JP2009102779A - Glove - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a glove for improving gripping force to enable a wearer to surely grip an object when worn. <P>SOLUTION: The hand glove 1 includes at least a finger part 10 covering the most part of fingers 100, and a back part 20 covering the most part of the back of the hand, wherein the back sides of the hand of the finger part 10 and the back part 20 includes longitudinal sewing lines 71 made of electrically-conductive fibers 70 having electrical conductivity, and the side of the finger part 10 includes a sewn line 51 formed of electrically-conductive fibers 70 and continuously formed outward in a width direction, and fray-preventive sewing lines 72 formed of the electrically conductive fibers 70, and the sewing lines 71 intersect the sewn lines 51 or the fray-preventive sewing lines 72 in the vicinity of the finger tip parts 14 of the finger part 10. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a glove that can reliably hold an object by wearing, for example.

  Gloves that can be securely gripped are required in sports and work where gripping clubs and bats is important, such as golf and baseball. For example, when gripping a grab, it is appropriate for the little finger, ring finger, and middle finger. A glove that imparts a strong tightening force has been proposed (see Patent Document 1).

  In this glove, a band extending to the base of the thumb and each finger is sewn on the back side of the hand. When gripping an object, this band gives an appropriate tightening force to the little, ring and middle fingers. can do. However, the tightening force of the little finger, ring finger, and middle finger imparted by this band is merely that the stretchability of the band assists the grip force of the little finger, ring finger, and middle finger, and does not improve the grip force itself.

JP 2002-65928 A

  An object of the present invention is to provide a glove that improves gripping power and can securely grip an object by wearing.

  The present invention is a glove having at least a finger part that covers most of the fingers and a hand back part that covers most of the back of the hand, on the back side of at least one hand of the finger part and the back of the hand. The glove is provided with a restraining means.

With the above configuration, by wearing the glove of the present invention and grasping the object such as a club or a bat by grasping the fist, the restraining means in the length direction restrains the back side of the hand, the interosseous muscle on the back side of the hand, Since the pressure points on the hand are pressed, the interosseous muscle responsible for gripping force and the tendon responsible for finger movement can be loosened, and the gripping force can be improved and the instantaneous force can be improved.
In this way, by wearing this glove, it is possible to improve the exercise function related to gripping including the grip strength.

As an aspect of the present invention, the restraining means can be configured by sewing a conductive thread material having conductivity.
The conductive thread material is made of copper on the surface of a synthetic fiber such as nylon fiber, aramid fiber, polyester fiber, acrylic fiber, vinylon fiber, polyvinyl chloride fiber, vinylidene fiber, polyethylene fiber, polypropylene fiber, or polyurethane fiber. It includes a yarn material formed with a metal film layer such as metal, or a yarn material formed by kneading a metal powder such as copper metal.

As a result, the back side of the hand is restrained with an appropriate restraining force, and since the conductive thread material has flexibility, the restraining means can be prevented from hindering the movement of the hand, and the conductive thread material is corona discharged. Therefore, the far infrared ray and negative ion irradiation effects by the corona discharge can be applied to the back side of the hand. Therefore, the interosseous muscle and the tendon can be activated to further improve the grip strength and the instantaneous power for the grip.
In addition, when the conductive thread material contains copper metal, it is possible to obtain antibacterial and deodorizing effects due to the copper metal, and to keep the worn article clean.

  Further, as an aspect of the present invention, a conductive yarn material is provided on the side of the finger portion, the conductive yarn material being continuous outside in the width direction, and constituting the restraint means near the fingertip of the conductive yarn material. Can be crossed with wood.

  As a result, the restraining means composed of the conductive thread material and the conductive thread material disposed on the lateral width side of the finger part are in contact with each other so that energization is possible. It will be covered with the conductive yarn material, and the far infrared ray and negative ion irradiation effect by the corona discharge from the conductive yarn material can be further improved.

