fabric 2 used in the Example. It is a knitting | organization organization chart at the time of knitting the water-absorbent fabric 2 used in the Example. It is a knitting | organization organization chart at the time of knitting the water-absorbent fabric 2 used in the Example. It is a knitting | organization organization chart at the time of knitting the water-absorbent fabric 3 used in the Example.

DESCRIPTION OF SYMBOLS 1 Flat plate 2 Water absorption fabric 3 Non-stretchable member 4 Stretchable member 5 Upper grip part of a tensile tester

Claims (3)

A lifting tool is attached to the center of gravity, and the water absorbent fabric placed on a flat plate in a state where water is applied is pulled up in the vertical direction with the lifting tool to measure the lifting load. A sex measuring method ,
In the lifting tool, the stretchable member and the non-stretchable member are connected in the longitudinal direction.   The method for measuring the skin-peeling property of a water-absorbent fabric according to claim 1, wherein the shape of the water-absorbent fabric is square or circular.   The method for measuring the skin separation property of a water-absorbent fabric according to claim 1, wherein a lifting load when the water-absorbent fabric is completely separated from the flat plate is measured.

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