JP2017188538A - Piezoelectric element using braid form and device using them - Google Patents

Abstract

The present invention provides a technique for further increasing the signal strength of a piezoelectric element using a piezoelectric fiber and further suppressing a noise signal.
A core part formed of conductive fibers, a sheath part formed of braided piezoelectric fibers so as to cover the core part, a conductive layer provided around the sheath part, A signal metal terminal connected and fixed to the core, and a shield metal terminal connected and fixed to the conductive layer, the signal metal terminal and the A piezoelectric element in which a shield metal terminal is fixed to each other through an insulator.
[Selection] Figure 1

Description

  The present invention relates to a braided piezoelectric element with a terminal in which a braid using a piezoelectric fiber is covered with a conductive layer, a fabric-like piezoelectric element using the braided piezoelectric element with a terminal, and a device using the same.

  In recent years, so-called wearable sensors have attracted attention, and products such as glasses and watches have begun to appear in the world. However, these devices have a feeling that they are worn, and a cloth-like shape, that is, a clothing-like shape that is the ultimate wearable is desired. As such a sensor, a piezoelectric element using a piezoelectric effect of a piezoelectric fiber is known. For example, Patent Document 1 discloses a piezoelectric element that includes two conductive fibers and one piezoelectric fiber, and these include piezoelectric units that are disposed on substantially the same plane while having contact with each other. Has been. Patent Document 2 discloses a fibrous or molded product made of a piezoelectric polymer, and in order to generate piezoelectricity by the tension applied in the axial direction thereof, the direction in which the tension is applied is different. A piezoelectric material characterized by being twisted is disclosed.

  On the other hand, in recent years, the number of input devices adopting a so-called touch panel method, that is, touch-type input devices has increased significantly. In addition to bank ATMs and station ticket vending machines, smartphones, mobile phones, portable game consoles, portable music players, etc., coupled with the development of thin display technology, the number of devices that use the touch panel method as an input interface has increased significantly. . As means for realizing such a touch panel system, a system using a piezoelectric sheet or piezoelectric fiber is known. For example, Patent Document 3 discloses a touch panel that uses a piezoelectric sheet made of L-type polylactic acid having an extending axis facing a predetermined direction.

  In these wearable sensors and touch panel type sensors, it is desired to extract a large electric signal even with a small stress generated in the piezoelectric material due to a small deformation applied to the piezoelectric material. For example, it is desired to stably extract a large electric signal even by a relatively small stress generated in a piezoelectric material due to a bending and stretching operation of a finger or an action of rubbing the surface with a finger or the like.

  The piezoelectric fiber of Patent Document 1 is an excellent material applicable to various uses, but it cannot necessarily output a large electric signal with respect to stress generated by a relatively small deformation, and obtains a large electric signal. The technology is not specified. In addition, the piezoelectric element described in Patent Document 1 has a bare conductive fiber serving as a signal line. Therefore, in order to suppress a noise signal, it is necessary to construct a noise shield structure separately. Therefore, the piezoelectric element described in Patent Document 1 still has room for improvement for practical use.

  The piezoelectric fiber of Patent Document 2 can output an electrical signal in response to tension or compression on the piezoelectric fiber by previously twisting the piezoelectric fiber by a special manufacturing method. However, Patent Document 2 does not disclose a technique for generating a sufficient electric signal with respect to a bending stress caused by bending or stretching a piezoelectric fiber or a shearing stress caused by rubbing the surface of the piezoelectric fiber. Therefore, when such a piezoelectric fiber is used, it is difficult to extract a sufficient electric signal only with a stress generated by a relatively small deformation that rubs the surface.

  The piezoelectric sheet of Patent Document 3 can output an electric signal by deformation (stress) with respect to the piezoelectric sheet. However, since it is in the form of a sheet in the first place, it is not flexible and cannot be used such that it can be bent freely like a cloth.

International Publication No. 2014/058077 Japanese Patent No. 3540208 JP 2011-253517 A

  An object of the present invention is to provide a fibrous piezoelectric element that can extract a large electrical signal even by a stress caused by a relatively small deformation and can suppress a noise signal. It is another object of the present invention to provide a piezoelectric element with a terminal that makes it possible to efficiently connect this element to a signal detection circuit.

As a combination of a conductive fiber and a piezoelectric fiber, the inventors of the present invention are more efficient by using a piezoelectric element in which the surface of a conductive fiber as a core is covered with a braided piezoelectric fiber and a conductive layer is further provided around the surface. It was discovered that electricity can be extracted well and that noise signals can be further suppressed.
In addition, various techniques for attaching a terminal to an insulation-coated conductive wire have been disclosed, but in the case of connecting a terminal to a conductive fiber covered with a piezoelectric fiber in a braid shape and further provided with a conductive layer around it, the prior art It was proved that application was difficult due to the difficulty of removing the coating, the characteristics derived from the fibers of the sheath, and the noise derived from the piezoelectricity. Furthermore, simply wiring from the ground terminal of the circuit to the surrounding conductive layer can not only prevent the mixing of noise at the terminal part, but also the piezoelectric fiber is unwound with complicated wiring work, and as a piezoelectric element It turns out that the functionality is easily lost. Therefore, a specific structure that can secure the electrical connection of the core lead wire and the terminal connected to each of the surrounding conductive layers while fixing the fibers of the sheath of the connection portion and the surrounding conductive layers together. I found out that I could solve this problem.
Furthermore, when applied to wearable devices, the noise from the instability of braided piezoelectric fibers is reduced by reducing the distance between the terminal portion of the piezoelectric element and the fixing portion to the flexible base material such as cloth. I found what I could do.
In order to provide a more functional wearable device, a method has been invented to efficiently create a device having a plurality of braids and to facilitate connection / disconnection to / from a circuit, thereby completing the present invention.

That is, the present invention includes the following inventions.
1. A core formed of conductive fibers;
A sheath formed of braided piezoelectric fibers so as to cover the core,
A conductive layer provided around the sheath;
A signal metal terminal connected and fixed to the core, and a shield metal terminal connected and fixed to the conductive layer, the signal metal terminal and the A piezoelectric element in which a shield metal terminal is fixed to each other through an insulator.
2. 2. The piezoelectric element according to 1 above, wherein a coverage of the sheath portion by the conductive layer is 25% or more.
3. 3. The piezoelectric element according to 1 or 2 above, wherein the conductive layer is formed of fibers.
4). The piezoelectric element according to any one of 1 to 3, wherein the shield metal terminal covers and holds the signal metal terminal via an insulator.
5. The signal metal terminal is connected and fixed in one of the following modes A and B, and the piezoelectric element fixed by the signal metal terminal or a component fixed to the signal metal terminal. Any one of the above 1 to 4, wherein at the end of the portion, the piezoelectric fiber that has been unwound from the core portion and is separated from the core portion has a portion that is less than 20% of the entire piezoelectric fiber of the sheath portion. The piezoelectric element according to one item.
A) Part of the signal metal terminal grips a portion of the fiber constituting the terminal portion of the piezoelectric element having a length of 0.5 mm or more, and the grip portion or a place within 1 mm from the grip portion A state in which the core of the piezoelectric element and the signal metal terminal are electrically connected and fixed directly or indirectly through a conductive material. B) A part of the signal metal terminal is fork-shaped or needle-shaped. The fork-like part or the needle-like part is connected to the conductive fiber of the core part directly or indirectly through a conductive material while being in contact with the sheath part of the piezoelectric element. 5. A state in which the piezoelectric element is fixed to the signal metal terminal by another part of the signal metal terminal or a component fixed to the signal metal terminal in Any one or all of the piezoelectric fibers in the sheath within 5 mm from the connecting portion between the core and the signal metal terminal have lost the fiber shape and are fused. The piezoelectric element as described.
7). A conductive material made of solder or conductive paste and electrically connected to the core portion is provided on the surface of the sheath portion, and the conductive material provided on the surface of the sheath portion and the signal metal The piezoelectric element according to any one of the above 1 to 6, wherein the core and the signal metal terminal are indirectly electrically connected by contact with the terminal.
8). A piezoelectric element comprising a fabric including the piezoelectric element according to any one of 1 to 7 above, wherein the signal metal terminal or the shield metal terminal is within 10 mm in length from a portion fixed to the piezoelectric element. In the range, a piezoelectric element in which at least a part of the piezoelectric element is fixed to a fabric-like substrate.
9. Two or more piezoelectric elements according to any one of the above 1 to 7 are arranged substantially in parallel, and two or more signal metal terminals connected to the respective piezoelectric elements are collected in one connector housing. The piezoelectric element according to any one of the above 1 to 8, wherein the piezoelectric element is connectable to another connector in a lump.
10. 9. The piezoelectric element according to 9 above, wherein two or more of the piezoelectric elements according to any one of 1 to 7 are arranged substantially in parallel as part of a yarn constituting a woven fabric or a knitted fabric.
11. The piezoelectric fiber contains polylactic acid as a main component,
The piezoelectric element according to any one of 1 to 10, wherein a winding angle of the piezoelectric fiber with respect to the conductive fiber is 15 ° or more and 75 ° or less.
12 The total fineness of the said piezoelectric fiber is a piezoelectric element as described in any one of said 1-11 which is 1 to 20 times the total fineness of the said conductive fiber.
13. The piezoelectric element according to any one of 1 to 12, wherein a fineness per one of the piezoelectric fibers is 1/20 or more and 2 or less of a total fineness of the conductive fibers.
14 The piezoelectric element according to any one of 8 to 10, further including a conductive fiber that intersects and contacts at least a part of the piezoelectric element.
15. 15. The piezoelectric element according to 14, wherein the conductive fiber constitutes 30% or more of the fibers intersecting with the piezoelectric element.
16. The piezoelectric element according to any one of 1 to 15 above,
Amplifying means for amplifying an electric signal output from the piezoelectric element in accordance with an applied pressure;
Output means for outputting the electrical signal amplified by the amplification means;
A device comprising:

  According to the present invention, it is possible to provide a piezoelectric element with a fibrous terminal that can extract a large electric signal even with a stress caused by a relatively small deformation and can further suppress a noise signal.

It is a schematic diagram which shows the structural example of the braided piezoelectric element which concerns on embodiment. It is a schematic diagram which shows the example of a connection of the braided piezoelectric element which concerns on embodiment (mode A), and metal terminals. It is a schematic diagram which shows the example of a connection of the braided piezoelectric element and metal terminal which concern on embodiment (mode B fork shape). It is a schematic diagram which shows the example of a connection of the braided piezoelectric element and metal terminal which concern on embodiment (mode B needle shape). It is a schematic diagram which shows the structural example of the fabric-like piezoelectric element which concerns on embodiment. It is a block diagram which shows a device provided with the piezoelectric element which concerns on embodiment. It is a schematic diagram which shows the structural example of a device provided with the fabric-like piezoelectric element which concerns on embodiment. It is a schematic diagram which shows the other structural example of a device provided with the fabric-like piezoelectric element which concerns on embodiment.

(Braided piezoelectric element)
FIG. 1 is a schematic diagram illustrating a configuration example of a braided piezoelectric element according to the embodiment.
The braided piezoelectric element 1 covers the core 3 formed of the conductive fiber B, the sheath 2 formed of the braided piezoelectric fiber A so as to cover the core 3, and the sheath 2. And a conductive layer 4.
The coverage of the sheath 2 by the conductive layer 4 is preferably 25% or more. Here, the coverage is the ratio of the area of the conductive region contained in the conductive layer 4 and the surface area of the sheath 2 when the conductive layer 4 is projected onto the sheath 2, and its value is preferably 25% or more, It is more preferably 50% or more, and further preferably 75% or more. If the coverage of the conductive layer 4 is less than 25%, the noise signal suppressing effect may not be sufficiently exhibited. When the conductive region is not exposed to the surface of the conductive layer 4, for example, when the sheath portion 2 is covered by using a fiber that encloses the conductive region as the conductive layer 4, go to the sheath portion 2 of the fiber. The ratio of the projected area to the surface area of the sheath 2 can be defined as the coverage.

  An electroconductive area | region is a part which bears the electroconductivity contained in the electroconductive layer 4, for example, refers to the electroconductive fiber part at the time of comprising the electroconductive layer 4 with an electroconductive fiber and an insulating fiber.

  In the braided piezoelectric element 1, a large number of piezoelectric fibers A densely surround the outer peripheral surface of at least one conductive fiber B. Although not bound by a specific theory, when the braided piezoelectric element 1 is deformed, a stress due to the deformation is generated in each of the many piezoelectric fibers A, thereby generating an electric field in each of the many piezoelectric fibers A. (Piezoelectric effect) As a result, it is presumed that a voltage change in which electric fields of a large number of piezoelectric fibers A surrounding the conductive fiber B are superimposed is generated in the conductive fiber B. That is, the electrical signal from the conductive fiber B increases as compared with the case where the braided sheath 2 of the piezoelectric fiber A is not used. As a result, the braided piezoelectric element 1 can extract a large electric signal even by a stress generated by a relatively small deformation. A plurality of conductive fibers B may be used.