Further, as an aspect of the present invention, a ventilation means for allowing ventilation inside and outside the finger portion can be provided at the tip of the finger portion.
If fingertip air permeability deteriorates, blood flow at the fingertips deteriorates, muscles and tendons become tense and inactive, and grip strength and instantaneous power against the grip decrease, but the above may ensure fingertip breathability. Therefore, the blood flow of the fingertips due to wearing of gloves is deteriorated, and it is possible to prevent a decrease in grip strength due to inactivation of muscles and tendons and instantaneous power for the grip.

As an aspect of the present invention, the ventilation means can be configured by a fingertip opening that penetrates the tip of the finger part.
As a result, the air permeability of the fingertip can be ensured, the conductivity of the conductive yarn material is improved, and the effects of negative ions etc. discharged in the air are received from the fingertip. More irradiation effect can be obtained.

As an aspect of the present invention, the aperture ratio of the fingertip opening can be set in a range of about 70 to 85%.
By setting the aperture ratio of the fingertip opening to a range of about 70 to 85%, sufficient air permeability and the effect of irradiation with far infrared rays and negative ions by the corona discharge can be obtained.

As an aspect of the present invention, the finger portion and the back portion of the hand can be made of a cloth material having at least one of a titanium component, a radium component, and a black silica component.
The titanium, radium, or black silica is formed in the form of powder or particles, respectively, and includes a material that is kneaded into the material itself or a material that is adhered to the surface.

  As a result, far infrared rays and negative ions are emitted by at least one of the titanium component, radium component, or black silica component of the finger portion and the back of the hand, thereby obtaining effects such as blood circulation promotion and body fluid purification of the entire hand. Can do. Therefore, the tension of interosseous muscles and tendons can be released to be flexible and activated, and the muscular strength and its instantaneous power can be further improved.

  Further, as an aspect of the present invention, the cloth material contains an elastic sheet layer having elasticity, a titanium sheet layer containing a titanium component, a radium component and a black silica component, and the elastic sheet layer and the titanium sheet layer. And an adhesive layer that covers the surfaces of the elastic sheet layer and the titanium sheet layer that are bonded with the adhesive.

  The elastic sheet layer may be natural resin such as natural rubber, or polyethylene, acrylic resin, polyamide, polyester, polypropylene, polyvinyl chloride, polystyrene, ABS resin, polycarbonate, nylon, polyacetal, fluororesin, polyvinylidene chloride, polyptadiene, hydrochloric acid. It includes a sheet-like body mainly composed of at least one kind of rubber or the like or a synthetic resin composed of a plurality of them.

  Thereby, the cloth material which has a titanium component, a radium component, and a black silica component can be comprised using the elastic sheet layer generally used. Therefore, it is possible to easily manufacture a glove capable of softening and activating the interosseous muscle and tendon and improving the grip strength and the instantaneous force at low cost.

  In addition, since the titanium sheet layer containing the pre-titanium component is bonded to the elastic sheet layer with the adhesive containing the radium component and the black silica component, the durable cloth material, that is, the above function The wearing thing which has can be obtained.

  According to this invention, it is possible to obtain a glove that improves gripping power and can reliably grip an object by wearing.

An embodiment of the present invention will be described below with reference to the drawings.
FIG. 1 showing a perspective view of a state in which the hand glove 1 is worn, FIG. 2 showing a plan view of the hand glove 1, FIG. 3 showing a developed plan view of the hand glove 1, and FIG. In addition, the hand glove 1 will be described.

The hand glove 1 is a synthetic leather glove that integrally covers from five fingers to the vicinity of the wrist, and integrally includes a finger portion 10, a back portion 20 and a palm portion 30 (FIG. 3).
The finger part 10 includes a thumb part 11 that allows insertion of the thumb 101 and each finger part 12 that permits insertion of the other index finger 102, middle finger 103, ring finger 104, and little finger 105. A fingertip opening 13 is provided at the tip of the thumb portion 11 and each finger portion 12. In FIG. 2, in order to facilitate understanding of the fingertip opening 13, the fingertips of the thumb portion 11 and each finger portion 12 when the fingertip opening 13 is not provided are indicated by dotted lines.
The fingertip opening 13 is opened with an aperture ratio of about 80% with respect to the fingertip portion 14 (FIG. 2) of the finger portion 10.

