JP2018170844A - Power generation device and input apparatus provided with the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power generation device capable of increasing the amplitude of a vibrating body and an input device provided with the power generation device. A power generation device 1 includes a housing 2, a vibrating body 3, a power generation unit 5, a first magnetic body 4, and a second magnetic body 7. The vibrating body 3 has a first end 31 that is elastic and mechanically vibrates in the vertical direction. The power generation unit 5 converts the vibration energy when the first end 31 vibrates into electrical energy. The first magnetic body 4 is provided at the first end 31, and the second magnetic body 7 is vertically aligned with the first end 31. The second magnetic body 7 attracts the first magnetic body 4 by a magnetic force from the bottom. When the second magnetic body 7 moves downward, the first end 31 is displaced downward, and when the second magnetic body 7 separates from the first magnetic body 4, the first end 31 vibrates. The second magnetic body 7 is a magnet 8 having a magnetic pole surface 80 on the upper surface thereof, and has at least one set of two magnetic poles having different polarities on the magnetic pole surface 80. [Selection diagram] Fig. 1

Description

  The present invention generally relates to a power generation device and an input device including the same, and more particularly to a power generation device that converts vibration energy of a vibrating body into electric energy and an input device including the power generation device.

  Conventionally, a power generator is known (for example, refer to patent documents 1). The power generation device described in Patent Document 1 includes a piezoelectric bimorph fixed by cantilever support, a permanent magnet attached to the free end of the piezoelectric bimorph, and a rotating shaft that rotates the permanent magnet. The piezoelectric bimorph and the rotating shaft are arranged so that the permanent magnets repel or attract each other when the rotating shaft rotates and the permanent magnets approach each other. As the rotating shaft rotates, the permanent magnets approach each other and mechanical distortion is applied to the piezoelectric bimorph. When the rotating shaft continues to rotate, the permanent magnets repel or attract each other, generating free vibration in the piezoelectric bimorph. To do. The power generation device generates power by vibrating the piezoelectric bimorph.

JP 2003-189441 A

  In the power generation device described in Patent Document 1, the amplitude of the vibrating piezoelectric bimorph (vibrating body) increases as the repulsion force or attractive force (adsorption force) between the permanent magnets increases. The larger the amplitude of the vibrating body, the larger the electric power during power generation.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a power generation device capable of increasing the amplitude of a vibrating body and an input device including the power generation device.

  A power generation device according to an aspect of the present invention includes a housing, a vibrating body, a power generation unit, a first magnetic body, and a second magnetic body. The vibrating body is a member that is elastic and is held by the housing, and has a vibrating section that vibrates mechanically in the vibration direction. The power generation unit converts vibration energy of the vibrating body when the vibration unit vibrates in the vibration direction into electric energy. The first magnetic body is provided in the vibration part. The second magnetic body is arranged side by side with the first magnetic body in the vibration direction, is movable in the vibration direction with respect to the housing, and is moved from the first direction that is one of the vibration directions. Adsorbed to the first magnetic body by magnetic force. The vibrator is configured to be displaced in the first direction by moving the second magnetic body in the first direction while the second magnetic body is attracted to the first magnetic body. Yes. The vibrating portion is configured to vibrate in the vibration direction by the elastic force of the vibrating body when the second magnetic body is separated from the first magnetic body. At least one of the first magnetic body and the second magnetic body is a magnet having a magnetic pole surface on one surface facing the other in the vibration direction. The magnet has at least one set of two magnetic poles having different polarities on the magnetic pole surface.

  In this power generation device, the vibrating body has a cantilever shape in which one end portion in an orthogonal direction orthogonal to the vibration direction is fixed to the housing, and the magnets are arranged in the orthogonal direction on the magnetic pole surface. It is preferable to have at least one set of the two magnetic poles.

  In this power generator, the vibrating body has a cantilever shape in which one end portion in an orthogonal direction orthogonal to the vibration direction is fixed to the housing. The magnet preferably includes at least one set of the two magnetic poles arranged in a direction intersecting both the orthogonal direction and the vibration direction on the magnetic pole surface.

  In this power generator, the magnet preferably has at least one pair of two magnetic poles arranged in the vibration direction.

  In this power generation device, it is preferable that the power generation unit includes a piezoelectric element provided on the vibrating body.

  An input device according to an aspect of the present invention includes the above power generation device and an operation unit that is movable in the vibration direction with respect to the housing, and the second magnetic body is interlocked with the operation unit. And move in the vibration direction.

  The present invention has the advantage that the amplitude of the vibrating body can be increased.

FIG. 1 is an exploded perspective view of an input device including a power generation device according to an embodiment of the present invention. FIG. 2 is a cross-sectional view of the above input device. FIG. 3 is a cross-sectional perspective view of the main part of the above power generator. FIG. 4 is a perspective view of a magnet in the above power generator. FIG. 5A is an explanatory diagram for explaining the magnetic flux of the magnet in the above power generator. Drawing 5B is an explanatory view for explaining magnetic flux of a magnet of a comparative example. 6A to 6C are explanatory diagrams of the operation of the vibrating body in the input device same as above.

  Hereinafter, the electric power generating apparatus 1 which concerns on embodiment of this invention, and the input device 100 provided with the same are demonstrated with reference to FIGS. 1-6C. However, the embodiment described below is only one of various embodiments of the present invention. The following embodiments can be variously modified according to design and the like as long as the object of the present invention can be achieved. In addition, each drawing described in the following embodiment is a schematic diagram, and the ratio of the size and thickness of each component in FIGS. 1 to 6C necessarily reflects the actual dimensional ratio. Not necessarily.

