WO2016060031A1 - Data glove - Google Patents

Abstract

The present invention addresses the problem of providing a data glove which imparts little discomfort when worn, and is capable of comparatively accurately detecting the movement of a hand. This data glove comprises a glove main body, and a plurality of distortion sensors which are disposed in the back side of the glove main body in regions corresponding to at least one finger of a first finger through a fifth finger, and which detect expansion and contraction of the glove main body. Two or more of the distortion sensors are disposed upon each finger of the aforementioned at least one finger. It is preferable for the plurality of distortion sensors to include a first distortion sensor and a second distortion sensor which are respectively disposed in the back side of the glove main body in a region corresponding to a proximal interphalangeal joint and in a region corresponding to a metacarpophalangeal joint of at least one finger of the second finger through the fifth finger, and which detect expansion and contraction of the glove main body in a proximal-distal direction. It is preferable for the data glove to further comprise a plurality of stretch prevention parts which are disposed in the back side of the glove main body in regions corresponding to areas between the metacarpophalangeal joints and extend along the proximal-distal direction, and which limit the elongation of the glove main body.

Description

Data glove

The present invention relates to a data glove.

A data glove in which a plurality of sensors are arranged on a glove in order to detect the movement of a finger of a human hand is commercially available. A commercially available data glove usually has a bending sensor disposed in a region corresponding to each joint of the hand, and detects the angle of the joint in real time.

Such a data glove not only reproduces hand movements in virtual reality technology used in games and the like, but also moves hand movements during sports such as golf swings or playing musical instruments such as pianos. It is also considered to be used for scientific analysis.

Especially, when analyzing the movements of hands of professional athletes and musicians, slight differences in movement may have a significant meaning. However, in the conventional data glove, the normal movement cannot be reproduced due to the uncomfortable feeling caused by wearing the data glove in which a large number of sensors are arranged, and effective data may not be obtained.

In addition, a data glove that detects bending and stretching of a finger by arranging a sensor that detects expansion and contraction of the cloth on the glove has also been proposed (see, for example, Japanese Patent Application Laid-Open No. 2000-329511). However, in the data glove described in this publication, since the movement of one finger is detected by one sensor, the movement of a finger having a plurality of indirects cannot be accurately detected. Moreover, in such a data glove, the position of the sensor is likely to shift, and it is difficult to accurately detect the movement of the hand. In addition, among the indirect fingers, there are joints that can swing in the left-right direction as well as bend and stretch in the dorso-ventral direction, for example, the interphalangeal joints of the second to fourth fingers. Therefore, the data glove described in the above publication cannot accurately detect hand movements.

JP 2000-329511 A

In view of the above inconveniences, an object of the present invention is to provide a data glove that is less discomfort due to wearing and that can detect the movement of the hand relatively accurately.

The invention made in order to solve the above-mentioned problems is arranged in a region corresponding to at least one of the first to fifth fingers on the glove body and the back side of the glove body, and detects expansion and contraction of the glove body. A data glove comprising a plurality of strain sensors, wherein two or more strain sensors are provided for each of the at least one finger. The “dorsal side” of the glove body refers to the side covering the back of the hand, and the palm side opposite to it is referred to as the “abdominal side”.

The data glove includes a plurality of strain sensors that detect expansion and contraction of the glove body in a region corresponding to at least one of the first to fifth fingers on the back side of the glove body, and at least 2 for each finger. By providing the above strain sensors, the same finger movement can be detected by a plurality of strain sensors. For this reason, the data glove can detect the movement of the finger relatively accurately. In addition, the strain sensor for detecting the elongation of the glove body is thin and can be in close contact with the hand and can reduce the reaction force. For this reason, even if the data glove is worn, delicate movements in sports, musical instrument performances, and the like can be performed as usual, so that the natural movement of the hand can be converted into data.

The plurality of strain sensors are disposed in a region corresponding to a joint between proximal phalanges and a region corresponding to a joint between middle finger phalanges of at least one of second to fifth fingers on the back side of the glove body. The first strain sensor and the second strain sensor that detect expansion and contraction in the proximal and distal directions of the glove body may be included. In this way, the proximal interphalangeal joint (PIP joint: second finger joint) and metacarpal joint (MP joint: finger joint) of at least one of the second to fifth fingers on the back side of the glove body. By measuring the elongation of the region corresponding to the third joint (ie, the joint at the base), the movement of the finger can be detected relatively accurately. In particular, since the middle interphalangeal joint is a portion where the second to fifth fingers branch from the palm, the glove is likely to be in close contact with the hand at this portion. As a result, since the strain sensor is difficult to be displaced, the movement of the interphalangeal joint can be detected relatively accurately.

It is preferable to have a plurality of stretch-proofing portions arranged along the proximal distal direction in a region corresponding to the middle interphalangeal joint on the back side of the glove body, and suppressing extension of the glove body. In this way, by arranging the stretch-proof part that suppresses the extension of the glove body between the joints of the metacarpophalangeal joints of the glove body, The stretch-proof portion is positioned at a valley-shaped portion to be formed, that is, a portion where the elongation of the skin is relatively small. Accordingly, since the strain sensor can be more reliably disposed on the joint of the metacarpophalangeal joint, bending and stretching of the joint of the intercarpal joint can be detected more accurately.

It is preferable that the proximal end of the stretch-proof portion is located closer to the strain sensor than the strain sensor, and is arranged so as to be bridged between the plurality of stretch-proof portions, and has a connection portion that suppresses the extension of the glove body. In this way, when the stretch-proof parts are connected to each other by the connection part that suppresses the extension of the glove body on the proximal side of the strain sensor, the bending of the wrist to the strain sensor arranged on the joint between the interphalangeal joints is performed. It is possible to reduce the influence of zero stretching.

The stretch-proof portion may be disposed so as to overlap with the wiring extending from the strain sensor. Thus, by arranging the stretch-proof portion so as to overlap the wiring extending from the strain sensor, the wiring is easy and the disconnection can be prevented, and the wiring hardly inhibits the expansion and contraction of the strain sensor.

As the plurality of strain sensors, a third strain sensor and a fourth strain sensor disposed in each region corresponding to the joint between the metacarpophalangeal joints of at least one of the first to fifth fingers on the back side of the glove body. The third strain sensor may be configured to detect expansion / contraction in the proximal / distal direction of the region, and the fourth strain sensor may detect expansion / contraction in the left-right direction of the region. In this way, by measuring the elongation of the glove body in two directions on the dorsal side of the interphalangeal joint of at least one of the first to fifth fingers, bending and stretching of the finger, Can be detected. Therefore, the data glove can detect the three-dimensional movement of the finger relatively accurately.

The third strain sensor and the fourth strain sensor may be arranged so as to intersect each other. Thus, by arranging the strain sensors so as to cross each other, it is possible to detect expansion and contraction in two different directions in substantially the same region of the glove body, and it is possible to more accurately detect the movement of the finger.