  The back of the hand 20 includes a slit 21 in the length direction on the wrist side between the ring finger and the little finger, and a belt 22 having a surface fastener on the inner surface side near the finger side end of the slit 21. Further, there are provided throttle portions 23 and 24 which are arranged in the width direction on the finger side and wrist side of the belt 22 and in which rubber is contained.

As shown in FIG. 3, the hand glove 1 configured in this way includes a main sheet 41 in which each finger portion 12, the back of the hand 20, and the palm portion 30 are processed with a single elastic fabric 60 in an appropriate shape, and a thumb portion. 11 is formed of a separate elastic fabric 60 and a thumb portion sheet 42 processed into an appropriate shape.
The main sheet 41 integrally constitutes the developed finger parts 12, the back of the hand 20, and the palm part 30, and includes an attachment opening 43 for attaching the thumb part 11 in the middle of the folding line 50.

  The thumb sheet 42 is formed in a substantially triangular shape, folded at a folding line 50 near the center in the width direction, overlapped with stitching lines 51 at both ends and stitched with conductive fibers 70, and a bottom portion around the mounting opening 43. The main sheet 41 is attached by sewing with a sewing line 51. Alternatively, the stitching lines 51 may be brought together and the stitching lines 51 may be spanned by the conductive fibers 70 and stitched.

Specifically, the main sheet 41 is folded back by the folding line 50, the stitching line 51 is stitched by the conductive fiber 70, the thumb sheet 42 is also folded by the folding line 50, and the stitching line 51 is stitched by the conductive fiber 70, and the thumb portion. The bottom side of the sheet 42 and the peripheral edge of the mounting opening 43 are stitched with conductive fibers 70 to form a glove shape.
At this time, breakage-preventing stitches 72 made of conductive fibers 70 are applied to the bottom portion of the main sheet 41, the slits 21, and the edge of the fingertip opening 13.

  Further, three conductive fibers 70 are sewn in the length direction around the back of the hand of each finger 12, near the attachment opening 43 of the back 20, and near the folding line 50 on the back of the hand of the thumb 11. Each sewing line 71 is configured.

  3, the sewing line 71 of each finger portion 12 extends to the vicinity of the fingertip opening 13 so as to intersect the fraying prevention sewing 72 of the fingertip opening 13.

  In addition, the conductive fiber 70 is sewed along the folding line 50 to form a sewing line 71. The conductive fiber 70 used here is a fiber in which a copper metal film layer is formed on the surface of a nylon fiber.

  Further, the elastic fabric 60 constituting the main sheet 41 and the thumb portion sheet 42 includes a jersey fabric 61 disposed on both surfaces and titanium containing a titanium component, as shown in FIG. 5 for explaining the configuration of the elastic fabric 60. The sheet 62 includes a chloroplane rubber sheet 63 having an appropriate thickness, and an adhesive layer 64 that bonds the titanium sheet 62 and the chloroplane rubber sheet 63.

  The jersey fabric 61 is configured using a thick nylon fiber such as 70 denier, and the titanium sheet 62 is a sheet-like body containing titanium powder. Titanium is a body-friendly metal that does not easily cause allergic reactions.

  The chloroplane rubber sheet 63 is a sheet of chloroplane rubber having countless independent bubbles therein, and the adhesive layer 64 is a layer made of an adhesive containing black silica powder and radium powder.