(1) Overview of Power Generation Device and Input Device As shown in FIG. 1, the input device 100 includes the power generation device 1 and a decorative cover 23, and is a device that can push the decorative cover 23. The input device 100 can notify an external device or the like that the push operation (input operation) has been performed with the push operation as a trigger. For example, the input device 100 includes a communication device, and when the push operation is performed, the input device 100 operates the communication device with power output from the power generation device 1. The communication device can transmit a communication signal to the receiving device by wireless communication. The radio signal is, for example, a radio signal according to a Bluetooth (registered trademark) standard, and a radio signal according to a Bluetooth (registered trademark) Low Energy standard. Since the input device 100 can transmit a wireless signal with the power output from the power generation device 1 when the decorative cover 23 is pushed, the input device 100 does not need to have a power source such as a battery. In addition to the communication device, the input device may include an appropriate device that uses power (or voltage or current) output from the power generation device 1.

  The power generation device 1 includes, for example, a vibrating body 3 that is elastically deformed and mechanically vibrates. When the user pushes the decorative cover 23, the vibrating body 3 is configured to vibrate. The power generation device 1 includes, for example, a power generation unit 5 including a piezoelectric element 6, and the power generation unit 5 converts vibration energy of the vibrating body 3 into electric energy. The vibrating body 3 is formed in a rectangular plate shape. Hereinafter, the respective directions defined by the thickness direction, the lateral direction, and the longitudinal direction of the vibrating body 3 will be described as an up-down direction, a left-right direction, and a front-rear direction. In addition, the up-down direction, the left-right direction, and the front-back direction of the present embodiment are not intended to limit the orientation when the input device 100 and the power generation device 1 are used.

(2) Configuration of Input Device The input device 100 includes the power generation device 1, the operation unit 9, and a decorative cover 23.

  The decorative cover 23 is formed in a bottomed cylindrical shape that opens downward. The decorative cover 23 has a substantially rectangular outer shape when viewed from above. The upper surface of the bottom plate of the decorative cover 23 is an operation surface 231, which is a surface that contacts when the operator pushes the decorative cover 23 downward with a finger or the like. The bottom surface of the bottom plate of the decorative cover 23 is in contact with the operation unit 9. The decorative cover 23 covers four locking portions 922 of the operation portion 9 (first operation portion 92) and a snap-fit structure of the body 21 and the cover 22 described later.

  The operation unit 9 includes a first operation unit 92 and a second operation unit 93. The first operation portion 92 is formed in a bottomed cylindrical shape that opens downward. As for the 1st operation part 92, seeing from upper direction, the external shape of the baseplate 921 becomes a substantially square shape. The outer shape of the bottom plate 921 of the first operation unit 92 is slightly smaller than the bottom plate of the operation surface 231 of the decorative cover 23, and the bottom plate 921 is stored in the internal space of the decorative cover 23. The first operation unit 92 is movable in the vertical direction with respect to the housing 2 of the power generation device 1. A columnar protrusion 923 (see FIG. 2) that protrudes downward from the lower surface of the bottom plate 921 of the first operation unit 92 is provided. The protruding portion 923 is press-fitted into the cylindrical portion 931 of the second operation portion 93. When the operation surface 231 is pushed downward, the first operation unit 92 moves the second operation unit 93 downward in conjunction with the push operation.

  The first operating portion 92 has four locking portions 922 that protrude downward from corner portions of a substantially square shape when viewed from above. The four locking portions 922 are provided at positions corresponding to four concave portions 214 provided in the body 21 of the casing 2 to be described later. The four locking portions 922 are caught by the corresponding four concave portions 214 in a state where the protruding portion 923 of the first operating portion 92 is press-fitted into the cylindrical portion 931 of the second operating portion 93. The four locking portions 922 suppress the first operating portion 92 from being detached from the body 21 when the first operating portion 92 moves upward with respect to the body 21.

  The second operation portion 93 includes a bottomed cylindrical tube portion 931 that opens upward, a push-in portion 932, and a pair of guide portions 933. The pushing portion 932 is formed in a plate shape, for example, and protrudes forward from the outer surface of the cylindrical portion 931. The pushing portion 932 is disposed above the support portion 912 of the movable portion 91, and pushes the support portion 912 downward when the second operation portion 93 moves downward. Each of the pair of guide portions 933 is formed in a hollow cylindrical shape, for example, and passes the pair of guide shafts 245 of the fixed portion 24. The pair of guide portions 933 guides the second operation portion 93 to move in the vertical direction by moving along the corresponding pair of guide shafts 245.

(3) Configuration of Power Generation Device As shown in FIGS. 1 and 2, the power generation device 1 includes a housing 2, a vibrating body 3, a piezoelectric element 6, a magnet 8, and a restriction unit 242.

  The vibrating body 3 has a first magnetic body 4. The first magnetic body 4 is a rectangular plate member made of, for example, stainless steel (Steel Special Use Stainless) whose main component is iron. A weight 33 is provided at the first end 31 that is the front end portion of the vibrating body 3 in the front-rear direction. A second end 32 (one end portion) which is a rear end portion of the vibrating body 3 is fixed to the fixing portion 24 and is fixed to the body 21. The vibrating body 3 has, for example, a cantilever shape protruding forward from the fixed portion 24. The vibrating body 3 can be mechanically vibrated (free vibration) by the first end 31 being displaced in the vertical direction (vibrating direction) relative to the second end 32 by elastic deformation. In other words, the first end 31 of the vibrating body 3 is a vibrating portion that vibrates mechanically in the vertical direction (vibrating direction).

