JP2011116205A - Solenoid for vehicle and shift device for vehicle automatic transmission - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a solenoid for a vehicle obviating the need of attaching a harness and obviating the risk that soldering crack may occur, and a shift device for a vehicle automatic transmission. <P>SOLUTION: The solenoid 100 for the vehicle includes a solenoid body 101 fixed to a circuit board 72, and a spring body with a conductive property and an elasticity. The proximal end side of the spring body is conductively connected to a coil wire equipped to the solenoid body 101, and the distal end side thereof is provide with a circuit abutting portion in contact with a circuit for the solenoid equipped on the circuit board 72. The circuit contact portion is configured to press the circuit for the solenoid by elasticity when fixed to the circuit board 72 of the solenoid body 101. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a vehicle solenoid used in a vehicle such as an automobile and a shift device for a vehicle automatic transmission including the vehicle solenoid.

  2. Description of the Related Art Conventionally, shift devices for automatic transmissions used in vehicles such as automobiles are widely known and disclosed in, for example, Patent Document 1. The shift device for an automatic transmission disclosed in Patent Document 1 is connected to a transmission switching member (guide bracket) that is connected to a transmission provided in a vehicle via a cable, and to the transmission switching member. · comprising coupling releasably linked change lever and a (shift lever). When the change lever is operated to move to each range in the main gate while being connected to the transmission switching member, the transmission switching member is rotated accordingly, and the cable is pushed and pulled during the rotation. Shift the transmission.

  Further, in such a shift device for an automatic transmission, once the change lever enters the parking (P) range provided in the main gate, the shift is locked so that the change lever does not unexpectedly move to another range. A locking mechanism is provided.

  As such a shift lock mechanism, for example, the one shown in FIG. The shift lock mechanism includes a lock member 201 that locks / unlocks a transmission switching member 200 that rotates in the front-rear direction (X-Y direction in the figure), and a vehicle solenoid 202 that is interlocked with a brake device provided in the vehicle. And. Further, the vehicle solenoid 202 includes a solenoid body 202a and a plunger 202b that moves in and out of the solenoid body 202a. The lock member 201 includes an abutting portion 201a that abuts the transmission switching member 200 at the upper end thereof, and the lower end of the lock member 201 is coupled to the tip of the plunger 202b. Further, a shaft support portion 201b is provided at the upper and lower intermediate portions of the lock member 201. When the lock member 201 rotates about the shaft support portion 201b, the contact portion 201a moves in the left-right direction (ZW in the figure). Direction).

  When the lever shaft 203 of the change lever enters the parking range, it is detected by detection means (not shown), and the plunger 202b of the vehicle solenoid 202 is caused to project. Accordingly, as shown in FIG. 20B, the lock member 201 rotates around the shaft support portion 201 b, and the contact portion 201 a is disposed at the rear position of the transmission switching member 200. In this state, the transmission switching member 200 cannot rotate rearward due to the locking member 201 being in the way, and the lever shaft 203 of the change lever connected thereto cannot be moved in the front-rear direction.

  From this state, when the brake pedal, which is a brake device, is depressed and the brake operation is started, the plunger 202b is moved in and out as shown in FIG. At that time, the lock member 201 rotates about the shaft support portion 201b, and the contact portion 201a moves backward from the rear position of the transmission switching member 200 to the left side. Thereby, the transmission switching member 200 can be rotated.

  Further, for example, as shown in FIG. 21, such a vehicle solenoid 202 has a harness 202e attached to the solenoid body 202a, and supplies power to the solenoid body 202a via the harness 202e.

JP 2007-230424 A

  However, if the harness 202e is attached to the solenoid body 202a, it takes a lot of time for the attachment work, and the attached harness 202e may interfere with other work.

  At that time, it is also conceivable to solder the solenoid body 202a to a solenoid circuit provided on the circuit board in place of the harness 202e. However, in this case, solder cracks may occur due to vibrations of the running vehicle, which may cause poor connection and is difficult to employ.

  An object of the present invention is to provide a vehicular solenoid and a vehicular automatic transmission shift device that can eliminate the need for attachment of a harness and that do not cause solder cracks.

  In order to solve the above-mentioned problem, the invention of claim 1 is a vehicle solenoid equipped in a vehicle so as to be electrically connected to a circuit board provided in the vehicle, the solenoid body having a coil wire; The solenoid body is fixed to the circuit board, and the spring body has a proximal end connected to the coil wire so as to be energized, and a distal end side of the spring body. A circuit abutting portion that abuts a solenoid circuit provided on the circuit board, and the circuit abutting portion can press the solenoid circuit by the elasticity when the solenoid body is fixed to the circuit board. to provide a vehicular solenoid, characterized in that is configured to.

  In order to solve the above problems, the invention of claim 2 is a shift device for a vehicle automatic transmission comprising a shift device main body and a shift lock mechanism having a vehicle solenoid according to claim 1, The shift device main body includes a change lever that is movable along a gate provided in the vehicle, and a transmission switching member that switches an automatic transmission provided in the vehicle in conjunction with the change lever. And a plunger that is controlled so as to be interlocked with a brake device provided in the vehicle and that moves in and out of the solenoid body, and the plunger is a parking lot in which the change lever is provided in the gate. When entering the range, the transmission switching member is maintained in a locked state in a state of protruding from the solenoid body, and the blurring is performed. To provide a shifting apparatus for a vehicle automatic transmission according to claim which is moved backwardly to the solenoid body during braking start operation of the key device is configured to be released to the locked state.

  According to a third aspect of the present invention, in the shift device for an automatic vehicle transmission according to the second aspect, the shift device for the automatic vehicle transmission further includes a casing held by a shift device body, and the circuit board includes: The solenoid body is housed in a fixed state in the casing, and the solenoid body is housed in the casing and is fixed to the circuit board when housed.

  According to a fourth aspect of the present invention, in the shift device for an automatic vehicle transmission according to the third aspect, the shift lock mechanism is engaged with and disengaged from a lock member that locks / unlocks the transmission switching member, and the vehicle solenoid. A locking arm that freely locks, and the locking arm is connected to the locking member so as to be interlocked with each other, and the locking arm and the transmission switching member are both locked from a locked position. The range up to the unlock position in the unlocked unlocked state is movable along a predetermined movable path, and the plunger is moved out of the movable path of the locking arm when the casing is held by the shift device body. From the position outside the retracted path, it moves across the movable path to the position inside the movable path and engages with the locking arm at the locked position. Are those adapted to be arranged to be.

  According to a fifth aspect of the present invention, in the shift device for an automatic vehicle transmission according to the fourth aspect, the lock member includes a lock shaft capable of entering and exiting a lock hole provided in the transmission switching member, and the lock shaft. A lock shaft operating member to be operated, and the lock shaft operating member is connected to the locking arm that is movable by being pressed by the change lever when the change lever enters the parking range. those who operates the lock shaft to take into the lock hole.