Black silica powder is a powder obtained by grinding black silica (scientific name: graphite silica), which is a natural ore. It contains plenty of natural minerals and stably absorbs far-infrared rays and weak radiation (α rays, β rays, γ rays). Can radiate. Therefore, the black silica powder has deodorizing, antibacterial, antifungal and moisture proofing effects, and can also provide the body with blood flow promotion, sweating, pain relief, warming and sleep.
The radium powder is a powder body obtained by pulverizing a radium ore, and the radium is disintegrated while emitting α-rays to generate a large amount of radioactive radon having radioactivity.

  The elastic fabric 60 having the above configuration can shut out the outside air without releasing the temperature of the hand wearing the hand glove 1 to the outside. Therefore, it is possible to ensure the heat retaining property of the hand wearing the hand glove 1.

  By inserting the finger 100 (101 to 105) into the thumb part 11 and each finger part 12 of the hand glove 1 having such a configuration, the fingertip of each finger 100 is exposed from the fingertip opening 13 at the tip of the finger part 10. In the aspect, it can mount | wear with the aspect which covers the back part and palm part of a hand to a wrist part.

  At this time, the three sewing lines 71 provided in each finger portion 12 are configured to cover the upper part of the phalanx (not shown) inside the finger on the back side of each finger 102 to 105, and the folding line 50 and the conductive fiber 70 of the sewing line 51 will be located in the both sides of each finger 102-105.

  Further, the three sewing lines 71 provided in the thumb portion 11 are configured to cover the upper part of the phalanx (not shown) inside the finger on the back side of the thumb 101, and the folding line 50 and the stitching line 51. The conductive fibers 70 are located on both sides of the thumb 101.

  In addition, the three sewing lines 71 provided on the back 20 of the hand are configured to cover the upper portion of the interosseous muscle between the metacarpal bones (not shown) in the back of the hand near the index finger 102, The conductive fiber 70 of the stitching line 51 is located on the side between the back of the hand and the palm.

  Thereby, by tightening the fist, the back side of the hand 100 and the back part of the hand 100 are restrained in the length direction by the sewing line 71, and the interosseous muscle and the pot are compressed. The tension of the tendon responsible for the operation of the finger 100 can be released to improve the grip strength and the instantaneous force.

  In addition, since the hand glove 1 is composed of the elastic fabric 60, it is possible to secure the heat retaining property of the hand wearing the hand glove 1, and to obtain effects such as blood circulation promotion and body fluid purification. The muscles and tendons are warmed, the tension is further released, and the muscle strength of the entire hand and its instantaneous power can be improved.

  Therefore, it is possible to relieve unnecessary muscle tension and to precisely control muscle strength and perform high-precision play and work in golf and the like that require accuracy.

  Moreover, by providing the fingertip opening 13 with an opening ratio of about 80% at the tip of each finger part 12, it is possible to prevent the tension of muscles and tendons caused by wearing the hand glove 1. Specifically, when the air permeability of the fingertip of the finger 100 is deteriorated, the flow of a bioelectric current described later is deteriorated, and the blood flow of the fingertip is deteriorated due to the deterioration of the flow of the bioelectric current, and muscles and tendons are strained. Since the fingertip opening 13 is provided at the tip of 12, the air permeability of the finger 100 can be ensured, so that deterioration of the flow of bioelectric current can be prevented. Therefore, it is possible to prevent the grip strength and the instantaneous force due to the tension of the muscles and tendons from decreasing.

  The bioelectric current is a weak current that flows through the body, and is responsible for human life support activities such as transmitting biological information from the cerebrum as electrical signals to the peripheral nerve region via a neural circuit. If the flow of the bioelectric current is disturbed by fatigue or stress, poor physical condition or the like is caused.

  The functions of the elastic fabric 60 such as blood circulation promotion and body fluid purification will be described in detail. As shown in FIG. 6, which is an explanatory diagram for explaining the functions of the elastic fabric 60, the elastic fabric 60 contacts the hand and fingers 100. By doing so, the titanium component, the radium component, and the black silica component of the elastic fabric 60 radiate far infrared rays and negative ions to the hand and the finger 100.