  Here, the piezoelectric fiber A preferably contains polylactic acid as a main component. “As a main component” means that the most component of the components of the piezoelectric fiber A is polylactic acid. The lactic acid unit in the polylactic acid is preferably 90 mol% or more, more preferably 95 mol% or more, and even more preferably 98 mol% or more.

The winding angle α of the piezoelectric fiber A with respect to the conductive fiber B is preferably 15 ° or more and 75 ° or less. That is, the winding angle α of the piezoelectric fiber A is preferably 15 ° or more and 75 ° or less with respect to the direction of the central axis CL of the conductive fiber B (core portion 3). However, in the present embodiment, the central axis CL of the conductive fiber B overlaps with the central axis (hereinafter, also referred to as “braid axis”) of the braided cord (sheath portion 2) of the piezoelectric fiber A. It can also be said that the winding angle α of the piezoelectric fiber A is preferably 15 ° or more and 75 ° or less with respect to the direction of the braid axis of A. From the viewpoint of extracting a larger electric signal, the angle α is more preferably 25 ° or more and 65 ° or less, further preferably 35 ° or more and 55 ° or less, and 40 ° or more and 50 ° or less. Particularly preferred. This is because when the angle α is out of this angle range, the electric field generated in the piezoelectric fiber A is remarkably lowered, and the electrical signal obtained from the conductive fiber B is thereby remarkably lowered.
The angle α can also be referred to as an angle formed by the main direction of the piezoelectric fiber A forming the sheath portion 2 and the central axis CL of the conductive fiber B, and a part of the piezoelectric fiber A is slackened. Or may be fuzzy.

  Here, the reason why the electric field generated in the piezoelectric fiber A is remarkably lowered is as follows. The piezoelectric fiber A has polylactic acid as a main component and is uniaxially oriented in the fiber axis direction of the piezoelectric fiber A. Here, polylactic acid generates an electric field when shear stress is generated in the orientation direction (in this case, the direction of the fiber axis of the piezoelectric fiber A), but tensile stress or compression is applied in the orientation direction. Less electric field is generated when stress occurs. Therefore, in order to generate shear stress in the piezoelectric fiber A when deformed parallel to the direction of the braid axis, the orientation direction of the piezoelectric fiber A (polylactic acid) is within a predetermined angular range with respect to the braid axis. It is speculated that it is good to be.

  In the braided piezoelectric element 1, as long as the object of the present invention is achieved, the sheath 2 may be mixed with fibers other than the piezoelectric fiber A, and the core 3 may be conductive. Mixing or the like may be performed in combination with fibers other than the fiber B.

  The length of the braided piezoelectric element composed of the core 3 of the conductive fiber B, the sheath 2 of the braided piezoelectric fiber A, and the conductive layer 4 covering the sheath 2 is not particularly limited. For example, the braided piezoelectric element may be manufactured continuously in manufacturing, and then cut to a required length for use. The length of the braided piezoelectric element is 1 mm to 10 m, preferably 5 mm to 2 m, more preferably 1 cm to 1 m. If the length is too short, the convenience of the fiber shape will be lost, and if the length is too long, it will be necessary to consider the resistance value of the conductive fiber B.

Hereinafter, each configuration will be described in detail.
(Conductive fiber)
As the conductive fiber B, any known fiber may be used as long as it exhibits conductivity. As the conductive fiber B, for example, metal fiber, fiber made of a conductive polymer, carbon fiber, fiber made of a polymer in which a fibrous or granular conductive filler is dispersed, or conductive on the surface of a fibrous material. The fiber which provided the layer which has is mentioned. Examples of the method for providing a conductive layer on the surface of the fibrous material include a metal coat, a conductive polymer coat, and winding of conductive fibers. Among these, a metal coat is preferable from the viewpoint of conductivity, durability, flexibility and the like. Specific methods for coating the metal include vapor deposition, sputtering, electrolytic plating, and electroless plating, but plating is preferable from the viewpoint of productivity. Such a metal-plated fiber can be referred to as a metal-plated fiber.

  As a base fiber coated with a metal, a known fiber can be used regardless of conductivity, for example, polyester fiber, nylon fiber, acrylic fiber, polyethylene fiber, polypropylene fiber, vinyl chloride fiber, aramid fiber, In addition to synthetic fibers such as polysulfone fibers, polyether fibers and polyurethane fibers, natural fibers such as cotton, hemp and silk, semi-synthetic fibers such as acetate, and regenerated fibers such as rayon and cupra can be used. The base fibers are not limited to these, and known fibers can be arbitrarily used, and these fibers may be used in combination.

  Any metal may be used as long as the metal coated on the base fiber exhibits conductivity and exhibits the effects of the present invention. For example, gold, silver, platinum, copper, nickel, tin, zinc, palladium, indium tin oxide, copper sulfide, and a mixture or alloy thereof can be used.

  When an organic fiber coated with metal having bending resistance is used for the conductive fiber B, the conductive fiber is hardly broken and excellent in durability and safety as a sensor using a piezoelectric element.

  The conductive fiber B may be a multifilament in which a plurality of filaments are bundled, or may be a monofilament composed of a single filament, or a single spun yarn or a bundle of a plurality of spun yarns It may be in the form (including twisted yarn) or may be a long / short composite yarn in which a filament and a spun yarn are combined. A multifilament is preferred from the viewpoint of long stability of electrical characteristics. In the case of monofilament or single spun yarn, the single yarn diameter is 1 μm to 5000 μm, preferably 2 μm to 100 μm. More preferably, it is 3 micrometers-50 micrometers. In the case of multifilaments, yarn bundles, and long and short composite yarns, the number of filaments or yarns is preferably 1 to 100,000, more preferably 5 to 500, and still more preferably 10 to 100. However, the fineness / number of the conductive fibers B is the fineness / number of the core part 3 used when producing the braid. A multifilament formed of a plurality of monofilaments also bundles a plurality of spun yarns. Both yarn bundle forms (including twisted yarns) and long and short composite yarns in which filaments and spun yarns are combined are counted as one conductive fiber B. Here, the core portion 3 is the total amount including the fibers other than the conductive fibers.

  If the diameter of the fiber is small, the strength is reduced and handling becomes difficult, and if the diameter is large, flexibility is sacrificed. The cross-sectional shape of the conductive fiber B is preferably a circle or an ellipse from the viewpoint of the design and manufacture of the piezoelectric element, but is not limited thereto.

Moreover, in order to efficiently extract the electrical output from the piezoelectric polymer, the electrical resistance is preferably low, and the volume resistivity is preferably 10 ⁻¹ Ω · cm or less, more preferably 10 ⁻² Ω · cm. cm or less, more preferably 10 ⁻³ Ω · cm or less. However, the resistivity of the conductive fiber B is not limited to this as long as sufficient strength can be obtained by detection of the electric signal.

The conductive fiber B must be resistant to movement such as repeated bending and twisting from the use of the present invention. As the index, one having a greater nodule strength is preferred. The nodule strength can be measured by the method of JIS L1013: 2010 8.6. The degree of knot strength suitable for the present invention is preferably 0.5 cN / dtex or more, more preferably 1.0 cN / dtex or more, and further preferably 1.5 cN / dtex or more. 2.0 cN / dtex or more is most preferable. As another index, one having a smaller bending rigidity is preferred. The bending rigidity is generally measured by a measuring device such as KES-FB2 pure bending tester manufactured by Kato Tech Co., Ltd. The degree of bending rigidity suitable for the present invention is preferably smaller than the carbon fiber “Tenax” (registered trademark) HTS40-3K manufactured by Toho Tenax Co., Ltd. Specifically, the bending stiffness of the conductive fiber is preferably 0.05 × 10 ⁻⁴ N · m ² / m or less, and preferably 0.02 × 10 ⁻⁴ N · m ² / m or less. More preferably, it is more preferably 0.01 × 10 ⁻⁴ N · m ² / m or less.

(Piezoelectric fiber)
As the piezoelectric polymer that is the material of the piezoelectric fiber A, a polymer exhibiting piezoelectricity such as polyvinylidene fluoride or polylactic acid can be used. However, in the present embodiment, the piezoelectric fiber A is used as a main component as described above. It is preferred to include polylactic acid. Polylactic acid, for example, is easily oriented by drawing after melt spinning and exhibits piezoelectricity, and is excellent in productivity in that it does not require an electric field alignment treatment required for polyvinylidene fluoride and the like. However, this is not intended to exclude the use of polyvinylidene fluoride or other piezoelectric materials in the practice of the present invention.

  As polylactic acid, depending on its crystal structure, poly-L-lactic acid obtained by polymerizing L-lactic acid and L-lactide, D-lactic acid, poly-D-lactic acid obtained by polymerizing D-lactide, and those There are stereocomplex polylactic acid having a hybrid structure, and any of them can be used as long as it exhibits piezoelectricity. From the viewpoint of high piezoelectricity, poly-L-lactic acid and poly-D-lactic acid are preferable. Since poly-L-lactic acid and poly-D-lactic acid are reversed in polarization with respect to the same stress, they can be used in combination according to the purpose.

  The optical purity of polylactic acid is preferably 99% or more, more preferably 99.3% or more, and further preferably 99.5% or more. If the optical purity is less than 99%, the piezoelectricity may be remarkably lowered, and it may be difficult to obtain a sufficient electrical signal due to the shape change of the piezoelectric fiber A. In particular, the piezoelectric fiber A preferably contains poly-L-lactic acid or poly-D-lactic acid as a main component, and the optical purity thereof is preferably 99% or more.

  The piezoelectric fiber A containing polylactic acid as a main component is drawn at the time of production and is uniaxially oriented in the fiber axis direction. Furthermore, the piezoelectric fiber A is not only uniaxially oriented in the fiber axis direction but also preferably contains polylactic acid crystals, and more preferably contains uniaxially oriented polylactic acid crystals. This is because polylactic acid exhibits higher piezoelectricity due to its high crystallinity and uniaxial orientation.

Crystallinity and uniaxial orientation are determined by homo PLA crystallinity X _homo (%) and crystal orientation Ao (%). As the piezoelectric fiber A of the present invention, the homo PLA crystallinity X _homo (%) and the crystal orientation degree Ao (%) preferably satisfy the following formula (1).
X _homo × Ao × Ao ÷ 10 ⁶ ≧ 0.26 (1)
If the above formula (1) is not satisfied, the crystallinity and / or uniaxial orientation is not sufficient, and the output value of the electric signal with respect to the operation may decrease, or the sensitivity of the signal with respect to the operation in a specific direction may decrease. is there. The value on the left side of the formula (1) is more preferably 0.28 or more, and further preferably 0.3 or more. Here, each value is obtained according to the following.

Homopolylactic acid crystallinity X _homo :
The homopolylactic acid crystallinity X _homo is obtained from crystal structure analysis by wide angle X-ray diffraction analysis (WAXD). In wide-angle X-ray diffraction analysis (WAXD), an X-ray diffraction pattern of a sample is recorded on an imaging plate under the following conditions by a transmission method using an Ultrax 18 type X-ray diffractometer manufactured by Rigaku.
X-ray source: Cu-Kα ray (confocal mirror)
Output: 45kV x 60mA
Slit: 1st: 1mmΦ, 2nd: 0.8mmΦ
Camera length: 120mm
Accumulation time: 10 minutes Sample: 35 mg of polylactic acid fibers are aligned to form a 3 cm fiber bundle.
In the obtained X-ray diffraction pattern, the _total scattering intensity I _total is obtained over the azimuth angle, and here, the integration of each diffraction peak derived from the homopolylactic acid crystal appearing near 2θ = 16.5 °, 18.5 °, 24.3 °. _Find the sum of the intensity ΣI _HMi . From these values, the homopolylactic acid crystallinity X _homo is determined according to the following formula (2).
Homopolylactic acid crystallinity X _homo (%) = ΣI _HMi / I _total × 100 (2)
Note that ΣI _HMi is calculated by subtracting diffuse scattering due to background and amorphous in the total scattering intensity.

(2) Crystal orientation degree Ao:
Regarding the crystal orientation degree Ao, in the X-ray diffraction pattern obtained by the above wide-angle X-ray diffraction analysis (WAXD), the diffraction peak derived from the homopolylactic acid crystal appearing in the vicinity of 2θ = 16.5 ° in the radial direction is oriented. The intensity distribution with respect to the angle (°) is taken, and the total half-value width Σ _Wi (°) of the obtained distribution profile is calculated from the following equation (3).
Crystal orientation degree Ao (%) = (360−ΣW _i ) ÷ 360 × 100 (3)

  In addition, since polylactic acid is a polyester that is hydrolyzed relatively quickly, in the case where heat and humidity resistance is a problem, a known hydrolysis inhibitor such as an isocyanate compound, an oxazoline compound, an epoxy compound, or a carbodiimide compound is added. Also good. Further, if necessary, the physical properties may be improved by adding an antioxidant such as a phosphoric acid compound, a plasticizer, a photodegradation inhibitor, and the like.

