JP5895593B2 - Cloth pressure sensor heater - Google Patents

Description

  The present invention relates to a cloth-like pressure sensor heater capable of measuring and heating pressures at a plurality of sites.

Conventionally, a product in which a heater is combined with a pressure sensor in which a pressure-sensitive material is provided on a surface facing each of a pair of electrode materials having a pair of surface shapes provided to face each other with a space is generally used. Yes. (For example, see Patent Document 1)
While being able to detect a pressure in the sensor operation area | region 18, it also has a heater function which can selectively heat the site | part in which the heat generating body 28 was provided.

Japanese translation of PCT publication No. 2003-533311 (FIG. 1)

In a product that combines such a conventional planar pressure sensor and a heater that can heat a selected part, when excessive pressure is applied to the planar pressure sensor and the electrode materials are in electrical contact with each other and short-circuited Overcurrent flows through the short-circuited part and heat is generated, and the part other than the selected part is heated, making it difficult to achieve the intended temperature distribution of the pressure sensor heater.
Therefore, an object of the present invention is to provide a cloth pressure sensor heater that can suppress a short circuit of a pressure sensor and heat only a selected portion.

  In the cloth-like pressure sensor heater of the present invention, the third fiber layer that electrically connects the first conduction part provided in the first fiber layer and the second conduction part provided in the second fiber layer. And a short-circuit preventing layer having insulation properties between the first conducting portion and the second conducting portion.

  According to the cloth-like pressure sensor heater of the present invention, an insulating short circuit provided between the first conduction part provided in the first fiber layer and the second conduction part provided in the second fiber layer. By providing a prevention layer, even if pressure is applied to the cloth-like pressure sensor heater, the distance between the first conduction part and the second conduction part is maintained, and a short circuit between the first conduction part and the second conduction part is suppressed. It becomes possible to do. For this reason, it is possible to suppress an unintended portion of the cloth-like pressure sensor heater from generating heat due to a short circuit, and to make the cloth-like pressure sensor heater have an intended temperature distribution.

Hereinafter, the embodiment will be described in detail with reference to the drawings, taking as an example the case where the cloth-like pressure sensor heater of the present invention is used as a pressure sensor and a heater for an automobile seat.
1 to 3 show a first embodiment of a cloth pressure sensor heater according to the present invention, FIG. 1 is an overall view of a seat provided with a cloth pressure sensor heater 1 on a seat surface, and FIG. 2 is a cloth pressure sensor heater. 3 is a partial schematic view showing the structure of FIG. 1, FIG. 3 is a cross-sectional view taken along the line AA in FIG. 2, (a) is a cross-sectional view taken along the line AA before pressure application, and (b) is a cross-sectional view taken along line AA during pressure application. Figure, (c) is a cross-sectional view when an excessive pressure is applied to a cloth-like pressure sensor heater that does not have a short-circuit prevention layer, and (d) is a cross-sectional view taken along a line AA when an excessive pressure is applied. Show.

  The cloth-like pressure sensor heater 1 of the present embodiment is provided on the seat surface of the seat as shown in FIG. As shown in FIG. 2, the cloth-shaped pressure sensor heater includes an upper layer conductive portion 4 (corresponding to the first conductive portion described in the claims) and an upper layer nonconductive portion 5 (corresponding to the first nonconductive portion described in the claims). And lower layer 3 (corresponding to the second conduction part described in claim) and upper layer 2 (corresponding to the first fiber layer described in claim) and lower layer conduction part 6 (corresponding to the second conduction part described in claim) Corresponding to the second fiber layer described in the section), a short-circuit prevention layer 11 provided at a position facing the upper layer 2 and the lower layer 3 with a space therebetween, and a surface facing the upper layer 2 of the short-circuit prevention layer 11 And a resistance variable heat generating layer 8 (corresponding to the third fiber layer described in the claims) provided between the lower layer 3 and the surface of the short-circuit prevention layer 11 facing the lower layer 3. .

