JP3178607U - gloves - Google Patents

Abstract

To provide a glove capable of easily operating a multi-touch panel without deteriorating wearing feeling.
In a glove 10A, a thread that forms a finger portion 15 covering the distal phalanx of a wearer's thumb 12, index finger 13, and middle finger 14 multiplies the current flowing by the synthetic resin fiber and the capacitance of the fingers 12-14. It is a twisted yarn twisted with conductive fibers transmitted to the touch panel, the yarn that forms the remaining portion 16 excluding the finger portion 15 is a twisted yarn twisted with a synthetic resin fiber, and the synthetic resin fiber is acrylic, polyester, polyurethane, polyethylene, The conductive fibers are made of any one of polyvinyl chloride, nylon, polypropylene, acetate, vinylon, vinylden, and rayon, and the conductive fibers are made of copper, silver, or iron.
[Selection] Figure 1

Description

  The present invention relates to a glove covering at least the back of the hand, the palm, and the five fingers of the part from the wearer's forearm to the five fingers, and more specifically, operating the capacitive multi-touch panel of the high-performance portable terminal. This is related to gloves that can be used.

  There is disclosed a capacitive touch panel operating glove that has a conductor of a predetermined area sewn on a touch panel operating surface of a fingertip and that allows easy operation of a display using a capacitive touch panel.

JP 2008-81896 A

  Since the glove disclosed in Patent Document 1 sews a conductor onto the touch panel operation surface of the fingertip of the glove, the fingertip in the glove increases in volume and not only decreases the feeling of wearing the glove, but also in a state where the glove is worn. When a finger is touched on the touch panel, the touch to the touch panel is hardly transmitted to each finger, and the touch panel operation may not be performed smoothly. In addition, since this glove has a cloth for making the gloves between the wearer's finger and the conductor, the glove becomes an insulator and transmits the current flowing by the capacitance of the wearer's finger to the multi-touch panel. In some cases, the panel cannot detect a change in capacitance due to the current.

  An object of the present invention is to provide a glove that can reliably transmit a current that flows due to the capacitance of a wearer's finger to a multi-touch panel without deteriorating a feeling of wear, and can easily operate the multi-touch panel. There is.

  The premise of the present invention for solving the above-mentioned problem is a glove that is made by weaving yarn and covers at least the back of the hand, the palm, and the five fingers of the part from the wearer's forearm to the five fingers.

  As a feature of the above-mentioned premise, the thread that forms the finger part of the glove that covers at least the distal phalanx of the wearer's thumb, forefinger, and middle phalanx of the middle finger is composed of synthetic resin fibers and electrostatic charges of the fingers. It is a twisted yarn twisted with conductive fibers that convey the current flowing through the capacity to the multi-touch panel, and the yarn that makes up the remaining part of the glove except the finger portion is the twisted yarn twisted with the synthetic resin fiber, the synthetic resin fiber is acrylic, Made of polyester, polyurethane, polyethylene, polyvinyl chloride, nylon, polypropylene, acetate, vinylon, vinylden, rayon, and conductive fibers made of copper, silver, or iron It is in.

  As an example of the present invention, the finger part of the glove includes a thumb covering part that covers the back and back of the thumb, an index finger covering part that covers the back and back of the index finger, and a middle finger covering part that covers the back and back of the middle finger.

  As another example of the present invention, the finger part of the glove covers only the thumb part of the thumb, the index cover part of the index finger covering only the index finger part, and the middle finger part covering the middle finger part. It is.

  As another example of the present invention, the ratio of the synthetic resin fiber to 100% by weight of the twisted yarn forming the finger part of the glove is in the range of 70 to 80% by weight, and the ratio of the conductive fiber to 100% by weight of the twisted yarn forming the finger part of the glove. Is in the range of 20-30% by weight.

  As another example of the present invention, the color of the twisted yarn that forms the finger portion of the glove is different from that of the remaining portion.

