JPWO2018181641A1 - Transducer and vibration presenting device using the same - Google Patents

Abstract

Provided is a transducer capable of reducing an adhesive layer while reducing an electrode material, and a vibration presenting device using the same. The transducer (1) includes a first electrode sheet (11) having a plurality of first through holes (11a), a second electrode sheet (12) having a plurality of second through holes (12a), and a first electrode sheet. A piezoelectric sheet (13) or a dielectric sheet (13) disposed between the first inner surface of (11) and the second inner surface of the second electrode sheet (12); A first protective sheet (14) covering one outer surface side and a second protective sheet (15) covering a second outer surface side of the second electrode sheet (12) are provided. The first protective sheet (14) adheres to the piezoelectric sheet (13) or the dielectric sheet (13) via the first through hole (11a) of the first electrode sheet (11).

Description

  The present invention relates to a transducer and a vibration presenting device using the same.

  JP-A-5-172839 discloses a piezoelectric film, two mesh-like electrodes arranged on both sides of the piezoelectric film, and two support plates made of a plate-like rigid body on both outer sides of each electrode. A piezoelectric vibration sensor comprising: Japanese Patent No. 4922482 discloses a piezoelectric woven fabric formed on a woven fabric using a cord-shaped piezoelectric fiber having a cord-shaped piezoelectric material and an electrode film formed on the surface of the piezoelectric material as a warp and a weft. A device is disclosed. Japanese Patent No. 6025854 discloses a piezoelectric element in which two conductive fibers and one piezoelectric fiber have a contact point with each other, and are formed in a woven form by three fibers.

  A piezoelectric or electrostatic transducer has a pair of electrodes. In the case where the electrode is formed of a flexible material while having a sheet shape without through holes, there is a problem that the cost of the electrode increases. By forming the electrode sheet in a mesh shape as described in JP-A-5-172839, it is possible to reduce the cost of the electrode material.

  Some transducers include a piezoelectric sheet or a dielectric sheet, electrode sheets disposed on both sides thereof, and a protective sheet made of an insulating material covering both outer surfaces thereof. The piezoelectric sheet or the dielectric sheet and the electrode sheet are bonded or integrally formed, and further, the electrode sheet and the protection sheet are bonded or integrally formed. As described above, a plurality of adhesive or integral moldings exist on one side of the piezoelectric sheet or the dielectric sheet. Therefore, it is required to reduce the number of manufacturing steps by reducing the number of adhesive layers.

  An object of the present invention is to provide a transducer capable of reducing the number of adhesive layers while reducing the number of electrode materials, and a vibration presentation device using the same.

(1. First transducer)
The first transducer according to the present invention includes a first electrode sheet having a plurality of first through holes, and a plurality of second through holes, and a second electrode sheet disposed to face the first electrode sheet. A piezoelectric sheet or a dielectric sheet disposed between at least a first inner surface of the first electrode sheet and a second inner surface of the second electrode sheet, and covering a first outer surface side of the first electrode sheet; A first protective sheet; and a second protective sheet that covers a second outer surface side of the second electrode sheet.

  As described above, the first electrode sheet includes the first through hole, and the second electrode sheet includes the second through hole. That is, the first electrode sheet and the second electrode sheet do not have the electrode material on the entire surface, but have a structure not including the electrode material in part. Therefore, the first electrode sheet and the second electrode sheet can reduce the cost by reducing the electrode material.

  Further, the first protective sheet is bonded to the piezoelectric sheet or the dielectric sheet via the first through hole of the first electrode sheet, or the second protective sheet is the second electrode sheet To the piezoelectric sheet or the dielectric sheet through the second through hole.

  The bonding of the first protective sheet to the piezoelectric sheet or the dielectric sheet can be achieved by utilizing the fact that the first electrode sheet has the first through hole. In this case, the first protective sheet adheres to the piezoelectric sheet or the dielectric sheet, so that the first electrode sheet interposed between the first protective sheet and the piezoelectric sheet or the dielectric sheet becomes the first protective sheet. Together with the piezoelectric sheet or the dielectric sheet. Therefore, the above configuration is applied as compared with the case where the adhesive layer is required both between the piezoelectric sheet or the dielectric sheet and the first electrode sheet and between the first electrode sheet and the first protective sheet. By doing so, the number of adhesive layers can be reduced. As a result, the number of manufacturing steps can be reduced, and the cost can be reduced.

  In addition, the bonding of the second protective sheet to the piezoelectric sheet or the dielectric sheet can be performed by utilizing the fact that the second electrode sheet has the second through hole. In this case, by bonding the second protective sheet to the piezoelectric sheet or the dielectric sheet, the second electrode sheet interposed between the second protective sheet and the piezoelectric sheet or the dielectric sheet becomes the second protective sheet. Together with the piezoelectric sheet or the dielectric sheet. Therefore, compared with the case where the adhesive layer is required both between the piezoelectric sheet or the dielectric sheet and the second electrode sheet, and between the second electrode sheet and the second protective sheet, the above configuration is applied. By doing so, the number of adhesive layers can be reduced. As a result, the number of manufacturing steps can be reduced, and the cost can be reduced.

(2. Second transducer)
The second transducer according to the present invention includes a first electrode sheet having a plurality of first through holes, a piezoelectric sheet or a dielectric sheet disposed at least on a first inner surface side of the first electrode sheet, A first protective sheet covering the first outer surface side of the one electrode sheet, wherein the first protective sheet is the piezoelectric sheet or the dielectric sheet via the first through hole of the first electrode sheet. Glue to Thereby, the effect by the first electrode sheet and the first protection sheet in the first transducer described above is exerted.

(3. Vibration presentation device)
The vibration presenting device according to the present invention includes a piezoelectric or electrostatic actuator, a first elastic body laminated on the actuator, and a second elastic body laminated on the opposite side of the actuator from the first elastic body. And a piezoelectric or dielectric sensor disposed around the actuator, the actuator, the first elastic body, in a state where the actuator laminate formed by the second elastic body is compressed in the laminating direction, and A cover for holding the first elastic body and the second elastic body in a state where the first elastic body and the second elastic body are compressed more than the actuator, and the pressing force in the stacking direction is applied to the cover from outside when the pressing force is applied. And a cover that transmits to a sensor and vibrates due to the vibration generated by the actuator. Then, one of the actuator and the sensor is the transducer described above. This makes it possible to reduce the cost of the vibration presenting device.

It is a top view of transducer 1 of a first embodiment. FIG. 2 is a sectional view taken along line II-II of FIG. 1. FIG. 3 is a sectional view taken along line III-III of FIG. 1. FIG. 3 is an exploded view of components of the transducer 1 shown in FIG. 2. FIG. 4 is an exploded view of components of the transducer 1 shown in FIG. 3. It is a top view of transducer 100 of a second embodiment. FIG. 7 is a sectional view taken along line VII-VII of FIG. 6. It is sectional drawing of the transducer 200 of 3rd embodiment. FIG. 9 is an exploded view of components of the transducer 200 shown in FIG. 8. It is sectional drawing of the transducer 300 of 4th Embodiment. FIG. 11 is an exploded view of components of the transducer 300 shown in FIG. It is sectional drawing of the transducer 400 of 5th Embodiment. FIG. 13 is an exploded view of components of the transducer 400 shown in FIG. It is sectional drawing of the transducer 500 of 6th Embodiment. 15 is an exploded view of components of the transducer 500 shown in FIG. It is sectional drawing of the vibration presentation apparatus 600 of 7th Embodiment. It is XVII-XVII sectional drawing of FIG. It is an exploded perspective view of three actuator units 610a, 610b, and 610c. It is an exploded perspective view of each actuator unit 610a, 610b, 610c.