  Here, since the vibrating body 3 has a cantilever shape, the vibration direction of the first end 31 vibrates in the vertical direction along an arc centered on the second end 32, for example. The direction in which the first end 31 vibrates when the body 3 is elastically deformed will be described simply as the vertical direction.

  The weight 33 is fixed to the upper surface of the vibrating body 3, for example. The weight 33 is formed in a plate shape that is long in the left-right direction. For example, the weight 33 is made of a nonmagnetic material such as a synthetic resin material, but may be made of a magnetic material such as a metal material. The weight 33 is provided to adjust the vibration characteristics when the first end 31 of the vibrating body 3 vibrates in the vertical direction. The vibration characteristics here are, for example, the amplitude, frequency, and duration of free vibration when the vibrating body 3 vibrates.

  Piezoelectric elements 6 are provided on the upper surface and the lower surface of the vibrating body 3, respectively. The piezoelectric element 6 is a so-called bimorph type piezoelectric element 6. The piezoelectric element 6 generates electric power and outputs electric power to the communication device when the first end 31 of the vibrating body 3 vibrates in the vertical direction. In other words, the piezoelectric element 6 functions as a power source for the communication device when the first end 31 of the vibrating body 3 vibrates. The piezoelectric element 6 constitutes a power generation unit 5 that converts vibration energy of the vibrating body 3 into electric energy. As an example, the piezoelectric element 6 is provided in the entire upper surface and the entire lower surface of the vibrating body 3, but is not limited thereto, and may be provided in a part of the upper surface and a part of the lower surface. The piezoelectric element 6 may be provided only on one of the upper surface and the lower surface of the vibrating body 3.

  The power generation unit 5 is not limited to the piezoelectric element 6. The power generation unit 5 may have, for example, an electromagnet in the vibrating body 3 and generate power using a change in a magnetic field due to vibration of the vibrating body 3. For example, the power generation unit 5 may include a magnetostrictive element in the vibrating body 3 and generate power using a change in magnetic flux of the magnetostrictive element due to vibration of the vibrating body 3.

  The upper surface of the magnet 8 (second magnetic body 7) is attracted to the lower surface of the first end 31 of the vibrating body 3. In other words, the magnet 8 attracts the vibrating body 3 (first magnetic body 4) with a magnetic force from below (first direction) which is one of the vertical directions. The magnet 8 has two sets of two magnetic poles having different polarities on the upper surface and two other magnetic poles on the lower surface. The upper surface of the magnet 8 is also called a magnetic pole surface 80. The magnet 8 attracts the first end 31 of the vibrating body 3 at the magnetic pole surface 80. The detailed configuration of the magnet 8 will be described in “(4) Magnet configuration”.

  The housing 2 includes a body 21 and a cover 22. The body 21 is formed in a bottomed cylindrical shape that opens upward. The body 21 has a substantially rectangular outer shape when viewed from above. The fixing portion 24 is screwed to the upper surface of the bottom plate 211. The side surface 212 of the body 21 is provided with four claw portions 213 (only two are shown in FIG. 1) protruding outward from the side surface 212 of the body 21. The four claw portions 213 are part of a snap-fit structure for hooking the four locking portions 223 (only two are shown in FIG. 1) of the cover 22. The opening of the body 21 is covered with a cover 22.

  The side surface 212 of the body 21 is provided with four recesses 214 in which the side surface 212 of the body 21 is recessed. The vertical dimension of each recess 214 is longer than the distance that the first operating portion 92 moves in the vertical direction with respect to the body 21. The four locking portions 922 of the first operating portion 92 are inserted into the four concave portions 214, respectively.

  The cover 22 is formed in a substantially rectangular plate shape when viewed from above. A hole 222 penetrating in the vertical direction is provided in the central portion of the plate portion 221 of the cover 22. The hole 222 of the cover 22 is provided so that the cylindrical portion 931 protrudes above the cover 22 through the cylindrical portion 931 of the second operation portion 93. Four locking portions 223 projecting downward are provided at the edge portion of the plate portion 221. When the four locking portions 223 are hooked on the four claw portions of the body 21, the body 21 and the cover 22 are integrated. Between the body 21 and the cover 22 in the vertical direction, the fixed portion 24, the vibrating body 3, the weight 33, the magnet 8, the movable portion 91, and a part of the second operation portion 93 are housed. The

  The fixing part 24 includes a base part 241 and a plate part 243. The base 241 is formed in a substantially rectangular plate shape when viewed from above.

  The base 241 has a mounting base 244 on the rear side of the upper surface of the base 241. The mounting base 244 is provided to fix the second end 32 of the vibrating body 3 to the fixing portion 24 with the plate portion 243 sandwiching the second end 32 of the vibrating body 3. The plate portion 243 and the second end 32 of the vibrating body 3 are screwed to the mounting base 244, for example.

  The base 241 has a restricting portion 242 that protrudes upward from the upper surface of the base 241 at the front end of the base 241. When the vibrating body 3 bends and the first end 31 of the vibrating body 3 moves downward by a predetermined amount, the restricting portion 242 contacts the lower surface of the first end 31 and moves below the first end 31 beyond that. Regulate the movement of Thereby, the downward movement amount of the first end 31 of the vibrating body 3 is restricted to a predetermined amount or less.