  According to the glove according to the present invention, the thread that forms the finger portion of the glove that covers at least the distal phalanx of the wearer's thumb, index finger, and middle phalanx of the middle finger includes synthetic resin fibers and conductive fibers. A twisted twisted yarn, the yarn that makes up the remaining part of the glove, excluding the finger part, is a twisted thread twisted with synthetic resin fiber, and the finger part and the remaining part are made integrally by weaving these twisted yarns The fingertip part of the glove does not increase in volume, can prevent the feeling of wear, and because the twisted yarn that makes the finger part contains conductive fibers, touch the finger part to the multi-touch panel. The current flowing by the capacitance of the fingers of the wearer can be transmitted from the glove to the panel, and the change in the capacitance due to the current can be detected by the panel. This glove can easily operate the multi-touch panel while the wearer wears the glove while maintaining its original wearing feeling.

  A glove with a finger part of the glove that covers the thumb and back of the thumb, an index finger covering part of the index finger and the back, and a middle finger covering part of the middle finger and the back of the glove By touching any one of the middle finger covering parts on the multi-touch panel, the current flowing by the electrostatic capacity of the fingers of the wearer can be transmitted from the covering part to the panel, and the capacitance changes due to the current. Can be detected by the panel. This glove can easily operate the multi-touch panel while the wearer wears the glove while maintaining its original wearing feeling.

  The glove with the finger part of the glove that covers only the thumb from the thumb, the index cover that covers only the index finger, and the middle finger that covers the middle finger only. By touching the multi-touch panel with any one of the cover covering part of the finger, the index finger, or the middle finger, the current flowing by the capacitance of the finger of the wearer can be transmitted from the covering part to the panel. The change in capacitance due to the current can be detected by the panel. This glove can easily operate the multi-touch panel while the wearer wears the glove while maintaining its original wearing feeling.

  A glove in which the ratio of the synthetic resin fiber to 100% by weight of the twisted yarn for making the finger part is in the range of 70 to 80% by weight, and the ratio of the conductive fiber to 100% by weight of the twisted yarn for making the finger part is in the range of 20 to 30% by weight. Since conductive fibers are contained in the above-mentioned ratio in the twisted yarn, by touching the finger part to the multi-touch panel, the current flowing by the capacitance of those fingers of the wearer can be reliably transmitted from the glove to the panel, The change in capacitance due to the current can be reliably detected by the panel. This glove can easily operate the multi-touch panel while the wearer wears the glove while maintaining its original wearing feeling.

  A glove that has a different color to the rest of the yarn that makes the finger part of the glove can easily distinguish between the finger part and the remaining part by the difference in color. When touching the multi-touch panel with a finger, it is possible to reliably touch the panel with the finger part that can transmit current to the panel, and the wearer can easily operate the panel while wearing gloves it can.

The perspective view of the glove shown as an example. FIG. 2 is an end view taken along line 2-2 in FIG. 1. The perspective view which shows the operation example of the multi touch panel in a glove. The perspective view of the glove shown as another example. FIG. 5 is an end view taken along line 5-5 of FIG. The perspective view which shows the operation example of the multi touch panel in a glove.

  The details of the glove according to the present invention will be described with reference to the accompanying drawings such as FIG. 1 which is a perspective view of a glove 10A shown as an example. 2 is an end view taken along line 2-2 of FIG. 1, and FIG. 3 is a perspective view illustrating an operation example of the multi-touch panel 23 in the glove 10A. In FIG. 1, only the right hand glove 10 </ b> A is illustrated, and a state in which the wearer 11 wears the glove 10 </ b> A in the right hand is illustrated. In FIG. 2, the index finger 13 wearing the gloves 10A is indicated by a two-dot chain line. In FIG. 3, a wearer 11 wearing a glove 10 </ b> A is operating a multi-touch panel 23 of a smartphone 22 (high function mobile terminal) of a capacitive type (surface type capacitive type or projection type capacitive type). An example is shown. In FIG. 1, the dimension in the length direction is indicated by an arrow A, and the dimension in the width direction is indicated by an arrow B.