  According to a sixth aspect of the present invention, in the shift device for an automatic vehicle transmission according to the fifth aspect, the shift lock mechanism further includes a biasing member that biases the lock shaft, and the lock shaft operating member includes: When the change lever enters the parking range, the lock shaft is inserted into the lock hole against the urging force of the urging member, and the urging member takes out the lock shaft that has entered the lock hole from the lock hole. It is what is energizing.

  According to the first aspect of the present invention, the spring body has a base end side connected to the coil wire so as to be energized, and has a circuit abutting portion abutting on a solenoid circuit provided on the circuit board on the front end side. The circuit contact portion is configured to be capable of pressing the solenoid circuit by elasticity when the solenoid body is fixed to the circuit board.

  Accordingly, the solenoid body can be connected to the circuit board so as to be energized, and power can be supplied to the solenoid body.

  At that time, since the circuit contact portion is pressed against the circuit for solenoid of the circuit board by the elasticity of the spring body, it is possible to eliminate the need for soldering work, etc. The connection work can be made easy, the harness can be made unnecessary, and the harness can be prevented from interfering with other work. Moreover, even when subjected to vibration or the like, the connection state between the two can be maintained, and the connection failure due to solder cracks can be prevented.

  According to a second aspect of the present invention, the plunger of the vehicle solenoid keeps the transmission switching member in the locked state with the change lever protruding from the solenoid body when the change lever enters the parking range, and the brake operation start operation of the brake device. At this time, it is configured to be able to be released from the locked state by being immersed in the solenoid body.

  As a result, it is possible to facilitate the installation work of the vehicle solenoid that constitutes a part of the shift lock mechanism of the shift device for the automatic vehicle transmission, and it is possible to simplify the structure of the entire device.

  According to claim 3, the circuit board is housed in a fixed state within the casing. The solenoid body is fixed to the circuit board by being housed in a fixed state in the casing.

  As a result, the circuit board and the solenoid body can be easily positioned and fixed to each other.

  According to the fourth aspect of the present invention, when the change lever enters the parking range, the plunger enters the movable path across the movable path from the position outside the movable path where the plunger retreats out of the movable path. until projecting dynamic and is configured to lock arm and the locking of the locking position.

  As a result, a force in a direction that makes a predetermined angle with the moving direction in which the plunger moves in and out with respect to the solenoid body is received from the locking arm, and the force that the plunger receives from the locking arm in the moving direction is reduced. it can. Therefore, even when the plunger moves in and out with a small force, the movement of the locking arm can be prevented. Therefore, the vehicle solenoid can be reduced in size, and the shift device as a whole can be reduced in size.

  According to claim 5, the locking member includes a lock shaft and a lock shaft-actuating member. The lock shaft operating member is operatively connected to the engaging arm that is pressed and moved by the change lever when the change lever enters the parking range, and the lock shaft is connected to the lock hole of the transmission switching member when moving. Operate to enter

  As a result, the transmission switching member can be more reliably locked and more reliable.

  According to the sixth aspect, the shift lock mechanism further includes a biasing member that biases the lock shaft. The lock shaft operating member puts the lock shaft into the lock hole against the urging force of the urging member when the change lever enters the parking range. Further, the urging member urges the lock shaft that has entered the lock hole so as to come out of the lock hole.

  As a result, when the engagement between the plunger and the engagement arm is released, the urging force of the urging member allows the lock shaft that has entered the lock hole to be taken out of the lock hole, and can be easily and reliably unlocked. it can.

1 is an exploded perspective view of an embodiment of a shift device for an automatic vehicle transmission provided with a shift lock mechanism having a vehicle solenoid according to the present invention. The shift control device is a perspective view of omitting the vehicle automatic transmission shift device. It is a perspective view which shows the positional relationship of the lock member of the state by which the shift lock was carried out, a change lever, and a transmission switching member. FIG. 4 is a side view showing a positional relationship among a lock member, a change lever, and a transmission switching member in a locked state in FIG. 3. It is a disassembled perspective view of a shift control apparatus. It is a disassembled perspective view of a left casing, a board | substrate, and the solenoid for vehicles. It is a side view of the state which accommodated the board | substrate and the solenoid for vehicles in the left casing. It is a disassembled perspective view of a 2nd press operation member. It is a perspective view which shows the positional relationship of the lock member of the unlocked state where the shift lock was cancelled | released, a change lever, and a transmission switching member. It is a top view which shows the positional relationship of a press operation member, a switch press member, and a lever position detection apparatus in case the lever shaft of a change lever exists in the left side position of a parking range. It is a perspective view of a shift control apparatus that is removed the casing. It is a side view which shows the positional relationship of the latching arm of the state where the plunger was in the shortest state, the change lever, and the transmission switching member. It is the side view which made a part the cross section which shows the positional relationship of the 1st press operation member and operation arm in the state of FIG. It is a top view which shows the positional relationship of the pressing operation member, switch pressing member, and lever position detection apparatus at the time of the lever axis | shaft of a change lever entering a parking range. It is the side view which made a part the cross section when the 1st press operation member contacted the pressed operation part of an operation arm. It is the side view which made a section the section at the time of the 1st press operation member pressing operation of the pressed operation part of an operation arm. It is a perspective view of both of the states where connection with a change member main part and a change lever was canceled. It is a top view which shows the positional relationship of the pressing operation member of the state in which the lever shaft of the change lever came to the subgate, the switch pressing member, and the lever position detection apparatus. It is a top view which shows the positional relationship of the press operation member of the state in which the lever axis | shaft of the change lever came to the plus gate of a subgate, a switch press member, and a lever position detection apparatus. In relation to a conventional shift lock mechanism using a vehicle solenoid, (a) is an explanatory diagram of a state in which a transmission switching member is locked, and (b) is an explanatory diagram of a state in which the transmission switching member is unlocked. is there. It is an enlarged perspective view of a vehicle solenoid of the shift lock mechanism of Figure 20.

  Hereinafter, the best mode for carrying out the present invention will be described in detail with reference to the drawings. FIG. 1 is an exploded perspective view of an embodiment of a shift device for a vehicle automatic transmission provided with a shift lock mechanism having a vehicle solenoid according to the present invention. Incidentally, X-direction of FIG. 1 shows a front, Y direction indicates backward. In addition, Z direction indicates the left, W direction indicates the right side. This is the same in the following FIGS.

  A shift device 1 for a vehicle automatic transmission according to this embodiment is for an automobile. As shown in FIGS. 1 and 2, a shift device main body fixed to a vehicle body side and a shift having a vehicle solenoid. And a locking mechanism.

  The shift device main body includes a frame body 2, a transmission switching member 3, a change lever 4, and a shift control device 6. Frame 2 includes a base 20, and a gate member 5. The base portion 20 has, on the front side, a lock shaft housing hole 21 that movably houses a lock shaft 91 of a shift lock mechanism, which will be described later, and a switching member receiving portion that is formed so as to cross a part of the lock shaft housing hole 21. And a groove 22. The gate member 5 will be described later.