The crossing angle of the third strain sensor and the fourth strain sensor may be substantially vertical. In this way, by arranging the two sensors substantially vertically, it is possible to detect bending and stretching in the dorso-ventral direction and swinging in the left-right direction with relatively high accuracy. Here, “substantially perpendicular” means that the angle between the two is 60 ° or more, preferably 80 ° or more.

The arrangement position of the third strain sensor and the fourth strain sensor may be the first finger (thumb). Thus, the movement of the hand can be grasped more accurately by detecting bending and stretching of the first finger in the dorso-abdominal direction and swinging in the left-right direction, which often swing in the left-right direction.

It is preferable to further include a fifth strain sensor that is disposed in a region along the proximal phalanx of the second finger or the fifth finger on the ventral side of the glove body and detects expansion and contraction in the proximal distal direction of the glove body. Thus, by providing the fifth strain sensor disposed in the region along the ventral proximal phalanx of the second finger or the fifth finger and detecting expansion and contraction in the proximal distal direction of the glove body, It is possible to detect a movement that warps to the back side. Thereby, the movement of the hand can be detected in more detail.

As described above, the data glove of the present invention is less uncomfortable due to wearing and can detect the movement of the hand relatively accurately.

It is a typical top view showing a data glove of one embodiment of the present invention. It is a typical perspective view which shows the wearing condition of the data glove of FIG. It is a typical fragmentary sectional view which shows the wearing condition of the data glove of FIG. It is a typical top view which shows the data glove of embodiment different from FIG. It is a typical back view of the data glove of FIG. It is a typical perspective view which shows the wearing condition of the data glove of FIG. FIG. 5 is a schematic plan view showing a data glove according to an embodiment different from those in FIGS. 1 and 4. FIG. 8 is a schematic plan view illustrating a data glove according to an embodiment different from those of FIGS. 1, 4, and 7.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings as appropriate.

[First embodiment]
1 to 3 includes a glove body 1, four first strain sensors 2 and four second strain sensors 3, a flexible printed circuit board 4, and a strain sensor 2 disposed in the glove body 1. , 3 and a plurality of wirings 5 for connecting the flexible printed circuit board 4.

More specifically, the first strain sensor 2 is provided on the outer surface side of the region corresponding to the proximal interphalangeal joint (PIP joint: second finger joint) of the second to fifth fingers on the back side of the glove body 1. Each is arranged and detects expansion and contraction of the glove body 1 in the proximal and distal directions. The second strain sensor 3 is located on the outer surface side of the region corresponding to the interphalangeal joint (MP joint: third joint of the finger, that is, the joint at the base) of the second finger to the fifth finger on the back side of the glove body 1. Each is arranged and detects expansion and contraction of the glove body 1 in the proximal and distal directions. The flexible printed circuit board 4 is disposed on the outer surface side of the region corresponding to the back of the glove body 1. The wiring 5 is disposed on the outer surface side of the back side of the glove body 1 and connects the strain sensors 2 and 3 and the flexible printed circuit board 4.

Further, the data glove is provided on the inner surface side of the region corresponding to the space between the anti-separation material 6 that strengthens the connection between the strain sensors 2 and 3 and the wiring 5 and the joint between the metacarpal joints on the back side of the glove body 1. A plurality of stretch-proofing portions 7 extending in the proximal-distal direction and the back-side inner surface side of the glove body 1 so as to span between the stretch-proofing portions 7 are connected between the stretch-proofing portions 7. Connecting portion 8 to be provided.

Here, the “inner surface” of the glove body 1 refers to the surface that comes into contact with the wearer's hand when the glove body 1 is worn, and the outer surface that is exposed to the outside when worn is referred to as the “outer surface”.

<Glove body>
The glove body 1 is formed in a bag shape that can be worn on the wearer's hand, and more specifically includes five finger accommodating portions that individually accommodate the wearer's five fingers. The glove body 1 is formed, for example, by stitching together a ventral fabric covering the palm and the ventral portion of five fingers and a dorsal fabric covering the back of the hand and the dorsal portion of the five fingers.

Examples of the material of the glove body 1 include knit, woven fabric, non-woven fabric, rubber, leather, etc., but those having elasticity are preferred, and knit is particularly preferably used.

Each of the five finger receiving portions of the glove body 1 is opened by exposing the wearer's fingertips, specifically the distal portion of the distal interphalangeal joint. The tension of the back fabric prevents the fingers from being bent and stretched, and prevents the wearer from feeling uncomfortable. In addition, by exposing the fingertips, it is easy to work with the fingertips, and musical instrument performances can be performed without a sense of incongruity.

Further, in the glove body 1 of the data glove in FIG. 1, a portion closer to the second strain sensor 3 in the region corresponding to the interphalangeal joint is left and right (near the extension line of the second strain sensor 3). And a slack 1a extending in a direction perpendicular to the distal direction. Specifically, the glove body 1 is sewn and shrunk so as to form a gather or a tuck so that the portion of the back of the hand closer to the wrist is folded when the dorsal fabric is joined to the ventral fabric.

The slack 1a relaxes the proximal and distal tension acting on the cloth on the back side of the glove body 1 by bending and stretching the wrist, and bending and stretching the wrist causes an error in the detection value of the second strain sensor 3. To prevent that.

The lower limit of the 10% elongation load per 1 cm width of the fabric forming the glove body 1 is preferably 0.01 N / cm, more preferably 0.02 N / cm, and even more preferably 0.03 N / cm. On the other hand, the upper limit of the 10% elongation load per 1 cm width of the fabric forming the glove body 1 is preferably 0.5 N / cm, more preferably 0.25 N / cm, and even more preferably 0.1 N / cm. When the 10% elongation load per 1 cm width of the fabric forming the glove body 1 is less than the lower limit, the adhesion of the data glove to the wearer's hand is insufficient, and the positions of the strain sensors 2 and 3 are shifted. The detection accuracy may be insufficient. On the other hand, when the 10% elongation load per 1 cm width of the fabric forming the glove body 1 exceeds the upper limit, the strain sensors 2 and 3 generate resistance to bending and stretching of the fingers, thereby causing the wearer of the data glove to There is a risk of discomfort.

Here, “10% elongation load” means a load (tension) required to stretch the measurement object to 1.1 times the length.

<Strain sensor>
The strain sensors 2 and 3 electrically detect expansion and contraction of the glove body 1. The strain sensors 2 and 3 are preferably laminated on the surface side of the back fabric constituting the glove body 1 so that the wearer does not feel uncomfortable.