(1. First embodiment)
(1-1. Outline of Transducer 1)
The transducer 1 is a piezoelectric transducer or a dielectric transducer. In the case of the piezoelectric type, the transducer 1 is an actuator that generates vibration, sound, or the like using a piezoelectric effect of a piezoelectric body, or a sensor that detects an external pushing force or the like. When the transducer 1 functions as a piezoelectric actuator, when a voltage is applied to the electrodes, the piezoelectric body is deformed, and vibration is generated with the deformation of the piezoelectric body. When the transducer 1 functions as a piezoelectric sensor, a voltage is generated between the electrodes due to the deformation of the piezoelectric body due to an external input such as a pressing force, and the voltage is detected. Detects external pushing force.

  In the case of the electrostatic type, the transducer 1 is an actuator that generates vibration, sound, or the like using a change in capacitance between electrodes, or a sensor that detects an external pressing force or the like. When the transducer 1 functions as an electrostatic actuator, when a voltage is applied to the electrodes, the dielectric is deformed in accordance with the potential between the electrodes, and vibration is generated with the deformation of the dielectric. When the transducer 1 functions as an electrostatic sensor, the dielectric material is deformed due to an external pressing force, vibration, sound, or the like, so that a voltage corresponding to the capacitance between the electrodes is generated. By detecting, an external pushing force or the like is detected.

(1-2. Configuration of Transducer 1)
The transducer 1 will be described with reference to FIGS. In the case of a piezoelectric type, the transducer 1 includes a first electrode sheet 11, a second electrode sheet 12, a piezoelectric sheet 13, a first protection sheet 14, and a second protection sheet 15. In the case of the electrostatic type, the transducer 1 includes a first electrode sheet 11, a second electrode sheet 12, a dielectric sheet 13, a first protection sheet 14, and a second protection sheet 15.

  The first electrode sheet 11 and the second electrode sheet 12 are conductive cloths. The first electrode sheet 11 and the second electrode sheet 12 have flexibility and elasticity while having conductivity. The first electrode sheet 11 and the second electrode sheet 12 are woven or non-woven fabrics formed of conductive fibers. Here, the conductive fiber is formed by coating the surface of the flexible fiber with a conductive material. The conductive fiber is formed, for example, by plating copper or nickel on the surface of a resin fiber such as polyethylene.

  The first electrode sheet 11 is provided with a plurality of first through-holes 11a (shown in FIGS. 1, 3 and 5) by forming a cloth with fibers. Similarly, the second electrode sheet 12 includes a plurality of second through holes 12a (shown in FIGS. 2 and 4).

  In the following, the case where the first electrode sheet 11 and the second electrode sheet 12 are conductive woven fabrics will be described as an example, but a conductive nonwoven fabric can also be applied. For example, as shown in FIG. 1, the first electrode sheet 11 is formed by weaving conductive fibers as warp and weft in the case of a conductive fabric. The area surrounded by the warp and the weft becomes the first through hole 11a. The same applies to the second through hole 12a.

  The first electrode sheet 11 and the second electrode sheet 12 are formed to have substantially the same size, and are arranged to face each other. Here, in the first electrode sheet 11, a surface facing the second electrode sheet 12 is referred to as a first inner surface, and a surface opposite to the second electrode sheet 12 is referred to as a first outer surface. Further, in the second electrode sheet 12, the surface facing the first electrode sheet 11 is referred to as a second inner surface, and the surface opposite to the first electrode sheet 11 is referred to as a second outer surface.

  The piezoelectric sheet 13 or the dielectric sheet 13 is formed of an elastically deformable piezoelectric or dielectric material. The piezoelectric sheet 13 or the dielectric sheet 13 is formed in a sheet shape and has the same outer shape as the outer shape of the first electrode sheet 11. The piezoelectric sheet 13 or the dielectric sheet 13 has a structure that expands and contracts in a thickness direction and expands and contracts in a plane direction along with expansion and contraction in the thickness direction. The piezoelectric sheet 13 or the dielectric sheet 13 is arranged between the first inner surface of the first electrode sheet 11 and the second inner surface of the second electrode sheet 12. The piezoelectric sheet 13 and the dielectric sheet 13 are non-adhesive but in contact with the first electrode sheet 11 and the second electrode sheet 12.

  For the first protection sheet 14 and the second protection sheet 15, a material having an insulating property is applied. In the present embodiment, the first protection sheet 14 and the second protection sheet 15 are formed of the same material as the dielectric sheet 13. That is, the first protection sheet 14 and the second protection sheet 15 are formed of an elastomer.

  The first protection sheet 14 covers the first outer surface side of the first electrode sheet 11. In the first protective sheet 14, the surface on the first electrode sheet 11 side is a surface that can be bonded. For example, an adhesive may be applied to the surface of the first protection sheet 14. The adhesive includes an adhesive directly applied to the first protective sheet 14, and a heat-weldable material (thermoplastic material) disposed on the surface side of the first protective sheet 14.

  Further, at least the surface of the first protective sheet 14 may be formed of a heat-weldable material (thermoplastic material). Of course, the first protective sheet 14 itself may be formed of a heat-sealable material. Then, the first protection sheet 14 is bonded to the first outer surface of the first electrode sheet 11, as shown in FIG.

  Further, as shown in FIG. 3, the first protective sheet 14 is bonded to the piezoelectric sheet 13 or the dielectric sheet 13 through the first through holes 11a of the first electrode sheet 11. That is, the first protection sheet 14 is bonded to the piezoelectric sheet 13 or the dielectric sheet 13 while being inserted through the first through-hole 11a. Then, by bonding the first protective sheet 14 to the piezoelectric sheet 13 or the dielectric sheet 13, the first electrode sheet 11 is locked to the first protective sheet 14 and the piezoelectric sheet 13 or the dielectric sheet 13. It is sandwiched between the body sheet 13 and the dielectric sheet 13.

  When an adhesive is applied to the first protective sheet 14, the first protective sheet 14 is adhered to the piezoelectric sheet 13 or the dielectric sheet 13 by pressing the first protective sheet 14. When a heat-sealable material (thermoplastic material) is disposed as an adhesive on the surface of the first protective sheet 14, the heat-sealable material is melted by heating and pressing the heat-sealable material. Then, the first protective sheet 14 and the piezoelectric sheet 13 or the dielectric sheet 13 are bonded to each other.

  When the first protective sheet 14 is formed of a heat-weldable material (thermoplastic material), the first protective sheet 14 is melted by pressing while heating the first protective sheet 14, It enters one through hole 11a. Thereafter, the first protection sheet 14 is solidified, so that the first protection sheet 14 adheres to the piezoelectric sheet 13 or the dielectric sheet 13.

  The second protective sheet 15 covers the second outer surface side of the second electrode sheet 12. In the second protective sheet 15, the surface on the second electrode sheet 12 side is a surface that can be bonded. For example, an adhesive may be applied to the surface of the second protective sheet 15. The adhesive includes an adhesive directly applied to the second protective sheet 15 and a heat-sealable material (thermoplastic material) disposed on the surface side of the second protective sheet 15.

  Further, at least the surface of the second protective sheet 15 may be formed of a heat-weldable material (thermoplastic material). Of course, the second protective sheet 15 itself may be formed of a heat-sealable material. Then, the second protection sheet 15 is bonded to the second outer surface of the second electrode sheet 12, as shown in FIG.