The upper layer conductive portion 4 is composed of a plurality of upper layer conductive portions 4a, b, c,... Which are made of silver coated fibers (manufactured by Shaoxing Unjia Boshoku Co., Ltd.) and have a width of 10 mm and a length of 200 mm. 4 is provided with an upper non-conducting portion 5 having a width of 2 mm and a length of 200 mm formed of a fiber made of polyester fiber (manufactured by Central Fiber Material, Gunze Polina) which is a non-conductive resin. The lower layer 3 is composed of a lower layer conductive portion 6a in which a silver coating fiber (manufactured by Shaoxing Yuka Textile Co., Ltd.) is woven into the entire surface.

The short-circuit prevention layer 11 is made of polyester fiber (manufactured by central fiber material, Gunze Polina) in the same manner as the upper layer non-conductive portion.
As shown in FIG. 3 (a), the resistance variable heat generating layer 8 is formed of a connecting yarn 8a that electrically connects the upper layer conductive portion 4 and the lower layer conductive portion 6 and reciprocates through the short-circuit prevention layer 11. . The connecting yarn 8a is a conductive polymer fiber having a diameter of about 10 μm obtained by a wet spinning method. A conductive polymer PEDOT / PSS once filtered using acetone (manufactured by Wako Chemical Co., Ltd .: 019-00353) as a solvent phase. aqueous dispersion (Starck Ltd. Clevios ^R P) and polyvinyl alcohol (PVA, manufactured by Kanto Kagaku) microsyringe at 2 [mu] L / min. of speed spinning solution of a mixture of 7 wt% aqueous solution of (Ito Seisakusho, MS-GLL100, It is generated by extrusion from the needle part inner diameter 260 μm). As a result of measuring the electrical conductivity of this conductive polymer fiber in accordance with JIS K 7194 (Test method for electrical resistivity of conductive plastics using the 4-probe method), the electrical resistivity (Ω · cm) is about 10 ^{− 1} Ω · cm.

Using a circular knitting machine made by Fukuhara Seiki Co., Ltd., the gauge, number of units, etc., the thickness of the variable resistance heating layer 8 between the upper layer 2 and the lower layer 3 is 10 mm, and the upper layer 2 of the resistance variable heating layer 8 is horizontal. Adjustment was made so that the total area of the cross section of the conductive polymer fiber per unit area of the flat surface was 50%.
The upper layer electric wire 9a is electrically connected to the upper layer conductive portion 4a of the upper layer 2, the upper layer electric wire 9b is electrically connected to the upper layer conductive portion 4b, and the upper layer electric wire 9c is electrically connected to the upper layer conductive portion 4c. A lower layer electric wire 10a is electrically connected to the lower layer conducting portion 6 of the lower layer 3, and the upper layer electric wire 9 and the lower layer electric wire 10 are connected to an unillustrated electrical resistance value measuring device (corresponding to the measuring means in the claims) and an unillustrated It is connected to a controller (corresponding to the heat generation control means described in the claims).

The length L of the connecting thread 8a between the upper layer conductive portion 4a and the lower layer conductive portion 6a is determined by the cloth pressure sensor 1
Is expressed as the following equation (1) as a function of the pressure F applied to. The coefficient α is approximately equal to the reciprocal of the spring constant in the cloth compression direction.
L = αF (1)
L: length [mm] of the connecting yarn 8a, F: pressure [Pa] applied to the cloth-like pressure sensor 1, [alpha]: coefficient [mm / Pa]
Here, the relationship between the electrical resistance value R, the electrical resistivity ρ, the length L of the connecting yarn 8a, and the cross-sectional area S of the connecting yarn 8a between the upper layer conducting portion 4a and the lower layer conducting portion 6a is expressed by the following equation (2). It is expressed as