  The glove 10A is worn by the wearer 11 in the hand for cold protection against cold or for protection against accidents and injuries. The glove 10A covers the wrist, the back of the hand, the palm, and the five fingers among the parts from the forearm of the wearer 11 toward the five fingers. To wear the gloves 10A, a hand is inserted through the hand insertion port. There are no particular limitations on the length, width and dimensions of glove 10A (including glove 10B described later), and it covers all parts of wearer 11 from the forearm to the five fingers. Alternatively, it may cover the back, palm, and five fingers of the wearer 11.

  In the glove 10A, the yarn that forms the finger portion 15 covering the distal phalanx of the thumb 12, the index finger 13, and the middle finger 14 of the wearer's five fingers is a twisted yarn obtained by twisting a thermoplastic synthetic resin fiber and a conductive fiber, The yarn forming the remaining portion 16 of the glove 10A excluding the finger portion 15 is a twisted yarn obtained by twisting a thermoplastic synthetic resin fiber. Glove 10A is a knitted fabric (flat knitting) made by weaving these twisted yarns. In the glove 10A, the color of the twisted yarn (thermoplastic synthetic resin fiber and conductive fiber) that forms the finger portion 15 is different from that of the remaining portion 16 (thermoplastic synthetic resin fiber).

  As shown in FIGS. 1 and 2, the finger portion 15 covers a thumb covering portion 17 that covers the palm and back of the distal phalanx of the thumb 12 of the wearer 11, and covers the palm and back of the distal phalanx of the index finger 13. An index finger covering portion 18 and a middle finger covering portion 19 covering the palm and back of the distal phalanx of the middle finger 14. In this glove 10A, the thumb covering portion 17 may cover the fingers and the spine of the proximal phalanx and the distal phalanx of the wearer's thumb 12, and the index finger covering portion 18 may cover the middle phalanx and the distal phalanx of the index finger 13. It may cover the bones and back of the bone. Further, the index finger covering portion 18 may cover the fingers and the spine of the index finger 13 from the proximal phalanx to the distal phalanx, and the middle finger covering portion 19 may cover the middle phalange and the distal phalange fingers. The spine may be covered, and the middle finger covering portion 19 may cover the fingers and the spine of the middle finger 14 from the proximal phalanx to the distal phalanx.

  The finger part 15 (thumb covering part 17, index finger covering part 18, middle finger covering part 19) of the right hand glove 10A only is made of twisted yarn obtained by twisting a thermoplastic synthetic resin fiber and a conductive fiber. The gloves 10A are made of a twisted yarn in which the finger portion and the remaining portion are twisted thermoplastic synthetic resin fibers. The remaining portion 16 of the glove 10A covering the wrist of the wearer 11 is mixed with elastic twisted yarn having elasticity (such as polyurethane fiber or polyether ester-based elastic twisted yarn), and the portion 16 wears the glove 10A. By tightening the wrist of the wearer 11, the glove 10 </ b> A is prevented from falling off or slipping during wearing.

  Thermoplastic synthetic resin fiber is made from acrylic, polyester, polyurethane, polyethylene, polyvinyl chloride, nylon, polypropylene, acetate, vinylon, vinylden, rayon (acrylic fiber, polyester fiber, polyurethane fiber, Polyethylene fiber, polyvinyl chloride fiber, nylon fiber, polypropylene fiber, acetate fiber, vinylon fiber, vinylden fiber, rayon fiber). Synthetic resin fibers are produced by extruding a thermoplastic synthetic resin (raw material) from a spinneret (nozzle). Production methods include melt spinning, dry spinning, and wet spinning. As the thermoplastic synthetic resin fiber, a modified cross-section fiber, a hollow fiber, a modified hollow fiber, and a core-sheath fiber can be used. The conductive fiber is made from any one of copper, silver, and iron conductive metals (copper fiber, silver fiber, and iron fiber). The conductive fiber is produced by extruding a conductive metal (raw material) from a spinneret (nozzle).