  Further, as shown in FIG. 2, the second protection sheet 15 is bonded to the piezoelectric sheet 13 or the dielectric sheet 13 via the second through holes 12a of the second electrode sheet 12. That is, the second protective sheet 15 is bonded to the piezoelectric sheet 13 or the dielectric sheet 13 while being inserted through the second through-hole 12a. Then, by bonding the second protective sheet 15 to the piezoelectric sheet 13 or the dielectric sheet 13, the second electrode sheet 12 is locked with the second protective sheet 15 and the piezoelectric sheet 13 or the dielectric sheet 13. It is sandwiched between the body sheet 13 and the dielectric sheet 13.

  When the adhesive is applied to the second protection sheet 15, the second protection sheet 15 is bonded to the piezoelectric sheet 13 or the dielectric sheet 13 by pressing the second protection sheet 15. When a heat-sealable material (thermoplastic material) is arranged as an adhesive on the surface side of the second protective sheet 15, the heat-sealable material is melted by heating and pressing the heat-sealable material. Then, the second protective sheet 15 and the piezoelectric sheet 13 or the dielectric sheet 13 are bonded to each other.

  When the second protective sheet 15 is formed of a heat-sealable material (thermoplastic material), the second protective sheet 15 is melted by pressing while heating the second protective sheet 15, It enters the two through holes 12a. Thereafter, the second protective sheet 15 is solidified, so that the second protective sheet 15 adheres to the piezoelectric sheet 13 or the dielectric sheet 13.

(1-3. Elastic modulus)
The first electrode sheet 11, the second electrode sheet 12, the piezoelectric sheet 13 or the dielectric sheet 13, the first protective sheet 14, and the second protective sheet 15 are elastically deformable and have flexibility and stretchability. Have. The relationship between the elastic coefficients in the thickness direction of each member will be described.

  The elastic coefficient of the piezoelectric sheet 13 or the dielectric sheet 13 is larger than the elastic coefficients of the first electrode sheet 11 and the second electrode sheet 12. Further, the elastic coefficient of the piezoelectric sheet 13 or the dielectric sheet 13 is larger than the elastic coefficients of the first protective sheet 14 and the second protective sheet 15. The first electrode sheet 11 and the second electrode sheet 12 have the same elastic coefficient. The first protective sheet 14 and the second protective sheet 15 have the same elastic coefficient. Here, the magnitude of the elastic coefficient of the first electrode sheet 11 and the first protective sheet 14 does not matter. Similarly, the magnitude of the elastic coefficient of the second electrode sheet 12 and the second protective sheet 15 does not matter.

  As described above, the first protection sheet 14 is bonded to the piezoelectric sheet 13 or the dielectric sheet 13 via the first through holes 11a of the first electrode sheet 11. At this time, the elastic coefficient of the first protective sheet 14 is smaller than the elastic coefficient of the piezoelectric sheet 13 or the dielectric sheet 13. Therefore, while the first protective sheet 14 is largely deformed due to the adhesion of the two, the piezoelectric sheet 13 or the dielectric sheet 13 is suppressed from being largely deformed.

  The elastic coefficient of the first electrode sheet 11 is smaller than the elastic coefficient of the piezoelectric sheet 13 or the dielectric sheet 13. Therefore, when the first electrode sheet 11 is pressed against the piezoelectric sheet 13 or the dielectric sheet 13, the first electrode sheet 11 is relatively easily deformed, and the piezoelectric sheet 13 or the dielectric sheet 13 is relatively deformed. Hard to do.

  The second protective sheet 15 is bonded to the piezoelectric sheet 13 or the dielectric sheet 13 via the second through holes 12a of the second electrode sheet 12. At this time, the elastic coefficient of the second protection sheet 15 is smaller than the elastic coefficient of the piezoelectric sheet 13 or the dielectric sheet 13. Therefore, while the second protective sheet 15 is largely deformed due to the adhesion of the two, the piezoelectric sheet 13 or the dielectric sheet 13 is suppressed from being largely deformed.

  The elastic coefficient of the second electrode sheet 12 is smaller than the elastic coefficient of the piezoelectric sheet 13 or the dielectric sheet 13. Therefore, when the second electrode sheet 12 is pressed against the piezoelectric sheet 13 or the dielectric sheet 13, the second electrode sheet 12 is relatively easily deformed, and the piezoelectric sheet 13 or the dielectric sheet 13 is relatively deformed. Hard to do.

  Therefore, when the first protection sheet 14 and the second protection sheet 15 are bonded to the piezoelectric sheet 13 or the dielectric sheet 13, the piezoelectric sheet 13 or the dielectric sheet 13 does not significantly deform in the thickness direction. . Therefore, in the initial state, the thickness of the piezoelectric sheet 13 or the dielectric sheet 13 can be prevented from being largely different depending on the position. The transducer 1 can have stable characteristics.

(1-4. Method of Manufacturing Transducer 1)
A method for manufacturing the transducer 1 will be described. As shown in FIGS. 4 and 5, each member constituting the transducer 1, that is, the first electrode sheet 11, the second electrode sheet 12, the piezoelectric sheet 13 or the dielectric sheet 13, the first protection sheet 14, and The second protection sheet 15 is prepared.

  Subsequently, the first electrode sheet 11 and the first protection sheet 14 are laminated on one surface of the piezoelectric sheet 13 or the dielectric sheet 13 in the order of the first electrode sheet 11 and the first protection sheet 14. On the other hand, the second electrode sheet 12 and the second protection sheet 15 are laminated on the other surface of the piezoelectric sheet 13 or the dielectric sheet 13 in the order of the second electrode sheet 12 and the second protection sheet 15.

  Subsequently, the laminate is compressed by hot pressing. Then, by pressing the first protection sheet 14 toward the piezoelectric sheet 13 or the dielectric sheet 13, the first protection sheet 14 is deformed and enters the first through hole 11 a of the first electrode sheet 11. Then, the surface of the first protective sheet 14 is bonded to the first electrode sheet 11 and the piezoelectric sheet 13 or the dielectric sheet 13 by thermal welding. At the same time, the second protection sheet 15 is pressed toward the piezoelectric sheet 13 or the dielectric sheet 13, whereby the second protection sheet 15 is deformed and enters the second through-hole 12 a of the second electrode sheet 12. Then, the surface of the second protective sheet 15 adheres to the second electrode sheet 12 and the piezoelectric sheet 13 or the dielectric sheet 13 by thermal welding. Finally, when the transducer 1 is of a piezoelectric type, a polling process is performed.

(1-5. Operation of transducer)
When the transducer 1 functions as a piezoelectric actuator, by applying a periodic voltage to the first electrode sheet 11 and the second electrode sheet 12, the piezoelectric sheet 13 is moved in the thickness direction and the surface direction according to the voltage. To expand and contract. Vibration due to expansion and contraction of the piezoelectric sheet 13 becomes vibration output as an actuator.

  When the transducer 1 functions as an electrostatic actuator, the dielectric sheet 13 expands and contracts in the thickness direction by applying a periodic voltage to the first electrode sheet 11 and the second electrode sheet 12. . When the charge stored in the first electrode sheet 11 and the second electrode sheet 12 increases, the dielectric sheet 13 is compressed and deformed. The thickness of the dielectric sheet 13 decreases, and the size of the dielectric sheet 13 in the plane direction increases. Conversely, when the charge stored in the first electrode sheet 11 and the second electrode sheet 12 decreases, the dielectric sheet 13 returns to its original thickness. That is, the thickness of the dielectric sheet 13 increases, and the size of the dielectric sheet 13 in the surface direction decreases.