  The base portion 241 has a pair of shafts 246 that protrude in the left-right direction from the respective end surfaces on both end surfaces in the left-right direction of the base portion 241. The pair of shafts 246 are provided so that the movable portion 91 can rotate around the shaft 246.

  The base 241 has a pair of guide shafts 245 that protrude upward from the upper surface of the base 241. The pair of guide shafts 245 are provided at positions corresponding to the pair of guide portions 933 of the second operation portion 93.

  The movable portion 91 moves the magnet 8 downward via the first operation portion 92 and the second operation portion 93 when the decorative cover 23 is pushed downward. Further, when the decorative cover 23 is changed from a state where the decorative cover 23 is pressed downward to a state where it is not pressed, the movable portion 91 moves the magnet 8 upward by the spring force received from the spring 916 and returns to the original position. 8 is returned to the original position. Therefore, the magnet 8 (second magnetic body 7) moves in the vertical direction (vibration direction) in conjunction with the operation unit 9.

  The movable portion 91 has a support portion 912 that is long in the left-right direction, and a pair of arm portions 910 that protrude rearward from both ends in the longitudinal direction of the support portion 912, and is U-shaped that is opened rearward when viewed from above. It is formed in a shape. The support portion 912 has a top plate 914 that is long in the left-right direction, and a pair of side plates 917 that protrude downward from both ends in the longitudinal direction of the top plate 914, and is U-shaped that opens downward when viewed from the front. Is formed. A concave portion 913 surrounded by the pair of side plates 917 and the top plate 914 opens downward. Since the horizontal dimension of the recess 913 is larger than the width of the vibrating body 3 in the left-right direction, the first end 31 of the vibrating body 3 is disposed in the recess 913.

  As shown in FIG. 3, a pair of ribs 915 (only one is shown in FIG. 3) and a pair of locking portions 918 projecting downward (one in FIG. 3) are provided on the lower surfaces of the pair of side plates 917, respectively. Only shown). The pair of ribs 915 are in contact with the upper surfaces of both end portions of the magnet 8 in the left-right direction. When the support portion 912 of the movable portion 91 moves downward, the pair of ribs 915 pushes the magnet 8 attracted to the vibrating body 3 downward, and moves the vibrating body 3 together with the magnet 8 downward by a predetermined amount. Further, the magnet 8 is pushed downward, and the magnet 8 is detached from the vibrating body 3. On the other hand, the pair of locking portions 918 are opposed to the lower surfaces of both end portions of the magnet 8 in the left-right direction. The vertical distance between the pair of ribs 915 and the pair of locking portions 918 is slightly larger than the vertical dimension of the magnet 8. Therefore, the magnet 8 can be slightly rotated along the surface of the pair of ribs 915 in a state where the pair of ribs 915 are in contact with the upper surface of the magnet 8. The pair of locking portions 918 hold the both ends of the magnet 8 with a pair of ribs 915 so as to be rotatable with respect to the support portion 912. In addition, the pair of locking portions 918 holds the magnet 8 between the pair of side plates 917. Thereby, the magnet 8 can move in the vertical direction in conjunction with the vertical movement of the support portion 912 of the movable portion 91 and can be slightly rotated with respect to the movable portion 91. For example, as shown in FIGS. 6A and 6B, the upper surface of the magnet 8 is parallel to the lower surface of the first end 31 of the vibrating body 3 even if the vibrating body 3 bends when the movable portion 91 moves downward. As the magnet 8 rotates, the attraction force to the first end 31 of the magnet 8 is stabilized.

  Each of the pair of arm portions 910 in the movable portion 91 is provided with a pair of shaft holes 911 into which a pair of shafts 246 provided in the base portion 241 are fitted. The movable portion 91 can rotate around the shaft hole 911. Each of the pair of arm portions 910 is provided with a spring 916. The pair of springs 916 applies a rotational force to each arm portion 910 to move the support portion 912 of the movable portion 91 upward. The pair of springs 916 are provided to push back the movable portion 91, the second operation portion 93, and the first operation portion 92 when the operator lifts his / her finger from the operation surface 231 of the decorative cover 23. ing.

  Between the pair of arm portions 910 of the movable portion 91, the second operation portion 93 is disposed.

(4) Configuration of Magnet As shown in FIGS. 4 and 5A, the magnet 8 has two magnetic poles having different polarities on the magnetic pole surface 80 that is the upper surface of the magnet 8. The magnet 8 is a neodymium magnet, for example. The first magnetic pole N1 of the two magnetic poles is an N pole, and the second magnetic pole S1 of the two magnetic poles is an S pole. The first magnetic pole N1 and the second magnetic pole S1 are arranged in the front-rear direction on the magnetic pole surface 80. A first region 86 having a large magnetic resistance is formed between the first magnetic pole N1 and the second magnetic pole S1. In FIG. 5A, the first region 86 is illustrated as a virtual surface that separates the first magnetic pole N1 and the second magnetic pole S1, and is a region having a surface orthogonal to the front-rear direction.

  Most of the magnetic flux (arrow indicated by a dotted line in FIG. 5A) emitted from the first magnetic pole N <b> 1 enters the second magnetic pole S <b> 1 through the space above the magnetic pole surface 80 of the magnet 8 without passing through the first region 86. Therefore, in the state where the lower surface of the first end 31 of the vibrating body 3 is in contact with the magnetic pole surface 80, most of the magnetic flux between the first magnetic pole N1 and the second magnetic pole S1 passes through the vibrating body 3, and the magnet 8 Adsorbs the vibrating body 3 by magnetic force.