  In this embodiment, as shown in FIGS. 1 and 3, the transmission switching member 3 includes a plate-shaped switching member main body 30, a lever holding portion 35 that holds the change lever 4, and the transmission switching member 3. shaft portion 36a attached to the apparatus main body 2, and a 36b.

  A cable connecting portion 33 that is connected to one end of the cable 10 (shown in FIG. 1) is provided on the upper front side of the switching member main body 30. The other end of the cable 10 is connected to an automatic transmission (not shown) provided in the vehicle, and the transmission switching member 3 is connected to the automatic transmission via the cable 10.

  In addition, a substantially rectangular connecting hole 32 is provided at a substantially front-rear center on the upper side of the switching member main body 30 so as to penetrate in the left-right direction (ZW direction) in the plate thickness direction.

  Further, a lock portion 37 having a lock hole 37 a is provided on the lower front side of the switching member main body 30. The lock portion 37 is formed so as to enter and exit the switching member receiving groove 22 of the apparatus main body 2.

  In this embodiment, the lever holding portion 35 is integrally formed with the switching member main body 30 on the right side (one side) of the switching member main body 30 on the W direction side in FIG.

  Further, the lever holding portion 35 has a substantially spherical spherical housing portion 35b having an opening 35a on the upper side as shown in FIGS. The lever holding part 35 includes a plurality of slits 35c, and the upper side of the lever holding part 35 is divided into a plurality of elastic pieces by these slits 35c.

  As a result, the opening 35a expands, and a spherical portion 42 of the change lever 4 (to be described later) can be forcibly inserted into the spherical storage portion 35b. It is like that.

  As shown in FIGS. 3 and 17, the shaft portions 36a and 36b include a first shaft portion 36a and a second shaft portion 36b. The first shaft portion 36a is formed integrally with the switching member main body 30 at the lower end of the switching member main body 30, and protrudes from the switching member main body 30 to the left side (the other side) in the Z direction in the figure. Yes. The second shaft portion 36b protrudes from the lever holding portion 35 on the right side in the W direction in the drawing.

  The first shaft portion 36a and the second shaft portion 36b have the same axis O1. In this embodiment, the axis O1 is formed so as to pass through the center of the spherical storage portion 35b.

  The first shaft portion 36a and the second shaft portion 36b are pivotally supported by the apparatus main body 2 so that the upper portion of the switching member main body 30 is moved back and forth about the axis O1 ( XY direction).

  As shown in FIGS. 1 to 3 and 17, the change lever 4 is provided at a lever shaft 41, a spherical portion 42 provided at the lower end of the lever shaft 41, and an intermediate portion in the vertical direction of the lever shaft 41. And a connecting piece 43.

  The lever shaft 41 is formed of a long cylindrical shape, and an operation gripping member (not shown) is attached to the tip portion on the upper end side, and the operation gripping member is gripped and operated by a driver.

  The spherical portion 42 is a portion to be held by the lever holding portion 35, and is formed of a spherical shape having a size capable of turning into the spherical storage portion 35 b of the lever holding portion 35.

  And this spherical part 42 is hold | maintained at the spherical storage part 35b so that the center may correspond to the center of the spherical storage part 35b, and it can rotate centering | focusing on the center. As a result, the distal end portion of the lever shaft 41 of the change lever 4 can be rotated with respect to the switching member main body 30 in the front-rear direction and the left-right direction (ZW direction).

  The connecting piece 43 is formed of a quadrangular section that can enter the connecting hole 32 of the switching member main body 30 and is formed to protrude from the lever shaft 41 toward the switching member main body 30 by a predetermined length. .

  The connecting piece 43 configured in this manner is described above as the lever shaft 41 rotates in the left-right direction (ZW direction) around the spherical portion 42 inserted in the spherical storage portion 35b of the lever holding portion 35. It is adapted to enter and exit the coupling hole 32 of the switching member body 30.

  Further, when the connecting piece 43 enters the connecting hole 32 of the switching member main body 30, the lever shaft 41 of the change lever 4 and the switching member main body 30 are connected to each other so as to be interlocked in the front-rear direction. switching member body 30 Setsu with the movable pivots together the front-rear direction.

  When the lever shaft 41 of the change lever 4 comes to a parking (P) range 53a of a gate plate 51 (described later) provided on the gate member 5 of the apparatus main body 2, the switching member main body 30 rotates to the frontmost side. It will be in the state. In this state, as shown in FIG. 2, the lock portion 37 of the switching member main body 30 enters the switching member receiving groove 22 of the device main body 2, and the lock hole 37 a of the lock portion 37 and the lock shaft accommodation hole 21 of the device main body 2. Is in a state that matches.

  As shown in FIGS. 1 and 2, the gate member 5 of the apparatus main body 2 includes a gate plate 51 and side walls 52a and 52b. In this embodiment, the gate plate 51 includes a main gate 53 that guides the lever shaft 41 in the auto mode and a sub-gate 54 that guides the lever shaft 41 in the manual mode.

  The main gate 53 includes a parking (P) range 53a, a reverse (R) range 53b that communicates with the parking range 53a, a neutral (N) range 53c that communicates with the reverse range 53b, and a drive that communicates with the neutral range 53c (D ) Range 53d.

  The sub gate 54 communicates with the drive range 53 d of the main gate 53 via the communication path 55. The sub-gate 54 is provided with a minus gate 54a and a plus gate 54b. In this embodiment, as shown in FIG. 2, a minus gate 54 a is provided on the front side and a plus gate 54 b is provided on the rear side with respect to the communication path 55. Thus, the minus gate 54a may be disposed on the rear side, and the plus gate 54b may be disposed on the front side.

  The gate plate 51 of this embodiment is provided with an auxiliary plate 56 on the upper side. The auxiliary plate 56 is a soft material that is softer than the gate plate 51 for suppressing a collision sound when the lever shaft 41 moves through the main gate 53 and the sub gate 54, and when the lever shaft 41 collides. It is composed of those that are less likely to generate collision noise. In this embodiment, the auxiliary plate 56 is made of a urethane elastomer.

  The auxiliary plate 56 includes a silencing gate 56 a corresponding to the main gate 53 and the sub gate 54. Although not shown, the silencing gate 56a is formed to be slightly narrower than the main gate 53 and the sub gate 54, and the auxiliary plate 56 protrudes from the inner peripheral edge of the main gate 53 and the sub gate 54.

  As a result, when the lever shaft 41 moves through the main gate 53 and the sub gate 54, the lever shaft 41 abuts against the side surface of the silencing gate 56a so that a collision sound is unlikely to occur.

  The side walls 52a and 52b are composed of a left side wall 52a and a right side wall 52b that extend downward from the left and right ends of the gate plate 51, respectively. A control device holding portion 52c that holds the vehicle shift control device 6 is provided on the upper side of the right side wall 52b.

  And the lower end of these left side walls 52a and right side walls 52b is being fixed to the base 20 via the fixed shaft 2a, as shown in FIG.

