WO2016052198A1 - Dispositif d'entrée de production d'énergie - Google Patents

Dispositif d'entrée de production d'énergie Download PDF

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Publication number
WO2016052198A1
WO2016052198A1 PCT/JP2015/076276 JP2015076276W WO2016052198A1 WO 2016052198 A1 WO2016052198 A1 WO 2016052198A1 JP 2015076276 W JP2015076276 W JP 2015076276W WO 2016052198 A1 WO2016052198 A1 WO 2016052198A1
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WO
WIPO (PCT)
Prior art keywords
power generation
switching
input device
operating
operated
Prior art date
Application number
PCT/JP2015/076276
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English (en)
Japanese (ja)
Inventor
鈴木 克俊
Original Assignee
アルプス電気株式会社
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by アルプス電気株式会社 filed Critical アルプス電気株式会社
Priority to JP2016551914A priority Critical patent/JP6243549B2/ja
Publication of WO2016052198A1 publication Critical patent/WO2016052198A1/fr

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    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02KDYNAMO-ELECTRIC MACHINES
    • H02K35/00Generators with reciprocating, oscillating or vibrating coil system, magnet, armature or other part of the magnetic circuit
    • H02K35/02Generators with reciprocating, oscillating or vibrating coil system, magnet, armature or other part of the magnetic circuit with moving magnets and stationary coil systems