The first strain sensor 2 is disposed in a region corresponding to the proximal interphalangeal joint (PIP joint) of the second finger to the fifth finger, that is, the distal end is disposed on the dorsal side of the middle phalanx, The end is affixed to the glove body 1 so as to be disposed on the back side of the proximal phalanx. The first strain sensor 2 expands when the corresponding interproximal joint of the corresponding finger is bent, and contracts when the proximate interphalangeal joint of the corresponding finger is extended.

The second strain sensor 3 is disposed in a region corresponding to the metacarpophalangeal joint (MP joint) of the second finger to the fifth finger, that is, the distal end is disposed on the dorsal side of the proximal phalanx. The distal end is affixed to the glove body 1 so as to be disposed on the dorsal side of the metacarpal bone. The second strain sensor 3 expands when the corresponding intermetacarpal joint of the corresponding finger is bent, and contracts when the corresponding intercarpal joint of the corresponding finger is extended.

As the strain sensors 2 and 3, strain resistance elements whose resistance values change due to expansion and contraction can be used, and in particular, a CNT strain sensor using carbon nanotubes (hereinafter sometimes referred to as CNT) is preferably used.

The CNT strain sensor includes, for example, a stretchable sheet-like base material attached to the glove body 1, a CNT film laminated on the surface side of the base material, and a protective film for protecting the CNT film. It can be configured.

The average thickness of the substrate of the CNT strain sensor can be, for example, 10 μm or more and 5 mm or less.

The material of the base material is not particularly limited as long as it has flexibility, and examples thereof include synthetic resin, rubber, non-woven fabric, deformable shape or material metal or metal compound, and the like.

Examples of the synthetic resin include phenol resin (PF), epoxy resin (EP), melamine resin (MF), urea resin (urea resin, UF), unsaturated polyester (UP), alkyd resin, polyurethane (PUR), heat Curable polyimide (PI), polyethylene (PE), high density polyethylene (HDPE), medium density polyethylene (MDPE), low density polyethylene (LDPE), polypropylene (PP), polyvinyl chloride (PVC), polyvinylidene chloride, polystyrene (PS), polyvinyl acetate (PVAc), acrylonitrile butadiene styrene resin (ABS), acrylonitrile styrene resin (AS), polymethyl methacrylate (PMMA), polyamide (PA), polyacetal (POM), polycarbonate (PC), modified Polif Niren'eteru (m-PPE), polybutylene terephthalate (PBT), polyethylene terephthalate (PET), and cyclic polyolefin (COP) and the like.

Examples of the rubber include natural rubber (NR), butyl rubber (IIR), isoprene rubber (IR), ethylene / propylene rubber (EPDM), butadiene rubber (BR), urethane rubber (U), and styrene / butadiene rubber (SBR). , Silicone rubber (Q), chloroprene rubber (CR), chlorosulfonated polyethylene rubber (CSM), acrylonitrile butadiene rubber (NBR), chlorinated polyethylene (CM), acrylic rubber (ACM), epichlorohydrin rubber (CO, ECO), Fluorine rubber (FKM), polydimethylsiloxane (PDMS), and the like can be given. Among these rubbers, natural rubber is preferable from the viewpoint of strength.

Further, the CNT film of the CNT strain sensor has a rectangular shape in front view. Electrodes are formed at both ends of the CNT film in the longitudinal direction, and the wiring 5 is joined to the electrodes by a conductive adhesive.

This CNT film is formed of a resin composition containing a large number of CNT fibers. Specifically, the CNT film has a plurality of CNT fiber bundles composed of a plurality of CNT fibers oriented in one direction, and a resin layer covering the peripheral surface of the plurality of CNT fiber bundles. When such a strain extending in the proximal-distal direction is applied to the CNT film, a change occurs in the contact state between the CNT fibers, and a resistance change can be obtained as a strain sensor. In order to detect strain more efficiently, it is preferable that the CNT fibers in the CNT film are oriented in the stretching direction.

The lower limit of the average thickness of the CNT film under no load is preferably 1 μm and more preferably 10 μm. On the other hand, the upper limit of the average thickness of the CNT film is preferably 1 mm, and more preferably 0.5 mm. When the average thickness of the CNT film is less than the lower limit, it may be difficult to form such a thin film, or the resistance may increase excessively during elongation. On the contrary, when the average thickness of the CNT film exceeds the upper limit, the stretchability may be insufficient, the resistance change with respect to expansion or contraction, that is, the detection sensitivity may be insufficient, or the wearer may be uncomfortable. is there.

Note that the CNT film may have a single layer structure in which CNT fibers are arranged substantially in parallel in a planar shape, or may have a multilayer structure. However, in order to ensure a certain degree of conductivity, a multilayer structure is preferable.

As the CNT fiber, either single-walled single-wall nanotubes (SWNT) or multi-walled multi-wall nanotubes (MWNT) can be used, but MWNT is preferable from the viewpoint of conductivity and heat capacity, and the diameter is 1.5 nm. More preferably, the MWNT is 100 nm or less.

The resin layer of the CNT strain sensor is a layer mainly composed of resin and covering the peripheral surface of a plurality of CNT fiber bundles. Examples of the main component of the resin layer include the synthetic resins and rubbers exemplified as the material for the base material. Among these, rubber is preferable. By using rubber, a sufficient protection function of the CNT fiber can be exhibited even against a large strain.

The lower limit of the average width in the left-right direction of the strain sensors 2 and 3 formed by such a CNT strain sensor in an unloaded state is preferably 0.5 mm and more preferably 1 mm. On the other hand, the upper limit of the average width of the strain sensors 2 and 3 is preferably 10 mm and more preferably 5 mm. When the average width of the strain sensors 2 and 3 is less than the lower limit, the detection sensitivity may be insufficient, or the strain sensors 2 and 3 may be torn due to bending and stretching of fingers. On the other hand, when the average width of the strain sensors 2 and 3 exceeds the upper limit, the wearer may feel uncomfortable.

Also, the lower limit of the average length in the proximal and distal directions of the strain sensors 2 and 3 under no load is preferably 10 mm, more preferably 15 mm. On the other hand, the upper limit of the average length of the strain sensors 2 and 3 is preferably 30 mm, and more preferably 25 mm. When the average length of the strain sensors 2 and 3 is less than the lower limit, the strain sensors 2 and 3 cannot be accurately placed on the back side of the joint, and the expansion and contraction of the strain sensors 2 and 3 due to bending and stretching of the joint becomes insufficient. There is a possibility that movement cannot be detected accurately. Conversely, when the average length of the strain sensors 2 and 3 exceeds the upper limit, the first strain sensor 2 and the second strain sensor 3 may interfere with each other and cannot be arranged side by side in the proximal distal direction. The average length of the first strain sensor 2 and the average length of the second strain sensor 3 may be different for each finger, and the average length of the first strain sensor 2 and the average of the second strain sensor 3 on the same finger. The length may be different.