R = ρL / S (2)
R: resistance value [kΩ], ρ: resistivity [Ω · mm], L: length [mm], S: cross-sectional area [mm ² ]
The case where the pressure applied to the upper layer conduction | electrical_connection part 4 is measured is demonstrated. When no pressure is applied to the upper layer conductive portion 4, the connecting yarn 8 a between the upper layer conductive portion 4 and the lower layer conductive portion 6 maintains a predetermined distance L independently. 3B, when the pressure F is applied to the upper layer conductive portion 4, the upper layer conductive portion 4 bends toward the lower layer conductive portion 6, and at the contact point B, the connecting yarn 8a and the upper layer conductive portion 4 are bent. The connecting yarn 8a connected to the upper layer conductive portion 4 is curved so that the lower layer conductive portion 6 and the lower layer conductive portion 6 are in contact with each other, and the energization path between the upper layer conductive portion 4 and the lower layer conductive portion 6 is shown by a broken line in FIG. Becomes L ′, which is shorter than L before pressure application. When pressure is further applied to the upper layer conductive portion 4a, the upper layer conductive portion 4 is further curved, and the length of the energization path between the upper layer conductive portion 4 and the lower layer conductive portion 6 is L ″, which is further compared to L ′. Shorter. For this reason, the electrical resistance value R between the upper layer conductive portion 4 and the lower layer conductive portion 6, which is proportional to the length L of the connecting yarn 8 a, becomes lower as pressure is applied to the upper layer conductive portion 4.

For this reason, the applied pressure F and the electrical resistance value between the upper layer conducting portion 4 and the lower layer conducting portion 6 show a continuous change as shown in FIG. 4, and the pressure F is calculated from the change in the electrical resistance value. Thus, the variable resistance heating layer 8 functions as a pressure sensor.
The case where the connecting yarn 8a connected to the upper layer conductive portion 4a is heated will be described. When a predetermined voltage is applied between the upper layer electric wire 9a and the lower layer electric wire 10a by the controller, the connecting yarn 8a generates heat because of its high electric resistivity, and functions as a heater.

A case where an excessive pressure is applied to the upper conductive portion 4 of the cloth pressure sensor heater 1 will be described. As shown in FIG. 3 (c), when the cloth-like pressure sensor heater 1 does not have the short-circuit prevention layer 11, the upper layer conducting portion 4 is deformed toward the lower layer conducting portion 6 by the applied pressure, and the upper layer conducting portion is formed. When the part 4 and the lower layer conductive part 6 come into contact with each other and are short-circuited, an overcurrent flows at the short-circuited portion and is abnormally heated. However, as shown in FIG. 3D, in the structure having the short-circuit prevention layer 11 between the upper layer conductive portion 4 and the lower layer conductive portion 6 as in the present invention, an excessive pressure is applied to the upper layer conductive portion 4. However, the distance is maintained between the upper layer conductive portion 4 and the lower layer conductive portion 6 by the thickness D of the short-circuit preventing layer, and the upper layer conductive portion 4 and the lower layer conductive portion 6 are prevented from being electrically contacted and short-circuited. It becomes possible to do. Furthermore, since at least the length D of the conduction path between the upper layer conduction unit 4 and the lower layer conduction unit 6 is secured, the heater function can be maintained without being short-circuited even when an excessive pressure is applied. The same effect can be obtained when an excessive pressure is applied to the lower layer conductive portion 6.

  Thus, the cloth-like pressure sensor 1 applies an excessive pressure while having a pressure sensor function and a heater function by providing the short-circuit prevention layer 11 between the upper layer conduction part 4 and the lower layer conduction part 6. Even in such a case, it is possible to suppress a short circuit. For this reason, it is possible to suppress an unintended portion of the cloth-like pressure sensor heater 1 from generating heat due to a short circuit, and it is possible to heat the cloth-like pressure sensor heater 1 to an intended temperature distribution.

  FIG. 5 shows a second embodiment, in which the same components as those in the first embodiment are denoted by the same reference numerals, and redundant description is omitted. As shown in FIG. 5, the upper layer 2 in which the upper layer conductive portions 4 and the upper layer non-conductive portions 5 are alternately provided in parallel, and the lower layer 3 in which the lower layer conductive portions 6 and the lower layer non-conductive portions 7 are alternately provided in parallel. And a variable resistance heat generating layer 8 formed of a connecting yarn 8a that electrically connects and reciprocates the upper layer conductive portion 4 and the lower layer conductive portion 6.