  When the transducer 1 functions as a piezoelectric sensor, the piezoelectric sheet 13 expands and contracts in the thickness direction due to the application of an external force, so that there is a gap between the first electrode sheet 11 and the second electrode sheet 12. Voltage is generated. The voltage can detect that the piezoelectric sheet 13 has been deformed in the thickness direction, and can detect that an external force has been applied.

  Further, when the transducer 1 functions as an electrostatic sensor, the dielectric sheet 13 expands and contracts in the thickness direction due to the application of an external force, and the first electrode sheet 11 and the second electrode sheet 12 The capacitance between them changes. By applying a predetermined periodic voltage between the first electrode sheet 11 and the second electrode sheet 12, an output voltage corresponding to the capacitance between the electrodes can be detected. Based on the output voltage, it is possible to detect that the dielectric sheet 13 is deformed in the thickness direction, and to detect that an external force is applied.

(1-6. Effect)
As described above, the first electrode sheet 11 includes the first through hole 11a, and the second electrode sheet 12 includes the second through hole 12a. That is, the first electrode sheet 11 and the second electrode sheet 12 do not have the electrode material on the entire surface, but have a structure that does not partially include the electrode material. Therefore, the first electrode sheet 11 and the second electrode sheet 12 can reduce the cost by reducing the electrode material.

  Furthermore, according to the transducer 1, the first protective sheet 14 is bonded to the piezoelectric sheet 13 or the dielectric sheet 13 by utilizing the fact that the first electrode sheet 11 has the first through hole 11a. It has gained. In this case, the first protective sheet 14 is bonded to the piezoelectric sheet 13 or the dielectric sheet 13 so that the first electrode sheet 11 interposed between the first protective sheet 14 and the piezoelectric sheet 13 or the dielectric sheet 13. Are integrated with the first protection sheet 14 and also with the piezoelectric sheet 13 or the dielectric sheet 13. Therefore, compared with the case where the adhesive layer is required both between the piezoelectric sheet 13 or the dielectric sheet 13 and the first electrode sheet 11 and between the first electrode sheet 11 and the first protection sheet 14. By applying the above configuration, the number of adhesive layers can be reduced. As a result, the number of manufacturing steps can be reduced, and the cost can be reduced.

  Further, the bonding of the second protective sheet 15 to the piezoelectric sheet 13 or the dielectric sheet 13 can be performed by utilizing the fact that the second electrode sheet 12 has the second through holes 12a. In this case, the second protective sheet 15 is bonded to the piezoelectric sheet 13 or the dielectric sheet 13 so that the second electrode sheet 12 interposed between the second protective sheet 15 and the piezoelectric sheet 13 or the dielectric sheet 13. Are integrated with the second protection sheet 15 and are integrated with the piezoelectric sheet 13 or the dielectric sheet 13. Therefore, compared with the case where the adhesive layer is required both between the piezoelectric sheet 13 or the dielectric sheet 13 and the second electrode sheet 12 and between the second electrode sheet 12 and the second protective sheet 15. By applying the above configuration, the number of adhesive layers can be reduced. As a result, the number of manufacturing steps can be reduced, and the cost can be reduced.

  The first protective sheet 14 may be formed of a heat-sealable material (thermoplastic material), and may be bonded to the piezoelectric sheet 13 or the dielectric sheet 13 by applying heat. Similarly, the second protection sheet 15 may be formed of a heat-sealable material (thermoplastic material), and may be bonded to the piezoelectric sheet 13 or the dielectric sheet 13 by applying heat.

  Some adhesives include volatile organic compounds (VOCs). In recent years, as an environmental measure, suppression of VOC emission has been demanded. Therefore, it is required not to use an adhesive or a solvent containing VOC. As described above, by bonding using a heat-sealable material, bonding can be performed without using an adhesive or solvent containing VOC. Therefore, the emission of VOC can be suppressed. Further, since the protective sheets 14 and 15 themselves are made of a material which can be thermally welded, manufacturing costs can be reduced by not using a dedicated material such as an adhesive.

(2. Second embodiment)
As shown in FIGS. 6 and 7, the transducer 100 of the second embodiment includes a first electrode sheet 111, a second electrode sheet 112, a piezoelectric sheet 13 or a dielectric sheet 13, a first protective sheet 14, A second protection sheet 15 is provided. The first electrode sheet 111 and the second electrode sheet 112 are not conductive cloths but are thin-film punching metals having flexibility and elasticity. The first electrode sheet 111 includes a plurality of first through holes 111a, and the second electrode sheet 112 includes a plurality of second through holes 112a. Although the first through-hole 111a and the second through-hole 112a are rectangular, they are not limited to rectangles, and may be circular or other shapes.

  Also in this case, the first protection sheet 14 is bonded to the piezoelectric sheet 13 or the dielectric sheet 13 via the first through hole 111a of the first electrode sheet 111. Further, the second protection sheet 15 is bonded to the piezoelectric sheet 13 or the dielectric sheet 13 via the second through-hole 112a of the second electrode sheet 112.

(3. Third embodiment)
As shown in FIGS. 8 and 9, the transducer 200 of the third embodiment includes a first electrode sheet 11, a second electrode sheet 12, a first piezoelectric sheet 213a or a first dielectric sheet 213a, and a second piezoelectric sheet. 213b or the second dielectric sheet 213b, the first protective sheet 14, and the second protective sheet 15.

  The first piezoelectric sheet 213a or the first dielectric sheet 213a is integrally formed on the first inner surface side of the first electrode sheet 11. The first piezoelectric sheet 213a or the first dielectric sheet 213a does not exist on the first outer surface side of the first electrode sheet 11. The first piezoelectric sheet 213a or the first dielectric sheet 213a is formed by attaching to the surface of the conductive fiber located on the first inner surface side of the first electrode sheet 11 by dipping, spraying, coating, or the like. Then, the first piezoelectric sheet 213a or the first dielectric sheet 213a has a through hole as in the first electrode sheet 11.

  The second piezoelectric sheet 213b or the second dielectric sheet 213b is integrally formed on the second inner surface side of the second electrode sheet 12. Note that the second piezoelectric sheet 213b or the second dielectric sheet 213b does not exist on the second outer surface side of the second electrode sheet 12. Similarly, the second piezoelectric sheet 213b or the second dielectric sheet 213b is formed by adhering to the surface of the conductive fiber located on the second inner surface side of the second electrode sheet 12 by dipping, spraying, coating, or the like. Is done. Then, the second piezoelectric sheet 213b or the second dielectric sheet 213b has a through-hole similarly to the second electrode sheet 12.

  The first protection sheet 14 adheres to the first outer surface of the first electrode sheet 11. Further, the first protection sheet 14 is provided with the second piezoelectric sheet 213b or the first through hole 11a of the first electrode sheet 11 and the through hole of the first piezoelectric sheet 213a or the first dielectric sheet 213a. It adheres to the second dielectric sheet 213b.

  The second protective sheet 15 is adhered to the second outer surface of the second electrode sheet 12. Further, the second protective sheet 15 is provided through the second through hole 12a of the second electrode sheet 12 and the through hole of the second piezoelectric sheet 213b or the second dielectric sheet 213b. It is bonded to the first dielectric sheet 213a.

  In this case, when the transducer 200 is of a piezoelectric type, a first piezoelectric sheet 213a and a second piezoelectric sheet 213b exist between the first electrode sheet 11 and the second electrode sheet 12, and the first piezoelectric sheet The piezoelectric effect is exhibited by both the 213a and the second piezoelectric sheet 213b. When the transducer 200 is of an electrostatic type, a first dielectric sheet 213a and a second dielectric sheet 213b exist between the first electrode sheet 11 and the second electrode sheet 12, and the first dielectric sheet 213a and the The capacitance changes due to both of the second dielectric sheets 213b.