The lower limit of the 10% elongation load of the strain sensors 2 and 3 is preferably 0.01N, more preferably 0.03N, and even more preferably 0.05N. On the other hand, the upper limit of the 10% elongation load of the strain sensors 2, 3 is preferably 0.5N, more preferably 0.3N, and even more preferably 0.2N. When the 10% elongation load of the strain sensors 2 and 3 is less than the lower limit, the detection accuracy may be insufficient due to expansion and contraction due to factors other than bending and stretching of the corresponding finger. On the other hand, when the 10% elongation load of the strain sensors 2 and 3 exceeds the upper limit, the reaction force at the time of elongation increases, which may give the wearer a feeling of strangeness.

The lower limit of the resistance value of each strain sensor 2 and 3 under no load is preferably 10Ω, for example, and more preferably 100Ω. On the other hand, the upper limit of the resistance value of the strain sensors 2 and 3 under no load is preferably 100 kΩ, and more preferably 10 kΩ. When the resistance value of the strain sensors 2 and 3 in the no-load state is less than the lower limit, the current for detecting the elongation may increase and the power consumption may increase. On the contrary, when the resistance value of the strain sensors 2 and 3 in the no-load state exceeds the upper limit, the voltage of the detection circuit becomes high, and it may be difficult to reduce the size and power.

The rate of change of the resistance value due to the extension of each of the strain sensors 2 and 3 is appropriately selected so as to obtain sufficient detection accuracy, but 10% of the resistance value of the strain sensors 2 and 3 in the unloaded state. The ratio of the resistance values in the stretched state is, for example, 2 times or more and 20 times or less.

For the attachment of the strain sensors 2 and 3 to the glove body 1, an adhesive that does not inhibit the expansion and contraction of the glove body 1 and the strain sensors 2 and 3 is used. Examples of such an adhesive include a moisture curable polyurethane adhesive.

<Flexible printed circuit board>
The flexible printed circuit board 4 is a printed circuit board having flexibility, and a connector 4a for connecting the wiring 5 to a computer or the like (not shown) is mounted on the proximal end side. Only the distal end of the flexible printed circuit board 4 is fixed to the glove body 1 so that the connector 4a is pressed against the back of the wearer's hand and hardly feels strange.

<Wiring>
The wiring 5 is disposed on the surface of the glove body 1 and electrically connects the strain sensors 2 and 3 and the flexible printed circuit board 4. Specifically, the wiring 5 is connected to the distal end of the first strain sensor 2 and the flexible printed circuit board 4, and the central portion is arranged to overlap the stretch-proof portion 7 described later. Distal connection portion 5a, four proximal connection portions 5b connecting the proximal end of the second strain sensor 3 and the flexible printed circuit board 4, respectively, and the proximal end of the first strain sensor 2 of each finger And four intermediate connection portions 5c connecting the distal ends of the second strain sensor 3 and the four intermediate connection portions 5c extending from the four intermediate connection portions 5c and connected to each other on the ventral side of the glove body 1 5d, and a ground connection portion 5e extending from the vicinity of the fifth finger of the interconnection portion 5d so as to overlap with the extension portion 7 described later and reach the flexible printed circuit board 4.

These wirings 5 can be formed of conductive thread (filamentous body) having conductivity. A conductive thread made of metal such as iron can be used as the conductive thread constituting the wiring 5, and a stainless steel thread is suitably used as the conductive thread made of metal. According to the stainless steel thread, the electric resistance is small, and even when the data glove is washed, there is an advantage that the change in the electric resistance is relatively small. In addition, as a thread | yarn which comprises this wiring 5, it is also possible to use the thread | yarn which apply | coated the electroconductive material to the insulating thread | yarn, and the thread | yarn formed by mixing electroconductive material.

The yarn constituting the wiring 5 preferably has an electric resistance per 10 cm of less than 100Ω, and more preferably less than 50Ω. Thereby, the electrical resistance of the wiring 5 can be reduced, and the detection signals from the strain sensors 2 and 3 can be accurately transmitted to the flexible printed circuit board 4. The “resistance value per 10 cm” is a resistance value between 10 cm of the yarn when a voltage of 5 V is applied, and can be measured using a general-purpose tester.

The wiring 5 has elasticity and is provided to deform following the deformation of the glove body 1. Specifically, the wiring 5 is formed by stretching and sewing a conductive thread. As defined in JIS-B-9003 (1999), “stretchable stretch” means “when a stretchable fabric is sewed, the stitches will not be cut or loosened due to the stretch of the fabric. Means sewing. Specifically, the wiring 5 of this embodiment can be formed by cover stitch (single-sided decorative stitching) or the like.

The upper limit of the 10% elongation load of this wiring 5 is preferably 0.1N, more preferably 0.05N. On the other hand, the lower limit of the 10% elongation load of the wiring 5 is not particularly limited. When the 10% elongation load of the wiring 5 exceeds the upper limit, the strain sensors 2 and 3 may interfere with the expansion and contraction of the glove body 1 and cause the wearer to feel uncomfortable, and the expansion and contraction of the glove body 1 may be uneven. Misalignment may occur and the detection accuracy may be insufficient.

Further, the wiring 5 of the present invention may be formed by sewing the conductive thread directly on the glove body 1, but the glove body can be formed by previously sewing the conductive thread on another stretchable fabric with an adhesive. You may arrange | position by adhere | attaching to 1. FIG. As an adhesive for adhering the fabric on which the wiring 5 is formed, for example, a hot melt adhesive or the like can be used.

<Peeling prevention material>
The anti-peeling material 6 is disposed so as to cover the electrodes formed at the ends of the strain sensors 2 and 3 and the wiring 5 connected to the electrodes, and prevents the wiring 5 from peeling from the electrodes of the strain sensors 2 and 3. To do. As such an anti-peeling material 6, for example, a knit material or a woven fabric is used, and is adhered to the glove body 1 so as to cover the fixed portion of the electrode and the wiring with an adhesive.

<Strengthening part>
The stretch-proof portion 7 is a region corresponding to a portion between the proximal interphalangeal joints of the second finger to the fifth finger on the dorsal side of the glove body 1, and the first finger side of the proximal interphalangeal joint of the second finger. And a region corresponding to the side opposite to the fourth finger of the proximal interphalangeal joint of the fifth finger, respectively, along the proximal distal direction. In other words, the second strain sensors 3 are respectively disposed between the stretch-proof portions 7.

Further, the stretch-proof portion 7 partially suppresses the extension of the glove body 1 by being laminated on the glove body 1. For this reason, as shown in FIG. 3, the stretch-proof portion 7 has a trough between the middle interphalangeal joints that reduces the amount of skin expansion and contraction when the wearer of the data glove bends the intercarpal joint. Each part is positioned at a corresponding part between the fingers in the palm. Thereby, the 2nd distortion sensor 3 arrange | positioned between the stretch prevention parts 7 can be arrange | positioned comparatively correctly on the joint of a metacarpophalangeal joint. The 10% elongation load of the stretch preventing part 7 is preferably larger than that of the strain sensors 2 and 3.