  The upper layer 2, the upper layer conductive portion 4, and the upper layer non-conductive portion 5 are the same as in the first embodiment. The lower layer 3 is formed of a polyester fiber, and the lower layer conductive portion 6 is formed by applying a conductive paste (made by Fujikura Chemical Co., Dotite) to the lower layer 3 and has a plurality of lower layer conductive portions 6a, b, c. The lower layer non-conductive portion 7 indicates a portion having a width of 200 mm and a length of 2 mm where the conductive paste is not applied. The lower layer conducting part 6 is electrically connected to all the upper layer conducting parts 4 by the connecting thread 8a. When viewed from above the sheet, the side along the longitudinal direction of the upper layer conducting part 4 and the side along the longitudinal direction of the lower layer conducting part 6 Are arranged so as to go straight.

The lower layer electric wire 10a is electrically connected to the lower layer conductive portion 6a, the lower layer electric wire 10b is electrically connected to the lower layer conductive portion 6b, and the lower layer electric wire 10c is electrically connected to the lower layer conductive portion 6c. The upper layer electric wire 9 and the lower layer electric wire 10 are respectively connected to an electric resistance value measuring device (not shown) (corresponding to the measuring means in the claims).
The case where the pressure transmitted to the resistance variable heating layer 8 composed of the connecting yarn 8a that connects the upper layer conductive portion 4a and the lower layer conductive portion 6a is measured will be described. When no pressure is applied to the upper layer conductive portion 4a or the lower layer conductive portion 6a, the connecting yarn 8a between the upper layer conductive portion 4a and the lower layer conductive portion 6a has a predetermined distance L.
Keep it independent. When pressure is applied to the upper conductive portion 4a, as in the first embodiment, as shown in FIG. 3B, the upper conductive portion 4a is curved toward the lower conductive portion 6a and is connected to the upper conductive portion 4a. The connecting yarn 8a is also curved, and the connecting yarn 8a is bent so that the connecting yarn 8a and the upper layer conducting portion 4a or the lower layer conducting portion 6a are in contact with each other at the contact point B, and the upper layer conducting portion 4a and the lower layer conducting portion 6a are The length of the energization path (similar to that shown by the broken line in FIG. 3B) is L ′, which is shorter than L before pressure application. For this reason, the electrical resistance value between the upper layer conduction | electrical_connection part 4a and the lower layer conduction | electrical_connection part 6a becomes low. Similarly, the same effect can be obtained with any combination of the upper conductive portion 4 and the lower conductive portion 6 of the upper conductive portions 4a, 4b, 4c... And the lower conductive portions 6a, 6b, 6c. It is done.

For this reason, the applied pressure F and the electrical resistance value between the upper layer conducting portion 4 and the lower layer conducting portion 6 show a continuous change as shown in FIG. 4, and the change in pressure is calculated from the change in the electrical resistance value. The variable resistance heating layer 8 functions as a pressure sensor.
Further, a case where the connecting yarn 8a electrically connected to the upper layer conductive portion 4a and the lower layer conductive portion 6a is caused to generate heat will be described. When a predetermined voltage is applied between the upper layer electric wire 9a and the lower layer electric wire 10a by the controller, the connecting yarn 8a generates heat because of its high electric resistivity, and functions as a heater.

When an excessive pressure is applied to the upper conductive portion 4 of the cloth-like pressure sensor heater 1, the structure having the short-circuit preventing layer 11 between the upper conductive portion 4 and the lower conductive portion 6 is the same as in the first embodiment. Even if an excessive pressure is applied to the upper layer conductive portion 4 or the lower layer conductive portion 6, the distance between the upper layer conductive portion 4 and the lower layer conductive portion 6 is maintained by the thickness D of the short-circuit prevention layer 11, and the upper layer It is possible to suppress a short circuit between the conductive part 4 and the lower conductive part 6 due to electrical contact. Furthermore, since at least the length D of the conduction path between the upper layer conduction unit 4 and the lower layer conduction unit 6 is secured, the heater function can be maintained without being short-circuited even when an excessive pressure is applied. The same effect can be obtained when an excessive pressure is applied to the lower layer conductive portion 6.