  The magnet 8 further includes a third magnetic pole N2 and a fourth magnetic pole S2 having different polarities, in addition to the first magnetic pole N1 and the second magnetic pole S1. The third magnetic pole N2 is an N pole, and the fourth magnetic pole S2 is an S pole. The third magnetic pole N2 and the fourth magnetic pole S2 are arranged in the front-rear direction. A first region 86 having a large magnetoresistance is formed between the third magnetic pole N2 and the fourth magnetic pole S2.

  The third magnetic pole N2 is provided below the second magnetic pole S1, and the second magnetic pole S1 and the third magnetic pole N2 are arranged in the vertical direction. The fourth magnetic pole S2 is provided below the first magnetic pole N1, and the first magnetic pole N1 and the fourth magnetic pole S2 are arranged in the vertical direction. A second region 85 having a large magnetic resistance is formed between the first magnetic pole N1 and the fourth magnetic pole S2. In FIG. 5A, the second region 85 is illustrated as a virtual surface that separates the first magnetic pole N1 and the fourth magnetic pole S2. The second region 85 is a region having a surface orthogonal to the up-down direction. By providing the third magnetic pole N2 having a polarity different from that of the second magnetic pole S1 below the second magnetic pole S1, the upper surface of the magnet 8 can be easily made the magnetic pole surface of the second magnetic pole S1, and the vertical direction passes through the upper and lower surfaces of the magnet 8. The magnetic flux can be increased. Similarly, by providing the fourth magnetic pole S2 having a polarity different from that of the first magnetic pole N1 below the first magnetic pole N1, the upper surface of the magnet 8 can be easily made the magnetic pole surface of the first magnetic pole N1, and the upper surface and the lower surface of the magnet 8 are formed. It is possible to increase the vertical magnetic flux passing therethrough.

  The attracting force that the magnet 8 attracts the vibrating body 3 is stronger than the attracting force that the magnet 800 of the comparative example shown in FIG. 5B attracts the vibrating body 3. The magnet 800 of the comparative example shows, for example, a magnet 800 in which a first magnetic pole N1 and a second magnetic pole S1 are arranged on both surfaces in the vertical direction.

  In the magnet 800 of the comparative example, a third region 803 having a large magnetic resistance is formed between the first magnetic pole N3 and the second magnetic pole S3. In FIG. 5B, the third region 803 is illustrated as a virtual surface separating the first magnetic pole N3 and the second magnetic pole S3, and is a region having a surface orthogonal to the vertical direction. In order for the magnet 800 of the comparative example to attract the vibrating body 3 with a magnetic force on the upper surface 801, it is necessary to pass the magnetic flux between the first magnetic pole N3 on the upper surface 801 and the second magnetic pole S3 on the lower surface through the vibrating body 3. Therefore, for example, it is necessary to form a magnetic path by attaching a back yoke or the like for forming a magnetic path to the magnet 800 so that the magnetic flux emitted from the upper surface 801 enters the lower surface 802. For example, since the back yoke is attached to the magnet 800 using an adhesive or the like, it takes time to assemble the back yoke and the magnet 800, and the workability is poor.

  On the other hand, the magnet 8 of the power generation device 1 of the present embodiment has a magnetic pole surface 80 on the top surface, and the magnetic pole surface 80 has a first magnetic pole N1 and a second magnetic pole S1 having different polarities, so The magnetic flux tends to pass through the vibrating body 3 above the magnet 8. For this reason, the magnet 8 can attract the vibrating body 3 with a magnetic force without the back yoke, and the back yoke can be omitted from the power generation device 1, so that the number of parts of the power generation device 1 can be reduced.

  Since the vibrating body 3 is formed of a magnetic material, the magnet 8 can attract the vibrating body 3, and therefore the material of the weight 33 is not limited to a magnetic material but may be a nonmagnetic material. For example, since the restrictions on the material, weight, and shape of the weight 33 are less than when the weight 33 is formed of a magnetic material, the designer can easily design the weight 33.

  By the way, the weight 33 is not an essential component and can be omitted. Further, the weight 33 may be a magnetic material in addition to the nonmagnetic material. In this case, the weight 33 may be the first magnetic body 4 and the vibrating body 3 may be a nonmagnetic material.

  The magnet 8 of the power generation apparatus 1 according to the present embodiment can attract the vibrating body 3 with a magnetic force without a back yoke, but may have a back yoke. Further, the back yoke is not limited to being disposed on the lower surface of the magnet 8, and may be disposed on the side surface and the upper surface of the magnet 8, for example. For example, yokes are arranged on the upper surface side of the first magnetic pole N1 and the upper surface side of the second magnetic pole S1 of the magnet 8, respectively, and the yoke protrudes upward. Since the yoke can reduce the leakage of magnetic flux into the space and increase the magnetic flux density at the upper end portion of the yoke, it is possible to further increase the attractive force of the magnet 8.

  In short, the yoke may be omitted or may be disposed near the magnet 8 in order to adjust the attractive force of the magnet 8.