Each of the stretch-proof portions 7 is located closer to the proximal side than the second strain sensor 3 where the proximal end is adjacent, and more distal than the second strain sensor 3 where the distal end is adjacent. Thereby, the force which acts on the cloth of the glove body 1 in the left-right direction can be prevented from acting on the second strain sensor 3 as the tension in the proximal distal direction.

Further, in the data glove, the stretch-proof portion 7 is laminated on the inner surface of the glove body 1. Thereby, the stretch prevention part 7 functions also as a slip stopper which prevents the glove body 1 from being displaced in the proximal distal direction with respect to the back of the wearer's hand.

Furthermore, the stretch-proof portion 7 also has an action of preventing an excessive force from acting on a portion where the wiring 5 is overlapped and being broken.

The material for forming the stretch-proof portion 7 may be the same material as the wiring 5, or may be synthetic rubber, natural rubber, or the like. The stretch-proof part 7 may be formed by applying these materials to the glove body 1, or a band-shaped member may be bonded with an adhesive.

The lower limit of the average width of the stretch-proof portion 7 in the left-right direction is preferably 0.5 mm, and more preferably 1 mm. On the other hand, the upper limit of the average width of the stretch-proof portion 7 is preferably 10 mm, and more preferably 5 mm. When the average width of the stretch-proof portion 7 is less than the lower limit, the strength of the stretch-proof portion 7 becomes insufficient, and there is a possibility that the lateral displacement of the second strain sensor 3 cannot be sufficiently suppressed. On the contrary, when the average width of the stretch-proof portion 7 exceeds the upper limit, the expansion / contraction of the glove body 1 may be excessively disturbed and the wearer may feel uncomfortable, or the expansion / contraction of the second strain sensor 3 may be inhibited. The detection sensitivity may be insufficient.

The lower limit of the average thickness of the stretch-proof portion 7 is preferably 0.05 mm, and more preferably 0.1 mm. On the other hand, the upper limit of the average thickness of the stretch-proof portion 7 is preferably 2 mm, and more preferably 1 mm. When the average thickness of the stretch prevention part 7 is less than the said minimum, there exists a possibility that expansion-contraction of the glove body 1 cannot fully be suppressed. On the contrary, when the average thickness of the stretch prevention part 7 exceeds the said upper limit, there exists a possibility of giving a wearer a discomfort.

The lower limit of the 10% elongation load of the stretch-proof portion 7 is preferably 0.2N, and more preferably 0.5N. On the other hand, the upper limit of the 10% elongation load of the stretch-proof portion 7 is preferably 5N, and more preferably 2N. When the 10% elongation load of the stretch prevention part 7 is less than the said minimum, there exists a possibility that expansion / contraction of the glove body 1 cannot fully be suppressed. On the contrary, when the 10% elongation load of the stretch prevention part 7 exceeds the said upper limit, there exists a possibility of giving a wearer a discomfort.

<Connection part>
The connecting portion 8 is disposed on the inner surface of the glove body 1 so as to be spanned between the stretch-proofing portions 7, and preferably extended in the left-right direction so as to connect between the proximal end portions of the stretch-proofing portion 7. It is installed. This connection part 8 functions as a non-slip | skid with respect to a wearer's back while suppressing the expansion-contraction of the proximal direction of the glove body 1 partially. The 10% elongation load of the connecting portion 8 is preferably larger than that of the strain sensors 2 and 3.

The connection portion 8 can be formed by the same material and the same method as the stretch-proof portion 7.

By disposing this connecting portion 8, when any one finger moves, the first strain sensor 2 or the second strain sensor 3 of the adjacent finger is moved by the movement of the cloth of the glove body 1. It is possible to prevent the position from being shifted and improve the detection accuracy of finger movement. Further, the connecting portion 8 keeps the interval between the stretch-proofing portions 7 constant, and the lateral tension acts on the cloth of the glove body 1 between the stretch-proofing portions 7 to affect the expansion and contraction of the second strain sensor 3. Suppress. That is, the connecting unit 8 connects and bundles the vibration isolating unit 7, thereby generating a positional deviation of the strain sensors 2 and 3 due to the movement of each finger and a detection error due to unintended expansion / contraction of the strain sensors 2 and 3 of the finger. Suppress.

The lower limit of the average width in the left-right direction of the connecting portion 8 is preferably 0.5 mm, and more preferably 1 mm. On the other hand, the upper limit of the average width of the connecting portion 8 is preferably 10 mm, and more preferably 5 mm. When the average width of the connecting portion 8 is less than the lower limit, the strength of the connecting portion 8 becomes insufficient, and the detection accuracy may not be sufficiently improved. On the contrary, when the average width of the connection part 8 exceeds the upper limit, there is a possibility that the expansion and contraction of the glove body 1 is excessively inhibited to give the wearer a feeling of strangeness.

The lower limit of the average thickness of the connecting portion 8 is preferably 0.05 mm, and more preferably 0.1 mm. On the other hand, as an upper limit of the average thickness of the connection part 8, 2 mm is preferable and 1 mm is more preferable. When the average thickness of the connection part 8 is less than the said minimum, there exists a possibility that expansion / contraction of the glove main body 1 cannot fully be suppressed. On the contrary, when the average thickness of the connection part 8 exceeds the said upper limit, there exists a possibility of giving a wearer a discomfort.

The lower limit of the 10% elongation load of the connecting portion 8 is preferably 0.2N, and more preferably 0.5N. On the other hand, the upper limit of the 10% elongation load of the connecting portion 8 is preferably 5N, and more preferably 2N. When the 10% elongation load of the connection part 8 is less than the said minimum, there exists a possibility that expansion / contraction of the glove body 1 cannot fully be suppressed. On the contrary, when the 10% elongation load of the connection part 8 exceeds the said upper limit, there exists a possibility of giving a wearer a discomfort.

<Advantages>
The data glove is connected to each proximal interphalangeal joint and metacarpal phalanx by strain sensors 2 and 3 arranged on the dorsal side of the proximal interphalangeal joint and the metacarpophalangeal joint of the second to fifth fingers. By detecting the expansion and contraction of the fabric of the glove body 1 that expands and contracts with the bending and stretching of the joint between the joints, the movements of the joints between the proximal interphalangeal joints and the joints between the metacarpal joints can be detected relatively accurately.

Also, the strain sensors 2 and 3 for detecting the elongation of the glove body 1 are thin, can be in close contact with the hand, and have a small reaction force, so that it is difficult for the wearer to feel uncomfortable. For this reason, even if the data glove is worn, it is possible to perform delicate operations in sports, musical instrument performances, etc. as usual, and to convert the natural movement of the hand into data.