  As a result, the moisture in the body fluid of the hand or finger 100 wearing the hand glove 1 composed of the elastic fabric 60 is negatively ionized, the body fluid itself becomes weak alkali, and the body fluid weakens alkalinity. The flowing bioelectric current is easy to flow.

  However, as described above, the body fluid is weakly alkalized by the elastic fabric 60, whereby the flow of the bioelectric current becomes smooth, and further, the purification of the bodily fluid is promoted by the smooth flow of the bioelectric current. Thereby, transmission of the electrical signal of biological information is also activated, and the movement of the muscle can be made smooth.

  Furthermore, since the water particles in the body fluid can be subdivided by the synergistic effect of the titanium component, the radium component and the black silica component that the elastic fabric 60 has, the effect of weak alkalinization of the body fluid itself due to the negative ionization of the water particles. Can be further improved.

  The confirmation test for subdividing the water particles by the elastic fabric 60 will be described below. Tap water is poured into two cups A and B, and the elastic fabric 60 is immersed in one cup A and stirred for about 10 seconds. , B was applied to the ink (see FIG. 7A), and the spread of the ink was observed.

  As a result, as shown in FIG. 7, which is a test result explanatory diagram showing the test results, in the cup B containing normal tap water, the ink is separated into two places near the surface and the bottom, whereas the ink of the cup A is used. Spread throughout.

  From this result, the normal tap water contained in the cup B has large water particles, so the ink is difficult to mix with the water particles and forms a film of the ink on the surface of the water, and collects and separates near the bottom. From the fact that the ink was mixed with the water particles and spread over the whole, it can be seen that the water particles of the cup A are subdivided by the elastic fabric 60.

  Thus, since the elastic fabric 60 subdivides the water particles constituting 2/3 of the body, the effect of weak alkalinization of the body fluid itself by negative ionization of the water particles can be further improved.

  Negative ions activate the body's natural defense functions and natural healing powers to improve immunity and endocrine hormones, and also activate metabolism by reducing the body oxidized by positive ions. Can do.

  In addition, negative ions bind to abnormal red blood cells that are linked in the form of bumps or dumplings, which occur when positive ions in the body enter the blood, and can improve the red blood cells into normal round shapes. The blood purification effect of being activated can also be obtained.

  Moreover, the far infrared rays irradiated with negative ions are long-wavelength light that cannot be visually observed, and can warm the deep part of the center of the substance. Therefore, by irradiating far infrared rays, the body can be warmed from the core and metabolism can be activated, and toxins in the body can be discharged out of the body.

  Further, as described above, the elastic fabric 60 can shut out the outside air without letting the temperature of the hand or finger 100 wearing the hand glove 1 to the outside, and can keep the hand and finger 100 warm. Since it can be secured, the tension of the interosseous muscle and tendon can be released.

  More specifically, as shown in FIG. 8 for explaining the release of tension of muscles and the like due to warming, the blood vessels 200 become thinner due to muscle tension and increased fat, and movement of red blood cells 201, that is, blood flow worsens. However, by warming the site, the muscle tension is released, the blood vessel 200 spreads, the movement of the red blood cells 201 becomes smooth, and the circulation of energy in the body is activated. Therefore, muscles that have been released from tension are also activated.

  Further, the folding line 50 and the sewing line 71 are sewn with the conductive fiber 70, and the fingertip opening 13 is provided at the tip of the finger portion 10, so that the minus is emitted from the elastic fabric 60 due to the conductive property of the conductive fiber 70. Ions can be applied to the hands and fingers 100 more effectively.

  Furthermore, the corona discharge of the conductive fiber 70 can activate the emission of negative ions from the elastic fabric 60, and can further improve the weak alkalinizing effect of the body fluid itself.