  Thus, the cloth-like pressure sensor 1 applies an excessive pressure while having a pressure sensor function and a heater function by providing the short-circuit prevention layer 11 between the upper layer conduction part 4 and the lower layer conduction part 6. Even in such a case, it is possible to suppress a short circuit. For this reason, it is possible to suppress an unintended portion of the cloth-like pressure sensor heater 1 from generating heat due to a short circuit, and it is possible to heat the cloth-like pressure sensor heater 1 to an intended temperature distribution.

As a third embodiment, the material is the same as that of the first embodiment. As shown in FIG. 6 (c), a cloth-like pressure sensor heater in which two resistance variable heat generating layers 8 having 2 mm and 8 mm are bonded together is used. Created. As a result, the same effect as in the first embodiment was obtained.
As the fourth embodiment, nylon fiber (manufactured by Chuo Textile Material, Gunzepoelon) was used as the non-conductive portion fiber in the first embodiment. As a result, the same effect as in the first embodiment was obtained.

By the way, although the cloth-like pressure sensor heater 1 of this invention was demonstrated taking the example of the said embodiment, it does not restrict to this embodiment, Various other embodiments are taken in the range which does not deviate from the summary of this invention. For example, the present invention can be applied not only to automobile seats but also to various uses such as cushion covers and hot carpets.
Examples of conductive materials used in the present invention include metal wires such as gold, silver, copper and nichrome, carbon-based materials such as carbon and graphite, particles made of semiconductors such as metals and metal oxides, acetylene-based and complex 5-membered Any of ring-type, phenylene-type, and aniline-type conductive polymers may be employed.

Examples of carbon-based materials as conductive materials include carbon fibers other than those generally commercially available such as carbon fibers (Torayca (Toray), Donakabo (Osaka Gas Chemical Co., Ltd.)). It is also possible to use fibers spun by mixing carbon powder or the like.
On the other hand, examples of particles used as the conductive material include carbon-based powders such as carbon black and ketjen black, metal fine particles such as carbon-based fibers, iron, and aluminum, and tin oxide (SnO ₂ ) as semiconductive fine particles. And zinc oxide (ZnO).

Those made of these materials alone, those coated on the surface by vapor deposition, coating, etc., those used as a core material and coated on the surface with another material can be used.
Among these, it is desirable to use carbon fiber or carbon powder as the conductive material from the viewpoint of easy availability in the market and specific gravity. There is no particular limitation on whether the conductive material is made of a single material or a plurality of materials.

In order to provide air permeability, the upper layer 2 and the lower layer 3 themselves are preferably formed of fibers. However, the upper layer conductive portion 4 and the lower layer conductive portion 6 are uniformly formed in the upper layer 2 and the lower layer 3 in a strip shape or on the entire surface. It can also be formed by applying a paint or the like. Examples of the conductive paint include Dotite manufactured by Fujikura Kasei.
As a cloth-like pressure sensor heater, the upper layer conductive portion 4 and the lower layer conductive portion 6 are substantially the same as the fibers forming the upper layer 2, the lower layer 3, and the resistance variable heat generating layer 8 in the sense of avoiding a sense of incongruity due to a difference in partial hardness. It is also possible to use a metal wire or conductive fiber having the same cross-sectional area, for example, a stranded wire obtained by twisting a metal such as nickel.

  The upper layer non-conductive portion 5, the lower layer non-conductive portion 7 and the short-circuit prevention layer are non-conductive portions, such as nylon 6, nylon 66 and other polyamides, polyethylene terephthalate, polyethylene terephthalate containing a copolymer component, polybutylene terephthalate, polyacrylonitrile, etc. From the viewpoint of cost and practicality, it is preferable to use a single resin or a mixture of fibers made of general-purpose resins.