  As shown in FIG. 5, the shift control device 6 includes a lever position detection device 7, a switch operation device 8, and a casing 10 that houses these.

  The casing 10 includes a left casing 10a and a right casing 10b (in FIG. 5, the left casing 10a appears on the right side and the right casing 10b appears on the left side). Further, the casing 10 includes a device main body holding portion that is held by the control device holding portion 52 c of the frame 2. In this embodiment, the apparatus main body holding part includes a pin holding hole 10d (shown in FIG. 1) and the like held by a holding pin 52d provided in the control apparatus holding part 52c.

  In addition, a part of the lever position detection device 7 and the switch operation device 8 are accommodated in the left casing 10a and the right casing 10b. Further, in this embodiment, a part of the lock member 90 is accommodated. Both are aligned to the left and right. In this state, as shown in FIG. 1, the holding pin 52d of the control device holding portion 52c of the frame body 2 is passed through the pin holding hole 10d, so that the casing 10 is connected to the control device holding portion of the frame body 2. 52c is held in a fixed state.

  As shown in FIG. 5, the lever position detection device 7 includes lever position detection switches 71a to 71e as a plurality of pressing switches, and a circuit board 72 that holds the lever position detection switches 71a to 71e.

  The lever position detection switches 71a to 71e all have the same configuration, and are configured to include a pressing button 72f as a pressing portion in the upper part. In this embodiment, the lever position detection switches 71a to 71e are five of a key interlock detection switch 71a, a parking detection switch 71b, a communication path detection switch 71c, a minus gate detection switch 71d, and a plus gate detection switch 71e. Has one.

  The key interlock detection switch 71a is for detecting when the lever shaft 41 of the change lever 41 enters a preset interlock region in the parking range 53a. The parking detection switch 71b is a lever shaft This is for detecting when 41 enters the parking range 53a.

  In this embodiment, the key interlock detection switch 71a is disposed on the front side and the right side of the parking detection switch 71b.

  The communication path detection switch 71 c is for detecting when the lever shaft 41 enters the communication path 55. The minus gate detection switch 71d detects when the lever shaft 41 enters the minus gate 54a of the sub-gate 54, and the plus gate detection switch 71e detects when the lever shaft 41 enters the plus gate 54b of the sub-gate 54. It is for detecting it.

  These are arranged in a single line in the front-rear direction, with the communication path detection switch 71c in the front-rear center and the negative gate detection switch 71d on the front side and the positive gate detection switch 71e on the rear side. Yes.

  In this embodiment, as shown in FIG. 5, the circuit board 72 holds the lever position detection switches 71 a to 71 e on the upper surface side, and can be energized with a vehicle solenoid 100 of a shift lock mechanism described later on the rear surface side. (Not shown) connected to the solenoid circuit (pattern) and a detection switch circuit (pattern) (not shown) connected to the lever position detection switches 71a to 71e so as to be energized.

  The circuit board 72 configured as described above is housed in a fixed state in the casing 10 while holding the lever position detection switches 71a to 71e.

  In detail, as shown in FIG. 6, the right casing 10b and the left casing 10a of the casing 10 are each provided with a board mounting groove 10e for mounting the circuit board 72 therein (in FIG. 6, in the left casing). Only the substrate mounting groove 10e of 10a is displayed, and the mounting groove of the right casing 10b is not displayed).

  Then, as shown in FIG. 7, the circuit board 72 is fixedly attached to the casing 10 by fitting the end of the circuit board 72 into the board mounting groove 10 e. For convenience of explanation, the lever position detection switches 71a to 71e attached to the circuit board 72 are omitted in FIGS.

  Further, as shown in FIG. 5, the circuit board 72 is provided with a connecting portion 10 c that is extended from each of the solenoid circuit and the detection switch circuit and is connected to be energized from the outside of the casing 10. In this embodiment, the connection portion 10 c includes a connection terminal (not shown) connected to the solenoid circuit and the detection switch circuit so as to be energized, and is attached to the casing 10.

  And the connection terminal extended from the control main-body part (not shown) provided in the vehicle can be connected to this connection part 10c from the outer side of the casing 10. FIG. Thereby, each of the lever position detection switches 71a to 71e is connected to the control main body through the detection switch circuit and the connection portion 10c so as to be able to be energized (communication), and is connected to the vehicle solenoid 100 connected to the solenoid circuit. The control body is connected to be energized.

  In this embodiment, the switch operating device 8 includes a switch pressing member 81 and two pressing operation members 83 and 84. The switch pressing member 81 includes a plurality of operation arms 81a to 81e and a support frame 81f as a support member that supports the operation arms 81a to 81e.

  In this embodiment, the operation arms 81a to 81e are a key interlock switch operation arm 81a, a parking detection switch operation arm 81b, a communication path detection switch operation arm 81c, and a minus gate detection switch operation arm 81d. And a plus gate detection switch operation arm 81e.

  The key interlock switch operation arm 81a presses the key interlock detection switch 71a, and the parking detection switch operation arm 81b presses the parking detection switch 71b.

  The communication path detection switch operating arm 81c is the communication path detection switch 71c, the negative gate detection switch operating arm 81d is the negative gate detection switch 71d, and the positive gate detection switch operating arm 81e is the positive gate detection. Each of the switches 71e is pressed.

  These operation arms 81a to 81e have substantially the same configuration, and hereinafter, the key interlock switch operation arm 81a will be described, and other description will be omitted. The key interlock switch operation arm 81a is made of a synthetic resin made of a long material having elasticity.

  As shown in FIG. 13, a switch pressing portion 81g for pressing the pressing button 72f of the key interlock detection switch 71a is provided on the lower surface on the distal end side of the key interlock switch operating arm 81a.

  At a middle portion in the longitudinal direction of the key interlock switch operation arm 81a, a pressed operation portion 81h is provided in which the key interlock switch operation arm 81a is operated by the first pressing operation member 83.

  The pressed operation portion 81h of this embodiment is formed so as to protrude upward from the upper surface of the key interlock switch operation arm 81a at a position separated from the switch pressing portion 81g by a predetermined distance.

  In this embodiment, the support frame 81f is integrally formed with the operation arms 81a to 81e as shown in FIG. The support frame 81f is housed in the casing 10 in a fixed state.

  Further, in this state, as shown in FIG. 13, the switch pressing portions 81g of the operation arms 81a to 81e are in contact with or above the pressing buttons 71f of the lever position detection switches 71a to 71e with a slight gap therebetween. Arranged.

  As shown in FIG. 5, the pressing operation member includes two members, a first pressing operation member 83 and a second pressing operation member 84. The first pressing operation member 83 is for pressing the key interlock switch operation arm 81a and the parking detection switch operation arm 81b.

  As shown in FIG. 10, the first pressing operation member 83 has a front-rear width at the right end side between the pressed operation portions 81h of the key interlock switch operation arm 81a and the parking detection switch operation arm 81b. It is configured to be wider than the distance in the front-rear direction, and the respective pressed operation portions 81h can be pressed simultaneously.