  Polylactic acid may be used as an alloy with other polymers. However, if polylactic acid is used as the main piezoelectric polymer, it contains at least 50% by mass or more based on the total mass of the alloy. Preferably, it is 70 mass% or more, Most preferably, it is 90 mass% or more.

  Examples of the polymer other than polylactic acid in the case of alloy include polybutylene terephthalate, polyethylene terephthalate, polyethylene naphthalate copolymer, polymethacrylate, and the like, but the invention is not limited thereto. Any polymer may be used as long as the desired piezoelectricity is exhibited.

  The piezoelectric fiber A may be a multifilament in which a plurality of filaments are bundled, or may be a monofilament composed of a single filament, or may be a single spun yarn or a bundle of a plurality of spun yarns. It may be in the form (including twisted yarn) or may be a long / short composite yarn in which a filament and a spun yarn are combined. In the case of a monofilament or one spun yarn, the single yarn diameter is 1 μm to 5 mm, preferably 5 μm to 2 mm, more preferably 10 μm to 1 mm. In the case of multifilament, yarn bundle form, and long / short composite yarn, the single yarn diameter is 0.1 μm to 5 mm, preferably 2 μm to 100 μm, more preferably 3 μm to 50 μm. The number of filaments or yarns of the multifilament, yarn bundle form, and long / short composite yarn is preferably 1 to 100,000, more preferably 50 to 50,000, and still more preferably 100 to 20,000. However, the fineness and the number of the piezoelectric fibers A are the fineness and the number per carrier when producing the braid, and the multifilament formed by a plurality of monofilaments also bundles a plurality of spun yarns. Both yarn bundle forms (including twisted yarns) and long and short composite yarns in which filaments and spun yarns are combined are counted as one piezoelectric fiber A. Here, even if a fiber other than the piezoelectric fiber is used in one carrier, the total amount including that is used.

  In order to use such a piezoelectric polymer as the piezoelectric fiber A, any known technique for forming a fiber from the polymer can be employed as long as the effects of the present invention are exhibited. For example, a method of extruding a piezoelectric polymer to form a fiber, a method of melt-spinning a piezoelectric polymer to make a fiber, a method of making a piezoelectric polymer fiber by dry or wet spinning, a method of making a piezoelectric polymer A technique of forming fibers by electrostatic spinning, a technique of cutting thinly after forming a film, and the like can be employed. As these spinning conditions, a known method may be applied according to the piezoelectric polymer to be employed, and a melt spinning method that is industrially easy to produce is usually employed. Furthermore, after forming the fiber, the formed fiber is stretched. As a result, a piezoelectric fiber A that is uniaxially oriented and exhibits large piezoelectricity including crystals is formed.

  In addition, the piezoelectric fiber A can be subjected to treatments such as dyeing, twisting, blending, and heat treatment before making the braided braid as described above.

  Furthermore, since the piezoelectric fiber A may be broken when the braid is formed, the piezoelectric fiber A may be cut off or fluff may come out, so that the strength and wear resistance are preferably high. It is preferably 5 cN / dtex or more, more preferably 2.0 cN / dtex or more, further preferably 2.5 cN / dtex or more, and most preferably 3.0 cN / dtex or more. The abrasion resistance can be evaluated by JIS L1095 9.10.2 B method, etc., and the number of friction is preferably 100 times or more, more preferably 1000 times or more, and further preferably 5000 times or more. Most preferably, it is 10,000 times or more. The method for improving the wear resistance is not particularly limited, and any known method can be used. For example, the crystallinity is improved, fine particles are added, or the surface is processed. Can do. In addition, when processing into braids, a lubricant can be applied to the fibers to reduce friction.

Moreover, it is preferable that the shrinkage rate of the piezoelectric fiber is small from the shrinkage rate of the conductive fiber described above. If the difference in shrinkage rate is large, the braid may bend due to heat treatment during post-fabrication after fabric production or after fabric production or during actual use, or due to changes over time, the flatness of the fabric may deteriorate, or the piezoelectric signal will become weak. May end up. When the shrinkage rate is quantified by the boiling water shrinkage rate described later, it is preferable that the boiling water shrinkage rate S (p) of the piezoelectric fiber and the boiling water shrinkage rate S (c) of the conductive fiber satisfy the following formula (4). .
| S (p) −S (c) | ≦ 10 (4)
The left side of the above formula (4) is more preferably 5 or less, and even more preferably 3 or less.

Further, it is preferable that the contraction rate of the piezoelectric fiber is small in difference from the contraction rate of fibers other than the conductive fibers, for example, insulating fibers. If the difference in shrinkage rate is large, the braid may bend due to heat treatment during post-fabrication after fabric production or after fabric production or during actual use, or due to changes over time, the flatness of the fabric may deteriorate, or the piezoelectric signal will become weak. May end up. When the shrinkage rate is quantified by the boiling water shrinkage rate, it is preferable that the boiling water shrinkage rate S (p) of the piezoelectric fiber and the boiling water shrinkage rate S (i) of the insulating fiber satisfy the following formula (5).
| S (p) −S (i) | ≦ 10 (5)
The left side of the above formula (5) is more preferably 5 or less, and even more preferably 3 or less.

Further, it is preferable that the shrinkage rate of the piezoelectric fiber is small. For example, when the shrinkage rate is quantified by boiling water shrinkage rate, the shrinkage rate of the piezoelectric fiber is preferably 15% or less, more preferably 10% or less, further preferably 5% or less, and most preferably 3% or less. is there. As a means for lowering the shrinkage rate, any known method can be applied. For example, the shrinkage rate can be reduced by relaxing the orientation of the amorphous part or increasing the crystallinity by heat treatment, and the heat treatment is performed. The timing is not particularly limited, and examples thereof include after stretching, after twisting, after braiding, and after forming into a fabric. In addition, the above-mentioned boiling water shrinkage shall be measured with the following method. A casserole of 20 times was made with a measuring machine having a frame circumference of 1.125 m, a load of 0.022 cN / dtex was applied, it was hung on a scale plate, and the initial casket length L0 was measured. After that, this casserole was treated in a boiling water bath at 100 ° C. for 30 minutes, allowed to cool, and again subjected to the above load, suspended on a scale plate, and the shrinkage casket length L was measured. Using the measured L0 and L, the boiling water shrinkage is calculated by the following equation (6).
Boiling water shrinkage = (L0−L) / L0 × 100 (%) (6)

(Coating)
The surface of the conductive fiber B, that is, the core portion 3 is covered with the piezoelectric fiber A, that is, the braided sheath portion 2. The thickness of the sheath part 2 covering the conductive fiber B is preferably 1 μm to 10 mm, more preferably 5 μm to 5 mm, further preferably 10 μm to 3 mm, most preferably 20 μm to 1 mm. preferable. If it is too thin, there may be a problem in terms of strength. If it is too thick, the braided piezoelectric element 1 may become hard and difficult to deform. In addition, the sheath part 2 said here refers to the layer adjacent to the core part 3. FIG.

In the braided piezoelectric element 1, the total fineness of the piezoelectric fibers A in the sheath 2 is preferably not less than 1/2 times and not more than 20 times the total fineness of the conductive fibers B in the core 3. 15 times or less, more preferably 2 times or more and 10 times or less. If the total fineness of the piezoelectric fiber A is too small relative to the total fineness of the conductive fiber B, the piezoelectric fiber A surrounding the conductive fiber B is too small and the conductive fiber B cannot output a sufficient electrical signal, Furthermore, there exists a possibility that the conductive fiber B may contact the other conductive fiber which adjoins. If the total fineness of the piezoelectric fiber A is too large relative to the total fineness of the conductive fiber B, there are too many piezoelectric fibers A surrounding the conductive fiber B, and the braided piezoelectric element 1 becomes hard and difficult to deform. That is, in any case, the braided piezoelectric element 1 does not sufficiently function as a sensor.
The total fineness referred to here is the sum of the finenesses of all the piezoelectric fibers A constituting the sheath portion 2. For example, in the case of a general 8-strand braid, it is the sum of the finenesses of 8 fibers.

  In the braided piezoelectric element 1, the fineness per piezoelectric fiber A of the sheath 2 is preferably 1/20 or more and 2 or less the total fineness of the conductive fiber B. It is more preferably 15 times or more and 1.5 times or less, and further preferably 1/10 time or more and 1 time or less. If the fineness per piezoelectric fiber A is too small with respect to the total fineness of the conductive fiber B, the piezoelectric fiber A is too small and the conductive fiber B cannot output a sufficient electric signal. A may be cut off. If the fineness per piezoelectric fiber A is too large relative to the total fineness of the conductive fiber B, the piezoelectric fiber A is too thick and the braided piezoelectric element 1 becomes hard and difficult to deform. That is, in any case, the braided piezoelectric element 1 does not sufficiently function as a sensor.

  In addition, when a metal fiber is used for the conductive fiber B, or when the metal fiber is mixed with the conductive fiber A or the piezoelectric fiber B, the fineness ratio is not limited to the above. This is because, in the present invention, the ratio is important in terms of contact area and coverage, that is, area and volume. For example, when the specific gravity of each fiber exceeds 2, it is preferable that the ratio of the average cross-sectional area of the fiber is the ratio of the fineness.

  Although it is preferable that the piezoelectric fiber A and the conductive fiber B are as close as possible, an anchor layer or an adhesive layer is provided between the conductive fiber B and the piezoelectric fiber A in order to improve the adhesiveness. May be.

  The covering method is a method in which the conductive fiber B is used as a core yarn, and the piezoelectric fiber A is wound around in a braid shape around the conductive fiber B. On the other hand, the shape of the braid of the piezoelectric fiber A is not particularly limited as long as an electric signal can be output with respect to the stress generated by the applied load. A braided string is preferred.

  The shape of the conductive fiber B and the piezoelectric fiber A is not particularly limited, but is preferably as close to a concentric circle as possible. When a multifilament is used as the conductive fiber B, the piezoelectric fiber A only needs to be covered so that at least a part of the surface (fiber peripheral surface) of the multifilament of the conductive fiber B is in contact. The piezoelectric fibers A may or may not be coated on all filament surfaces (fiber peripheral surfaces) constituting the multifilament. What is necessary is just to set suitably the covering state of the piezoelectric fiber A to each internal filament which comprises the multifilament of the conductive fiber B, considering the performance as a piezoelectric element, the handleability, etc.

  The braided piezoelectric element 1 of the present invention does not need to have an electrode on the surface thereof, so that there is no need to further cover the braided piezoelectric element 1 itself, and there is an advantage that malfunction is unlikely.

(Conductive layer)
As an aspect of the conductive layer 4, in addition to coating, a film, a fabric, and a fiber may be wound, or they may be combined.

  The coating for forming the conductive layer 4 may be any coating containing a substance exhibiting conductivity, and any known one may be used. For example, a metal, a conductive polymer, and a polymer in which a conductive filler is dispersed can be given.

  When the conductive layer 4 is formed by winding a film, a film obtained by forming a conductive polymer and a polymer dispersed with a conductive filler is used, and a conductive layer is provided on the surface. A film may be used.

  In the case where the conductive layer 4 is formed by winding a fabric, a fabric having a conductive fiber 6 described later as a constituent component is used.

  In the case where the conductive layer 4 is formed by winding a fiber, a cover ring, a knitted fabric, or a braid can be considered as the technique. Moreover, the fiber used is the conductive fiber 6, and the conductive fiber 6 may be the same type as the conductive fiber B or a different type of conductive fiber. Examples of the conductive fiber 6 include metal fibers, fibers made of a conductive polymer, carbon fibers, fibers made of a polymer in which a fibrous or granular conductive filler is dispersed, or conductive on the surface of the fibrous material. The fiber which provided the layer which has is mentioned. Examples of the method for providing a conductive layer on the surface of the fibrous material include a metal coat, a conductive polymer coat, and winding of conductive fibers. Among these, a metal coat is preferable from the viewpoint of conductivity, durability, flexibility and the like. Specific methods for coating the metal include vapor deposition, sputtering, electrolytic plating, electroless plating, and the like, but plating is preferable from the viewpoint of productivity. Such a metal-plated fiber can be referred to as a metal-plated fiber.

  As a base fiber coated with a metal, a known fiber can be used regardless of conductivity, for example, polyester fiber, nylon fiber, acrylic fiber, polyethylene fiber, polypropylene fiber, vinyl chloride fiber, aramid fiber, In addition to synthetic fibers such as polysulfone fibers, polyether fibers and polyurethane fibers, natural fibers such as cotton, hemp and silk, semi-synthetic fibers such as acetate, and regenerated fibers such as rayon and cupra can be used. The base fibers are not limited to these, and known fibers can be arbitrarily used, and these fibers may be used in combination.