  By the way, the number of magnetic poles arranged in the front-rear direction on the magnetic pole surface 80 of the magnet 8 is not limited to two and may be four or more. In other words, in the magnetic pole surface 80, two or more sets of two magnetic poles arranged in the front-rear direction may be used. Similarly, the number of magnetic poles arranged in the vertical direction of the magnet 8 is not limited to two and may be four or more. In other words, in the magnetic pole surface 80, two or more sets of two magnetic poles arranged in the vertical direction (vibration direction) may be used. The magnet 8 is not limited to attracting the front end of the first end 31 of the vibrating body 3, and may attract a portion of the first end 31 near the second end 32, or near the center of the vibrating body 3. These sites may be adsorbed.

  In the power generation apparatus 1 of the present embodiment, the example in which the magnet 8 can be attracted to the vibrating body 3 has been described, but the present invention is not limited to this example. For example, the movable portion 91 of the power generation device 1 may include a member to be attracted formed of a metal material instead of the magnet 8, and the magnet 8 may be provided on the vibrating body 3. In that case, the attracted member is the second magnetic body 7, and the magnet 8 is the first magnetic body 4. It is only necessary that the attracted member is supported by the support portion 912 of the movable portion 91 and can be moved in the vertical direction in conjunction with the movable portion 91, and the attracted member can be attracted to the magnet 8. The magnet 8 provided on the vibrating body 3 can also serve as the weight 33 of the vibrating body 3.

  In addition, for example, the vibrating body 3 may have a magnet different from the magnet 8 in the vicinity of the first end 31 instead of the plate-like member made of SUS steel as the first magnetic body 4. In short, both the first magnetic body 4 and the second magnetic body 7 may be configured by magnets, and the first magnetic body 4 and the second magnetic body 7 may be configured to adsorb each other.

(5) Operation Procedure of Input Device An operation procedure of the input device 100 will be described with reference to FIGS.

  FIG. 6A shows the input device 100 in a state where the operation surface 231 of the decorative cover 23 is not pushed. FIG. 6B shows the input device 100 in a state where the operator pushes the operation surface 231 downward with a finger. In FIG. 6B, the downward force applied to the operation surface 231 is illustrated as F1. 6B, when a downward force F1 is applied to the decorative cover 23, the decorative cover 23 moves downward, and in conjunction with the downward movement of the decorative cover 23, the first operation unit 92 and the second operation unit 93, the support part 912 of the movable part 91, and the magnet 8 move downward. When the pushing portion 932 of the second operation portion 93 pushes the support portion 912 of the movable portion 91 downward, the movable portion 91 rotates around the shaft hole 911 and moves the magnet 8 downward. Since the magnet 8 is attracted to the first end 31 of the vibrating body 3 by the magnetic pole surface 80 on the upper surface, the vibrating body 3 first end 31 also moves downward in conjunction with the downward movement of the magnet 8, and the vibrating body. 3 bends downward.

  When the vibrating body 3 bends downward, the lower surface of the vibrating body 3 comes into contact with the upper end of the restricting portion 242 of the fixed portion 24, and the downward movement of the vibrating body 3 is restricted. In this state, the decorative cover 23, the first operation unit 92, and the second operation unit 93 are further movable downward. FIG. 6C shows a state in which the operator presses the operation surface 231 of the decorative cover 23 with a finger and applies a downward force F1 larger than the state of FIG. 6B to the decorative cover 23. The vibrating body 3 is in contact with the restricting portion 242 and restricted from moving downward, but the magnet 8 moves further downward in conjunction with the movement of the movable portion 91. When the elastic force of the vibrating body 3 exceeds the attracting force of the magnet 8, the vibrating body 3 is mechanically vibrated in the vertical direction away from the magnet 8. The piezoelectric element 6 can output electric power by the vibration of the vibrating body 3.

  As the attracting force of the magnet 8 to the vibrating body 3 increases, the relative positional relationship between the vibrating body 3 and the magnet 8 changes when the vibrating body 3 bends while the magnet 8 is attracted to the vibrating body 3. Therefore, the number of magnetic fluxes passing through the vibrating body 3 is difficult to change. Therefore, the attracting force with which the magnet 8 attracts the vibrating body 3 is likely to be stabilized. When the attracting force of the magnet 8 is stable, the elastic force of the vibrating body 3 at the time when the magnet 8 is pulled off from the vibrating body 3 is likely to be stable. Therefore, the magnitude of the force that pushes the operation surface 231 downward to vibrate the vibrating body 3 is less likely to vary. In other words, the power generation device 1 can reduce variation in force required for the push operation when the operator pushes the operation surface 231 in order to vibrate the vibrating body 3.

  When the operator removes his / her finger from the operation surface 231 so that the downward force F1 is not applied to the decorative cover 23, the movable portion 91 rotates about the shaft hole by the force received by the movable portion 91 from the pair of springs 916. To return to the original position. The magnet 8 also moves upward in conjunction with the movable portion 91 and returns to the original position. The vibrating body 3 is attracted to the magnet 8 that has been returned to its original position and becomes stationary.