  As shown in FIGS. 5 and 9, the first pressing operation member 83 includes a lever pressing portion 83a pressed against the lever shaft 41 of the change lever 4 and pressed operation portions 81h of the operating arms 81a and 81b. And a pressing operation portion 83b that performs the pressing operation.

  In this embodiment, a part of the left end surface (right side in FIG. 5) of the first pressing operation member 83 forms the lever pressing portion 83a, and a part of the lower surface on the right end side of the first pressing operation member 83 is the pressing operation portion 83b. I am doing. Further, as shown in FIG. 13, the pressing operation portion 83b includes, at the right end thereof, an inclined portion 83c that gradually increases in height toward the right.

  The right side of the first pressing operation member 83 configured as described above is accommodated in the casing 10 so as to be movable in the left-right direction. Specifically, as shown in FIGS. 5 and 10, the first pressing operation member 83 has a pressing operation portion 83b that is predetermined from the pressed operation portion 81h of the key interlock switch operation arm 81a and the parking detection switch operation arm 81b. As shown in FIGS. 14 and 16, it is arranged to move in a range from the left position separated by a distance to the position above the pressed operation portion 81h.

  Further, although not shown, the lever pressing portion 83a of the first pressing operation member 83 protrudes outward from the left end of the casing 10 and is disposed substantially below the parking range 53a of the gate plate 51, as shown in FIG. Thus, the lever shaft 41 is pressed when entering the parking range 53a.

  The second pressing operation member 84 presses the communication path detection switch operation arm 81c, the minus gate detection switch operation arm 81d, and the plus gate detection switch operation arm 81e.

  As shown in FIG. 5 and FIG. 6, the second pressing operation member 84 of this embodiment is a second pressing operation member main body 86 and a slide held by the second pressing operation member main body 86 so as to be movable in the left-right direction. And a member 85.

  The sliding member 85 is a pressing operation for pressing the lever pressing portion 85a for the sliding member pressed by the lever shaft 41 of the change lever 4 and the pressed operation portions 81h of the operation arms 81c to 81e (see FIG. 5). Part 85b.

  Although not shown, the pressing operation portion 85b is also provided with an inclined portion that gradually increases in height toward the right side on the right side.

  The second pressing operation member main body 86 includes a pair of front and rear long holding pieces 86a for holding the second pressing operation member 84 on both front and rear sides.

  Each of the holding pieces 86a includes sliding protrusions 86b along the longitudinal direction on the inner surfaces facing each other (only the rear side appears in FIG. 6). Then, the sliding members 85 are slidably fitted into the sliding protrusions 86b so as to be slidable on both the front and rear side surfaces of the sliding member 85, whereby the sliding member 85 is moved to the second pressing operation member main body 86. Are movably held in the left-right direction (Z-W direction).

  The pair of holding pieces 86a holding the sliding member 85 are configured so that the lever shaft 41 of the change lever 4 can be inserted therebetween, and the lever shaft 41 is pressed against the left end portion of each of the opposing inner surfaces. The main body lever pressing portion 86c is formed. The main body lever pressing portion 86c and the sliding member lever pressing portion 85a constitute a lever pressing portion of the second pressing operation member 84.

  The second pressing operation member main body 86 holding the sliding member 85 in this way is connected to the pressed operation portion 81h of the negative gate detection switch operation arm 81d in the casing 10, as shown in FIGS. The plus gate detection switch operation arm 81e is housed above the pressed operation portion 81h so as to be movable in the front-rear direction.

  Further, in this stored state, as shown in FIG. 10, the pressing operation portion 85b of the sliding member 85 is disposed at the left position separated from the pressed operation portion 81h of the communication path detection switch operation arm 81c by a predetermined distance. ing. Then, as shown in FIG. 18, when the sliding member 85 moves relative to the second pressing operation member main body 86, the pressing operation portion 85b is positioned above the pressed operation portion 81h of the communication path detection switch operation arm 81c. And press.

  Further, the sliding member 85 that comes to the upper position of the pressed operation portion 81h is on the left side with respect to the second pressing operation member main body 86 by the first coil spring 87a as the first urging means as shown in FIG. Is being energized. Thus, the sliding member 85 pressed by the lever shaft 41 returns to the original position on the right side of the pressed operation portion 81h shown in FIG.

  Further, the right end side of the second pressing operation member main body 86 is put in the casing 10, and as shown in FIG. 19, the pressing operation portion 85b of the sliding member 85 is a pressed operation portion of the plus gate detection switch operation arm 81e. A range from the upper position of 81h to the upper position (not shown) of the pressed operation portion 81h of the negative gate detection switch operation arm 81d is movable in the front-rear direction.

  Further, as shown in FIG. 8, the second pressing operation member main body 86 pressed by the lever shaft 41 is urged by the second urging means, and when the pressing from the lever shaft 41 is eliminated. The original position shown in FIG. 10 is returned.

  Specifically, the second pressing operation member main body 86 is provided with second urging means on the upper side thereof. The second urging means of this embodiment includes a protruding piece holding portion 89 fixed to the second pressing operation member main body 86 and a pair of front and rear protruding pieces held by the protruding piece holding portion 89 so as to be slidable in the front-rear direction. 88 and a second coil spring 87b disposed between the projecting pieces 88.

  Although not shown, each of the projecting pieces 88 is disposed in the casing 10 so as to contact the inner wall of the casing 10.

  When the second pressing operation member main body 86 is pressed by the lever shaft 41 and moves forward or rearward, the projecting piece 88 abutting against the inner wall of the casing 10 is rearward or forward of the projecting piece holding portion 89. Move relative to the direction.

  During the relative movement, the second coil spring 87b is compressed, whereby the second pressing operation member main body 86 is urged rearward or forward.

  Note that the holding piece 86 a of the second pressing operation member main body 86 and the sliding member lever pressing portion 85 a of the sliding member 85 protrude outward from the left end of the casing 10 and are arranged below the communication path 55 of the gate plate 51. 18, when the lever shaft 41 enters the communication path 55 as shown in FIG. 18, the lever shaft 41 can enter between the holding pieces 86 a and press the sliding member lever pressing portion 85 a of the sliding member 85. It is like that.

  Next, the shift lock mechanism will be described. This shift lock mechanism shift-locks (locks) when the lever shaft 41 of the change lever 4 enters the parking range 53a so that the lever shaft 41 of the change lever 4 does not unexpectedly move to the other ranges 53b to 53d. Is for.

  As shown in FIGS. 3 and 4, the shift lock mechanism of this embodiment is interlocked with a lock member 90 that is detachably engaged with the transmission switching member 3 and a brake pedal as a brake device provided in the vehicle. The vehicle solenoid 100 is controlled so as to be obtained, and a locking arm 94 that is detachably locked to the vehicle solenoid 100 is provided.

  The lock member 90 includes a lock shaft 91 and a long lock shaft operation member 92 that moves the lock shaft 91 in a movable manner.