Definitions

  • the present invention relates to a power generation input device capable of generating power with the same power generation unit when any one of a plurality of operation members is operated.
  • Patent Document 1 describes an invention relating to a power generation input device.
  • a space is formed between two opposing ends of the magnetic path forming member, and a rotating body is provided in this space.
  • the rotating body has one magnet and a magnetized member that is superposed on different magnetic pole faces of the magnet.
  • two magnetized members magnetized to different poles are alternately opposed to the opposing end of the magnetic path forming member during the rotation.
  • the magnetic flux in the magnetic path forming member is changed.
  • the magnetic path forming member is provided with a power generating coil, and electric power is generated according to a change in magnetic flux in the magnetic path forming member. Electric power is generated when the operation member is operated in one direction and when it is operated in the other direction. This electric power is rectified and applied to the signal processing circuit, and the operation member is operated in one direction and operated in the other direction. Each produces a signal.
  • the conventional power generation input device described in Patent Document 1 is provided with one operation member for one rotating body, a plurality of operation members are provided, and each operation member is operated. In order to generate an operation signal corresponding to the above, it is necessary to provide a plurality of power generation input devices.
  • the present invention solves the above-described conventional problems, and an object of the present invention is to provide a power generation input device in which one power generation unit can be operated by a plurality of operation members.
  • the power generation input device of the present invention includes a magnetic path forming member, a rotating member that has a magnet and changes the magnetic flux applied to the magnetic path forming member by its rotating operation, and the electric power is generated by a change in magnetic flux in the magnetic path forming member
  • a power generation unit having a power generation coil to be induced
  • a switching member that applies a rotational force to the rotating member, and an operation member that operates the switching member to rotate the rotating member
  • a plurality of the operating members are provided for one power generation unit and one switching member, and a moving force is applied from the operating member to the switching member when any of the operating members is operated.
  • the rotating member is rotated.
  • the power generation input device of the present invention can generate power with a common power generation unit by moving a common switching member by operating any one of a plurality of operation members. Therefore, various operations can be performed with the power generated by the minimum number of power generation units.
  • the power generation input device of the present invention is provided with a spring member that biases the switching member to an initial position, and the switching member is defined as the initial position regardless of which of the plurality of operating members is operated. It can be configured to be moved to the switching position in the reverse direction.
  • the operation direction of the plurality of operation members intersects the movement direction of the switching member, and a cam mechanism is provided between each of the operation members and the switching member.
  • the rotation member is rotated by the relative operation of the power generation unit and the switching member
  • the switching member moves, and the rotation member can be rotated by the relative operation of the switching member and the power generation unit.
  • the first operation member and the other operation member have the same operation direction, and are provided with a swing transmission mechanism that moves the switching member by the operation force of the other operation member.
  • a swing transmission mechanism that moves the switching member by the operation force of the other operation member.
  • a plurality of the other operation members can be provided.
  • the power generation input device of the present invention is provided with a detection member that detects which one of the plurality of operation members is operated, and the detection member operates with electric power induced in the coil.
  • a signal processing circuit that operates with the power induced in the coil is provided, and in the signal processing circuit, which operation member is operated when receiving the power and receiving a detection signal from the detection member. A different signal is generated for each of the plurality of operation members.
  • a different signal is generated for each operation of the plurality of operating members, and when the switching member moves to the other, a single release signal Is preferably produced.
  • the processing operation of the signal processing circuit is simplified, and various input operations can be performed using a plurality of operation members.
  • the power generation unit and the switching member are commonly used by a plurality of operation members, various operations can be performed using the minimum number of power generation units.
  • FIG. 1 The perspective view which shows the electric power generation input device of the 1st Embodiment of this invention
  • 1 is an exploded perspective view of the power generation input device shown in FIG. (A)
  • B) is the front view which shows the electric power generation input device of 1st Embodiment according to operation
  • (A) and (B) show the power generation input device of the first embodiment by operation, and are sectional views taken along the line IV-IV in FIG.