  Any metal may be used as long as the metal coated on the base fiber exhibits conductivity and exhibits the effects of the present invention. For example, gold, silver, platinum, copper, nickel, tin, zinc, palladium, indium tin oxide, copper sulfide, and a mixture or alloy thereof can be used.

  When the metal fiber-coated organic fiber having bending resistance is used for the conductive fiber 6, the conductive fiber is hardly broken and excellent in durability and safety as a sensor using a piezoelectric element.

  The conductive fiber 6 may be a multifilament in which a plurality of filaments are bundled, or may be a monofilament composed of a single filament, or may be a single spun yarn or a bundle of a plurality of spun yarns. It may be in the form (including twisted yarn) or may be a long / short composite yarn in which a filament and a spun yarn are combined. A multifilament is preferred from the viewpoint of long stability of electrical characteristics. In the case of monofilament or single spun yarn, the single yarn diameter is 1 μm to 5000 μm, preferably 2 μm to 100 μm. More preferably, it is 3 micrometers-50 micrometers. In the case of multifilaments, yarn bundles, and long and short composite yarns, the number of filaments or yarns is preferably 1 to 100,000, more preferably 5 to 500, and still more preferably 10 to 100.

  If the diameter of the fiber is small, the strength is reduced and handling becomes difficult, and if the diameter is large, flexibility is sacrificed. The cross-sectional shape of the conductive fiber 6 is preferably a circle or an ellipse from the viewpoint of design and manufacture of the piezoelectric element, but is not limited thereto.

In order to enhance the noise signal suppression effect, the electrical resistance is preferably low, and the volume resistivity is preferably 10 ⁻¹ Ω · cm or less, more preferably 10 ⁻² Ω · cm or less, and still more preferably. Is 10 ⁻³ Ω · cm or less. However, the resistivity is not limited as long as a noise signal suppressing effect can be obtained.

The conductive fiber 6 must be resistant to movement such as repeated bending and twisting from the application of the present invention. As the index, one having a greater nodule strength is preferred. The nodule strength can be measured by the method of JIS L1013 8.6. The degree of knot strength suitable for the present invention is preferably 0.5 cN / dtex or more, more preferably 1.0 cN / dtex or more, and further preferably 1.5 cN / dtex or more. 2.0 cN / dtex or more is most preferable. As another index, one having a smaller bending rigidity is preferred. The bending rigidity is generally measured by a measuring device such as KES-FB2 pure bending tester manufactured by Kato Tech Co., Ltd. The degree of bending rigidity suitable for the present invention is preferably smaller than the carbon fiber “Tenax” (registered trademark) HTS40-3K manufactured by Toho Tenax Co., Ltd. Specifically, the flexural rigidity of the conductive fiber is preferably 0.05 × 10 ⁻⁴ N · m ² / m or less, and preferably 0.02 × 10 ⁻⁴ N · m ² / m or less. More preferably, it is more preferably 0.01 × 10 ⁻⁴ N · m ² / m or less.

(Terminal)
The braided piezoelectric element 1 of the present invention further includes a signal metal terminal connected and fixed to the core portion, and a shield metal terminal connected and fixed to the conductive layer 4 provided around the sheath portion. The signal metal terminal and the shield metal terminal are fixed to each other via an insulator, and these two metal terminals can be handled as an integrated connector part, so the connection to a circuit for processing signals is simple. It is possible to reliably and reliably reduce noise.
In addition, it is preferable that the shielding metal terminal covers and holds the signal metal terminal via an insulator from the viewpoint of reducing noise entering at the terminal portion. Covering here means that the metal terminal for shielding is placed close to the signal metal terminal, and in that state it is projected on the front view, rear view, left side view, right side view, plan view and bottom view. In this case, the ratio of the area where the shield metal terminal regions overlap is 50% or more of the total area of the signal metal terminal regions in each figure. In addition, you may provide the opening part and insulator required in order to connect another terminal and the metal terminal for signals.

The signal metal terminal of the braided piezoelectric element 1 of the present invention is preferably connected and fixed to the core portion in one of the following modes A and B.
A) Part of the signal metal terminal grips a portion of the fiber constituting the end portion of the braided piezoelectric element of 0.5 mm or longer, and in the grip portion or a place within 1 mm from the grip portion, A state in which the core portion of the braided piezoelectric element and the signal metal terminal are connected and fixed directly or indirectly through a conductive material.
B) A part of the signal metal terminal is fork-like or needle-like, and the fork-like part or needle-like part is in direct contact with the conductive fiber of the core part or while being in contact with the sheath part of the braided piezoelectric element. The braided piezoelectric element is connected to the signal metal by another part of the signal metal terminal or a part fixed to the signal metal terminal at a location within 10 mm from the connection location, indirectly connected through the material. A state fixed to the terminal made of.

(Connection by mode A)
FIG. 2 (mode A) is a schematic diagram showing a configuration example of the connection mode A according to the embodiment.
The piezoelectric fiber and the conductive fiber constituting the end of the braided piezoelectric element are held by a holding portion which is a part of the signal metal terminal. The gripped state refers to a state in which the braided piezoelectric element is sandwiched or wound by the grip portion of the signal metal terminal and fixed to each other. A structure in which the signal metal terminal formed into a nail shape is plastically deformed by a tool to be in the gripped state, and a state in which the signal metal terminal is engaged by an engagement portion provided in the metal terminal or the insulating portion; The following structure is preferably employed. The signal metal terminal has a shape that can be connected to another terminal on the right side of FIG. The signal metal terminal is fixed to the shield metal terminal via an insulator, and the shield metal terminal is arranged to cover the signal metal terminal. The shield metal terminal has a grip portion, and the conductive layer 4 is gripped by the grip portion to be electrically connected and fixed to the conductive layer 4.
As the connector parts that can make such connections, the coaxial connectors disclosed in JP-A-4-282580, JP-A-2002-324636, JP-A-2012-79652, and the like can be suitably used.

  The gripping portion of the signal metal terminal is preferably 0.5 mm or more. If the length is shorter than this, the braided piezoelectric element and the signal metal terminal are not easily fixed, and various forces are required for wearable device applications. Is added to the element, the braided piezoelectric element and the signal metal terminal may be separated or the electrical connection may become unstable. The length of the grip portion is more preferably 0.7 mm or more, and further preferably 1.0 mm or more. Here, the length of the gripping portion is the length of the braided piezoelectric element gripped by the signal metal terminal, and is the length measured in the length direction of the braided piezoelectric element. When the braided piezoelectric element is gripped at a plurality of positions as shown in FIG. 2, the total length of the gripped portions is obtained.

  The core portion of the braided piezoelectric element and the signal metal terminal are connected directly or indirectly via a conductive material at the grip portion of the signal metal terminal or a location within 1 mm from the grip portion. Although not particularly shown in FIG. 2, as described later in the present invention, it is preferable that the sheath of the braided piezoelectric element is not broken at the fixed portion with the signal metal terminal. Even in the case, the sheath is not completely removed, and the core part of the braided piezoelectric element and the signal are removed by partial removal by melting of the sheath and application of a conductive material such as solder or conductive paste. It enables metal terminals to be electrically connected. However, even when the sheath is unraveled by cutting or removing the sheath at the end of the braided piezoelectric element, the insulator that fixes the signal metal terminal sufficiently holds the sheath, However, this is not the case when it can be considered that the sheath is not unraveled, that is, when it does not become a harmful noise source.

(Connection by aspect B)
FIG. 3 (mode B fork shape) is a schematic diagram showing a configuration example of a connection mode using a signal metal terminal provided with the fork-shaped portion of mode B according to the embodiment. FIG. 4 (mode B needle shape) is a schematic diagram illustrating a configuration example of a connection mode using a signal metal terminal including the needle-shaped portion of the mode B according to the embodiment.
3 and 4, as shown in the respective cross-sectional views, the fork-like portion or the needle-like portion which is a part of the signal metal terminal is in contact with the sheath portion of the braided piezoelectric element while conducting the core portion. It is directly connected to the conductive fiber or indirectly through a conductive material. The signal metal terminal has a shape that can be connected to another terminal on the right side of each figure. The signal metal terminal is fixed to the shield metal terminal via an insulator, and the shield metal terminal is arranged to cover the signal metal terminal. The shield metal terminal has a grip portion, and the conductive layer 4 is gripped by the grip portion to be electrically connected and fixed to the conductive layer 4.
A stack type cable connector disclosed in Japanese Patent Application Laid-Open No. 2006-277960 can be suitably used as a connector component capable of such connection.

  In the aspect B, when the fixing force of the braided piezoelectric element only by the fork-like portion or the needle-like portion of the signal metal terminal is insufficient, another part of the signal metal terminal or the signal metal The braided piezoelectric element is preferably fixed to the signal metal terminal also by a component fixed to the terminal. Moreover, it is preferable that such an additional fixing | fixed part exists in the place within 10 mm from the connection location of the metal terminal for signals, and the conductive fiber of a core part. If there is an additional fixing part only at a part exceeding 10mm from the connection point, the entire braided piezoelectric element that is not fixed and the sheath part that is unwound by the signal metal terminal move unstable due to impact on the sensor, etc. Can cause In order to fix the braided piezoelectric element by another part of the signal metal terminal or by a part fixed to the signal metal terminal, the braided piezoelectric element is attached to a part of the signal metal terminal as in the mode A. The braided piezoelectric element is sandwiched and held by parts such as a resin housing fixed to the signal metal terminal, or is fixed to the signal metal terminal or the signal metal terminal by an adhesive. More preferably, it is fixed to the parts.

  In FIGS. 3 and 4, as an example of an additional fixing part, an insulator is provided as an exterior of the signal metal terminal, and the braided piezoelectric element is sandwiched and held by the left part of the insulator in the figure, The fixed part is a part fixed to the signal metal terminal. As shown in the cross-sectional views of FIGS. 3 and 4, the insulator is divided into two parts, an upper part and a lower part, and the upper part of the insulator may be fixed in advance to a signal metal terminal. When connecting and fixing the braided piezoelectric element to the signal metal terminal, sandwich the braided piezoelectric element between the signal metal terminal fixed to the upper part of the insulator and the lower part of the insulator, and further apply force from above and below It is preferable that the signal metal terminal is inserted into the braided piezoelectric element and the upper and lower insulators are fixed in contact with each other. Therefore, the fork-like part or the needle-like part of the signal metal terminal has the thinness or thinness necessary for being inserted between the fibers of the piezoelectric fiber of the sheath part, or the piezoelectric fiber of the sheath part It is preferable to have the sharpness necessary for partially cutting the substrate. One signal metal terminal may have a plurality of fork-like portions or a plurality of needle-like portions, or may have a fork-like portion and a needle-like portion at the same time. When using a signal metal terminal having a fork-shaped part, if the thickness of the sheath part is too thick or if the total fineness of the core part is too low, the fork-shaped part will be difficult to contact the core part. It is preferably 1 mm or less, more preferably 0.5 mm or less, and the total fineness of the core is preferably 50 dTex or more, more preferably 100 dTex or more.

(Terminal connection)
The braided piezoelectric element of the present invention has a piezoelectric fiber that is separated from the core portion by unraveling the tissue of the sheath portion at the end of the portion fixed by the signal metal terminal or the component fixed to the signal metal terminal. It is preferable to have a portion that is less than 20% of the entire piezoelectric fiber of the sheath portion. If it exceeds 20%, the piezoelectric fiber away from the core portion moves in an unstable manner due to an impact on the sensor or the like, so that a piezoelectric signal is randomly generated and causes noise. The portion where the braided piezoelectric element is fixed by the signal metal terminal or the component fixed to the signal metal terminal is the portion held by the signal metal terminal in the mode A, or the signal metal in the mode B The braided piezoelectric element is formed by a part in which the fork-like portion and the needle-like portion of the manufactured terminal are in contact with the sheath portion of the braided piezoelectric element, or a part such as a resin housing fixed to the signal metal terminal in the modes A and B Indicates a portion in which the braided piezoelectric element is fixed to a signal metal terminal or a component fixed to the signal metal terminal by an adhesive. The end refers to a region within 1 mm from the boundary between the fixed part and the non-fixed part. When the tissue of the sheath part is unwound and separated from the core part, the piezoelectric fiber of the sheath part reaches from the core part surface to a place where the distance is 1.5 times or more the average thickness of the sheath part of the braided piezoelectric element. It is determined for each piezoelectric fiber (that is, fiber supplied from one carrier when creating a braid). When the piezoelectric fiber of the sheath part is a multifilament, 50% or more of the filaments constituting one piezoelectric fiber is a distance of 1.5 times or more the average thickness of the sheath part of the braided piezoelectric element from the core surface. 1, it is determined that one piezoelectric fiber is separated from the core portion by unraveling the tissue of the sheath portion. The determination may be observed from the side surface of the braided piezoelectric element, or a cross section may be observed. When observing the cross section, it is cut and observed after being fixed with an epoxy resin or the like so that the sheath portion is not unraveled excessively at the time of cutting.