  The lock shaft 91 is housed in the lock shaft housing hole 21 (see FIG. 2) of the apparatus main body 2 so as to be movable in the axial direction, and as shown in FIG. When moving to the side), the lock member 37 enters the lock hole 37a of the switching member main body 30. Thereby, the switching member main body 30 that has entered the switching member receiving groove 22 of the apparatus main body 2 is locked.

  The lock shaft 91 housed in the lock shaft housing hole 21 is urged to the right side (the other direction side) in the axial direction by a coil spring 21b as an urging member provided in the lock shaft housing hole 21, The urging force causes the lock shaft 91 that has entered the lock hole 37a to come out of the lock hole 37a.

  The lock shaft operating member 92 has a longitudinal upper end side (one end side) thereof rotatably connected to the first pressing operation member 83 in the casing 10, and the first pressing operation member 83 is connected to the change lever 4. When the first pressing operation member 83 is moved by being pressed by the lever shaft 41, the upper end side of the lock shaft operation member 92 is moved along with the movement. Therefore, in this embodiment, the lock shaft operating member 92 is indirectly pressed against the lever shaft 41 of the change lever 4 via the first pressing operation member 83.

  Further, the intermediate portion 92a in the longitudinal direction of the lock shaft operating member 92 is pivotally supported by the casing 10 in the casing 10, so that the upper end side and the lower end side (the other end side) are centered on the intermediate portion 92a. And can be rotated in the left-right direction.

  Further, as shown in FIG. 5, a U-shaped locking groove 92b opened from the lower end surface is provided at the lower end of the lock shaft operating member 92. The lower end side of the lock shaft operating member 92 is extended to the outside from the lower end of the casing 10 as shown in FIG. 1. When the casing 10 is attached to the right side wall 52 b, the lock shaft operating member 92 is provided with a locking shaft 91. A pin 91a (shown in FIGS. 1 and 4) is inserted into the locking groove 92b. Thereby, the lower end of the lock shaft operating member 92 and the lock shaft 91 are rotatably connected.

  The locking arm 94 is interlocked with the lock member 90 and moves within a certain range when the lock member 90 and the switching member main body 30 are engaged and disengaged.

  In this embodiment, the locking arm 94 is integrally extended downward from the first pressing operation member 83, as shown in FIGS. 3 and 4, and the locking member is interposed via the first pressing operation member 83. It moves in the left-right direction in conjunction with 90 lock shaft operating members 92.

  As shown in FIG. 6, the vehicle solenoid 100 includes a solenoid main body 101 and a plunger 102 protruding from the solenoid main body 101.

  The solenoid body 101 includes a box body 101a, a coil wire (not shown) disposed inside the box body 101a, and two spring bodies 103 having conductivity and elasticity.

  The spring body 103 includes a circuit contact portion 103a on the distal end side. Further, the proximal end side of the spring body 103 is connected to the coil wire so as to be energized. The circuit contact portion 103a is for contacting the solenoid circuit of the circuit board 72, and protrudes at a predetermined height on the circuit board 72 side above the box body 101a.

  The solenoid body 101 configured as described above is housed in the casing 10 in a fixed state. More specifically, as shown in FIG. 6, the right casing 10b and the left casing 10a of the casing 10 are each provided with a solenoid mounting portion 10f for mounting the solenoid body 101 on the lower side of the board mounting groove 10e inside. (In FIG. 6, only the solenoid mounting portion 10f of the left casing 10a is displayed, and the mounting portion of the right casing 10b is not displayed).

  Then, as shown in FIG. 7, the solenoid main body 101 is fixedly attached to the casing 10 by fitting the solenoid main body 101 into the solenoid mounting portion 10f.

  Further, when the solenoid body 101 is fitted into the solenoid mounting portion 10f, the circuit contact portion 103a contacts with the solenoid circuit of the circuit board 72 in a pressed state. Therefore, the elasticity of the spring body 103 acts on the circuit contact portion 103a, and the circuit contact portion 103a is always kept pressed against the solenoid circuit.

  The plunger 102 is disposed so as to be movable in and out (movable in the axial direction) from the solenoid body 101. Further, the plunger 102 of this embodiment is always urged in a direction protruding from the solenoid body 101 by a biasing spring (not shown) provided in the solenoid body 101, and the coil of the solenoid body 101 is As the magnetic force is generated by energizing the wire, the solenoid body 101 is immersed (sucked) against the biasing force of the biasing spring.

  Therefore, the plunger 102 of this embodiment moves from the longest state (the state shown in FIG. 4) in which the protrusion length from the solenoid main body 101 is projected and moved relative to the solenoid main body 101 to the solenoid main body 101. The range from the solenoid body 101 to the shortest state (state shown in FIG. 12) where the protrusion length from the solenoid body 101 is the shortest is movable with respect to the solenoid body 101.

  The vehicle solenoid 100 is controlled by the control main body so as to be interlocked with the brake pedal. More specifically, when the control body detects that the lever shaft 41 of the change lever 4 has entered the parking range 53a by the parking detection switch 71b, when the brake pedal is depressed, the control body Based on the detection, the vehicle solenoid 100 is energized, and the plunger 102 of the vehicle solenoid 100 is moved into the solenoid body 101 with the energization.

  In the vehicle solenoid 100 configured as described above, the solenoid main body 101 is accommodated in the casing 10 as described above, and in the accommodated state, the axial direction of the plunger 102 is aligned along the front-rear direction and the locking arm. It is orthogonal to the moving direction of 94. In addition, the plunger 102 is in the shortest state where the plunger 102 is retracted as shown in FIG. 12, and is located outside the path retracted from the movable path where the locking arm 94 moves. 2. As shown in FIG. 4, it is disposed so as to have a position in the path that has entered the path across the movable path.

  Next, the operation of the shift device 1 will be described. For convenience of explanation, the lever shaft 41 of the change lever 4 will be described from the state where it is not in the parking range 53a of the main gate 53, for example, the left side of the parking range 53a.

  When the lever shaft 41 is at the left side position of the parking range 53a, as shown in FIGS. 9 and 10, the first pressing operation member 83 is separated from the lever shaft 41 and the key interlock switch operation arm. 81a and the parking detection switch operation arm 81b are arranged on the left side of the pressed operation portion 81h.

  Further, as shown in FIG. 11, the locking arm 94 closes the front side of the plunger 102 of the vehicle solenoid 100, and the distal end surface of the plunger 102 which is projected to move by the urging force of the urging spring is provided. The state is in contact with the rear surface of the locking arm 94. The lock portion 37 of the switching member main body 30 enters the switching member receiving groove 22 of the apparatus main body 2, and the lock hole 37 a of the lock portion 37 and the lock shaft accommodation hole 21 of the apparatus main body 2 are in agreement. (See FIG. 2).

  When the lever shaft 41 enters the parking range 53a from this state, the lever shaft 41 contacts the lever pressing portion 83a of the first pressing operation member 83 as shown in FIG.