(6) Summary As described above, the power generation device 1 includes the housing 2, the vibrating body 3, the power generation unit 5 (here, the piezoelectric element 6), the first magnetic body 4, and the second magnetic body 7 ( Here, a magnet 8) is provided. The vibrating body 3 is a member that is elastic and is held by the housing 2, and has a vibrating portion (here, the first end 31) that vibrates mechanically in the vibration direction (the vertical direction here). The power generation unit 5 converts the vibration energy of the vibrating body 3 when the vibration unit (first end 31) vibrates in the vibration direction (vertical direction) into electrical energy. The 1st magnetic body 4 is provided in the vibration part (1st end 31). The second magnetic body 7 is arranged side by side with the first magnetic body 4 in the vibration direction (vertical direction). The second magnetic body 7 is movable in the vibration direction (vertical direction) with respect to the housing 2 and attracts the first magnetic body 4 with a magnetic force from a first direction (downward here) which is one of the vibration directions. To do. When the second magnetic body 7 moves in the first direction (downward) with the second magnetic body 7 adsorbed to the first magnetic body 4, the vibrating portion (first end 31) is in the first direction (downward). ) To be displaced. When the second magnetic body 7 is separated from the first magnetic body 4, the vibrating portion (first end 31) is vibrated in the vibration direction (vertical direction) by the elastic force of the vibrating body 3. At least one of the first magnetic body 4 and the second magnetic body 7 (here, the second magnetic body 7) has one surface (here, the upper surface of the second magnetic body 7) facing the other in the vibration direction (vertical direction). The magnet 8 is a magnetic pole surface 80. The magnet 8 has at least one set of two magnetic poles (here, the first magnetic pole N1 and the second magnetic pole S1) having different polarities on the magnetic pole surface 80.

  According to the above configuration, the magnet 8 (second magnetic body 7) has at least one set of two magnetic poles having different polarities on the magnetic pole surface 80 attracted to the first magnetic body 4, so that a large amount of magnetic flux passes through the two magnetic poles. However, it is easy to pass through the first magnetic body 4 (first end 31) disposed at a position close to the magnetic pole surface 80. Therefore, the magnet 8 can stabilize the attracting force of the magnet 8 without forming a magnetic path by a back yoke or the like. Further, as the number of magnetic fluxes passing through the first magnetic body 4 (first end 31) increases, the attracting force of the magnet 8 increases. For this reason, most of the magnetic flux passing through the two magnetic poles of the magnetic pole surface 80 passes through the first magnetic body 4 (first end 31), so that the attractive force of the magnet 8 compared to the case where there is one magnetic pole on the magnetic pole surface 80. Becomes easier to stabilize, and its adsorption force becomes relatively large. When the attracting force of the magnet 8 increases, the elastic force of the vibrating body 3 at the time when the magnet 8 is pulled off from the vibrating body 3 also increases. As a result, the power generation device 1 can increase the amplitude of the vibrating body 3.

  In the power generation device 1 of the present embodiment, the vibrating body 3 is fixed to the housing 2 at one end (here, the second end 32) in an orthogonal direction (here, the front-rear direction) orthogonal to the vibration direction (up-down direction). Cantilevered. The magnet 8 preferably has at least one pair of two magnetic poles (first magnetic pole N1 and second magnetic pole S1) arranged in the orthogonal direction (front-rear direction) on the magnetic pole surface 80. According to the above configuration, the vibrating body 3 has a cantilever shape in which one end portion (second end 32) is fixed to the housing 2, and thus is orthogonal to the one end portion (second end 32) of the vibrating body 3. The other end portion (here, the first end 31) on the opposite side can be bent in the vibration direction (vertical direction). Since the two magnetic poles of the magnet 8 are arranged in the orthogonal direction (front-rear direction) on the magnetic pole surface 80, the magnet 8 is opposite to the one end portion (second end 32) in the vibrating body 3 in the orthogonal direction (front-rear direction). Adsorption force can be applied to the other end (first end 31) on the side. The magnet 8 attracts the other end (first end 31) rather than attracts the one end (second end 32), because of the attracting force applied to the vibrating body 3 when the magnet 8 moves downward. Since the moment is increased, the vibrating body 3 can be bent more greatly downward. Thereby, when the vibrating body 3 vibrates, the amplitude of the vibrating body 3 can be increased.

  In the power generator 1 of the present embodiment, the magnet 8 preferably has at least one pair of two magnetic poles (the first magnetic pole N1 and the second magnetic pole S1) arranged in the vibration direction (vertical direction). According to the above configuration, since two magnetic poles having different polarities are arranged in the vibration direction (vertical direction), it is easy to form the magnetic pole surface 80 through which the magnetic flux passes from the magnet 8 in the vibration direction on one surface intersecting the vibration direction in the magnet 8. ing.

  In the power generation device 1 of the present embodiment, the power generation unit 5 preferably includes a piezoelectric element 6 provided on the vibrating body 3. Thereby, the power generation unit 5 can convert the vibration energy when the vibrating body 3 vibrates mechanically into electrical energy using the piezoelectric element 6.

  The input device 100 according to the present embodiment includes an operation unit 9 (here, a first operation unit 92 and a second operation unit 93) that can move in the vibration direction (vertical direction) with respect to the power generation device 1 and the housing 2. And. The second magnetic body 7 (magnet 8) is configured to move in the vibration direction (vertical direction) in conjunction with the operation unit 9 (first operation unit 92 and second operation unit 93). According to the above configuration, since the input device 100 includes the power generation device 1, the attractive force of the magnet 8 that vibrates the vibrating body 3 can be increased.

  By the way, the magnet 8 is not limited to a neodymium magnet but may be an appropriate magnet such as a ferrite magnet, a cobalt magnet, or an alnico magnet.

  The vibrating part of the vibrating body 3 is not limited to the first end 31 of the vibrating body 3, and may be near the center of the vibrating body 3. Further, the second end 32 of the vibrating body 3 is not limited to being fixed to the body 21 via the fixing portion 24 and may vibrate in the vibration direction.

(Modification)
A power generation apparatus according to a modified example of the present embodiment (hereinafter, also simply referred to as a modified power generation apparatus) will be described. In addition, about the structure similar to this embodiment, the same code | symbol is turned down and description is abbreviate | omitted.