  The signal metal terminal of the element of the present invention may be fixed to the end of the braided piezoelectric element as shown in FIG. 2 (mode A), FIG. 3 (mode B fork) and FIG. 4 (mode B needle). It can also be fixed in the middle of the braided piezoelectric element.

  In order to achieve the purpose of suppressing noise derived from piezoelectricity, the element of the present invention fixes the signal metal terminal without removing the fiber of the sheath portion of the braid which is an insulating coating, and also the core portion and the signal metal It has a seemingly contradictory structure that ensures electrical connection of the manufactured terminals. The following two examples are given as structures for achieving this.

  As an example of the structure, a structure in which a part of or all of the piezoelectric fibers in the sheath portion within 5 mm from the connecting portion between the core portion and the signal metal terminal and the sheath is lost and fused is preferably employed. . That is, when the piezoelectric fiber constituting the sheath portion after fixing the signal metal terminal is melted, the piezoelectric fiber of the sheath portion that prevents the electrical connection between the signal metal terminal and the core portion is caused to flow, and the signal metal After securing the electrical connection between the manufactured terminal and the core portion, the piezoelectric fiber can be solidified and fixed again by cooling or the like. The solid solidified after the piezoelectric fiber is melted has an advantage that the braided piezoelectric element and the signal metal terminal can be fixed like an adhesive. Further, when a polymer fiber such as polylactic acid is used as the piezoelectric fiber, the solid that has been solidified after melting loses piezoelectricity, and therefore does not become a noise source. Piezoelectric fibers can be melted by heat treatment at a temperature of 160 ° C. or higher when polylactic acid fibers are used. However, unnecessary decomposition of polylactic acid and unnecessary melting of the sheath and deformation of other members are prevented. Therefore, it is preferable to carry out at 220 ° C. or lower. The melting of the piezoelectric fiber can also be performed when the signal metal terminal is fixed, and it is preferable to increase the gripping pressure of the signal metal terminal while confirming whether the electrical connection is secured. In order to prevent deformation of the sheath part, it is preferable to heat the signal metal terminal to transmit heat to the sheath part and to melt it. From the viewpoint of process safety and the ability to process a plurality of elements at the same time, it is also preferable to carry out after attaching the signal metal terminal.

  As another example of the structure, the sheath surface is made of a conductive material made of solder or conductive paste and electrically connected to the core, and the sheath material is made of a conductive material and a signal metal. A structure in which the core and the signal metal terminal are indirectly connected by contacting the terminal can be exemplified. The conductive material has a function of interposing between the core portion and the signal metal terminal and electrically conducting, and from a liquid state (including slurry) to a solid state by temperature change, solvent removal, or chemical reaction. Any material can be used as long as it changes, and a conductive paste containing a conductive filler such as solder, metal or carbon is preferably used. In particular, solder and silver paste are preferably used from the viewpoint of handleability and conductivity. Since the braided piezoelectric element of the present invention is an aggregate of fibers with an insulation coating, the conductive surface is infiltrated by adhering the above-mentioned conductive material from the surface, and the conductive surface electrically connected to the core portion is the sheath surface. However, in order to make the electrical connection with the core more reliable, adjust the fluidity before solidifying the conductive material to make it easier to penetrate the core, or before solidifying the conductive material It is preferable to apply a physical stimulus to the braided piezoelectric element to widen the gap between the fibers in the sheath, or to attach a conductive material to the cut surface at the end of the braided piezoelectric element.

(Fixing to base material)
In the braided piezoelectric element of the present invention, at least a part of the braided piezoelectric element is a cloth within a range of 10 mm or less from the portion where the signal metal terminal or the shield metal terminal is fixed to the braided piezoelectric element. It is preferable to be fixed to the substrate. When there is no place fixed to the cloth-like base material within 10 mm, the braided piezoelectric element that is not fixed moves unstable due to an impact on the cloth-like base material and the metal terminal, and causes noise. The fixing to the cloth-like substrate may be performed by post-processing such as adhesion and sewing, or may be fixed by weaving or knitting as a yarn constituting the fabric structure.

(Production method)
In the braided piezoelectric element 1 of the present invention, the surface of at least one conductive fiber B is covered with the braided piezoelectric fiber A. Examples of the manufacturing method include the following methods. In other words, the conductive fiber B and the piezoelectric fiber A are produced in separate steps, and the conductive fiber B is wrapped around the conductive fiber B in a braid shape and covered. In this case, it is preferable to coat so as to be as concentric as possible.

  In this case, as preferred spinning and stretching conditions when polylactic acid is used as the piezoelectric polymer for forming the piezoelectric fiber A, the melt spinning temperature is preferably 150 ° C. to 250 ° C., and the stretching temperature is preferably 40 ° C. to 150 ° C. The draw ratio is preferably 1.1 to 5.0 times, and the crystallization temperature is preferably 80 ° C to 170 ° C.

  As the piezoelectric fiber A to be wound around the conductive fiber B, a multifilament in which a plurality of filaments are bundled may be used, a monofilament may be used, or a single spun yarn or a plurality of spun yarns may be used. Bundles of yarns (including twisted yarns) may be used, and long and short composite yarns combining filaments and spun yarns may be used. Moreover, as the conductive fiber B around which the piezoelectric fiber A is wound, a multifilament in which a plurality of filaments are bundled may be used, or a monofilament may be used. Further, a single spun yarn, a yarn bundle form (including twisted yarn) in which a plurality of spun yarns are bundled, or a long / short composite yarn in which a filament and a spun yarn are combined may be used.

  As a preferable form of the coating, the conductive fiber B can be used as a core yarn, and the piezoelectric fiber A can be formed in a braid shape around the conductive fiber B to form a round braid. . More specifically, an 8-strand braid having 16 cores and a 16-strand braid are included. However, for example, the piezoelectric fiber A may be shaped like a braided tube, and the conductive fiber B may be used as a core and inserted into the braided tube.

  The conductive layer 4 is manufactured by coating or fiber winding, but fiber winding is preferable from the viewpoint of ease of manufacturing. As a method for winding the fiber, a cover ring, a knitted fabric, and a braid are conceivable, and any method may be used.

  By the manufacturing method as described above, the braided piezoelectric element 1 in which the surface of the conductive fiber B is covered with the braided piezoelectric fiber A and the conductive layer 4 is provided around the surface can be obtained.

  Since the braided piezoelectric element 1 of the present invention does not require the formation of an electrode for detecting an electric signal on the surface, it can be manufactured relatively easily.

(Protective layer)
A protective layer may be provided on the outermost surface of the braided piezoelectric element 1 of the present invention. This protective layer is preferably insulative, and more preferably made of a polymer from the viewpoint of flexibility. In the case of providing the protective layer with insulation, of course, in this case, the entire protective layer is deformed or rubbed on the protective layer, but these external forces reach the piezoelectric fiber A, There is no particular limitation as long as it can induce polarization. The protective layer is not limited to those formed by coating with a polymer or the like, and may be a film, fabric, fiber or the like, or a combination thereof.

  The thinner the protective layer is, the easier it is to transmit shear stress to the piezoelectric fiber A. However, if it is too thin, problems such as destruction of the protective layer itself are likely to occur, and preferably 10 nm to 200 μm. More preferably, they are 50 nm-50 micrometers, More preferably, they are 70 nm-30 micrometers, Most preferably, they are 100 nm-10 micrometers. The shape of the piezoelectric element can also be formed by this protective layer.

  Furthermore, a plurality of layers made of piezoelectric fibers can be provided, or a plurality of layers made of conductive fibers for extracting signals can be provided. Of course, the order and the number of layers of these protective layers, layers made of piezoelectric fibers, and layers made of conductive fibers are appropriately determined according to the purpose. In addition, as a method of winding, the method of forming a braid structure in the outer layer of the sheath part 2, or covering it is mentioned.

(Function)
The braided piezoelectric element 1 of the present invention is, for example, a stress generated when a load is applied to the braided piezoelectric element 1 by rubbing the surface of the braided piezoelectric element 1, that is, a stress applied to the braided piezoelectric element 1. It can be used as a sensor for detecting the size and / or application position. In addition, the braided piezoelectric element 1 of the present invention can take out an electrical signal as long as shear stress is applied to the piezoelectric fiber A by pressing force other than rubbing or bending deformation. For example, the “applied stress” to the braided piezoelectric element 1 includes the frictional force between the surface of the piezoelectric element, that is, the surface of the piezoelectric fiber A and the surface of the contacted object such as a finger, or the piezoelectric fiber. Examples thereof include a resistance force in the vertical direction with respect to the surface or tip of A and a resistance force against bending deformation of the piezoelectric fiber A. In particular, the braided piezoelectric element 1 of the present invention can efficiently output a large electric signal when bent or rubbed in a parallel direction with respect to the conductive fiber B.

  Here, the “applied stress” applied to the braided piezoelectric element 1 is, for example, approximately 1-1000 Pa as a guide when the stress is of a magnitude that rubs the surface with a finger. Of course, it goes without saying that the magnitude of the applied stress and the position of the applied stress can be detected even if it is more than this. When inputting with a finger or the like, it is preferable to operate even with a load of 1 Pa to 500 Pa, and more preferable to operate with a load of 1 Pa to 100 Pa. Of course, as described above, it operates even with a load exceeding 500 Pa.

  It is also possible to detect deformation due to pressure applied to the braided piezoelectric element 1 by measuring the capacitance change between the conductive fiber B and the conductive layer 4 at the core of the braided piezoelectric element 1. become. Further, when a plurality of braided piezoelectric elements 1 are used in combination, the pressure applied to the braided piezoelectric element 1 is measured by measuring the capacitance change between the conductive layers 4 of each braided piezoelectric element 1. It is also possible to detect deformation due to.

(Fabric piezoelectric element)
FIG. 5 is a schematic diagram illustrating a configuration example of a fabric-like piezoelectric element using the braided piezoelectric element according to the embodiment.
The cloth-like piezoelectric element 7 includes a cloth 8 including at least one braided piezoelectric element 1. The fabric 8 is not limited as long as at least one of the fibers (including the braid) constituting the fabric is the braided piezoelectric element 1 and the braided piezoelectric element 1 can exhibit the function as a piezoelectric element. Any woven or knitted fabric may be used. In forming the cloth, as long as the object of the present invention is achieved, weaving, knitting and the like may be performed in combination with other fibers (including braids). Of course, the braided piezoelectric element 1 may be used as a part of a fiber (for example, warp or weft) constituting the fabric, or the braided piezoelectric element 1 may be embroidered or bonded to the fabric. Good. In the example shown in FIG. 5, the fabric-like piezoelectric element 7 has at least one braided piezoelectric element 1 and insulating fibers 9 as warps and alternately has conductive fibers 10 and insulating fibers 9 as wefts. Plain woven fabric. The conductive fiber 10 may be the same type or different type of conductive fiber B, and the insulating fiber 9 will be described later. Note that all or part of the insulating fibers 9 and / or the conductive fibers 10 may be braided.

  In this case, when the cloth-like piezoelectric element 7 is deformed by bending or the like, the braided piezoelectric element 1 is also deformed along with the deformation, so that the cloth-like piezoelectric element 7 is generated by an electric signal output from the braided piezoelectric element 1. Can be detected. Since the cloth-like piezoelectric element 7 can be used as a cloth (woven or knitted fabric), it can be applied to, for example, a garment-shaped wearable sensor.

  Further, in the fabric-like piezoelectric element 7 shown in FIG. 5, the conductive fiber 10 intersects and contacts the braided piezoelectric element 1. Therefore, the conductive fiber 10 intersects and covers at least a part of the braided piezoelectric element 1, covers it, and shields at least a part of the electromagnetic wave going to the braided piezoelectric element 1 from the outside. Can be seen. Such a conductive fiber 10 has a function of reducing the influence of electromagnetic waves on the braided piezoelectric element 1 by being grounded. That is, the conductive fiber 10 can function as an electromagnetic wave shield for the braided piezoelectric element 1. Accordingly, for example, the S / N ratio (signal-to-noise ratio) of the cloth-like piezoelectric element 7 can be remarkably improved without overlapping the conductive cloth for electromagnetic wave shielding on and under the cloth-like piezoelectric element 7. In this case, from the viewpoint of electromagnetic shielding, the higher the proportion of the conductive fibers 10 in the wefts (in the case of FIG. 5) intersecting the braided piezoelectric element 1, the better. Specifically, 30% or more of the fibers forming the fabric 8 and intersecting the braided piezoelectric element 1 are preferably conductive fibers 10, more preferably 40% or more, and 50% or more. Is more preferable. Thus, in the cloth-like piezoelectric element 7, the cloth-like piezoelectric element 7 having an electromagnetic wave shielding function can be obtained by inserting the conductive fiber 10 as at least a part of the fibers constituting the cloth.