  In the third embodiment, the first piezoelectric sheet 213a or the first dielectric sheet 213a is an integral member with the first electrode sheet 11, and the second piezoelectric sheet 213b or the second dielectric sheet 213b is a second electrode sheet. It becomes an integral member with the sheet 12. Therefore, the number of parts is reduced because the piezoelectric sheet or the dielectric sheet does not exist alone.

(4. Fourth embodiment)
As shown in FIGS. 10 and 11, the transducer 300 of the fourth embodiment includes a first electrode sheet 11, a second electrode sheet 12, a first piezoelectric sheet 313a or a first dielectric sheet 313a, and a second piezoelectric sheet. 313b or the second dielectric sheet 313b, the first protection sheet 14, and the second protection sheet 15 are provided.

  The first piezoelectric sheet 313a or the first dielectric sheet 313a is integrally formed on the first inner surface side and the first outer surface side of the first electrode sheet 11. That is, the first piezoelectric sheet 313a or the first dielectric sheet 313a includes the first inner sheet portion 313a1 and the first outer sheet portion 313a2. The first piezoelectric sheet 313a or the first dielectric sheet 313a is formed by adhering to all surfaces of the conductive fibers of the first electrode sheet 11 by dipping, spraying, coating, or the like. Then, the first piezoelectric sheet 313a or the first dielectric sheet 313a has a through hole as in the first electrode sheet 11.

  The second piezoelectric sheet 313b or the second dielectric sheet 313b is integrally formed on the second inner surface side and the second outer surface side of the second electrode sheet 12. That is, the second piezoelectric sheet 313b or the second dielectric sheet 313b includes the second inner sheet portion 313b1 and the second outer sheet portion 313b2. Similarly, the second piezoelectric sheet 313b or the second dielectric sheet 313b is formed by adhering to all surfaces of the conductive fibers of the second electrode sheet 12 by dipping, spraying, coating, or the like. Then, the second piezoelectric sheet 313b or the second dielectric sheet 313b has a through-hole similarly to the second electrode sheet 12.

  The first protective sheet 14 is bonded to the first outer sheet portion 313a2 of the first piezoelectric sheet 313a or the first dielectric sheet 313a. Further, the first protection sheet 14 is connected to the second piezoelectric sheet 313b via the first through hole 11a of the first electrode sheet 11 (corresponding to the through hole of the first piezoelectric sheet 313a or the first dielectric sheet 313a). Alternatively, it is bonded to the second inner sheet portion 313b1 of the second dielectric sheet 313b.

  The second protective sheet 15 is bonded to the second outer sheet portion 313b2 of the second piezoelectric sheet 313b or the second dielectric sheet 313b. Further, the second protective sheet 15 is provided with the first piezoelectric sheet 313a via the second through hole 12a of the second electrode sheet 12 (corresponding to the through hole of the second piezoelectric sheet 313b or the second dielectric sheet 313b). Alternatively, the first dielectric sheet 313a is bonded to the first inner sheet portion 313a1.

  In this case, the first inner sheet portion 313a1 and the second inner sheet portion 313b1 exist between the first electrode sheet 11 and the second electrode sheet 12, and the first inner sheet portion 313a1 and the second inner sheet portion 313b1 As a result, the piezoelectric effect is exerted, or the capacitance changes.

(5. Fifth Embodiment)
As shown in FIGS. 12 and 13, the transducer 400 of the fifth embodiment includes a first electrode sheet 11, a second electrode sheet 12, a piezoelectric sheet 413 or a dielectric sheet 413, a first protection sheet 14, and a A second protection sheet 15 is provided.

  The piezoelectric sheet 413 or the dielectric sheet 413 is integrally formed on the first inner surface side of the first electrode sheet 11. The piezoelectric sheet 413 or the dielectric sheet 413 does not exist on the first outer surface side of the first electrode sheet 11. The piezoelectric sheet 413 or the dielectric sheet 413 is formed by attaching to the surface of the conductive fiber located on the first inner surface side of the first electrode sheet 11 by dipping, spraying, coating, or the like. Then, the piezoelectric sheet 413 or the dielectric sheet 413 has a through hole as in the first electrode sheet 11.

  The first protection sheet 14 adheres to the first outer surface of the first electrode sheet 11. Further, the first protective sheet 14 is bonded to the piezoelectric sheet 413 or the dielectric sheet 413. The second protection sheet 15 adheres to the second outer surface of the second electrode sheet 12. Further, the second protective sheet 15 is bonded to the piezoelectric sheet 413 or the dielectric sheet 413 via the second through holes 12a of the second electrode sheet 12.

  In this case, no piezoelectric material or dielectric material is attached to the second electrode sheet 12. Therefore, the piezoelectric material or the dielectric material is attached only to the first electrode sheet 11. Therefore, the manufacturing cost can be reduced.

(6. Sixth embodiment)
As shown in FIGS. 14 and 15, the transducer 500 of the sixth embodiment includes a first electrode sheet 11, a second electrode sheet 12, a piezoelectric sheet 513 or a dielectric sheet 513, a first protection sheet 14, and a A second protection sheet 15 is provided.

  The piezoelectric sheet 513 or the dielectric sheet 513 is integrally formed on the first inner surface side and the first outer surface side of the first electrode sheet 11. That is, the piezoelectric sheet 513 or the dielectric sheet 513 includes the inner sheet portion 513a and the outer sheet portion 513b. The piezoelectric sheet 513 or the dielectric sheet 513 is formed by adhering to all surfaces of the conductive fibers of the first electrode sheet 11 by dipping, spraying, coating, or the like. Then, the piezoelectric sheet 513 or the dielectric sheet 513 has a through hole as in the first electrode sheet 11.

  The first protective sheet 14 adheres to the outer sheet portion 513b of the piezoelectric sheet 513 or the dielectric sheet 513. The second protection sheet 15 adheres to the second outer surface of the second electrode sheet 12. Further, the second protective sheet 15 is bonded to the piezoelectric sheet 513 or the inner sheet portion 513a of the dielectric sheet 513 via the second through hole 12a of the second electrode sheet 12.

(7. Modification)
The above-described transducer 1 includes the first electrode sheet 11, the second electrode sheet 12, the piezoelectric sheet 13 or the dielectric sheet 13, the first protection sheet 14, and the second protection sheet 15. Not limited to this configuration, the transducer 1 is configured to include the first electrode sheet 11, the piezoelectric sheet 13 or the dielectric sheet 13, and the first protection sheet 14, and the above-described second electrode sheet 12 and second protection sheet 15 A configuration without such a configuration may be employed. In this case, the transducer 1 can replace the second electrode sheet 12 with a conductive material having no through hole. For example, the conductive material can be replaced with a plate, a shaft, a pipe, or the like formed of metal or a conductive material other than metal. Also in this case, the effects of the first electrode sheet 11 and the first protection sheet 14 are exhibited. Further, the present invention can be similarly applied to the transducers 100, 200, 300, 400, and 500 of other embodiments.

(8. Seventh embodiment)
A vibration presenting apparatus 600 using the above-described transducers 1, 100, 200, 300, 400, 500 (hereinafter, referred to as “transducer 1 etc.”) will be described with reference to FIGS. Here, in FIGS. 16 to 19, the thickness of each member is exaggerated for easy understanding. Therefore, the thickness of the vibration presenting device 600 in the vertical direction in FIGS. 16 and 17 is actually extremely small.