  Furthermore, when the lever shaft 41 enters the parking range 53a, the lever pressing portion 83a is pressed, and the first pressing operation member 83 moves to the right (see FIG. 14). When the first pressing operation member 83 is moved, both the locking arms 94 are moved to the right side to the right position of the plunger 102 of the vehicle solenoid 100 (see FIG. 3).

  At the same time, the lock shaft operating member 92 rotates counterclockwise in FIG. 3, and the lock shaft 91 is moved to the right in FIG. 3 against the urging force of the coil spring 21b. As a result, the lock shaft 91 enters the lock hole 37a of the switching member main body 30 to place the switching member main body 30 in the locked state.

  When the locking arm 94 passes through the plunger 102 of the vehicle solenoid 100, the plunger 102 in contact with the locking arm 94 is moved by the urging force of the urging spring as shown in FIG. 94 moves across the movable path to the position in the path and reaches the longest state.

  Further, when the first pressing operation member 83 is moved, the pressing operation portion 83b starts to press the pressed operation portion 81h of the parking detection switch operation arm 81b as shown in FIG. 15, and the key interlock switch operation is performed. The pressing operation portion 81h of the arm 81a is pressed.

  By this pressing operation, the switch pressing portions 81g of the parking detection switch operating arm 81b and the key interlock switch operating arm 81a press the pressing buttons 72f of the parking detection switch 71b and the key interlock detection switch 71a, respectively.

  At that time, the key interlock switch operating arm 81a has elasticity, and can be bent in the longitudinal direction as shown in FIG. Accordingly, even if the pressed operation portion 81h is pressed with an excessive force, the pressing button 72f can be prevented from being pressed with the excessive force, and the detection switches 71a and 71b can be prevented from being overloaded. On the other hand, the push button 72f can be reliably pressed by elasticity, and each detection switch 71a, 71b can be operated reliably.

  When the parking detection switch 71b is pressed, information to that effect is transmitted to the control main body of the vehicle. The received control main body waits for the brake pedal to be depressed and energizes the vehicle solenoid 100 when the brake pedal is depressed as will be described later.

  When the key interlock detection switch 71a is pressed, information to that effect is transmitted to the vehicle control body, and the received control body receives the key that has entered the key insertion hole provided in the vehicle. Make the key insertion hole ready for removal.

  In this state, the lock shaft 91, the lock shaft operating member 92, the locking arm 94, and the first pressing operation member 83 each move in the opposite direction by the biasing force of the coil spring 21b.

  However, since the plunger 102 is located at the position in the path of the locking arm 94, the locking arm 94 is locked to the plunger 102 to maintain the position as shown in FIG. The operation member 92 and the first pressing operation member 83 also maintain their positions. Therefore, the switching member main body 30 is maintained in the locked state.

  In this state, the lever shaft 41 connected to the switching member main body 30 cannot move in the front-rear direction. Therefore, for example, even if the lever shaft 41 is erroneously moved while the vehicle is stopped, the lever shaft 41 maintains the position of the parking range 53a and can be prevented from moving from the parking range 53a to the reverse range 53b.

  When the lever shaft 41 enters the parking range 53a, the lever shaft 41 of the change lever 4 is moved to the parking range 53a by a locking means (not shown) for detachably locking the change lever 4 and the gate member 5. You can maintain the state that entered.

  To release the locked state and drive the vehicle, step on the brake pedal. As a result, the control main body that has detected it energizes the solenoid main body 101 via the circuit board 72. Then, as shown in FIG. 12, the plunger 102 moves into the position outside the path of the locking arm 94 against the urging force of the urging spring by the generation of the magnetic force by the energization, and becomes the shortest state.

  As a result, the locking between the locking arm 94 and the plunger 102 is released. As a result of the release of the engagement, the engagement arm 94, the lock shaft 91, the lock shaft operation member 92, and the first pressing operation member 83 are moved in the opposite direction by the urging force of the coil spring 21b.

  Then, as shown in FIGS. 9 and 11, the locking arm 94 moves to the front position of the plunger 102 and closes the front of the plunger 102. In this state, when the stepping operation of the brake pedal is stopped, the control main body unit that detects the operation stops the energization of the vehicle solenoid 100.

  As a result, the plunger 102 of the vehicle solenoid 100 projects by the urging force of the urging spring, contacts the rear surface of the locking arm 94, and maintains that state.

  Further, with the movement of the first pressing operation member 83, the parking detection switch 71b that has been pressed is released and the pressing operation is stopped.

  When the parking detection switch 71b is no longer pressed, information to that effect is transmitted to the control body, and the control body is based on that information (or no longer receives the pressed information). The vehicle solenoid 100 is controlled not to be energized when the brake pedal is subsequently depressed.

  Therefore, the control main body of this embodiment is in the state where the parking detection switch 71b detects that the change lever 4 has entered the parking range 53a as described above (while the parking detection switch 71b is on). When the brake pedal is depressed, the vehicle solenoid 100 is energized, and control is performed so that the vehicle solenoid 100 is not energized even when the brake pedal is depressed while the parking detection switch 71b is OFF.

  As the first pressing operation member 83 moves, the key interlock detection switch 71a is not pressed before the parking detection switch 71b is not pressed. Then, the information to that effect is transmitted to the control main body, and the received control main body receives the key from the key insertion hole and the vehicle based on the information (or no longer receives the pressed information). Is controlled so as not to be removed by means of a key removal prevention means (not shown) provided in FIG.

  Thereafter, the lever shaft 41 of the change lever 4 is taken out of the parking range 53a, and when it is operated to move to the reverse range 53b, neutral range 53c, or drive range 53d along the main gate 53, it is connected to the change lever 4. The switching member main body 30 rotates forward.

  Further, when the switching member main body 30 is rotated, the cable 10 (shown in FIG. 1) is pushed and pulled to switch the automatic transmission.

  Further, when the lever shaft 41 enters the communication path 55 (see FIG. 2) from the drive range 53d, the lever shaft 41 comes into contact with the sliding member lever pressing portion 85a of the sliding member 85 of the second pressing operation member 84 (see FIG. 2). (See FIG. 18).

  In this state, when the lever shaft 41 further moves to the right subgate 54 side through the communication path 55, as shown in FIG. 18, the sliding member 85 has a negative gate at its right end. The detection switch operation arm 81d and the positive gate detection switch operation arm 81e move to the right side until they are positioned to the right of the pressed operation portion 81h. During the movement, the pressed operation portion 81h of the communication path detection switch operating arm 81c is pressed.

  In accordance with this pressing operation, the switch pressing portion 81g of the communication path detection switch operation arm 81c presses the pressing button 72f of the communication path detection switch 71c.

  Also in this case, since the communication path detection switch operation arm 81c has elasticity, it can be bent in the longitudinal direction as shown in FIG. 16, and the key interlock switch operation arm 81a and the parking detection switch operation can be operated. It functions similarly to the arm 81b.