Further, by crossing the conductive line 70 and the sewing line 71 of the folding prevention line 72 of the folding line 50 and the fingertip opening 13 with the sewing line 71, the folding line 50, the sewing line 51, and the folding prevention stitching 72 of the fingertip opening 13 and the sewing are performed. The entire conductive fibers 70 sewn on each of the attachment lines 71 are electrically connected to improve the electrical conductivity. Therefore, it is possible to further improve the effect of activation of negative ion radiation from the elastic fabric 60 and weak alkalinization of the body fluid itself by corona discharge of the conductive fiber 70.
Moreover, by using the conductive fiber 70 provided with the copper metal film layer, it is possible to obtain an antibacterial action and a deodorizing action against Staphylococcus aureus by the same metal.

Next, an effect confirmation test performed to confirm the effect of the hand glove 1 of the present embodiment will be described.
In the effect confirmation test, the grip strength measurement is performed three times at intervals of 1 minute with the left hand when wearing the commonly used golf glove 150 and when wearing the hand glove 1. Confirmed improvement in grip strength. As shown in FIG. 9 (a) of the measurement situation when the golf glove 150 is worn and FIG. 9 (b) of the measurement situation when the hand glove 1 is worn, the measurement is performed in a standing state. The later measurement started 3 minutes after the hand glove 1 was attached.

  In this test, in the case of golf, in general, only the left hand is often worn with gloves (approximately 85%), so the measurement was made only for the left hand. In this confirmation test, the grip strength meter 160 uses “GRIP-D manufactured by TAKEI”. The measurement results of 10 people are shown below.

As shown in the above table, it was confirmed that the grip strength was increased in all 10 measurers. The increase rate was confirmed to be an increase rate of a little less than 15% to a minimum of less than 6%, and the overall average increase rate was 10.7%. From this, it was possible to confirm the effect of increasing grip strength by wearing the wristband 10 regardless of gender and age.

  As the effect has been confirmed in the effect confirmation test, the conductive fiber 70 is sewn and sewn to the desired location on the hand glove 1 composed of the elastic fabric 60 and the sewing line 71 is formed. By disposing it on the back of the hand, the tension of interosseous muscles and tendons is released, and the electrical conductivity of the bioelectric current is improved by weak alkalinization of the body fluid itself by the emission of negative ions from the elastic fabric 60, and the muscles and transmission nerves associated therewith As a result of releasing the tension of interosseous muscles and tendons due to the heat activation of the elastic fabric 60 and the heat retaining property, the instantaneous force related to the grip of the hand or the finger 100 can be improved and the grip strength can be improved.

Furthermore, since the muscle tension of the hand and fingers 100 as a whole is released and the muscles and transmission nerves are activated, it is possible to control the delicate balance of the muscles, and to realize highly accurate play and work.
By wearing the hand glove 1, it is possible to obtain functions such as blood circulation promotion and body fluid purification of the elastic fabric 60, and promote the health of the wearer.

  Further, in the above-described embodiment of the fingertip opening 13, the aperture ratio is set to about 80%, but it may be set in the range of about 70 to 85%. When the aperture ratio is set to 70% or less, the air permeability of the fingertip cannot be sufficiently secured, the flow of bioelectric current is deteriorated, the muscles and tendons are tense, and the gripping force and its instantaneous force are reduced. On the contrary, when the aperture ratio is set to 85% or more, the negative ions emitted from the elastic fabric 60 cannot be more effectively applied to the fingertip portion, and the tension of muscles and tendons cannot be released.

  In this embodiment, the ventilation means at the tip of the finger part 12 is constituted by the fingertip opening 13 penetrating the inside and outside of the finger part 12, but the ventilation means is constituted by a mesh-like mesh having an appropriate opening ratio. It may be configured. Thereby, the same effect as the fingertip opening 13 can be obtained.

  In the above embodiment, the back 20 and the palm 30 are composed of the jersey fabric 61, the titanium sheet 62 containing the titanium component, the chloroprene rubber sheet 63, and the elastic fabric 60 composed of the adhesive layer 94. You may comprise 20 and the palm part 30 with the elastic fabric 90 provided with the some through-hole, and the mesh-shaped elastic fabric 90. FIG.