  Since the finger portion 15 (the thumb covering portion 17, the index finger covering portion 18, the middle finger covering portion 19) of the glove 10A is a knitted fabric containing conductive fibers, the remaining portion 16 made of a twisted yarn of synthetic resin fibers is used. Compared to the above, the electric resistance is small, and the current flowing by the capacitance of the thumb 12, the index finger 13, and the middle finger 14 of the wearer 11 can be easily transmitted from the finger portion 15 to the outside. On the contrary, the remaining portion 16 of the glove 10A is a knitted product made from a twisted yarn obtained by twisting synthetic resin fibers, and therefore compared with a finger portion 15 made from a twisted yarn obtained by twisting synthetic resin fibers and conductive fibers. However, the electric resistance is very large, and for example, the current flowing due to the capacitance of the ring finger 20 and the little finger 21 of the wearer 11 cannot be transmitted from the remaining portion 16 to the outside.

  When the wearer 11 who wears the gloves 10A operates the multi-touch panel 23 of the smartphone 22, as shown in FIG. The touch panel 23 is operated. When the finger part 15 (the thumb covering part 17, the index finger covering part 18, the middle finger covering part 19) of the glove 10A is touched on the multi-touch panel 23, the current flowing by the capacitance of the wearer's thumb 12, index finger 13, and middle finger 14 is applied to the finger. The panel 23 detects the change in capacitance due to the current transmitted from the portion 15 to the panel 23, and the capacitance of the panel 23 changes accordingly, so that the panel 23 can be operated while wearing the gloves 10A. It becomes.

  In the glove 10A, the ratio of the thermoplastic synthetic resin fiber to 100% by weight of the twisted yarn forming the finger part 15 (thumb covering part 17, forefinger covering part 18, middle finger covering part 19) is in the range of 70% by weight to 80% by weight. Preferably, it is in the range of 75% by weight or more and 80% by weight or less, and the ratio of the conductive fiber to 100% by weight of the twisted yarn forming the finger portion 15 is in the range of 20% by weight or more and 30% by weight or less, preferably 20% by weight or more. It is in the range of 25% by weight or less.

  When the proportion of the conductive fiber is less than 20% by weight, the electrical resistance of the finger portion 15 of the glove 10A increases, the conductivity of the finger portion 15 decreases, and the current that flows due to the capacitance of the fingers 12 to 14 of the wearer 11 May not be transmitted from the finger portion 15 to the multi-touch panel 23, and the panel 23 may not be operated with the gloves 10A worn.

  When the proportion of the conductive fiber exceeds 30% by weight, the amount (ratio) of the low-flexibility conductive fiber increases more than necessary, compared with the amount (ratio) of the thermoplastic synthetic resin fiber having high flexibility. The hardness of the portion 15 is increased and the flexibility is lowered, so that not only the thumb 12, the index finger 13 and the middle finger 14 of the wearer 11 wearing the glove 10A are uncomfortable, but also the touch touching the multi-touch panel 23 is felt from the glove 10A. It is difficult to be transmitted to the fingers 12 to 14, the operability with respect to the panel 23 is lowered, and the operation of the panel 23 may be difficult.

  In the glove 10A, the ratio of the synthetic resin fiber to 100% by weight of the twisted yarn forming the finger portion 15 is in the above range, and the ratio of the conductive fiber to the 100% by weight of the twisted yarn forming the finger portion 15 is in the above range. The current flowing due to the capacitance of the thumb 12, the index finger 13, and the middle finger 14 of the wearer 11 can be reliably transmitted from the finger portion 15 to the multi-touch panel 23 in the worn state, and the panel 23 can be easily operated while wearing the gloves 10A. It becomes possible to operate. In the glove 10A, the hardness of the finger portion 15 does not increase more than necessary, the flexibility of the finger portion 15 can be prevented from being lowered, and the operability with respect to the panel 23 is not lowered.

  The glove 10 </ b> A has a finger portion 15 (thumb covering portion 17, forefinger covering portion 18, middle finger covering portion 19) and a remaining portion 16 that are integrally formed by weaving twisted yarn, and the finger portion 15 is compared with the remaining portion 16. The volume of the fabric does not increase, the wearer's fingers 12 to 14 wearing the gloves 10A do not feel uncomfortable, the wear feeling can be prevented from being lowered, and the twisted yarn forming the finger portion 15 is made of conductive fibers. Therefore, the current flowing through the capacitance of the fingers 12 to 14 of the wearer 11 can be reliably transmitted to the multi-touch panel 23, and the glove 10A is worn while maintaining a predetermined wearing feeling. The panel 23 can be easily operated.