  • the power generation input device 1 has the X1 direction as the left direction, the X2 direction as the right direction, the Y1 direction as the front, the Y2 direction as the rear, and the Z1 direction as the upper direction.
  • the Z2 direction is downward.
  • the moving direction of the switching member 20, which will be described later is the X1-X2 direction. When moved to the X1, the initial position of the switching member 20 is obtained, and when moved in the X2 direction, the switching position of the switching member 20 is obtained.
  • the power generation input device has a support base 10.
  • the support base 10 is made of a nonmagnetic material such as a synthetic resin material. As shown in FIG. 2, the support base 10 is formed with a guide recess 11 extending rearward (Y2 direction) and in the left-right direction (X1-X2 direction). Although omitted in FIG. 2, a back base 13 shown in FIG. 3 is provided behind the support base 10, and the support base 10 and the back base 13 are fixed to each other with a fixing screw or the like.
  • a switching member (switching slider) 20 is fitted in the guide recess 11 of the support base 10.
  • the switching member 20 is supported so as to be movable in the X1-X2 direction in the guide recess 11 with the rear side supported by the back base 13.
  • the switching member 20 is made of a nonmagnetic material such as a synthetic resin material.
  • the support base 10 is formed with a protrusion 14 protruding forward, and a sliding space 15 extending in the X1-X2 direction is formed in the protrusion 14 in the front-rear direction (Y1-Y2 direction). It is provided to penetrate through.
  • the switching member 20 is provided with an urging protrusion 21 protruding forward (Y1 direction), and the urging protrusion 21 is slidably inserted into the sliding space 15.
  • Two compression coil springs 25 are accommodated in the sliding space 15, and the compression coil springs 25 are interposed in a compressed state between the inner wall portion 15 a on the X2 side of the sliding space 15 and the biasing protrusion 21. is doing.
  • the switching member 20 is urged toward the X1 direction by the elastic force of the compression coil spring 25.
  • the switching member 20 is provided with a pair of operation cams 22 and 22 facing forward (Y1 direction).
  • the operation cams 22 are arranged with an interval in the X1-X2 direction with the installation area of the compression coil spring 25 interposed therebetween.
  • Each operation cam 22 is an inner wall surface on the X2 side of the cam recess 22a, and is an inclined surface that extends in the right direction (X2 direction) as it goes upward (Z1 direction).
  • a switching cam 23 is formed at the end of the switching member 20 on the X2 side.
  • the switching cam 23 is a cam groove (cam hole) penetrating the switching member 20 in the front-rear direction, and is formed so as to be inclined in the left direction (X1 direction) as it goes upward (Z1 direction).
  • operation holes 16 and 16 are opened on the upper surface of the support base 10, and sliding grooves 17 and 17 extending vertically below the operation holes 16 and 16 are formed in the rear part of the support base 10.
  • Operation members 27 and 27 are inserted into the operation holes 16 and 16 from above.
  • the operation members 27 are made of a nonmagnetic material such as synthetic resin.
  • the operating members 27, 27 are formed with sliding protrusions 27b, 27b that are directed forward (Y1 direction) in an up and down direction, and the sliding protrusions 27b, 27b are fitted in the sliding grooves 17, 17,
  • the operation members 27 and 27 are individually movable in the vertical direction (Z1-Z2 direction).
  • the operation members 27 and 27 are integrally formed with follower portions 27c and 27c protruding rearward (Y2 direction), and the follower portions 27c and 27c slide on the operation cam 22 formed on the switching member 20. Opposite to be able to move.
  • the operation cam 22 and the follower parts 27c and 27c constitute an operation cam mechanism.
  • the operation members 27 and 27 are individually urged downward to press the follower portions 27 c and 27 c against the operation cams 22 and 22.
  • An urging member is provided.
  • the upper ends of the operation members 27 and 27 are operation pressing portions 27a and 27a.
  • the operation pressing portions 27a and 27a are pressed by an operation button (not shown) disposed above, and the operation members 27 and 27 are individually pressed downward. Operated.
  • the moving direction (Z1-Z2 direction) of the operating members 27, 27 is a direction orthogonal to the moving direction (X1-X2 direction) of the switching member 20. As shown in FIG. 3B, when any one of the plurality of operation members 27, 27 is pushed downward, the switching member 20 is moved rightward.
  • the power generation input device 1 is provided with a detection member 45 that detects which of the plurality of operation members 27 has been operated.
  • the detection member 45 is shown in the circuit diagram shown in FIG. In the first embodiment, since two operation members 27 are provided, at least one detection member 45 is required.
  • a magnet is provided on one operation member 27, and a magnetic sensor is used as the detection member 45 on the support base 10 or the back base 13. Further, a mechanical switch that detects that at least one operation member 27 has been operated may be used as the detection member 45.
  • the support base 10 is formed with a switching window 12 penetrating in the front-rear direction (Y1-Y2 direction), and a switching cam 23 provided on the switching member 20 is located behind the switching window 12. Opposite.
  • a rotating member 30 is housed in a switching window 12 formed in the support base 10.