Further, the upper layer 2 and the lower layer 3 have no particular problem as long as they form a breathable cloth. However, the resistance can be changed by using the above-mentioned woven fabric, nonwoven fabric, knitted fabric, or the like. It is also preferable from the viewpoint of fixing the heat generating layer 8, the purpose of generating heat to feel warmth, the purpose of uniform deformation due to pressure, and the purpose of maintaining insulation between the upper and lower layers.
The short-circuit prevention layer of the present invention is installed in parallel with the upper and lower layers. This is because, when sensing between the upper and lower layers, the method of changing the resistance value differs for each sensing portion unless parallel. If they are installed in parallel, even if they are close to the upper layer or close to the lower layer, the uniformity of the sensing output can be maintained. Extremely, it may be in contact with the inside of the upper layer or the lower layer, or the side where the resistance variable heating layer is present. However, installation in both upper and lower layers is not preferable because the sensing performance is lowered. In order to make the sensing performance as high as possible, it is more preferable to install it between the upper and lower layers.

The short-circuit prevention layer can be installed by stacking two layers of the above-described three-dimensional knitted fabric (FIG. 6 (c)) or by protruding a loop on one side of the three-dimensional knitted fabric (FIG. 6 (d)). There is another method of forming a surface on the loop that has been formed. The former is formed so that the resistance variable heat generating layers have contact points with each other on the side facing the short-circuit prevention layer of the fabric produced without forming the conductive layer on one side. In order to make it easy to have a contact, a method of protruding in a loop shape as in the latter method is also possible. Along with the latter manufacturing method, in order to form a cloth that protrudes in a loop shape, it can be formed by adjusting the pitch, the number, etc. of the circular knitting machine. Another woven fabric or knitted fabric is formed on the loop portion. In any method, a non-conductive material is used as a material for forming the short-circuit insulating layer.

The resistance value reading means used for measuring the resistance change at an arbitrary part is a commonly used resistance meter, LCR meter, a method of measuring a voltage ratio with a reference resistance based on the measurement principle with a voltmeter, etc. Are used alone or in combination.
As the heat generating part control means used to generate heat at an arbitrary part, a commonly used switching element, relay or the like is used alone or in combination.

In order to increase the sensing accuracy, it is preferable that the upper layer conductive portion 4 and the lower layer conductive portion 6 are made of a material having a lower electrical resistivity than the normal resistance variable heat generating layer 8.
The insulator referred to in the present invention refers to a material having an electrical performance insulating property, and generally refers to a material having low electrical conductivity. Here, the resistivity is generally greater than 10 ⁶ Ω · cm.
The resistivity referred to here means a resistivity determined in accordance with JIS K 7194 (Resistivity test method by conductive probe 4-probe method).

As the insulator, a cloth-like or film-like insulator is preferably used, and a material made of rubber, paper, resin, or the like can be used.
The present invention aims at pressure sensing and heat generation in a state having air permeability. From this viewpoint, an insulator having air permeability is preferable, and a cloth is very preferable.

The cloth here refers to a thin cloth-like material and is mainly formed of fibers. Of course, it is preferable to use a fabric because it has not only the air permeability necessary for the present invention but also can sufficiently follow deformation due to pressure and has a restoring property.
Furthermore, it is preferable that this fabric is formed of synthetic fibers.
In the present invention, the fiber refers to a fiber that is spun by a method such as melt spinning, wet spinning, electrospinning, or the like, as well as a slit such as a film cut. The diameter and width of the fibers at this time are about several μm to several hundreds of μm per one. When forming a woven fabric or knitted fabric, weaving, ease of knitting, weaving, woven fabric after knitting, knitted fabric It is preferable because of its softness as a fabric and ease of handling as a fabric.

By making these fibers into bundles (bundles) of several tens to several thousands, handling as fibers becomes easy. At this time, twisting may be applied.
In the present invention, these fibers and / or bundle fibers are used to form the fabric.
Synthetic fibers refer to fibers using general-purpose resins. Polyamides such as nylon 6 and nylon 66, polyethylene terephthalate, polyethylene terephthalate containing copolymerization components, polybutylene terephthalate, and polyacrylonitrile, which are used for the general fibers described above. A fiber made of a general-purpose resin such as a single resin or a mixture thereof is used.