  The glove 10A is different from that of the remaining portion 16 in the color of the twisted yarn that forms the finger portion 15 (thumb covering portion 17, index finger covering portion 18, middle finger covering portion 19). Can clearly distinguish between the finger portion 15 and the remaining portion 16, and when the fingers 12 to 14 wearing the gloves 10 </ b> A touch the multi-touch panel 23, the current can be transmitted to the multi-touch panel 23. The part 15 can be reliably touched to the panel 23, and the operation of the panel 23 can be easily performed in a state where the wearer 11 wears the gloves 10A.

  FIG. 4 is a perspective view of a glove 10B shown as another example, and FIG. 5 is an end view taken along line 5-5 of FIG. FIG. 6 is a perspective view showing an operation example of the multi-touch panel 23 in the glove 10B. In FIG. 4, only the right hand glove 10 </ b> B is shown, and the wearer 11 wears the glove 10 </ b> B on the right hand. In FIG. 5, the index finger 13 wearing the gloves 10B is indicated by a two-dot chain line. In FIG. 6, a wearer 11 wearing a glove 10 </ b> B is operating a multi-touch panel 23 of a smartphone 22 (high function mobile terminal) of a capacitance type (surface type capacitance method or projection type capacitance method). An example is shown. In FIG. 4, the dimension in the length direction is indicated by an arrow A, and the dimension in the width direction is indicated by an arrow B.

  Similar to that of FIG. 1, the glove 10 </ b> B is worn by the wearer 11 on the hand for protection against cold or protection against accidents and injuries, and among the parts from the forearm of the wearer 11 toward the five fingers, Cover the back of the hand, palm, and five fingers. To wear the gloves 10B, a hand is inserted through the hand insertion port.

  In the glove 10B, the thread that forms the finger portion 15 covering the proximal phalanx to the distal phalanx of the thumb 12, the index finger 13, and the middle finger 14 of the five fingers of the wearer 11 twists the thermoplastic synthetic resin fiber and the conductive fiber. The yarn that forms the remaining portion 16 of the glove 10A excluding the finger portion 15 is a twisted yarn obtained by twisting a thermoplastic synthetic resin fiber. The glove 10B is a knitted fabric (flat knitting) made by knitting these twisted yarns. In the glove 10B, the color of the twisted yarn (thermoplastic synthetic resin fiber and conductive fiber) that forms the finger portion 15 is different from that of the remaining portion 16 (thermoplastic synthetic resin fiber).

  As shown in FIGS. 4 and 5, the finger portion 15 includes a thumb cover covering portion 24 that covers only the fingers from the proximal phalanx to the distal phalanx of the wearer 11, and the proximal phalanx to the distal phalanx of the index finger 13. An index finger covering portion 25 that covers only the finger collar up to the bone, and a middle finger sheath covering portion 19 covering only the finger collar from the proximal phalanx to the distal phalanx of the middle finger 14. In this glove 10 </ b> A, the thumb cover portion 24 may cover only the finger bone of the distal phalanx of the thumb 12 of the wearer 11, and the index finger cover portion 25 may cover the middle phalanx and the distal phalanx of the index finger 13. You may coat only the fingers. Further, the index finger cover portion 25 may cover only the distal phalange fingers of the index finger 13, and the middle finger cover portion 26 covers only the middle phalanx and the distal phalange fingers of the middle finger 14. The cover part 26 of the middle finger may cover only the finger part of the distal phalanx of the middle finger 14.