  The pressed communication path detection switch 71c transmits information indicating that the communication path has been pressed to the control main body. The received control main body unit switches from the auto mode state to the manual mode state.

  In the state where the lever shaft 41 enters the sub-gate 54, the connecting piece 43 of the change lever 4 comes out of the connecting hole 32 of the switching member main body 30 as shown in FIG. The connection with 30 is released.

  Therefore, in this disengaged state, the change lever 4 and the switching member main body 30 are not interlocked, and the automatic transmission is maintained in the drive state even if the lever shaft 41 of the change lever 4 moves the sub-gate 54 in the front-rear direction. The

  When the lever shaft 41 that has entered the sub-gate 54 is inserted into the plus gate 54b, for example, as shown in FIG. 19, when the lever shaft 41 enters the plus gate 54b, the main body lever of the second pressing operation member main body 86 is provided. The pressing portion 86c is pressed rearward.

  During the pressing, the second pressing operation member main body 86 and the sliding member 85 held by the second movement member 85 are moved rearward, and the pressing operation portion 85b of the sliding member 85 is operated by the pressed operation portion 81h of the plus gate detection switch operation arm 81e. Is pressed.

  Further, along with this pressing operation, the switch pressing portion 81g of the operating arm 81e for the plus gate detection switch presses the pressing button 72f of the plus gate detection switch 71e.

  Also in this case, the plus gate detection switch operation arm 81e has elasticity, and thus functions in the same manner as the key interlock switch operation arm 81a and the like.

  Then, the pressed plus gate detection switch 71e transmits information indicating that it has been pressed to the control main body. The received control main body shifts up only once based on the information.

  When the lever shaft 41 that has entered the plus gate 54b is returned to the original position, the hand that pushes the lever shaft 41 in is operated. As a result, the second pressing operation member 84 returns to the original position by the urging force of the second coil spring 87b (see FIG. 8), and accordingly, the lever shaft 41 moves between the plus gate 54b and the minus gate 54a in the sub-gate 54. Return to the intermediate position (position shown in FIG. 18).

  On the other hand, when the lever shaft 41 is inserted into the minus gate 54a, the main body lever pressing portion 86c of the second pressing operation member main body 86 is pressed forward when the lever shaft 41 enters the minus gate 54a.

  During the pressing, the second pressing operation member main body 86 and the sliding member 85 held thereby move forward, and the pressing operation portion 85b of the sliding member 85 moves to the pressed operation portion 81h of the minus gate detection switch operation arm 81d. Is pressed.

  In accordance with this pressing operation, the switch pressing portion 81g of the negative gate detection switch operation arm 81d presses the pressing button 72f of the negative gate detection switch 71d.

  Then, the pressed minus gate detection switch 71d transmits information indicating that it has been pressed to the control main body. The received control main body shifts down only once based on the information.

  Further, when the hand is released from the lever shaft 41 that has entered the minus gate 54a, the second pressing operation member 84 returns to its original position by the urging force of the second coil spring 87b (see FIG. 8). However, it returns to the intermediate position (position shown in FIG. 18) between the plus gate 54b and the minus gate 54a in the sub-gate 54.

  Thereafter, when the lever shaft 41 of the change lever 4 is returned from the sub-gate 54 through the communication path 55 to the drive range 53d, the connection piece 43 of the change lever 4 enters the connection hole 32 of the switching member body 30 again. The change lever 4 and the switching member main body 30 are connected again.

  When the lever shaft 41 of the change lever 4 is moved from the drive range 84 of the main gate 53 to the neutral range 53c, the switching member main body 30 connected to the change lever 4 rotates to the front side opposite to the above. To do.

DESCRIPTION OF SYMBOLS 1 Shift device for automatic vehicle transmissions 3 Transmission switching member 4 Change lever 5 Gate member 6 Shift control device 7 Lever position detection device 8 Switch operating device 10 Casing 30 Switching member main body 72 Circuit board 90 Lock member 91 Lock shaft 92 Lock shaft Operation member 94 Locking arm 100 Solenoid for vehicle 102 Plunger 103 Spring body 103a Circuit contact portion

Claims (6)

A vehicle solenoid equipped in a vehicle so as to be connected to a circuit board provided in the vehicle so as to be energized,
A solenoid body having a coil wire, and a spring body having conductivity and elasticity;
The solenoid body is fixed to the circuit board;
The spring body has a base end side connected to the coil wire so as to be energized, and has a circuit abutting portion abutting on a solenoid circuit provided on the circuit board on the front end side.
The vehicle solenoid, wherein the circuit contact portion is configured to be able to press the solenoid circuit by the elasticity when the solenoid body is fixed to the circuit board. A shift device for a vehicle automatic transmission comprising a shift device main body and a shift lock mechanism having a vehicle solenoid according to claim 1,
The shift device main body includes a change lever that can move along a gate provided in the vehicle, and a transmission switching member that switches an automatic transmission provided in the vehicle in conjunction with the change lever.
The vehicle solenoid is further controlled to be interlocked with a brake device provided in the vehicle, and further includes a plunger that moves in and out of the solenoid body,
When the change lever enters a parking range provided at the gate, the plunger keeps the transmission switching member in a locked state in a state of protruding from the solenoid body, and at the time of a brake operation start operation of the brake device. A shift device for an automatic vehicle transmission, wherein the shift device is configured to be immersed in the solenoid body to release the locked state. The shift device for a vehicle automatic transmission further includes a casing held by the shift device body,
The circuit board is housed in a fixed state in the casing;
The shift device for an automatic vehicle transmission according to claim 2, wherein the solenoid body is housed in the casing and is fixed to the circuit board when housed. . The shift lock mechanism includes a lock member that locks / unlocks the transmission switching member, and a locking arm that is detachably locked to the vehicle solenoid,
The locking arm is connected to the locking member so as to be interlocked with the locking member and the transmission switching member from a locked position in a locked state to an unlocked position in an unlocked state in which both are unlocked. Move the range along a predetermined movable path,
When the casing is held by the shift device main body, the plunger protrudes from an out-of-path position where the locking arm is retracted out of the movable path to an in-path position that crosses the movable path and enters the movable path. 4. The shift device for an automatic vehicle transmission according to claim 3, wherein the shift device is arranged so as to be able to move and engage with an engaging arm at the locked position. The lock member includes a lock shaft that can enter and exit a lock hole provided in the transmission switching member, and a lock shaft operation member that operates the lock shaft,
The lock shaft operating member is operably connected to the locking arm that is pressed and moved by the change lever when the change lever enters the parking range, and the lock shaft is inserted into the lock hole when moving. The shift device for an automatic vehicle transmission according to claim 4, wherein the shift device is operated as described above. The shift lock mechanism further includes a biasing member that biases the lock shaft,
The lock shaft operating member enters the lock shaft against the urging force of the urging member when the change lever enters a parking range,
The shift device for an automatic vehicle transmission according to claim 5, wherein the biasing member biases the lock shaft that has entered the lock hole so as to come out of the lock hole.

Images