  The vibration presenting device 600 has a function as a sensor for detecting an external pushing force and a function as an actuator for presenting vibration. The vibration presenting apparatus 600 detects, for example, when a pressing force is applied by a human finger or the like, and then presents tactile vibration to the finger.

  As shown in FIGS. 16 and 17, the vibration presenting device 600 includes an actuator 610, a first conductive portion 620, a second conductive portion 630, a first elastic body 640, a second elastic body 650, a sensor 660, and a third elastic body. 601, a cover 670, a conducting wire 680, and a control device 690 are provided.

  At least one of the actuator 610 and the sensor 660 uses the above-described transducer 1 or the like. That is, only the actuator 610, only the sensor 660, or both the actuator 610 and the sensor 660 apply the transducer 1 or the like. In the present embodiment, the transducer 1 and the like are applied to both the actuator 610 and the sensor 660.

  The actuator 610 includes a plurality of actuator units 610a, 610b, 610c. In the present embodiment, as shown in FIG. 18, the actuator 610 includes three actuator units 610a, 610b, and 610c, and is formed by stacking three actuator units 610a, 610b, and 610c. However, the actuator 610 may include only one actuator unit 610a.

  Each actuator unit 610a, 610b, 610c has a plurality of transducers 1 and the like stacked. As shown in FIG. 19, in each of the actuator units 610a, 610b, and 610c, the first electrode sheet 11 and the second electrode sheet 12 are offset in the left-right direction (longitudinal direction). Specifically, a part of the first electrode sheet 11 and a part of the second electrode sheet 12 are arranged to face each other. In the first electrode sheet 11 and the second electrode sheet 12, the remaining part that does not face each other is located on the opposite side with respect to the facing part.

  That is, in FIG. 19, the first electrode sheet 11 and the second electrode sheet 12 face each other in the center part in the left-right direction, and the left electrode part has the second electrode sheet 11 while the first electrode sheet 11 exists. The second electrode sheet 12 is present on the right side, while the first electrode sheet 11 is not present.

  The length of the piezoelectric sheet 13 or the dielectric sheet 13 in the longitudinal direction (the width in the left-right direction in FIG. 19) is in a range where the first electrode sheet 11 and the second electrode sheet 12 face each other. The length is formed so as to face the existing area and the entire area where only the second electrode sheet 12 exists.

  The first protective sheet 14 covers the entire surface of the first electrode sheet 11 and the exposed portion of the piezoelectric sheet 13 or the dielectric sheet 13. The second protective sheet 15 covers the plurality of second electrode sheets 12 and the exposed portions of the piezoelectric sheet 13 or the dielectric sheet 13 over the entire surface.

  Subsequently, the actuator units 610a, 610b, 610c will be described with reference to FIG. Each of the actuator units 610a, 610b, and 610c includes an actuator body 616 located at the center in the left-right direction of FIG. 18, a first terminal 617 located on the left side of FIG. 18, and a second terminal 618 located on the right side of FIG. And The first terminal 617 is a terminal having a positive potential in the actuator body 616, and the second terminal 618 is a terminal having a ground potential in the actuator body 616. Here, the first terminal 617 and the second terminal 618 extend on opposite sides with respect to the actuator main body 616.

  Here, the first electrode sheet 11 includes a first opposing electrode portion 611a located at a central portion in the left-right direction, and a first terminal electrode portion 611b extending from the first opposing electrode portion 611a. The second electrode sheet 12 includes a second opposing electrode portion 612a located at a central portion in the left-right direction, and a second terminal electrode portion 612c extending from the second opposing electrode portion 612a. The first counter electrode section 611a and the second counter electrode section 612a face each other. The direction in which the first terminal electrode portion 611b extends from the first counter electrode portion 611a is opposite to the direction in which the second terminal electrode portion 612c extends from the second counter electrode portion 612a.

  The piezoelectric sheet 13 and the dielectric sheet 13 include a piezoelectric body 613a or a dielectric body 613a, a first extension 613b, and a second extension 613c. The piezoelectric body 613a or the dielectric body 613a is interposed between the first counter electrode 611a and the second counter electrode 612a. The first extension portion 613b extends from the piezoelectric body 613a or the dielectric body 613a and is interposed between the plurality of first terminal electrode portions 611b. The second extending portion 613c extends from the piezoelectric body 613a or the dielectric body 613a and is interposed between the plurality of second terminal electrode portions 612c.

  As described above, instead of having only the first terminal electrode portion 611 b exist outside the actuator body 616, the first extension portion 613 b which is a part of the piezoelectric sheet 13 and the dielectric sheet 13 is provided outside the actuator body 616. The first terminal electrode portion 611b and the first extension portion 613b are laminated. Therefore, the total thickness of the first terminal electrode portion 611b and the first extension portion 613b is only smaller by the thickness of the second electrode sheet 12 than the actuator body 616. Therefore, generation of a large deformation force near the boundary between the first terminal electrode portion 611b and the first counter electrode portion 611a can be suppressed. As a result, the component of the conductive path connected to the first counter electrode portion 611a can have high durability. The same applies to the second terminal electrode portion 612c.

  Further, the first protection sheet 14 includes a first protection main body 614a, a first protection_first terminal protection part 614b, and a first protection_second terminal protection part 614c. The first protection main body 614a covers the first counter electrode 611a. The first protection_first terminal protection part 614b covers the first terminal electrode part 611b. The first protection_second terminal protection part 614c covers the second terminal electrode part 612c.

  The second protection sheet 15 includes a second protection main body 615a, a second protection_first terminal protection part 615b, and a second protection_second terminal protection part 615c. The second protection main body 615a covers the first counter electrode 611a. The second protection_first terminal protection part 615b covers the first terminal electrode part 611b. The second protection_second terminal protection part 615c covers the second terminal electrode part 612c.

  As shown in FIGS. 16 and 17, the first conductive portion 620 is formed in a sheet shape from an elastically deformable material (e.g., an elastomer) and is bent in an L shape. The first conductive portion 620 may be formed by mixing a conductive filler in the elastomer, or may be a conductive cloth like the first electrode sheet 11.

  One side of the L-shape of the first conductive portion 620 is formed in a direction intersecting (for example, orthogonally) to the planar surface of the actuator main body 616. Then, one side of the L-shape of the first conductive portion 620 is in contact with the end face of the first terminal 617. In detail, one side of the L-shape of the first conduction portion 620 is in contact with the end of the first terminal electrode portion 611b and the end of the first extension portion 613b. Therefore, the first conduction part 620 is electrically connected to the ends of the plurality of first terminal electrode parts 611b.

  The other side of the L-shape of the first conductive portion 620 extends in a direction away from the actuator main body 616 and is formed parallel to the planar surface direction of the actuator main body 616. The other side of the L-shape of first conduction portion 620 is electrically connected to conducting wire 680.

  Similarly to the first conductive portion 620, the second conductive portion 630 is formed in a sheet shape from an elastically deformable material (e.g., an elastomer), and is bent in an L shape. The second conductive portion 630 is formed by mixing a conductive filler in the elastomer.

  One side of the L-shape of the second conductive portion 630 is formed in a direction intersecting (orthogonal to) the planar surface of the actuator main body 616. Then, one side of the L-shape of the second conductive portion 630 is in contact with the end surface of the second terminal 618. Specifically, one side of the L-shape of the second conductive portion 630 is in contact with the end of the second terminal electrode portion 612c and the end of the second extending portion 613c. Therefore, the second conduction part 630 is electrically connected to the ends of the plurality of second terminal electrode parts 612c.