  Examples of the woven structure of the woven fabric include a three-layer structure such as plain weave, twill weave, and satin weave, a change structure, a single double structure such as a vertical double weave and a horizontal double weave, and a vertical velvet. The type of knitted fabric may be a circular knitted fabric (weft knitted fabric) or a warp knitted fabric. Preferable examples of the structure of the circular knitted fabric (weft knitted fabric) include flat knitting, rubber knitting, double-sided knitting, pearl knitting, tuck knitting, floating knitting, one-side knitting, lace knitting, and bristle knitting. Examples of the warp knitting structure include single denby knitting, single atlas knitting, double cord knitting, half tricot knitting, back hair knitting, jacquard knitting, and the like. The number of layers may be a single layer or a multilayer of two or more layers. Further, it may be a napped woven fabric or a napped knitted fabric composed of a napped portion made of a cut pile and / or a loop pile and a ground tissue portion.

(Multiple piezoelectric elements)
In the cloth-like piezoelectric element 7, a plurality of braided piezoelectric elements 1 can be used side by side. For example, the braided piezoelectric elements 1 may be used for all warps or wefts, or the braided piezoelectric elements 1 may be used for several or a part of them. Alternatively, the braided piezoelectric element 1 may be used as a warp in a certain part, and the braided piezoelectric element 1 may be used as a weft in another part.

  Further, when a plurality of braided piezoelectric elements 1 are used side by side, since the distance between the conductive fibers B is short, it is efficient in taking out an electric signal. Particularly in the present invention, a plurality of metal terminals connected to each braided piezoelectric element are fixed together in one connector housing to form a connector having a plurality of poles, and a connector having a plurality of other poles collectively. By making the connection possible, it is possible to increase the efficiency of device manufacture and to facilitate connection and removal by the user, which is particularly preferable. By incorporating it into the fabric or knitted fabric as described above, it is possible to easily arrange a plurality of braided piezoelectric elements approximately in parallel at a desired interval, and easily fix each metal terminal to the connector. There are advantages you can do. Here, “substantially parallel” means that the fibers are bent such as two adjacent warps constituting a plain woven fabric and two adjacent courses constituting a tentacle knitting. When drawing straight lines that average, they are parallel. At this time, by adjusting the weaving density and the knitting density, it is preferable to adjust the distance between the plurality of braided piezoelectric elements to the terminal distance of a connector often used in an electronic circuit. 0.5 mm, 1.0 mm, 1.25 mm, 1 It is more preferable to adjust the distance to any one of distances of 0.5 mm, 2.0 mm, and 2.54 mm (distance between the centers of braids). Also, a plurality of metal terminals are connected to a plurality of braided piezoelectric elements at a time using a connector having a fork-like portion of mode B and having a plurality of metal terminals fixed to one connector housing in advance. Is particularly preferable from the viewpoint of simplification of the process.

(Insulating fiber)
In the cloth-like piezoelectric element 7, insulating fibers can be used for portions other than the braided piezoelectric element 1 (and the conductive fiber 10). At this time, the insulating fiber may be a stretchable material or a fiber having a shape for the purpose of improving the flexibility of the cloth-like piezoelectric element 7.

  In this way, by arranging the insulating fiber in addition to the braided piezoelectric element 1 (and the conductive fiber 10), the operability of the cloth-like piezoelectric element 7 (e.g., ease of movement as a wearable sensor) is improved. It is possible to make it.

As such an insulating fiber, it can be used if the volume resistivity is 10 ⁶ Ω · cm or more, more preferably 10 ⁸ Ω · cm or more, and further preferably 10 ¹⁰ Ω · cm or more.

Insulating fibers such as polyester fibers, nylon fibers, acrylic fibers, polyethylene fibers, polypropylene fibers, vinyl chloride fibers, aramid fibers, polysulfone fibers, polyether fibers, polyurethane fibers, etc., cotton, hemp, silk, etc. Natural fibers, semi-synthetic fibers such as acetate, and regenerated fibers such as rayon and cupra can be used. It is not limited to these, A well-known insulating fiber can be used arbitrarily. Furthermore, these insulating fibers may be used in combination, or may be combined with a fiber having no insulating property to form a fiber having insulating properties as a whole.
Also, any known cross-sectional shape fiber can be used.

(Applied technology for piezoelectric elements)
The piezoelectric element such as the braided piezoelectric element 1 or the cloth-like piezoelectric element 7 of the present invention can output the contact, pressure, and shape change to the surface as an electric signal in any form. It can be used as a sensor (device) for detecting the magnitude of stress applied to the element and / or the applied position. Further, the electric signal can be used as a power generation element such as a power source for moving other devices or storing electricity. Specifically, power generation by using it as a moving part of a human, animal, robot, machine, etc. that moves spontaneously, power generation on the surface of a shoe sole, rug, or structure that receives pressure from the outside, shape change in fluid Power generation, etc. In addition, in order to generate an electrical signal due to a shape change in the fluid, it is possible to adsorb a chargeable substance in the fluid or suppress adhesion.

  FIG. 6 is a block diagram showing a device 11 including the piezoelectric element 12 of the present invention. The device 11 includes a piezoelectric element 12 (example: braided piezoelectric element 1, fabric-like piezoelectric element 7), an amplifying means 13 for amplifying an electrical signal output from the piezoelectric element 12 in accordance with an applied pressure, and an amplifying means. 13 is provided with output means 14 for outputting the electric signal amplified at 13, and transmission means 15 for transmitting the electric signal output from the output means 14 to an external device (not shown). If this device 11 is used, the stress applied to the piezoelectric element is calculated by an arithmetic process in an external device (not shown) based on an electrical signal output by contact with the surface of the piezoelectric element 12, pressure, or shape change. The magnitude and / or applied position can be detected. Alternatively, calculation means (not shown) for calculating the magnitude of the stress applied to the piezoelectric element 12 and / or the applied position based on the electrical signal output from the output means 14 may be provided in the device 11. Good. Whether the transmission method by the transmission means 15 is wireless or wired may be appropriately determined according to the sensor to be configured.

  Further, not only the amplification means but also known signal processing means such as noise removing means and means for processing in combination with other signals can be used in combination. The order of connection of these means can be appropriately changed according to the purpose. Of course, the electric signal output from the piezoelectric element 12 may be processed as it is after being transmitted to the external device as it is.

  7 and 8 are schematic views showing a configuration example of a device including the braided cloth-like piezoelectric element according to the embodiment. The amplifying unit 13 in FIGS. 7 and 8 corresponds to that described with reference to FIG. 6, but the output unit 14 and the transmitting unit 15 in FIG. 6 are not shown in FIGS. 7 and 8. When a device including the fabric-like piezoelectric element 7 is configured, a lead wire from the core portion 3 of the braided piezoelectric element 1 is connected to the input terminal of the amplifying means 13, and the braided piezoelectric element 1 is connected to the ground (earth) terminal. A braided piezoelectric element different from the braided piezoelectric element 1 connected to the conductive layer 4 or the conductive fiber 10 of the cloth-like piezoelectric element 7 or the input terminal of the amplifying means 13 is connected. For example, as shown in FIG. 7, in the cloth-like piezoelectric element 7, the lead wire from the core portion 3 of the braided piezoelectric element 1 is connected to the input terminal of the amplifying means 13, and the conductive layer 4 of the braided piezoelectric element 1 is connected. Ground (earth). Instead of the conductive layer 4 of the braided piezoelectric element 1, the conductive fiber 10 that intersects and contacts the braided piezoelectric element 1 may be grounded. Further, for example, as shown in FIG. 8, when a plurality of braided piezoelectric elements 1 are arranged in the cloth-like piezoelectric element 7, the lead wire from the core portion 3 of one braided piezoelectric element 1 is used as the input terminal of the amplifying means 13. The lead wire from the core part 3 of another braided piezoelectric element 1 aligned with the braided piezoelectric element 1 is grounded (grounded).

  Since the device 11 of the present invention is flexible and can be used in either a string form or a cloth form, a very wide range of applications can be considered. Specific examples of the device 11 of the present invention include a touch panel, a human or animal surface pressure sensor, for example, a glove or a band, which has a shape such as a hat, gloves, clothes including a sock, a supporter, or a handkerchief. Sensors that detect bending, twisting, and expansion / contraction of joints shaped like supporters. For example, when used for humans, it can be used as an interface for detecting contact and movement, collecting information on movement of joints and the like for medical purposes, amusement purposes, and moving lost tissues and robots. In addition, it can be used as a stuffed animal that imitates animals and humanoids, a surface pressure sensor of a robot, a sensor that detects bending, twisting, and expansion / contraction of a joint. In addition, it can be used as a surface pressure sensor or shape change sensor for bedding such as sheets and pillows, shoe soles, gloves, chairs, rugs, bags, and flags.

  Furthermore, since the device 11 of the present invention is braided or cloth-like and flexible, it can be used as a surface pressure sensor or a shape change sensor by sticking or covering the whole or part of the surface of any structure. Can do.

  Furthermore, since the device 11 of the present invention can generate a sufficient electric signal simply by rubbing the surface of the braided piezoelectric element 1, it can be used for a touch input device such as a touch sensor, a pointing device, or the like. . Further, since the position information and shape information in the height direction of the measurement object can be obtained by rubbing the surface of the measurement object with the braided piezoelectric element 1, it can be used for surface shape measurement and the like.

  Hereinafter, the present invention will be described more specifically by way of examples. However, the present invention is not limited to these examples.

The fabric for piezoelectric elements was manufactured by the following method.
(Manufacture of polylactic acid)
The polylactic acid used in the examples was produced by the following method.
To 100 parts by mass of L-lactide (manufactured by Musashino Chemical Laboratory, Inc., optical purity 100%), 0.005 part by mass of tin octylate was added, and 180 ° C. in a reactor equipped with a stirring blade in a nitrogen atmosphere. Then, 1.2 times equivalent of phosphoric acid was added to tin octylate, and then the remaining lactide was removed under reduced pressure at 13.3 Pa to obtain chips to obtain poly-L-lactic acid (PLLA1). . The obtained PLLA1 had a mass average molecular weight of 152,000, a glass transition point (Tg) of 55 ° C., and a melting point of 175 ° C.

(Piezoelectric fiber)
PLLA1 melted at 240 ° C. was discharged from a 24-hole cap at 20 g / min and taken up at 887 m / min. This unstretched multifilament yarn was stretched 2.3 times at 80 ° C. and heat-set at 100 ° C. to obtain a multifilament uniaxially stretched yarn of 84 dTex / 24 filament.

(Conductive fiber)
Silver-plated nylon manufactured by Mitsufuji Corporation, product name “AGposs” 100d34f was used as conductive fiber B, conductive fiber 6 and conductive fiber 10. The volume resistivity of this fiber was 1.1 × 10 ⁻³ Ω · cm.

(Insulating fiber)
Polyethylene terephthalate melted at 280 ° C. was discharged from a 24-hole cap at 45 g / min and taken up at 800 m / min. The undrawn yarn was drawn at 80 ° C. and 2.5 times, and heat-fixed at 180 ° C. to obtain a multifilament drawn yarn of 84 dTex / 24 filament.

(Braided piezoelectric element)
As a sample of Example 1, as shown in FIG. 1, the conductive fiber B is used as a core yarn, and the eight piezoelectric fibers A are wound around the core yarn in a braid shape to form an eight-ply braid. Further, the conductive fiber 6 was wound around the piezoelectric fiber A in the sheath portion in an eight-strand braid form to form the conductive layer 4, and the braided piezoelectric element 1 was formed. Here, the winding angle α of the piezoelectric fiber A with respect to the fiber axis CL of the conductive fiber B was 45 °. The coverage of the conductive layer 4 of the sample of Example 1 was 100%. The braided piezoelectric element is cut, and the conductive fiber 6 constituting the conductive layer 4 having a terminal end of 10 mm is loosened and separated from the piezoelectric fiber A and the conductive fiber B, and then the SH connector manufactured by Nippon Crimp Terminal Manufacturing Co., Ltd. After the contact is made of a signal metal terminal, the 0.4 mm long portion and the 0.8 mm long claw portion are bent, and the piezoelectric fiber A and the conductive fiber B remaining at the end of the braided piezoelectric element are gripped. The soldering iron was applied to the signal metal terminal and heated to partially melt the sheath portion of the grip portion. The electrical connection between the terminal core of the braided piezoelectric element and the signal metal terminal was confirmed, and the excess braided piezoelectric element ahead of the grip portion was cut. Also, another Japan Crimp Terminal Manufacturing SH connector contact is used as a shield metal terminal, and a 0.4 mm long portion and a 0.8 mm long claw portion are bent, and the piezoelectric fiber A and the conductive fiber. The conductive fiber 6 separated from B was gripped. The conductive fiber 6 separated from the piezoelectric fiber A without being gripped by the shielding metal terminal was excised. The signal metal terminal and the shield metal terminal are inserted and fixed in the SH connector housing 2P manufactured by Nippon Crimp Terminal Manufacturing Co., Ltd., and insulated around the braided piezoelectric element 1 10 mm from the end face of the connector housing. An epoxy-based adhesive was attached to fix the SH connector and the braided piezoelectric element 1. This braided piezoelectric element with a terminal was used as a braided piezoelectric element 101.