[Second Embodiment]
4 to 6 includes a glove body 1, four first strain sensors 2, four second strain sensors 3, and one third strain sensor 11 disposed on the back side of the glove body 1. One fourth strain sensor 12 and two fifth strain sensors 13, a flexible printed circuit board 4, and a plurality of wires 5 connecting the first and second strain sensors 2, 3 and the flexible printed circuit board 4; A plurality of second wirings 14 connecting the third and fourth strain sensors 11, 12 and the flexible printed circuit board 4, and a plurality of third wirings 15 connecting the fifth strain sensor 13 and the flexible printed circuit board 4. With.

The data glove includes an anti-peeling material 6 that strengthens the connection between the strain sensors 2, 3, 11, 12, 13 and the wirings 5, 14, 15 extending from the strain sensors 2, and the proximal phalanx on the inner surface of the glove body 1. A plurality of stretch-proof portions 7 respectively extending proximally and distally in a region corresponding to the space between the joints, and arranged on the back side of the glove body 1 so as to be bridged between the stretch-proof portions 7. And a connecting portion 8 that connects between the stretch preventing portions 7.

The configuration of the strain sensors 2 and 3, the wiring 5, the peeling prevention material 6, the stretch prevention portion 7 and the connection portion 8 in the data glove of FIG. 6. Since it is the same as that of the extension part 7 and the connection part 8, the overlapping description is abbreviate | omitted.

<Strain sensor>
The third strain sensor 11 is disposed along the proximal distal direction on the outer surface side of each corresponding region of the joint between the metacarpophalangeal joints of the first finger on the back side of the glove body 1. That is, the third strain sensor 11 is attached to the glove body 1 such that the distal end is disposed on the dorsal side of the proximal phalanx and the proximal end is disposed on the dorsal side of the metacarpal bone. Specifically, the third strain sensor 11 is disposed in the vicinity of the side edge of the ventral fabric of the glove body 1 and substantially parallel to the seam of the back fabric and the ventral fabric. The dorsal side of the first finger means the outer side in the bending and extending direction (extend side) of the interphalangeal joint and interphalangeal joint, and when wearing the data glove, the second finger to the fifth finger dorsal side. The orientation is different. Therefore, the third strain sensor 11 expands when the first intermetacarpal joint is bent, and contracts when the first intercarpal joint is extended. Thereby, the 3rd distortion sensor 11 detects expansion-contraction of the proximal direction of the glove body 1.

The fourth strain sensor 12 is disposed along the left-right direction on the outer surface side of each region corresponding to the joint between the metacarpophalangeal joints of the first finger on the back side of the glove body 1. More specifically, the fourth strain sensor 12 has one end arranged at a position corresponding to the middle finger interphalangeal joint of the first finger and the middle finger bone of the second finger, and the other end of the fourth finger. It is arranged on the opposite side of the internode joint from the second finger. For this reason, the fourth strain sensor 12 mainly extends on the back fabric of the glove body 1, and the other end is on the vent fabric near the joint of the back fabric and the vent fabric of the glove body 1. To be positioned. The fourth strain sensor 12 expands when the metacarpal bone of the first finger swings toward the palm, and contracts when the metacarpal bone of the first finger swings toward the instep side. Thereby, the 4th distortion sensor 12 detects expansion-contraction of the glove body 1 in the left-right direction.

It is preferable that the third strain sensor 11 and the fourth strain sensor 12 are arranged so as to cross each other. Further, the crossing angle between the fifth strain sensor and the fourth strain sensor 12 is preferably substantially vertical. Note that “substantially vertical” means that the angle between the two is 60 ° or more, preferably 80 ° or more.

The fifth strain sensor 13 is disposed on the outer surface side of the portion along the proximal phalanx on the ventral side of the second finger and the fifth finger, and detects expansion and contraction in the proximal distal direction of the glove body 1. Specifically, the fifth strain sensor 13 expands when the corresponding finger is bent back, and contracts when the corresponding finger is returned to the ventral side. In addition, the fifth strain sensor 13 is disposed so as not to overlap the joint between the metacarpophalangeal joint and the proximal interphalangeal joint so as not to hinder the bending operation of the metacarpophalangeal joint and the proximal interphalangeal joint. .

These strain sensors 11, 12, and 13 can be the same as the strain sensors 2 and 3. In addition, similarly to the strain sensors 2 and 3, the separation preventing material 6 is disposed in the strain sensors 11, 12, and 13.

<Wiring>
The second wiring 14 includes two proximal connection portions 14a that connect the proximal ends of the strain sensors 11 and 12 to the flexible printed circuit board 4, respectively, and an intermediate connection that connects the distal ends of the strain sensors 11 and 12 to each other. Part 14b and an interconnecting part 14c for connecting the intermediate connecting part 14b to the interconnecting part 5d of the wiring 5. The material or the like of the second wiring 14 can be the same as that of the wiring 5.

The third wire 15 connects the distal end of the fifth strain sensor 13 to the flexible printed circuit board 4, and connects the proximal end of the fifth strain sensor 13 to the interconnect portion 5 d of the wire 5. Interconnecting portion 15b. The material or the like of the third wiring 15 can be the same as that of the wiring 5.

<Advantages>
Further, since the data glove includes the third strain sensor 11 and the fourth strain sensor 12 disposed on the back side of the joint between the metacarpophalangeal joints of the first finger, By measuring the extension in the two directions of the region corresponding to the dorsal side of the joint, it is possible to detect the bending and stretching of the first finger and the lateral movement of the first finger. Therefore, the data glove can detect the three-dimensional movement of the first finger relatively accurately.

As described above, the third strain sensor 11 and the fourth strain sensor 12 are disposed on the first finger, and in addition to bending and extending the joint in the dorsoventral direction, the joint swings in the left-right direction orthogonal to the dorsoventral direction. In many cases, the movement of the first finger can be detected more accurately, and as a result, the entire movement can be grasped more accurately.

More specifically, when the movement of the hand during the performance of the keyboard instrument is detected using the data glove, it is possible to detect the keystroke by the left / right swing of the first finger detected by the fourth strain sensor 12. The change of the position of the keyboard on which the first finger is arranged, for example, the first finger is changed from the second finger to the fifth finger by bending and stretching of the interphalangeal joint of the first finger detected by the third strain sensor 11 It is possible to grasp the finger-pushing operation passing through the lower side. Since the distal interphalangeal joint operates substantially in conjunction with the proximal interphalangeal joint, the movement of the proximal interphalangeal joint detected by the fourth strain sensor 12 can be performed without providing a separate sensor. Can be analogized.