  The other side of the L-shape of the second conductive portion 630 extends in a direction away from the actuator main body 616 and is formed parallel to the planar surface direction of the actuator main body 616. The other side of the L-shape of second conductive portion 630 is electrically connected to conductive wire 680.

  With the first conductive portion 620, a conductive path can be easily formed between the plurality of first terminal electrode portions 611b. Similarly, a conductive path can be easily formed between the plurality of second terminal electrode portions 612c by the second conductive portion 630. Further, since the first conductive portion 620 and the second conductive portion 630 are elastically deformable, they can follow the deformation of the first terminal 617 and the second terminal 618. Therefore, even if the first terminal 617 and the second terminal 618 are deformed, a conductive path can be easily formed between the first terminal electrode portion 611b and the second terminal electrode portion 612c.

  The first elastic body 640 is arranged in contact with one planar surface of the actuator body 616 (the upper surface in FIG. 16). The second elastic body 650 is arranged in contact with the other planar surface (the lower surface in FIG. 16) of the actuator main body 616, that is, the opposite side of the actuator main body 616 from the first elastic body 640. That is, the first elastic body 640 and the second elastic body 650 are respectively arranged on both end faces (upper and lower faces in FIG. 16) of the actuator main body 616 facing in a direction perpendicular to the plane.

  Further, as shown in FIG. 17, the first elastic body 640 includes both end faces (the surfaces on which the first terminal 617 and the second terminal 618 do not exist) (the left and right sides in FIG. Surface)). Further, as shown in FIG. 16, the first elastic body 640 includes a planar one surface of the first terminal 617 (upper surface in FIG. 16) and a planar one surface of the second terminal 618 (upper surface in FIG. 16). ). The second elastic body 650 is arranged in contact with the other planar surface (the lower surface in FIG. 16) of the first terminal 617 and the other planar surface (the lower surface in FIG. 16) of the second terminal 618. Further, the first elastic body 640 is disposed in contact with all of the L-shaped outer surface of the first conductive portion 620 and all of the L-shaped outer surface of the second conductive portion 630.

For the first elastic body 640 and the second elastic body 650, a material having a small elastic modulus E ₍₆₄₀₎ , E ₍₆₅₀₎ and a small loss coefficient tanδ ₍₆₄₀₎ , tanδ ₍₆₅₀₎ is used. In other words, the first elastic body 640 and the second elastic body 650 are preferably made of a material that is soft and has low damping characteristics. In particular, the first elastic body 640 and the second elastic body 650 have elastic moduli E ₍₆₄₀₎ and E ₍₆₅₀₎ smaller than the elastic modulus E1 _{(616) in} the stacking direction of the actuator body 616 (in the direction perpendicular to the plane ₎ . Have. Further, the elastic modulus E ₍₆₄₀₎ of the first elastic body 640 is smaller than the elastic modulus E2 ₍₆₁₆₎ of the actuator body 616 in the surface direction.

  As the sensor 660, the transducer 1 or the like is applied. Sensor 660 is located around actuator 610. In the present embodiment, the sensor 660 is stacked on an actuator stack (610, 640, 650) formed by the actuator 610, the first elastic body 640, and the second elastic body 650. In particular, the sensor 660 is stacked on the second elastic body 650 on the side opposite to the actuator 610. In addition to the above, the sensor 660 may be arranged in parallel with the actuator 610 in a direction orthogonal to the stacking direction of the actuator 610.

The third elastic body 601 is laminated on the actuator laminate (610, 640, 650) and the sensor 660, and is arranged on the sensor 660 on the side opposite to the actuator laminate (610, 640, 650). The third elastic body 601 is formed of the same material as the first elastic body 640 and the second elastic body 650. Accordingly, the elastic modulus E ₍₆₀₁₎ and the loss coefficient tan δ ₍₆₀₁₎ of the third elastic body 601 are the elastic modulus E ₍₆₄₀₎ and the loss coefficient tan δ _{(640) of} the first elastic body 640, and the elasticity of the second elastic body 650. It is the same as the ratio E ₍₆₅₀₎ and the loss factor tan δ ₍₆₅₀₎ .

  Here, as shown in FIG. 17, the sensor 660 extends from the sensor main body 660a disposed between the actuator laminate (610, 640, 650) and the third elastic body 601, and extends from the sensor main body 660a. And a sensor terminal portion 660b that is bent and formed so as to extend around the third elastic body 601 on the side opposite to the sensor body portion 660a. The sensor body 660a corresponds to the transducer 1 and the like, and the sensor terminal 660b is electrically connected to the first electrode sheet 11 and the second electrode sheet 12 in the sensor body 660a. The sensor terminal 660b is located between the third elastic body 601 and the conductor 680.

  The cover 670 surrounds the actuator 610, the first conductive part 620, the second conductive part 630, the first elastic body 640, the second elastic body 650, the sensor 660, and the third elastic body 601. Various materials such as a metal and a resin are applied to the cover 670, for example. The cover 670 transmits the pushing force to the sensor 660 when a pushing force in the stacking direction of the actuator laminates (610, 640, 650) is applied from the outside. Further, the cover 670 vibrates due to the vibration generated by the actuator 610, and applies vibration to a human finger that has applied a pressing force to the cover 670.

  The cover 670 includes a first cover 671 as a pedestal, and a second cover 672 as a member attached to the first cover 671 and to which a pushing force is applied. The first cover 671 and the second cover 672 connect the actuator body 616, the first elastic body 640, the second elastic body 650, the sensor 660, and the third elastic body 601 in the stacking direction of the actuator stacked body (610, 640, 650). (In the vertical direction in FIG. 16). In this state, the first elastic body 640, the second elastic body 650, and the third elastic body 601 are connected to the actuator main body in the stacking direction of the actuator stacked bodies (610, 640, 650) from the relationship of the elastic modulus E of each member. 616 and the sensor 660 are more compressed. Here, in FIG. 17, the third elastic body 601 and the first cover 671 are shown as not in contact with each other due to the presence of the sensor terminal portion 660b. However, since the sensor terminal portion 660b is actually thin, The trielastic body 601 and the first cover 671 are in contact with each other in a pressed state.

  Further, the first cover 671 holds the actuator main body 616 and the first elastic body 640 in a compressed state in the plane direction of the actuator main body 616 (the left-right direction in FIG. 17). In this state, the first elastic body 640 is compressed more than the actuator main body 616 in the plane direction of the actuator main body 616 from the relation of the elastic modulus E of each member.

  The conducting wire 680 is arranged on the same plane as the first cover 671 located on the inner side surface of the cover 670. In the present embodiment, the conductor 680 is formed by printing on the first cover 671, but a cable or the like may be used. Control device 690 drives actuator 610 to generate vibration when sensor 660 detects the pressing force applied to cover 670. Although the control device 690 is arranged outside the cover 670, it may be arranged inside the cover 670.

  Since the vibration presenting apparatus 600 includes the transducer 1 and the like, cost reduction can be achieved. Further, the vibration presenting device 600 includes a sensor 660 and an actuator 610. Therefore, the response of the vibration presenting device 600 from the detection of the pressing force to the presentation of the vibration is very good. The vibration presenting apparatus 600 can present a large vibration without increasing the size while including the sensor 660 for detecting the pressing force and the actuator 610.

  Further, the actuator 610 and the sensor 660 are stacked in a direction in which a pressing force is applied. Therefore, the position where the pressing force is detected and the position where the vibration is applied are the same. Therefore, when a human finger applies a pressing force to the cover 670, vibration can be directly applied to the finger itself.