  • the rotating member 30 includes a magnet 31, a first magnetizing member 32 and a second magnetizing member 33 sandwiching the magnet 31.
  • the magnet 31 is plate-shaped, and one plate surface is a first magnetized surface 31a and the other plate surface is a second magnetized surface 31b.
  • the first magnetized surface 31a and the second magnetized surface 31b are magnetized to different magnetic poles.
  • the first magnetizing member 32 is in close contact with the first magnetized surface 31a
  • the second magnetizing member 33 is in close contact with the second magnetized surface 31b.
  • the rotating member 30 is held by the bracket 34 from the rear (Y2 side).
  • the left side portion 34a of the bracket 34 is on the left side (X1 side) of the rotating member 30.
  • the right side 34b is located on the right side (X2 side).
  • a support shaft 35a protruding in the X1 direction is integrally formed on the left side portion 34a of the bracket 34, and a support shaft 35b protruding in the X2 direction is integrally formed on the right side portion 34b.
  • a bearing groove 12a is formed on the left inner wall, and a bearing groove 12b is formed on the right inner wall.
  • a stopper member 18 is fixed to the front portion of the support base 10.
  • the stopper member 18 is integrally formed with restricting protrusions 18a and 18a that protrude rearward.
  • the support shaft 35a is inserted into the bearing groove 12a
  • the support shaft 35b is inserted into the bearing groove 12b
  • the restricting protrusions 18a and 18a of the stopper member 18 are The support shafts 35a and 35b are prevented from coming off by being fitted into the bearing grooves 12a and 12b.
  • the rotating member 30 is rotatably supported in the switching window 12 around the support shafts 35a and 35b.
  • the bracket 34 is integrally formed with a follower protrusion 36 protruding rearward, and the follower protrusion 36 is slidably inserted into the switching cam 23 formed on the switching member 20. Has been. Therefore, the rotating member 30 can be rotated by the moving force of the switching member 20.
  • the switching cam 23 and the follower protrusion 36 constitute a switching cam mechanism.
  • the front surface (Y1 direction) of the support base 10 is a yoke support surface 10a, and a magnetic path forming member (magnetic path yoke) 40 is fixed to the yoke support surface 10a.
  • a magnetic path forming member (magnetic path yoke) 40 is fixed to the yoke support surface 10a.
  • On the right side (X2 side) end of the magnetic path forming member 40 there are provided an upper facing end surface 41 and a lower facing end surface 42 that are spaced vertically to face each other.
  • the magnetic path forming member 40 is made of a magnetic material, and is configured so that the magnetic flux can pass through the inside substantially along a U-shaped path from the upper facing end face 41 to the lower facing end face 42.
  • the magnetic path forming member 40 may be integrally formed with one member as long as the magnetic flux can pass through the inside, or may be configured by combining a plurality of members.
  • the lower part of the magnetic path forming member 40 is inserted into the bobbin 46, and the power generation coil 47 is wound around the bobbin 46.
  • the magnetic path forming member 40 is fixed to the yoke support surface 10 a, the bobbin 46 and the power generation coil 47 are accommodated inside the opening 19 formed in the support base 10.
  • the rotating member 30 is positioned between the upper facing end surface 41 and the lower facing end surface 42 of the magnetic path forming member 40. To do.
  • the rotating member 30, the magnetic path forming member 40, and the power generating coil 47 constitute a power generating unit.
  • the switching member 20 is moved to the left (X1 side) by the elastic force of the compression coil spring 25. It is in the initial position. At this time, all the operation members 27 are lifted upward (Z1 direction) by the respective operation cams 22.
  • the magnetic flux path when the rotating member 30 is in the initial posture is as follows: magnet 31 ⁇ second magnetizing member 33 ⁇ lower end surface 33a of second magnetizing member 33 ⁇ lower facing end surface 42 ⁇
  • the magnetic path forming member 40 ⁇ the upper facing end face 41 ⁇ the upper end face 32 a of the first magnetizing member 32 ⁇ the first magnetizing member 32.
  • the magnetic flux path is changed from the magnet 31 to the second magnetizing member 33 to the upper end surface 33b of the second magnetizing member 33 to the upper facing end surface 41 to the magnetic path formation.
  • FIG. 5 shows a control circuit 50 attached to the power generation input device 1 shown in FIGS.
  • the first electromotive force V1 first induced current
  • the capacitor 54 is charged and discharged through the diode group 53, and the wavelength of the current based on the first electromotive force V1 applied to the electromotive force line 55 is slightly increased.
  • the current whose wavelength has been increased is supplied from the power line 56 to the rectifier circuit 57 and converted into direct current, and direct current power is supplied to the power input portions of the signal processing circuit 58 and the transmission circuit 59.
  • DC power is also supplied to the detection member 45 provided with a magnetic sensor or the like.
  • the ON signal line 64 is drawn out from one end 51 of the winding of the power generation coil 47.
  • a diode 61 is provided on the ON signal line 64 to pass a current based on the first electromotive force V1.
  • the current passing through the diode 61 flows to the resistor R1, and an ON signal based on the voltage value set by the resistor R1 is generated by the signal processing device 58.
  • the ON input section 58a To the ON input section 58a.