  As a sample of Example 2, as shown in FIG. 1, the conductive fiber B is used as a core yarn, and the eight piezoelectric fibers A are wound around the core yarn in a braid shape to form an eight-punch braid. Further, four insulating fibers 9 are wound clockwise, one conductive fiber 6 and three insulating fibers 9 are wound around the piezoelectric fiber A of the sheath portion in a left-handed manner, and the conductive layer 4 in the form of an eight-strand braid. Thus, a braided piezoelectric element 1 was formed. Here, the winding angle α of the piezoelectric fiber A with respect to the fiber axis CL of the conductive fiber B was 45 °. Moreover, the coverage of the conductive layer 4 of the sample of Example 2 was 25%. As in Example 1, the SH connector contact manufactured by Nippon Crimp Terminal Manufacturing Co., Ltd. is connected to the conductive fiber B as a signal metal terminal, and the SH connector manufactured by Nippon Crimp Terminal Manufacturing Co., Ltd. is connected to the conductive fiber 6. The contact is connected as a shield metal terminal, and the signal metal terminal and the shield metal terminal are inserted into the SH connector housing 2P manufactured by Japan Crimp Terminal Manufacturing Co., Ltd. and fixed, and a braid of 10 mm from the connector housing end face An insulating epoxy adhesive was attached around the piezoelectric element 1 to fix the SH connector and the braided piezoelectric element 1. This braided piezoelectric element with terminals was used as a braided piezoelectric element 102.

  As a sample of Example 3, the braided piezoelectric element 1 to which the terminal used in Example 1 is not connected is cut, and the conductive fiber 6 constituting the conductive layer 4 of the terminal 10 mm is loosened to be electrically conductive with the piezoelectric fiber A. After separating from the conductive fiber B, “Dotite” (registered trademark) D-363 (manufactured by Fujikura Kasei Co., Ltd.) is attached as a conductive paste to the piezoelectric fiber A and the conductive fiber B remaining at the end of the braided piezoelectric element. After being allowed to solidify, using a SH connector contact made by Nippon Crimp Terminal Manufacturing Co., Ltd. as a signal metal terminal, the 0.4 mm long part and 0.8 mm long claw part are bent and the conductive paste is attached The end of the piezoelectric element was gripped. The continuity between the core portion at the other end of the braided piezoelectric element and the signal metal terminal was confirmed. Also, another Japan Crimp Terminal Manufacturing SH connector contact is used as a shield metal terminal, and a 0.4 mm long portion and a 0.8 mm long claw portion are bent, and the piezoelectric fiber A and the conductive fiber. The conductive fiber 6 separated from B was gripped, and the conductive fiber 6 separated from the piezoelectric fiber A without being gripped by the shielding metal terminal was excised. The above-mentioned signal metal terminal and shield metal terminal are inserted and fixed in SH connector housing 2P manufactured by Nippon Crimp Terminal Manufacturing Co., Ltd. An epoxy is placed around braided piezoelectric element 1 10 mm from the end face of the connector housing. A system adhesive was attached, and the SH connector and the braided piezoelectric element 1 were fixed. This braided piezoelectric element with a terminal was used as a braided piezoelectric element 103.

  As a sample of Example 4, the braided piezoelectric element 1 to which the terminal used in Example 1 is not connected is cut, and the conductive fiber 6 constituting the conductive layer 4 of the terminal 10 mm is loosened to be electrically conductive with the piezoelectric fiber A. After separating from the conductive fiber B, “Dotite” (registered trademark) D-363 (manufactured by Fujikura Kasei Co., Ltd.) is attached as a conductive paste to the piezoelectric fiber A and the conductive fiber B remaining at the end of the braided piezoelectric element. Then, 2 mm was inserted into the center contact of the SMA-P coaxial connector and solidified to make a signal metal terminal, and the continuity between the core of the other end of the braided piezoelectric element and the signal metal terminal was confirmed. . Further, the metal sheath of the SMA-P type coaxial connector is used as a shield metal terminal, and the conductive fiber 6 separated from the piezoelectric fiber A and the conductive fiber B is gripped and connected and fixed by a sleeve, for shielding. The conductive fiber 6 separated from the piezoelectric fiber A without being gripped by the metal terminal was excised. As described above, the braided piezoelectric element 104 with a terminal in which the signal metal terminal and the shield metal terminal are integrated via an insulator is referred to as a braided piezoelectric element 104. The SMA-P connector used in this example has a structure in which the shield metal terminal (exterior) completely covers the signal metal terminal (center contact) in the left side view.

  As a sample of Example 5, two insulating fibers 9 and braided piezoelectric elements 1 (same as the sample in which the terminal of Example 1 is not connected) are arranged on the warp as shown in FIG. 9 and conductive fibers 10 were alternately arranged to produce a plain woven fabric, and a cloth-like piezoelectric element 7 was obtained. After loosening the conductive fibers 6 constituting the conductive layer 4 of 10 mm from the ends of the two braided piezoelectric elements 1 in the fabric-like piezoelectric elements 7 and separating them from the piezoelectric fibers A and B, the piezoelectric fibers From the OMRON XG pressure connector 10 poles, the two fork-shaped metal parts are pointed into the exposed parts of A and used as signal metal terminals. At the same time, from the piezoelectric fiber A and the conductive fiber B The separated conductive fibers 6 were put together, and the conductive fiber bundle was inserted into one pole of a fork-shaped metal portion of the 10 electrodes of the pressure contact connector to form a shield metal terminal. Further, the braided piezoelectric element is sandwiched and fixed between the upper part of the connector housing fixed to the metal part and the lower part which is paired with the upper part. Conduction between the terminal core of the two braided piezoelectric elements 1 and the two-pole signal metal terminal, and between the conductive layer 4 of the braided piezoelectric element 1 and the one-pole shield metal terminal In this case, the insulation between the two-pole signal metal terminal and the one-pole shield metal terminal was confirmed. These two braided piezoelectric elements with signal metal terminals were designated as braided piezoelectric elements 105-1 and 105-2, respectively. The braided piezoelectric element was fixed by the warp of the plain woven fabric, and the distance between the signal metal terminal and the warp of the plain woven fabric was 0.1 mm.

  As a sample of Example 6, the braided piezoelectric element 1 to which the terminal used in Example 1 is not connected is cut, and the conductive fiber 6 constituting the conductive layer 4 of the terminal 10 mm is loosened, and the piezoelectric fiber A and the conductive material are removed. After separating from the fiber B and further loosening the piezoelectric fiber A at the end and exposing the core part by 1 mm, the sheath part was removed using the SH connector contact made by Nippon Crimp Terminal Manufacturing Co., Ltd. as the signal metal terminal. The nail portion was gripped by the nail portion having a length of 0.4 mm, and the nail portion was bent so that the nail portion having a length of 0.8 mm was held by the nail portion having a length of 0.8 mm. The continuity between the core portion at the other end of the braided piezoelectric element and the signal metal terminal was confirmed. Also, another Japan Crimp Terminal Manufacturing SH connector contact is used as a shield metal terminal, and a 0.4 mm long portion and a 0.8 mm long claw portion are bent, and the piezoelectric fiber A and the conductive fiber. The conductive fiber 6 separated from B was gripped, and the conductive fiber 6 separated from the piezoelectric fiber A without being gripped by the shielding metal terminal was excised. The signal metal terminal and the shield metal terminal were inserted and fixed in SH connector housing 2P manufactured by Nippon Crimp Terminal Manufacturing Co., Ltd. This braided piezoelectric element with terminals was used as a braided piezoelectric element 106.

  As a sample of Comparative Example 1, the braided piezoelectric element 1 whose terminal used in Example 1 is not connected is cut, and the conductive fiber 6 constituting the conductive layer 4 of the terminal 10 mm is loosened to conduct the conductive with the piezoelectric fiber A. After separating from the conductive fiber B, “Dotite” (registered trademark) D-363 (manufactured by Fujikura Kasei Co., Ltd.) is attached as a conductive paste to the piezoelectric fiber A and the conductive fiber B remaining at the end of the braided piezoelectric element. After being allowed to solidify, using a SH connector contact made by Nippon Crimp Terminal Manufacturing Co., Ltd. as a signal metal terminal, the 0.4 mm long part and 0.8 mm long claw part are bent and the conductive paste is attached The end of the piezoelectric element was gripped. The continuity between the core portion at the other end of the braided piezoelectric element and the signal metal terminal was confirmed. Also, another Japan Crimp Terminal Manufacturing SH connector contact is used as a shield metal terminal, and a 0.4 mm long portion and a 0.8 mm long claw portion are bent, and the piezoelectric fiber A and the conductive fiber. The conductive fiber 6 separated from B was gripped, and the conductive fiber 6 separated from the piezoelectric fiber A without being gripped by the shielding metal terminal was excised. The above-mentioned signal metal terminal and shield metal terminal are respectively inserted and fixed in two Japan Crimp Terminal Manufacturing SH connector housings 2P, and around the braided piezoelectric element 1 10 mm from the connector housing end face. An epoxy-based adhesive was attached to each to fix each SH connector and braided piezoelectric element 1. This braided piezoelectric element with terminals was used as a braided piezoelectric element 201.

  As a sample of Comparative Example 2, as in Example 1, the conductive fiber B was used as a core yarn, and the eight piezoelectric fibers A were wound around the core yarn in a braid form to form an eight-punch braid. However, the conductive layer 4 was not formed, and a braided piezoelectric element was formed. Here, the winding angle α of the piezoelectric fiber A with respect to the fiber axis CL of the conductive fiber B was 45 °. After bonding and solidifying “Dotite” (registered trademark) D-363 (manufactured by Fujikura Kasei Co., Ltd.) as a conductive paste to the piezoelectric fibers A and conductive fibers B at the ends of the braided piezoelectric element, manufacture of a Japan crimp terminal Using a SH connector contact manufactured by Co., Ltd. as a signal metal terminal, a 0.4 mm long portion and a 0.8 mm long claw portion were bent, and the braided piezoelectric element end to which the conductive paste was adhered was gripped. The continuity between the core portion at the other end of the braided piezoelectric element and the signal metal terminal was confirmed. The above-mentioned signal metal terminals are inserted and fixed in SH connector housing 2P manufactured by Nippon Crimp Terminal Manufacturing Co., Ltd., and an epoxy adhesive is attached around braided piezoelectric element 1 10 mm from the end face of the connector housing. The SH connector and the braided piezoelectric element 1 were fixed. This braided piezoelectric element with terminals was used as a braided piezoelectric element 202.

(Performance evaluation and evaluation results)
The performance evaluation and evaluation results of the braided piezoelectric elements 101, 102, 103, 104, 105-1, 105-2, 106, 201, 202 are as follows.

Example 1
The SH connector housing manufactured by Japan Crimp Terminal Manufacturing Co., Ltd., to which the metal terminal for signal and the metal terminal for shielding in the braided piezoelectric element 101 are fixed, is connected to the SH connector base 2P manufactured by Japan Crimp Terminal Manufacturing Co., Ltd. The signal metal terminal is connected to an oscilloscope (digital oscilloscope DL6000 series product name “DL6000” manufactured by Yokogawa Electric Corp.) via a wiring through a 1000 times amplification circuit, for shielding the braided piezoelectric element 1 The metal terminals were connected to be grounded. The braided piezoelectric element 101, the measurement circuit, and the ground were connected together by an SH connector. In addition, at the end of the gripping portion of the signal metal terminal, the piezoelectric fiber that was separated from the core portion by unraveling the tissue of the sheath portion was 0%.
As a result of bending the braided piezoelectric element 101 by 90 degrees, a potential difference of about 100 mV is detected by an oscilloscope as an output from the braided piezoelectric element 101, and a sufficiently large electric signal can be detected by deformation of the braided piezoelectric element 1. Was confirmed. Moreover, the noise signal in stationary was 20 mV, and the S / N ratio was 5, indicating that the noise signal was sufficiently suppressed.