Further, in the data glove, by arranging the third strain sensor 11 and the fourth strain sensor 12 so as to intersect, it is possible to detect the expansion and contraction in two different directions of the substantially same region of the glove body 1, Finger movements can be detected more accurately. In particular, since the crossing angle of the third strain sensor 11 and the fourth strain sensor 12 is substantially vertical, it is possible to detect bending and stretching in the dorsoventral direction and swinging in the left and right direction with relatively high accuracy.

The data glove is provided with the fifth strain sensor 13 in a region corresponding to the proximal phalanx of the second finger and the fifth finger to move the second finger and the fifth finger outward, that is, the middle finger. It is possible to detect a movement that warps the internode joint outward.

[Third embodiment]
The data glove in FIG. 7 is specialized for detecting the movement of the first finger. The data glove includes a glove body 20 and a third strain sensor 11 and a fourth strain sensor 12 that are disposed in a region corresponding to the vicinity of the joint between the metacarpophalangeal joints of the first finger of the glove body 20. The data glove includes a flexible printed circuit board 4 and wirings 14 connecting the strain sensors 11 and 12 and the flexible printed circuit board 4.

The glove body 20 of the data glove accommodates only the first finger like a known thumb supporter, and includes a finger accommodating portion 21 that accommodates the first finger, and a fixing portion 22 that is mounted around the wrist. Have

For this reason, the third strain sensor 11 and the fourth strain sensor 12 are disposed in the finger accommodating portion 21, and the flexible printed circuit board 4 is disposed on the back side of the fixing portion 22.

The wiring 14 includes two proximal connection portions 14a that connect the proximal ends of the strain sensors 11 and 12 to the flexible printed circuit board 4, respectively, and an intermediate connection portion 14b that connects the distal ends of the strain sensors 11 and 12 to each other. And a distal connection portion 14 d for connecting the intermediate connection portion 14 b to the flexible printed circuit board 4.

Other detailed configurations of the glove body 20 of the data glove, the third strain sensor 11, the fourth strain sensor 12, the flexible printed circuit board 4, and the wiring 14 are the glove body 20 in the data glove of FIGS. This is the same as the third strain sensor 11, the fourth strain sensor 12, the flexible printed circuit board 4, and the wiring 14. For this reason, the overlapping description about these structures is abbreviate | omitted.

By detecting the movement of the first finger using the data glove, it can be determined whether the movement of the subject is likely to cause tendonitis or a finger.

[Fourth embodiment]
The data glove in FIG. 8 detects the movement of the first finger, the second finger, and the fifth finger. The data glove includes a glove body 1 and a third strain sensor disposed in each region corresponding to the vicinity of the interphalangeal joint in the first finger, the second finger, and the fifth finger on the back side of the glove body 1. 11, 11 a, 11 b and fourth strain sensors 12, 12 a, 12 b, the flexible printed circuit board 4, and wiring 14 connecting the strain sensors 11, 11 a, 11 b, 12, 12 a, 12 b and the flexible printed circuit board 4. Is provided.

The glove body 1, the third strain sensor 11, the fourth strain sensor 12, and the flexible printed circuit board 4 in the data glove are the glove body 1, the third strain sensor 11, the fourth strain sensor 12, and the flexible in the data glove in FIG. Similar to the printed circuit board 4. For this reason, the overlapping description about these structures is abbreviate | omitted.

The third strain sensors 11a and 11b of the second finger and the fifth finger mainly detect expansion and contraction in the proximal / distal direction of the glove body 1 respectively. Thereby, these 3rd distortion sensors 11a and 11b detect bending extension of the joint between interphalanges of the 2nd finger and the 5th finger.

On the other hand, the 4th strain sensors 12a and 12b of the 2nd finger and the 5th finger mainly detect the expansion and contraction in the left-right direction orthogonal to the proximal distal direction of the glove body 1 respectively. Thereby, these 4th distortion sensors 12a and 12b detect the peristalsis of the left-right direction in the joint of the middle finger interphalangeal of the 2nd finger and the 5th finger. In order to detect such left and right peristaltic movements of the second and fifth fingers, it is preferable that the fourth strain sensors 12a and 12b are disposed on the distal side of the center of the interphalangeal joint. .

The wiring 14 of the data glove includes a proximal connection portion 14a that connects one end of each of the strain sensors 11, 11a, 11b, 12, 12a, and 12b to the flexible printed circuit board 4, and a third strain sensor 11, 11a, and 11b. An intermediate connection portion 14b that connects the other ends of the fourth strain sensors 12, 12a, and 12b to each other; a distal connection portion 14d that connects the other ends of the fourth strain sensors 12, 12a, and 12b to the flexible printed circuit board 4; Have The intermediate connection portion 14b and the distal connection portion 14d are flexible starting from the distal ends of the third strain sensors 11, 11a, 11b, respectively, and via the other ends of the fourth strain sensors 12, 12a, 12b of the same finger. It is one wiring that extends to the printed circuit board 4.

In this embodiment, it is possible to detect in detail the movement of aligning the fingers of the hand or expanding the fingers, particularly for the first finger, the second finger, and the fifth finger. The opening and closing between the third finger and the fourth finger can be inferred from the movement of the second finger and the fifth finger.

[Other Embodiments]
The said embodiment does not limit the structure of this invention. Therefore, in the embodiment described above, components of each part of the embodiment can be omitted, replaced, or added based on the description and technical common sense in the present specification, and they are all interpreted as belonging to the scope of the present invention. Should.

The data glove only needs to have at least two strain sensors in a region corresponding to at least one of the first to fifth fingers on the back side of the glove body, and only a region corresponding to any one finger. The first strain sensor and the second strain sensor may be provided, or the third strain sensor and the fourth strain sensor may be provided only in a region corresponding to any one finger.

Further, in the above-described embodiment, the number given before the strain sensor is merely a convenience. For example, when a further strain sensor that mainly detects the horizontal expansion and contraction of the same region is disposed in the vicinity of the second strain sensor of the first embodiment of FIG. It corresponds to the third strain sensor and the fourth strain sensor in the fifth to fifth embodiments. Note that “mainly detected” means that when a detection value is separated into a direction in which the detection value is intended and a component in a direction orthogonal thereto, the component in the intended direction is larger. It means 5 times or more.

The data glove is a strain sensor for detecting expansion and contraction in the proximal and distal directions of the glove body in a region corresponding to the interphalangeal joint of at least one of the second to fifth fingers on the back side of the glove body. However, the present invention is not limited to this.

In particular, in the data glove, when two strain sensors disposed on at least one finger detect expansion and contraction in the proximal distal direction of the glove body, it corresponds to a metacarpophalangeal joint and a proximal interphalangeal joint. Although it is preferable that a strain sensor is disposed in each region, the present invention is not limited to this.

Further, in the data glove, when two strain sensors disposed on at least one finger detect expansion and contraction of the glove body in a direction crossing each other, the two strain sensors are arranged in a region corresponding to the interphalangeal joint. However, the present invention is not limited to this.