  In addition, since the sensor 660 is sandwiched between the second elastic body 650 and the third elastic body 601, the sensor 660 is not restricted in the expansion / contraction operation. Therefore, the sensitivity of the sensor 660 to the pressing force applied to the cover 670 is amplified. Therefore, even if the applied pushing force is small, the sensor 660 can detect the pushing force. However, the vibration presenting device 600 may be configured not to include the third elastic body 601.

1,100,200,300,400,500: Transducer, 11, 111: First electrode sheet, 11a, 111a: First through hole, 12, 112: Second electrode sheet, 12a, 112a: Second through hole, 13, 413, 513: piezoelectric sheet, dielectric sheet, 14: first protective sheet, 15: second protective sheet, 213a, 313a: first piezoelectric sheet, first dielectric sheet, 213b, 313b: second 313a1: first inner sheet portion, 313a2: first outer sheet portion, 313b1: second inner sheet portion, 313b2: second outer sheet portion, 513a: inner sheet portion,
513b: outer sheet portion, 600: vibration presenting device, 601: third elastic body, 610: actuator, 610a, 610b, 610c: actuator unit, 611a: first counter electrode portion, 611b: first terminal electrode portion, 612a: 612c: second terminal electrode section, 613a: piezoelectric body, dielectric body, 613b: first extension section, 613c: second extension section, 614a: first protection body, 614b: first section One protection_first terminal protection part, 614c: first protection_second terminal protection part, 615a: second protection body, 615b: second protection_first terminal protection part, 615c: second protection_second terminal protection Part, 616: actuator main body, 617: first terminal, 618: second terminal, 620: first conductive part, 630: second conductive part, 640: first elastic body, 650: Two elastic bodies, 660: sensor, 660a: sensor body, 660b: sensor terminal portions, 670: cover,
671: First cover, 672: Second cover, 680: Conductor, 690: Control device

Claims (12)

A first electrode sheet having a plurality of first through holes,
A plurality of second through-holes, a second electrode sheet disposed to face the first electrode sheet,
A piezoelectric sheet or a dielectric sheet disposed between at least a first inner surface of the first electrode sheet and a second inner surface of the second electrode sheet,
A first protective sheet covering the first outer surface side of the first electrode sheet,
A second protective sheet covering the second outer surface side of the second electrode sheet,
With
The first protective sheet adheres to the piezoelectric sheet or the dielectric sheet through the first through hole of the first electrode sheet,
Or
The transducer, wherein the second protective sheet adheres to the piezoelectric sheet or the dielectric sheet via the second through hole of the second electrode sheet. The piezoelectric sheet or the dielectric sheet is non-adhered to the first electrode sheet and the second electrode sheet, the first inner surface of the first electrode sheet and the second inner surface of the second electrode sheet. Placed between
The first protective sheet adheres to the piezoelectric sheet or the dielectric sheet through the first through hole of the first electrode sheet, and adheres to the first outer surface of the first electrode sheet,
The second protective sheet adheres to the piezoelectric sheet or the dielectric sheet through the second through hole of the second electrode sheet, and adheres to the second outer surface of the second electrode sheet, The transducer according to claim 1. The piezoelectric sheet or the dielectric sheet,
A first piezoelectric sheet or a first dielectric sheet integrally formed on the first inner surface side of the first electrode sheet,
A second piezoelectric sheet or a second dielectric sheet formed integrally with the second inner surface side of the second electrode sheet and arranged in contact with the first piezoelectric sheet or the dielectric sheet,
With
The first protective sheet is bonded to the second piezoelectric sheet or the second dielectric sheet via the first through hole of the first electrode sheet, and the first outer surface of the first electrode sheet Glued to
The second protective sheet is bonded to the first piezoelectric sheet or the first dielectric sheet through the second through hole of the second electrode sheet, and the second outer surface of the second electrode sheet The transducer of claim 1, wherein the transducer is adhered to. The piezoelectric sheet or the dielectric sheet,
A first piezoelectric sheet or a first dielectric sheet integrally formed on the first inner surface side and the first outer surface side of the first electrode sheet,
The second piezoelectric sheet or the second piezoelectric sheet or the second piezoelectric sheet which is integrally formed on the second inner surface side and the second outer surface side of the second electrode sheet and is arranged in contact with the first piezoelectric sheet or the dielectric sheet. A dielectric sheet;
With
The first protective sheet is adhered to the second piezoelectric sheet or the second dielectric sheet through the first through hole of the first electrode sheet, and the first piezoelectric sheet or the first Glued to the dielectric sheet,
The second protective sheet is bonded to the first piezoelectric sheet or the first dielectric sheet through the second through hole of the second electrode sheet, and the second piezoelectric sheet or the second The transducer of claim 1, wherein the transducer adheres to a dielectric sheet. The piezoelectric sheet or the dielectric sheet is integrally formed on the first inner surface side of the first electrode sheet,
The first protective sheet adheres to the first outer surface of the first electrode sheet,
The second protective sheet adheres to the piezoelectric sheet or the dielectric sheet through the second through hole of the second electrode sheet, and adheres to the second outer surface of the second electrode sheet, The transducer according to claim 1. The piezoelectric sheet or the dielectric sheet is integrally formed on the first inner surface side and the first outer surface side of the first electrode sheet,
The first protective sheet is bonded to the piezoelectric sheet or the dielectric sheet,
The second protective sheet adheres to the piezoelectric sheet or the dielectric sheet through the second through hole of the second electrode sheet, and adheres to the second outer surface of the second electrode sheet, The transducer according to claim 1.   The transducer according to claim 1, wherein the first electrode sheet and the second electrode sheet are conductive cloth. The modulus of elasticity of the piezoelectric sheet or the dielectric sheet is larger than the modulus of elasticity of the first electrode sheet and the second electrode sheet,
The transducer according to any one of claims 1 to 7, wherein an elastic coefficient of the piezoelectric sheet or the dielectric sheet is larger than elastic coefficients of the first protective sheet and the second protective sheet. The first protective sheet is formed of a heat-sealable material and adheres to the piezoelectric sheet or the dielectric sheet by applying heat,
Or
9. The transducer according to claim 1, wherein the second protective sheet is formed of a heat-sealable material, and adheres to the piezoelectric sheet or the dielectric sheet by applying heat. A first electrode sheet having a plurality of first through holes,
At least a piezoelectric sheet or a dielectric sheet disposed on the first inner surface side of the first electrode sheet,
A first protective sheet covering the first outer surface side of the first electrode sheet,
With
A transducer, wherein the first protective sheet adheres to the piezoelectric sheet or the dielectric sheet via the first through hole of the first electrode sheet. A piezoelectric or electrostatic actuator,
A first elastic body laminated on the actuator,
A second elastic body laminated on the opposite side of the actuator from the first elastic body,
A piezoelectric or dielectric sensor arranged around the actuator,
While the actuator, the first elastic body, and the actuator laminate formed by the second elastic body are compressed in the laminating direction, the first elastic body and the second elastic body are compressed more than the actuator. A cover that holds in a state where the cover is pressed, transmits the pressing force to the sensor when a pressing force in the stacking direction is applied to the cover from the outside, and the cover vibrates due to vibration generated by the actuator.
With
A vibration presenting device, wherein one of the actuator and the sensor is the transducer according to any one of claims 1 to 10. The sensor is stacked on the actuator stack,
The vibration presenting apparatus further includes a third elastic body that is stacked on the actuator stack and the sensor, and is disposed on a side of the sensor opposite to the actuator stack,
The vibration presenting device according to claim 11, wherein the cover holds the third elastic body in a state where the third elastic body is compressed more than the sensor.

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