  Thereby, the breathability of the hand back part 20 and the palm part 30 can be ensured, and it can prevent that the grip strength by the tension | tensile_strength of a muscle and a tendon and its instantaneous power fall. Specifically, by attaching the hand glove 1, as described above, the breathability of the back of the hand 20 and the palm 30 is deteriorated and the flow of the biocurrent is deteriorated. The deterioration of the flow can be prevented. Therefore, it is possible to prevent the grip strength and the instantaneous force due to the tension of the muscles and tendons from decreasing.

In correspondence between the configuration of the present invention and the above-described embodiment,
The fingers of the present invention correspond to the finger 100, the thumb 101, the index finger 102, the middle finger 103, the ring finger 104 and the little finger 105,
Similarly,
The gloves correspond to the hand glove 1,
The restraining means corresponds to the sewing line 71,
The conductive yarn material corresponds to the conductive fiber 70,
The conductive thread material that continues the width direction outside to the side of the finger part corresponds to the conductive fiber 70 sewn by the sewing line 51,
The ventilation means and the fingertip opening correspond to the fingertip opening 13,
The cloth material corresponds to the elastic cloth 60,
The elastic sheet layer corresponds to the jersey fabric 61,
The titanium sheet layer corresponds to the titanium sheet 62,
The adhesive corresponds to the chloroprene rubber sheet 63,
The skin layer corresponds to the adhesive layer 64, but the present invention is not limited to the configuration of the above-described embodiment, and many embodiments can be obtained.

The perspective view of the state which wore the hand glove. Top view of a hand glove. The expansion | deployment top view of a hand glove. AA sectional view of a hand glove. Explanatory drawing explaining the structure of an elastic fabric. Explanatory drawing explaining the function of an elastic fabric. The test-result explanatory drawing which shows the test result of the confirmation test about water particle subdivision. Explanatory drawing explaining the releasing of the tension | tensile_strength of the muscle by the warming of a mounting | wearing site | part. Explanatory drawing explaining the measurement condition of the effect confirmation test of a hand glove.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Hand glove 10 ... Finger part 13 ... Finger tip opening 14 ... Finger tip part 20 ... Hand back part 60 ... Elastic fabric 61 ... Jersey cloth 62 ... Titanium sheet 63 ... Chloro plain rubber sheet 64 ... Adhesive layer 70 ... Conductive fiber 71 ... Sewing Line 100 ... Finger 101 ... Thumb 102 ... Index finger 103 ... Middle finger 104 ... Ring finger 105 ... Little finger

Claims (8)

A glove having at least a finger part covering most of the fingers and a hand back part covering most of the back of the hand,
A glove provided with restraining means in the length direction on the back side of at least one of the finger part and the back part of the hand. The restraining means;
The glove of Claim 1 comprised by sewing the electroconductive thread material which has electroconductivity. To the side of the fingers,
Conductive thread material is arranged on the outside in the width direction,
The glove according to claim 2, wherein the glove is crossed with a conductive yarn material constituting the restraining means in the vicinity of a fingertip of the conductive yarn material. At the tip of the finger part,
The glove according to claim 1, 2, or 3, further comprising a ventilation means that allows ventilation inside and outside the finger part. The ventilation means,
The glove according to claim 1, 2 or 3, comprising a fingertip opening penetrating the tip of the finger part. The aperture ratio of the fingertip opening,
The glove according to claim 5, wherein the glove is set in a range of about 70 to 85%. The finger part and the back part of the hand,
The glove in any one of Claims 1-6 comprised with the cloth material which has at least one among a titanium component, a radium component, or a black silica component. An elastic sheet layer having elasticity of the cloth material;
A titanium sheet layer containing a titanium component;
An adhesive containing a radium component and a black silica component, and bonding the elastic sheet layer and the titanium sheet layer;
The glove of Claim 7 comprised with the skin layer which coat | covers the surface of the said elastic sheet layer bonded by this adhesive agent and the said titanium sheet layer.