In the data glove, the third strain sensor and the fourth strain sensor may be disposed separately so as not to cross each other, and the angle between the two may not be substantially vertical. Specifically, the other end of the fourth strain sensor (the side far from the second finger) may be disposed on the proximal phalanx distal to the third strain sensor, and the other end of the fourth strain sensor is You may arrange | position on the metacarpal bone of the proximal side rather than a 3rd distortion sensor. Moreover, you may arrange | position the proximal end of a 3rd strain sensor in a distal side rather than a 4th strain sensor. Specifically, when the position of the third strain sensor is applied to the proximal interphalangeal joint, it is possible to detect the vertical and horizontal movements of the fingertip.

The data glove may include a strain sensor for detecting the expansion and contraction of the glove body in the left-right direction in order to detect the left-right movement of the glove in addition to the region corresponding to the vicinity of the joint between the metacarpophalangeal joints. In this case, it is preferable to provide a strain sensor at a position where tension is applied to the skin by the movement of the joint, that is, a position where the glove body expands and contracts.

In the data glove, the stretch-proof part and the connection part may be changed in position or may be omitted.

In the data glove, the stretch-proof part and the wiring need not overlap. For example, the stretch-proof portion and the wiring may be arranged in parallel or may be arranged so as to intersect in plan view.

In the data glove, the wiring may be used as a stretch-proof part or a connection part. That is, the stretch-proof part and the connection part may not be formed as independent components, and the extension of the glove body 1 may be suppressed by wiring. For this reason, the width and thickness of the wiring may be partially increased. Further, the stretch-proof portion and the connection portion may be disposed on the outer surface of the glove body 1. Further, the stretch-proof portion and the connection portion may be formed on different surfaces of the glove body 1.

In the data glove, the glove body may be one in which the tip of the finger accommodating portion is closed and covers the fingertip of the wearer.

Further, the data glove may be configured to connect the wiring to an external processing device without going through the flexible printed circuit board. The data glove is mounted with an arithmetic device, a wireless communication device, etc. for processing a signal on the flexible printed circuit board. Also good.

In the data glove, an anti-slip layer may be formed at positions corresponding to both ends of the strain sensor of the proximal interphalangeal joint on the inner surface of the back fabric of the glove body. Thereby, the positional displacement of the proximal interphalangeal joint strain sensor in the proximal distal direction during the measurement can be prevented, and the detection accuracy of the movement of the proximal interphalangeal joint can be improved. As a material of the anti-slip layer, for example, synthetic rubber, natural rubber, or the like can be used.

The data glove may include a strain sensor other than the region corresponding to the proximal interphalangeal joint and the metacarpophalangeal joint. The strain sensor that detects the movement of the first finger (thumb) may be provided in another region that does not correspond to the joint between the metacarpophalangeal joints, and is located at a position that corresponds to between the joints on which the skin acts by the movement of the joint. It may be provided.

In the data glove, each strain sensor may be any sensor as long as it can detect the elongation of the glove body, and may have a shape such as a thread shape in addition to the belt shape, and does not have a CNT film. Also good. As the thread-like CNT strain sensor, a CNT fiber bundle in which a plurality of CNT fibers are aligned in one direction and arranged in a thread shape and the outer periphery is coated with an elastic resin can be used. Moreover, as a strain sensor other than the CNT strain sensor, it is only necessary to be able to detect the expansion and contraction of the glove body and to have appropriate stretchability and flexibility, and is preferably formed in a band shape or a string shape. .

The strain sensor may be formed by applying a material constituting the strain sensor, such as a paint containing CNT, to the cloth constituting the glove body, in addition to being attached to the glove body.

The connecting portion spanned between the stretch-proof portions is not limited to the proximal end of the stretch-proof portion, and may be connected at other positions. Moreover, you may connect between adjacent stretch-proof parts by a some connection part.

The data glove of the present invention can be suitably used for analyzing the movements of the hands of athletes and instrument players.

DESCRIPTION OF SYMBOLS 1 Glove body 1a Sag 2, 3 Strain sensor 4 Flexible printed circuit board 4a Connector 5 Wiring 5a Distal connection part 5b Proximal connection part 5c Intermediate connection part 5d Interconnection part 5e Ground connection part 6 Detachment prevention material 7 Stretch prevention part 8 Connection part 11, 12, 13 Strain sensor 14, 15 Wiring 14a Proximal connection part 14b Intermediate connection part 14c, 15b Interconnection part 14d, 15a Distal connection part

Claims (10)

1. The glove body,
   A plurality of strain sensors disposed in a region corresponding to at least one of the first to fifth fingers on the back side of the glove body, and detecting expansion and contraction of the glove body,
   A data glove in which two or more strain sensors are arranged for each of at least one finger.
2. The plurality of strain sensors are disposed in a region corresponding to a joint between proximal phalanges and a region corresponding to a joint between middle finger phalanges of at least one of second to fifth fingers on the back side of the glove body. The data glove according to claim 1, further comprising a first strain sensor and a second strain sensor that detect expansion and contraction in a proximal and distal direction of the glove body.
3. 3. The apparatus according to claim 2, further comprising a plurality of stretch-proof portions disposed along a proximal distal direction in a region corresponding to a joint between metacarpophalangeal joints on the back side of the glove body, and suppressing extension of the glove body. The listed data glove.
4. The proximal end of the stretch-proof portion is located proximal to the strain sensor;
   The data glove according to claim 3, further comprising a connecting portion that is arranged so as to be bridged between the plurality of stretch-proofing portions and suppresses the extension of the glove body.
5. The data glove according to claim 3 or 4, wherein the stretch-proof portion is disposed so as to overlap with a wiring extending from the strain sensor.
6. As the plurality of strain sensors, a third strain sensor and a fourth strain sensor disposed in each region corresponding to the joint between the metacarpophalangeal joints of at least one of the first to fifth fingers on the back side of the glove body. Including
   6. The device according to claim 1, wherein the third strain sensor is configured to detect expansion / contraction in the proximal / distal direction of the region, and the fourth strain sensor is configured to detect expansion / contraction in the horizontal direction of the region. The data glove according to item 1.
7. The data glove according to claim 6, wherein the third strain sensor and the fourth strain sensor are arranged so as to intersect with each other.
8. The data glove according to claim 7, wherein an intersection angle of the third strain sensor and the fourth strain sensor is substantially vertical.
9. The data glove according to claim 6, 7 or 8, wherein an arrangement position of the third strain sensor and the fourth strain sensor is an area corresponding to the first finger.
10. From the 1st strain sensor which is arranged in the field along the proximal phalanx of the 2nd finger or the 5th finger in the ventral side of the glove body, and further detects the expansion and contraction of the proximal direction of the glove body. The data glove according to claim 9.
    

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