  • the signal processing circuit 58 recognizes that the operation member 27 has been operated when an ON signal is given to the ON input section 58a. Furthermore, since the detection signal from the detection member 45 activated by the first electromotive force V1 is given, it is possible to recognize which operation member 27 has been operated.
  • the current based on the second electromotive force V2 is supplied from the other end 52 of the winding of the power generating coil 47. Is applied to the diode 63 via the OFF signal line 62. Then, an OFF signal having a voltage value determined by the resistor R ⁇ b> 2 is input to the OFF input unit 58 b of the signal processing circuit 58. As a result, the signal processing circuit 58 recognizes that the operating force F applied to the operating member 27 has been released.
  • the signal processing circuit 58 can be operated by being supplied with the first electromotive force V1 or the second electromotive force V2.
  • an operation signal is obtained when an ON signal with the operation member 27 pressed is obtained. Is generated. Further, it is possible to identify which operation member 27 is operated by referring to the detection output from the detection member 45 activated by the first electromotive force V1. Therefore, different operation signals are generated when the right operation member 27 is pressed and when the left operation member 27 is pressed. However, when the operation force F is released, the same release signal is generated regardless of which operation member has been pressed.
  • the two types of operation signals and one type of release signal are given to the data input unit of the transmission circuit 59 that operates with the first electromotive force V1 or the second electromotive force V2, and are externally transmitted by RF transmission or infrared transmission. A signal is transmitted to the circuit.
  • the power generation input device 101 includes a cylindrical nonmagnetic support base 111 having a ceiling portion and a nonmagnetic back base 113 that closes an opening on the lower side (Z2 side) of the support base 111.
  • the inside of 111 is a mechanism storage part.
  • a cylindrical unit support space 112 extending vertically is formed in the center of the ceiling portion of the support base 111, and the power generation unit 120 inside the unit support space 112 is accommodated.
  • the power generation unit 120 has a unit case 121 made of a nonmagnetic material.
  • the unit case 121 is a cylindrical case, and is supported in the unit support space 112 so as to be slidable in the vertical direction (Z1-Z2).
  • magnetic path forming members 40, 40 are provided in the unit case 121.
  • a magnetic core 40 a is passed between the magnetic path forming member 40 and the magnetic path forming member 40 inside the unit case 121.
  • the magnetic path forming members 40, 40 and the magnetic core 40a are both made of a magnetic material, and the magnetic core 40a constitutes a part of the magnetic path forming member.
  • a power generation coil 47 is wound around the magnetic core 40a.
  • a bearing member 118 is mounted between one magnetic path forming member 40 and the other magnetic path forming member 40.
  • the bearing member 118 is formed with holding grooves 118a and 118a extending in the vertical direction on both left and right sides, and the holding grooves 118a and 118a are inserted into the respective end portions 40a and 40a of the two magnetic path forming members 40 from above. It is fixed in such a way.
  • Rotating member 30 is supported on bearing member 118. As shown in FIG. 12, the rotating member 30 is configured by laminating a magnet 31, a first magnetizing member 32, and a second magnetizing member 33. The magnet 31 and the magnetizing members 32, 33 are made of a nonmagnetic material. It is held by the formed bracket 34.
  • the power generation unit 120 is composed of the rotating member 30, the magnetic path forming members 40, 40, the magnetic core 40a, the power generation coil 47, and the unit case 121 that houses them.
  • the bracket 34 is integrally formed with a support shaft 35a projecting upward (Z1 side) and a support shaft 35b projecting downward (not shown).
  • a support shaft 35a is supported in a bearing hole 118b formed in the upper part of the bearing member 118, and a support shaft 35b is supported in a bearing hole formed in the lower part.
  • the rotary member 30 is rotatable about a vertically extending shaft. It has become.
  • a switching member 20 is provided inside the support base 111.
  • a lower portion of the switching member 20 is a sliding shaft portion 20a, and is slidably inserted into a sliding hole 121a opened at the bottom of the unit case 121.
  • a switching cam 23 is formed on the switching member 20, and a follower protrusion 36 formed on a bracket 34 that holds the rotating member 30 is slidably inserted into the switching cam 23.
  • the switching cam 23 and the follower projection 36 constitute a switching cam mechanism.
  • a compression coil spring (not shown) is interposed between the ceiling inner surface 121b of the unit case 121 and the arm portions 20b, 20b extending to the left and right sides of the switching member 20, The switching member 20 is always urged downward (Z2 direction).
  • a first operation member 127 a is provided at the center of the support base 111 so as to be able to move downward, and the first operation member 127 a is in contact with the upper surface of the unit case 121.
  • a second operation member 127 b is provided above the center portion of the back base 113. The second operation member 127 b is fitted and fixed to the lower end portion of the sliding shaft portion 20 a formed on the switching member 20.
  • the support base 111 is provided with a plurality of other operation members 127c so as to surround the first operation member 127a.