(Example 2)
The SH connector housing manufactured by Japan Crimp Terminal Manufacturing Co., Ltd., to which the metal terminal for signal and the metal terminal for shielding in the braided piezoelectric element 102 are fixed, is connected to the SH connector base 2P manufactured by Japan Crimp Terminal Manufacturing Co., Ltd. The signal metal terminal is connected to an oscilloscope (digital oscilloscope DL6000 series product name “DL6000” manufactured by Yokogawa Electric Corp.) via a wiring through a 1000 times amplification circuit, for shielding the braided piezoelectric element 1 The metal terminals were connected to be grounded. The braided piezoelectric element 102, the measurement circuit, and the ground were connected together by an SH connector. In addition, at the end of the gripping portion of the signal metal terminal, the piezoelectric fiber that was separated from the core portion by unraveling the tissue of the sheath portion was 0%.
As a result of bending the braided piezoelectric element 102 by 90 degrees, a potential difference of about 100 mV is detected by an oscilloscope as an output from the braided piezoelectric element 102, and a sufficiently large electric signal can be detected by deformation of the braided piezoelectric element 1. Was confirmed. Moreover, the noise signal in stationary was 20 mV, and the S / N ratio was 5, indicating that the noise signal was sufficiently suppressed.

(Example 3)
The SH connector housing manufactured by Japan Crimp Terminal Manufacturing Co., Ltd., to which the metal terminal for signal and the metal terminal for shielding in the braided piezoelectric element 103 are fixed, is connected to the SH connector base 2P manufactured by Japan Crimp Terminal Manufacturing Co., Ltd. The signal metal terminal is connected to an oscilloscope (digital oscilloscope DL6000 series product name “DL6000” manufactured by Yokogawa Electric Corp.) via a wiring through a 1000 times amplification circuit, for shielding the braided piezoelectric element 1 The metal terminals were connected to be grounded. The braided piezoelectric element 103, the measurement circuit, and the ground were connected together by an SH connector. In addition, at the end of the gripping portion of the signal metal terminal, the piezoelectric fiber that was separated from the core portion by unraveling the tissue of the sheath portion was 0%.
As a result of bending the braided piezoelectric element 103 by 90 degrees, a potential difference of about 100 mV is detected by an oscilloscope as an output from the braided piezoelectric element 103, and a sufficiently large electric signal can be detected by deformation of the braided piezoelectric element 1. Was confirmed. Moreover, the noise signal in stationary was 20 mV, and the S / N ratio was 5, indicating that the noise signal was sufficiently suppressed.

Example 4
The SMA-P type coaxial connector to which the signal metal terminal and the shield metal terminal in the braided piezoelectric element 104 are fixed is connected to the SMA-J type coaxial connector, and the signal metal terminal is an oscilloscope (Yokogawa It is connected to a digital oscilloscope DL6000 series product name “DL6000” manufactured by Denki Co., Ltd. via a wiring through a 1000 × amplification circuit so that the shield metal terminal of the braided piezoelectric element 1 is grounded. Connected. The braided piezoelectric element 104 and the connection to the measurement circuit and the earth were collectively made by an SMA type connector. In addition, at the end of the gripping portion of the signal metal terminal, the piezoelectric fiber that was separated from the core portion by unraveling the tissue of the sheath portion was 0%.
As a result of bending the braided piezoelectric element 104 by 90 degrees, a potential difference of about 100 mV is detected by an oscilloscope as an output from the braided piezoelectric element 104, and a sufficiently large electric signal can be detected by deformation of the braided piezoelectric element 1. Was confirmed. Further, the noise signal in a stationary state was 16 mV, the S / N ratio was 6, and it was found that the noise signal was sufficiently suppressed.

(Example 5)
Connect XG pressure connector made by Omron Co., Ltd., to which signal metal terminal and shield metal terminal of braided piezoelectric element 105-1 and braided piezoelectric element 105-2 are fixed, to pin header of 2 rows x 5 rows The signal metal terminal is connected to an oscilloscope (digital oscilloscope DL6000 series product name “DL6000” manufactured by Yokogawa Electric Corporation) via a 1000 × amplification circuit via wiring, and the shield of the braided piezoelectric element 1 The metal terminals were connected so as to be grounded. The braided piezoelectric element 105-1 and the braided piezoelectric element 105-2 were connected to the measurement circuit and the ground collectively by an XG pressure contact connector. In addition, at the end of the fork-shaped metal portion of the signal metal terminal, the piezoelectric fibers that are separated from the core portion due to the unraveling of the sheath portion are 0 for both the braided piezoelectric element 105-1 and the braided piezoelectric element 105-2. %Met.
As a result of bending the braided piezoelectric element 105-1 and the braided piezoelectric element 105-2 by 90 degrees by bending the cloth-like piezoelectric element 7, the output from the braided piezoelectric element 105-1 and the braided piezoelectric element 105-2 is obtained. In each case, a potential difference of about 100 mV was detected by an oscilloscope, and it was confirmed that a sufficiently large electric signal could be detected by deformation of the braided piezoelectric element 1. Moreover, the noise signal in stationary was 20 mV, and the S / N ratio was 5, indicating that the noise signal was sufficiently suppressed.

(Example 6)
The SH connector housing manufactured by Japan Crimp Terminal Manufacturing Co., Ltd., to which the metal terminal for signal and the metal terminal for shielding in the braided piezoelectric element 106 are fixed, is connected to the SH connector base 2P manufactured by Japan Crimp Terminal Manufacturing Co., Ltd. The signal metal terminal is connected to an oscilloscope (digital oscilloscope DL6000 series product name “DL6000” manufactured by Yokogawa Electric Corp.) via a wiring through a 1000 times amplification circuit, for shielding the braided piezoelectric element 1 The metal terminals were connected to be grounded. The braided piezoelectric element 106 and the connection to the measurement circuit and the earth were collectively made by the SH connector. Further, at the end of the grip portion of the signal metal terminal, 75% of the piezoelectric fibers were separated from the core portion because the tissue of the sheath portion was unwound.
As a result of bending the braided piezoelectric element 106 by 90 degrees, a potential difference of about 100 mV was detected by the oscilloscope as an output from the braided piezoelectric element 106, but noise with an amplitude of about 30 mV was superimposed on the signal near the peak. Noise generation due to bending motion was confirmed. Moreover, the noise signal in stationary was 20 mV, and the S / N ratio was 5, indicating that the noise signal was sufficiently suppressed.

(Comparative Example 1)
An SH connector housing manufactured by Japan Crimp Terminal Manufacturing Co., Ltd., in which the signal metal terminals in the braided piezoelectric element 201 are fixed, and an SH connector housing manufactured by Japan Crimp Terminal Manufacturing Co., Ltd., in which the shield metal terminals are fixed, Each is connected to SH connector base 2P manufactured by Japan Crimp Terminal Manufacturing Co., Ltd., and the signal metal terminal is amplified 1000 times via wiring to an oscilloscope (Yokogawa Electric's digital oscilloscope DL6000 series product name "DL6000") They were connected via a circuit and connected so that the shield metal terminal of the braided piezoelectric element 1 was grounded. The connection to the braided piezoelectric element 201, the measurement circuit, and the ground was performed separately by the two sets of SH connectors, so the work was complicated, and the conductive fibers 6 pulled on the shielding metal terminals were frayed. In addition, at the end of the gripping portion of the signal metal terminal, the piezoelectric fiber that was separated from the core portion by unraveling the tissue of the sheath portion was 0%.
As a result of bending the braided piezoelectric element 201 by 90 degrees, a potential difference of about 100 mV is detected by an oscilloscope as an output from the braided piezoelectric element 201, and a sufficiently large electric signal can be detected by deformation of the braided piezoelectric element 1. Was confirmed. Further, the noise signal in a stationary state was 25 mV, the S / N ratio was 4, and the noise signal was not sufficiently suppressed.

(Comparative Example 2)
The SH connector housing manufactured by Japan Crimp Terminal Manufacturing Co., Ltd., to which the signal metal terminal in the braided piezoelectric element 202 is fixed, is connected to the SH connector base 2P manufactured by Japan Crimp Terminal Manufacturing Co., Ltd. Connected to an oscilloscope (digital oscilloscope DL6000 series product name “DL6000” manufactured by Yokogawa Electric Corporation) via a 1000-times amplification circuit via wiring, the noise signal in a stationary state was 1000 mV. The braided piezoelectric element 202 was bent 90 degrees, but the noise signal was large and the electric signal derived from the bending could not be determined. In addition, at the end of the gripping portion of the signal metal terminal, the piezoelectric fiber that was separated from the core portion by unraveling the tissue of the sheath portion was 0%.

DESCRIPTION OF SYMBOLS A Piezoelectric fiber B Conductive fiber 1 Braided piezoelectric element 2 Sheath part 3 Core part 4 Conductive layer 6 Conductive fiber 7 Fabric-like piezoelectric element 8 Fabric 9 Insulating fiber 10 Conductive fiber 11 Device 12 Piezoelectric element 13 Amplifying means 14 Output means 15 Transmission means CL Fiber axis α Wrapping angle 100 Plain fabric

Claims (16)

A core formed of conductive fibers;
A sheath formed of braided piezoelectric fibers so as to cover the core,
A conductive layer provided around the sheath;
A signal metal terminal connected and fixed to the core, and a shield metal terminal connected and fixed to the conductive layer, the signal metal terminal and the A piezoelectric element in which a shield metal terminal is fixed to each other through an insulator.   The piezoelectric element according to claim 1, wherein a covering ratio of the sheath portion by the conductive layer is 25% or more.   The piezoelectric element according to claim 1, wherein the conductive layer is formed of a fiber.   The piezoelectric element according to any one of claims 1 to 3, wherein the shield metal terminal covers and holds the signal metal terminal via an insulator. The signal metal terminal is connected and fixed in one of the following modes A and B, and the piezoelectric element fixed by the signal metal terminal or a component fixed to the signal metal terminal. 5. The piezoelectric fiber according to any one of claims 1 to 4, wherein at the end of the portion, the piezoelectric fibers that are untied from the core portion and have a structure that is less than 20% of the total piezoelectric fibers of the sheath portion. The piezoelectric element according to claim 1.
A) Part of the signal metal terminal grips a portion of the fiber constituting the terminal portion of the piezoelectric element having a length of 0.5 mm or more, and the grip portion or a place within 1 mm from the grip portion A state in which the core of the piezoelectric element and the signal metal terminal are electrically connected and fixed directly or indirectly through a conductive material. B) A part of the signal metal terminal is fork-shaped or needle-shaped. The fork-like part or the needle-like part is connected to the conductive fiber of the core part directly or indirectly through a conductive material while being in contact with the sheath part of the piezoelectric element. The piezoelectric element is fixed to the signal metal terminal by another part of the signal metal terminal or a part fixed to the signal metal terminal in a place within   The part or all of the piezoelectric fibers of the sheath within 5 mm from the connecting portion between the core and the signal metal terminal loses the fiber shape and is fused. The piezoelectric element described in 1.   A conductive material made of solder or conductive paste and electrically connected to the core portion is provided on the surface of the sheath portion, and the conductive material provided on the surface of the sheath portion and the signal metal The piezoelectric element according to any one of claims 1 to 6, wherein the core and the signal metal terminal are indirectly electrically connected by contact with the terminal.   In a piezoelectric element provided with the cloth containing the piezoelectric element as described in any one of Claims 1-7, within 10 mm in length from the part by which this metal terminal for signals or the metal terminal for shielding was fixed to this piezoelectric element In the range described above, a piezoelectric element in which at least a part of the piezoelectric element is fixed to a fabric-like substrate.   Two or more piezoelectric elements according to any one of claims 1 to 7 are arranged substantially in parallel, and two or more signal metal terminals connected to the respective piezoelectric elements are provided in one connector housing. The piezoelectric element as described in any one of Claims 1-8 collectively and connectable with another connector collectively.   The piezoelectric element according to claim 9, wherein two or more of the piezoelectric elements according to claim 1 are arranged substantially in parallel as part of a yarn constituting a woven fabric or a knitted fabric. The piezoelectric fiber contains polylactic acid as a main component,
The piezoelectric element according to any one of claims 1 to 10, wherein a winding angle of the piezoelectric fiber with respect to the conductive fiber is 15 ° or more and 75 ° or less. The total fineness of the piezoelectric fiber is 1 to 20 times the total fineness of the conductive fiber,
The piezoelectric element as described in any one of Claims 1-11.   The piezoelectric element according to any one of claims 1 to 12, wherein a fineness per one of the piezoelectric fibers is 1/20 or more and 2 or less of a total fineness of the conductive fibers.   The piezoelectric element according to any one of claims 8 to 10, further comprising a conductive fiber that intersects and contacts at least a part of the piezoelectric element.   The piezoelectric element according to claim 14, wherein the conductive fiber constitutes 30% or more of fibers intersecting the piezoelectric element. The piezoelectric element according to any one of claims 1 to 15,
Amplifying means for amplifying an electric signal output from the piezoelectric element in accordance with an applied pressure;
Output means for outputting the electrical signal amplified by the amplification means;
A device comprising:

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