It is physically possible to use natural fibers, but when sensing performance and heater performance are taken into account, quality such as variations in fiber diameter and physical properties in the fiber length direction can be obtained more stably with synthetic fibers. From the viewpoint of cost and availability, synthetic fibers are preferable.
In the present invention, the connecting yarn 8a does not necessarily have to be connected by one at the connecting portion 11, and as shown in FIGS. 6A and 6B, either the upper layer 2 or the lower layer 3, or the upper layer 2 and the lower layer 3 and the connecting yarn 8a may be cut off. However, the cut end 12 needs to be fixed to the upper layer 2 or the lower layer 3 by some means.

Overall view of a seat with a cloth pressure sensor heater on the seat Schematic showing the structure of the cloth-like pressure sensor heater in the first embodiment (A) AA sectional view of FIG. 2 (before pressure application), (b) AA sectional view of FIG. 2 (during pressure application), (c) Cloth-like sensor heater without a short-circuit prevention layer Sectional view (during application of excessive pressure), (d) AA sectional view of FIG. 2 (during application of excessive pressure) A graph showing the relationship between the length of the connecting yarn and the electrical resistance value Schematic which showed the structure of the cloth-like pressure sensor heater in 2nd Embodiment. (A) Other form 1 of connecting thread, (b) Other form 2 of connecting thread, (c) Method 1 of creating cloth-shaped pressure sensor heater, (d) Method 2 of creating cloth-shaped pressure sensor heater

DESCRIPTION OF SYMBOLS 1 Cloth-like pressure sensor heater 2 Upper layer 3 Lower layer 4 Upper layer conduction | electrical_connection part 5 Upper layer non-conduction part 6 Lower layer conduction | electrical_connection part 7 Lower layer non-conduction part 8 Resistance variable heat generation layer 8a Connection thread 11 Short-circuit prevention layer

Claims (7)

A first fiber layer, a second fiber layer provided at a position facing the first fiber layer with a space therebetween, and a third fiber provided between the first fiber layer and the second fiber layer A cloth-like pressure sensor heater having a layer,
The first fiber layer has a plurality of conductive first conductive portions electrically insulated by a first non-conductive portion having insulation,
The second fiber layer has a second conductive part having conductivity,
The third fiber layer is entangled with the first conduction part and the second conduction part, and the first fiber layer and the second fiber layer are electrically connected to each other with a predetermined electrical resistance value. Have a thread,
Even when the first conduction part or the second conduction part is deformed between the first fiber layer and the second fiber layer by a pressure applied from the outside, the first conduction part and the second conduction part Securing a predetermined space between the first conductive portion and the second conductive portion to prevent a short circuit,
When the connection thread is pushed and bent by the first conduction part or the second conduction part deformed by pressure applied from the outside, the connection part of the first conduction part and the short-circuit prevention layer and the connection thread A middle portion between the two is bent so as to contact the first conductive portion, and a middle portion between the second conductive portion and the connection portion between the short-circuit prevention layer and the connecting yarn is in contact with the second conductive portion. Curved and
The short-circuit prevention layer has an electrical resistance value higher than that of the connecting yarn,
Measuring means for measuring an electrical resistance value between the selected first conductive portion and the second conductive portion;
A voltage is applied between the said selected first conductive portion and the second conductive portion, have a heating control means for heating the connecting yarn,
A cloth-like pressure sensor heater, wherein the surface of the connecting yarn has conductivity . The second fiber layer is electrically insulated by a second non-conductive portion having insulation, and has a plurality of second conductive portions having conductivity,
The cloth-like pressure sensor heater according to claim 1, wherein the second conduction portion is electrically connected to the first conduction portion by the connecting yarn . The cloth-like pressure sensor heater according to claim 1, wherein the short-circuit prevention layer is provided at a position facing the first fiber layer . The cloth-like pressure sensor heater according to claim 1, wherein the short-circuit prevention layer comprises a fiber layer .   The cloth-like pressure sensor heater according to claim 1, wherein the short-circuit prevention layer is made of an insulator.   The cloth-like pressure sensor heater according to claim 1, wherein the short-circuit preventing layer is made of an insulating cloth.   The cloth-like pressure sensor heater according to claim 6, wherein the cloth is made of synthetic fiber.

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