  A twisted yarn in which a finger portion 15 (thumb covering portion 24, index finger covering portion 25, middle finger covering portion 26) of only the right hand glove 10B twists a thermoplastic synthetic resin fiber and a conductive fiber. The left hand glove 10B is made of a twisted yarn obtained by twisting a thermoplastic synthetic resin fiber in the finger portion and the remaining portion. The remaining portion 16 of the glove 10B covering the wrist of the wearer 11 is mixed with elastic elastic yarn (polyurethane fiber, polyether ester elastic elastic yarn, etc.) having elasticity, and the portion 16 wears the glove 10B. By tightening the wrist of the wearer 11, the glove 10 </ b> B is prevented from falling off or being displaced during wearing.

  The thermoplastic synthetic resin fiber is made of any one of acrylic, polyester, polyurethane, polyethylene, polyvinyl chloride, nylon, polypropylene, acetate, vinylon, vinylden, and rayon, as in FIG. The conductive fiber is made of any one of copper, silver, and iron conductive metals, similar to that of FIG.

  Since the finger portion 15 (the thumb cover portion 24, the index finger cover portion 25, the middle finger cover portion 26) of the glove 10B is a knitted fabric containing conductive fibers, the glove 10B is made of a twisted yarn in which synthetic resin fibers are twisted. Compared with the remaining portion 16 made, the electric resistance is small, and the current flowing by the capacitance of the thumb 12, the index finger 13, and the middle finger 14 of the wearer 11 can be easily transmitted from the finger portion 15 to the outside. On the contrary, the remaining portion 16 of the glove 10B is a knitted product made from a twisted yarn made by twisting a synthetic resin fiber, and thus compared with a finger portion 15 made from a twisted yarn made by twisting a synthetic resin fiber and a conductive fiber. However, the electric resistance is very large, and for example, the current flowing due to the capacitance of the ring finger 20 and the little finger 21 of the wearer 11 cannot be transmitted from the remaining portion 16 to the outside.

  When the wearer 11 wearing the glove 10B operates the multi-touch panel 23 of the smartphone 22, as shown in FIG. The touch panel 23 is operated. When the finger touch panel 15 of the glove 10B (the thumb cover covering part 24, the index finger cover covering part 25, the middle finger cover covering part 26) is touched on the multi-touch panel 23, the wearer's thumb 12, index finger 13, and middle finger 14 are electrostatically charged. The current flowing due to the capacitance is transmitted from the finger portion 15 to the panel 23, and the change in the capacitance due to the current is detected by the panel 23, thereby changing the capacitance of the panel 23, so that the glove 10 </ b> B is worn. The panel 23 can be operated.

  In the glove 10B, the ratio of the thermoplastic synthetic resin fiber to 100% by weight of the twisted yarn forming the finger part 15 (the thumb cover part 24, the index finger cover part 25, the middle finger cover part 26) is 70% by weight or more 80%. It is in the range of not more than% by weight, preferably in the range of not less than 75% by weight and not more than 80% by weight, and the ratio of the conductive fibers to 100% by weight of the twisted yarn forming the finger portion 15 is preferably in the range of not less than 20% by weight and not more than 30% by weight. Is in the range of 20 wt% to 25 wt%.

  When the proportion of the conductive fiber is less than 20% by weight, the electrical resistance of the finger portion 15 of the glove 10B increases, the conductivity of the finger portion 15 decreases, and the current that flows due to the capacitance of the fingers 12 to 14 of the wearer 11 May not be transmitted from the finger portion 15 to the multi-touch panel 23, and the panel 23 may not be operated with the glove 10B worn.

  When the proportion of the conductive fiber exceeds 30% by weight, the amount (ratio) of the low-flexibility conductive fiber increases more than necessary, compared with the amount (ratio) of the thermoplastic synthetic resin fiber having high flexibility. The hardness of the portion 15 is increased and the flexibility is lowered. Not only does the thumb 11, the index finger 13, and the middle finger 14 of the wearer 11 wearing the glove 10B feel uncomfortable, but the touch touched on the multi-touch panel 23 is caused by the glove 10B. It is difficult to be transmitted to the fingers 12 to 14, the operability with respect to the panel 23 is lowered, and the operation of the panel 23 may be difficult.