  In the magnet 8 of the power generation device 1 of the present embodiment, the first magnetic pole N1 and the second magnetic pole S1 are arranged in the front-rear direction on the magnetic pole surface 80. However, in the modified magnet, the first magnetic pole N1 and the second magnetic pole S1 are arranged on the magnetic pole surface. Two magnetic poles S1 are arranged in the left-right direction.

  In the power generator of the modified example, the vibrating body 3 has a cantilever shape in which one end portion (second end 32) in the orthogonal direction (front-rear direction) orthogonal to the vibration direction (up-down direction) is fixed to the housing 2. . The magnet of the modified example has two magnetic poles (first magnetic pole N1 and second magnetic pole) arranged in a direction (here, left-right direction) intersecting both the orthogonal direction (front-rear direction) and the vibration direction (up-down direction) on the magnetic pole surface 80. It is preferred to have at least one set of S1).

  According to the above configuration, the vibrating body 3 has a cantilever shape in which one end portion (second end 32) is fixed to the housing 2, and thus is orthogonal to the one end portion (second end 32) of the vibrating body 3. The other end portion (here, the first end 31) on the opposite side can be bent in the vibration direction (vertical direction). Here, when the vibrating body 3 is formed of a material having a large elastic force in the vibration direction, the vibrating body 3 is bent in the vibration direction while the magnet of the modification is adsorbed to the first magnetic body 4. At this time, the rear end portion of the magnetic pole surface 80 of the magnet according to the modification is easily separated from the first magnetic body 4. However, since the two magnetic poles are arranged in the direction (left-right direction) intersecting both the orthogonal direction and the vibration direction on the magnetic pole surface 80, the first magnetic body 4 is easily in contact with the vicinity of the front end of the magnetic pole surface 80. Thereby, even if the vibrating body 3 is formed of a material having a large elastic force in the vibration direction, the number of magnetic fluxes passing through the first magnetic body 4 among magnetic fluxes passing through the two magnetic poles is difficult to decrease. As a result, the attractive force of the magnet of the modified example is easily stabilized, and the elastic force of the vibrating body 3 at the time when the magnet of the modified example is removed from the vibrating body 3 is increased. Thereby, the power generator of the modification can increase the amplitude of the vibrating body 3.

  In the modified magnet, the first magnetic pole N1 and the fourth magnetic pole S2 are arranged in the vertical direction, and the fourth magnetic pole S2 is disposed below the first magnetic pole N1. In the modified magnet, the second magnetic pole S1 and the third magnetic pole N2 are arranged in the vertical direction, and the third magnetic pole N2 is disposed below the second magnetic pole S1. Thereby, the upper surface of the magnet of the modified example is likely to be a magnetic pole surface between the first magnetic pole N1 and the fourth magnetic pole S2.

  By the way, the number of magnetic poles arranged in the left-right direction is not limited to two and may be four or more. In other words, the number of two magnetic poles arranged in a direction intersecting both the orthogonal direction and the vibration direction may be two or more.

DESCRIPTION OF SYMBOLS 100 Input device 1 Power generation device 2 Case 242 Restriction part 3 Vibrating body 32 2nd end (one end part)
4 First magnetic body 5 Power generation section 6 Piezoelectric element 7 Second magnetic body 8 Magnet 80 Magnetic pole surface 9 Operation section N1 First magnetic pole (magnetic pole)
S1 Second magnetic pole (magnetic pole)

Claims (6)

A housing,
A member having elasticity and being held by the housing, and having a vibrating part that vibrates mechanically in a vibration direction; and
A power generation unit that converts vibration energy of the vibrating body into electric energy when the vibration unit vibrates in the vibration direction;
A first magnetic body provided in the vibrating section;
The first magnetic body is arranged side by side in the vibration direction, is movable in the vibration direction with respect to the housing, and the first magnetic body is magnetically moved from a first direction that is one of the vibration directions. A second magnetic material to be adsorbed;
With
When the second magnetic body moves in the first direction with the second magnetic body adsorbed to the first magnetic body, the vibrating portion is displaced in the first direction, and the second magnetic body is displaced. The vibrating portion is configured to vibrate in the vibration direction by an elastic force of the vibrating body when a body is separated from the first magnetic body,
At least one of the first magnetic body and the second magnetic body is a magnet having one surface facing the other in the vibration direction as a magnetic pole surface,
The magnet has at least one set of two magnetic poles having different polarities on the magnetic pole surface. The vibrating body has a cantilever shape in which one end portion in an orthogonal direction orthogonal to the vibration direction is fixed to the housing.
The power generation device according to claim 1, wherein the magnet has at least one set of the two magnetic poles arranged in the orthogonal direction on the magnetic pole surface. The vibrating body has a cantilever shape in which one end portion in an orthogonal direction orthogonal to the vibration direction is fixed to the housing.
The power generator according to claim 1, wherein the magnet has at least one set of the two magnetic poles arranged in a direction intersecting both the orthogonal direction and the vibration direction on the magnetic pole surface. The power generator according to claim 1, wherein the magnet has at least one set of two magnetic poles arranged in the vibration direction. The power generation device according to claim 1, wherein the power generation unit includes a piezoelectric element provided on the vibrating body. A power generator according to claim 1;
An operation unit movable in the vibration direction with respect to the housing;
With
The input device, wherein the second magnetic body is configured to move in the vibration direction in conjunction with the operation unit.

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