  • a total of six other operation members 127c are provided, each of which can be pressed downward.
  • a swing transmission mechanism 131 is provided below each of the other operation members 127c.
  • the inner end 131a of the swing transmission mechanism 131 is in contact with the lower side of the second operation member 127b.
  • the detection member 45 is fixed to the other end portion of the swing transmission mechanism 131.
  • Each detection member 45 is opposed to the lower side of the other operation member 127c.
  • the detection member 45 is a tactile switch that is a switch mechanism that causes a tactile feeling.
  • the structure is a mechanical contact type push button switch.
  • a push button, a movable contact made of a metal reversing spring, and a fixed contact are arranged in an insulating resin case.
  • the push button is pushed by the other operation member 127c, the movable contact is inverted to create a click feeling, and is brought into and out of contact with the fixed contact, thereby switching the electrical conduction state.
  • Each detection member 45 is connected to a signal processing circuit 58 similar to that shown in FIG. 5 via a flexible cable.
  • FIG. 7 and 8 show a state where none of the operation members is operated.
  • the ceiling inner surface 121b of the unit case 121 and the switching member 20 are repelled in the vertical direction by the compression coil spring, the follower protrusion 36 provided on the rotating member 30 of the power generation unit 120 is It moves to the upper end part of the switching cam 23 formed in 20.
  • the rotating member 30 is in the initial posture shown in FIG.
  • FIG. 9 shows an operation state in which the first operation member 127a located at the center portion of the support base 111 is pressed downward by the operation force F.
  • the unit case 121 and the power generation unit 120 are lowered together with the first operation member 127a. Since the switching member 20 is pressed against the inner end 131a of the swing transmission mechanism 131 together with the second operation member 127b, the power generation unit 120 is lowered without the switching member 20 moving.
  • the follower projection 36 provided on the rotating member 30 moves downward in the switching cam 23 formed on the switching member 20, and the rotating member 30 is counterclockwise from the initial posture shown in FIG. To turn.
  • the unit case 121 and the power generation unit 120 are moved together by the biasing force of the compression coil spring provided between the ceiling inner surface 121 b of the unit case 121 and the switching member 20.
  • the first operating member 127a returns to its original position, and the rotating member 30 also returns to the initial posture shown in FIG.
  • the first magnetizing member 32 of the rotating member 30 faces the opposing end face 42 of the magnetic path forming member 40, and the second magnetizing member 33 is It faces the other facing end face 41.
  • the first magnetizing member 32 faces the facing end surface 41 and the second magnetizing member 33 faces the facing end surface. 42.
  • the first electromotive force V1 shown in FIG. 6 is generated by the change in the magnetic flux flowing in the magnetic path forming member 40 at this time.
  • FIG. 10 shows a state in which the operating force F is obtained in one of the six other operating members 127c.
  • the operating force F is applied to the swing transmission mechanism 131 via the detection member 45, the swing transmission mechanism 131 swings, and the switching member 20 is lifted upward via the second operation member 127b. Since the switching member 20 is lifted without the power generation unit 120 moving, the rotation member 30 is rotated counterclockwise from the initial posture shown in FIG. Therefore, the first electromotive force V1 shown in FIG.
  • the swing transmission mechanism 131 Since the swing transmission mechanism 131 is provided with the return spring 132, when the operation force F with respect to the other operation member 127c is removed, the swing transmission mechanism 131 returns to the initial state shown in FIGS. Return to position. At this time, since the switching member 20 is lowered, the rotation member 30 is returned to the initial posture shown in FIG. 12 by the switching cam 23, and the second electromotive force V2 shown in FIG.
  • the power generation operation of the power generation unit 120 is the same when the first operation member 127a is pressed and when any of the other operation members 127c is pressed.
  • an ON signal is supplied to the ON input portion 58a of the signal processing circuit 58 both when the first operating member 127a is pressed and when any of the other operating members 127c is pressed. Is given.
  • an OFF signal is given to the OFF input unit 58b of the signal processing circuit 58 in any case.
  • a detection member 45 such as a tactile switch is provided below all other operation members 127c
  • a plurality of other operation members are detected by a detection signal of the detection member 45. It can be identified which of the 127c has been operated.
  • the first operation member 127a is not provided with the detection member 45. Therefore, the signal processing circuit 58 activated by the first electromotive force V1 can know which of the other operation members 127c has been operated by receiving the signal of the detection member 45. Furthermore, when the signal of the detection member 45 is not detected when the ON signal is received, it can be recognized that the first operation member 127a has been operated. Therefore, the signal processing circuit 58 can generate an operation signal corresponding to the operated operation member.
  • the second operation member 127b located on the lower side may be configured to be pushed upward with a finger.