  In the glove 10B, the ratio of the synthetic resin fiber to 100% by weight of the twisted yarn forming the finger portion 15 is in the above range, and the ratio of the conductive fiber to 100% by weight of the twisted yarn forming the finger portion 15 is in the above range. The current flowing due to the capacitance of the thumb 12, the index finger 13, and the middle finger 14 of the wearer 11 can be reliably transmitted from the finger portion 15 to the multi-touch panel 23 in a worn state, and the panel 23 can be easily worn while wearing the gloves 10B. It becomes possible to operate. In the glove 10B, the hardness of the finger portion 15 does not increase more than necessary, and the flexibility of the finger portion 15 can be prevented from being lowered, and the operability with respect to the panel 23 is not lowered.

  The glove 10 </ b> B is integrally formed by knitting twisted yarn between the finger part 15 (the thumb cover part 24, the index finger cover part 25, the middle finger cover part 26) and the remaining part 16. In comparison, the volume of the finger portion 15 does not increase, the wearer's fingers 12 to 14 wearing the gloves 10B do not feel uncomfortable, and the wear feeling can be prevented from being lowered. Since the conductive yarn is included in the twisted yarn to be produced, the current flowing due to the capacitance of the fingers 12 to 14 of the wearer 11 can be reliably transmitted to the multi-touch panel 23, and a glove is maintained while maintaining a predetermined wearing feeling. The panel 23 can be easily operated while wearing 10B.

  The glove 10B has a different color because the color of the twisted yarn that forms the finger part 15 (the thumb cover part 24, the index finger cover part 25, the middle finger cover part 26) is different from that of the remaining part 16. The wearer 11 of the glove 10 </ b> B can clearly distinguish the finger portion 15 from the remaining portion 16, and when the fingers 12 to 14 wearing the glove 10 </ b> B touch the multi-touch panel 23, current is applied to the multi-touch panel 23. The finger part 15 which can be transmitted can be reliably touched to the panel 23, and the operation of the panel 23 can be easily performed while the wearer 11 wears the gloves 10B.

10A Gloves 10B Gloves 11 Wearer 12 Thumb 13 Index Finger 14 Middle Finger 15 Finger Part 16 Residual Part 17 Thumb Covered Part 18 Index Finger Covered Part 19 Middle Finger Covered Part 22 Smartphone (High Functional Mobile Terminal)
23 Multi-touch panel 24 Cover part of thumb 25 Cover part of index finger 26 Cover part of middle finger

Claims (5)

In a glove that is made by weaving yarn and covers at least the back of the hand, the palm, and the five fingers of the part from the wearer's forearm to the five fingers,
The thread that forms the finger part of the glove that covers at least the distal phalanx of the wearer's thumb, index finger, and middle phalanx of the middle finger multiplies the current flowing by the synthetic resin fiber and the capacitance of the fingers. It is a twisted yarn twisted with conductive fibers transmitted to the touch panel, the yarn that makes up the remaining part of the glove excluding the finger portion is the twisted yarn twisted with the synthetic resin fiber, and the synthetic resin fiber is acrylic, polyester Made of any of polyurethane, polyethylene, polyvinyl chloride, nylon, polypropylene, acetate, vinylon, vinylden, rayon, and the conductive fiber is made of copper, silver or iron Gloves characterized by that.   The finger part of the glove is a thumb covering part covering the palm and back of the thumb, an index finger covering part covering the index finger and the back, and a middle finger covering part covering the middle finger and the back. Gloves as described in   The finger part of the glove is a thumb covered part that covers only the thumb part of the thumb, an index finger covering part that covers only the index finger part, and a middle finger part covering part of the middle finger part. The glove according to claim 1.   The ratio of the synthetic resin fiber to 100% by weight of the twisted yarn that forms the finger part of the glove is in the range of 70 to 80% by weight, and the ratio of the conductive fiber to 100% by weight of the twisted yarn that forms the finger part of the glove is 20 to 20%. The glove according to any one of claims 1 to 3, which is in the range of 30% by weight.   The glove according to any one of claims 1 to 4, wherein a color of the twisted yarn forming the finger part of the glove is different from that of the remaining part.

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