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Abstract

L'invention aborde le problème de la réalisation d'un dispositif d'entrée de production d'énergie de telle sorte qu'une unité de production d'énergie commune peut être mise en fonctionnement par de multiples éléments d'actionnement. L'invention réalise à cet effet un dispositif d'entrée de production d'énergie comprenant deux éléments d'actionnement (27, 27). Lorsque l'un ou l'autre des éléments d'actionnement (27) est actionné, un élément de basculement (20) est déplacé vers la droite (direction X2) par une came d'actionnement (22), un élément rotatif (30) doté d'un aimant est mis en rotation par la force de déplacement de l'élément de basculement (20) de telle sorte qu'un flux magnétique à l'intérieur d'un élément de formation de trajet magnétique est modifié, et de l'électricité est générée par une bobine de générateur. Un élément de détection est disposé sur au moins l'un des éléments d'actionnement (27) et l'élément de détection est actionné par une force électromotrice résultante et peut identifier lequel des éléments d'actionnement (27) a été actionné.
PCT/JP2015/076276 2014-09-29 2015-09-16 Dispositif d'entrée de production d'énergie WO2016052198A1 (fr)

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JP2014199014 2014-09-29

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Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN108799028A (zh) * 2018-07-11 2018-11-13 深圳市无电通科技有限公司 循环分解装置和循环发电装置及循环分解方法
KR20190031296A (ko) * 2016-09-02 2019-03-25 알프스 알파인 가부시키가이샤 발전 장치
JP6741334B1 (ja) * 2020-05-14 2020-08-19 ヤマウチ株式会社 発電装置

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JP2013021746A (ja) * 2011-07-07 2013-01-31 Alps Electric Co Ltd 発電入力装置および前記発電入力装置を使用した電子機器
US20130093540A1 (en) * 2010-03-23 2013-04-18 Zf Friedrichshafen Ag Induction generator

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US20130093540A1 (en) * 2010-03-23 2013-04-18 Zf Friedrichshafen Ag Induction generator
JP2013021746A (ja) * 2011-07-07 2013-01-31 Alps Electric Co Ltd 発電入力装置および前記発電入力装置を使用した電子機器

Cited By (6)

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KR102172547B1 (ko) 2016-09-02 2020-11-02 알프스 알파인 가부시키가이샤 발전 장치
CN108799028A (zh) * 2018-07-11 2018-11-13 深圳市无电通科技有限公司 循环分解装置和循环发电装置及循环分解方法
CN108799028B (zh) * 2018-07-11 2024-04-30 广东易百珑智能科技有限公司 循环分解装置和循环发电装置及循环分解方法
JP6741334B1 (ja) * 2020-05-14 2020-08-19 ヤマウチ株式会社 発電装置
JP2021180576A (ja) * 2020-05-14 2021-11-18 ヤマウチ株式会社 発電装置

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