JP4574038B2 - Shift device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a shift device, and more particularly to a shift device suitable for locking a shift lever in a shift-by-wire system.
[0002]
[Prior art]
Conventionally, in an automobile equipped with an automatic transmission, a shift position of the automatic transmission is designated by operating a shift lever of the shift device.
[0003]
The mechanism that locks the shift lever locks the shift lever to the parking position (parking position) so that it cannot be moved to another position if it is not operated with other operations such as the brake pedal operation. was there. For example, in the shift lever device disclosed in Japanese Patent Application Laid-Open No. 10-59132, the shift lever is provided so that a linear shift gate can be reciprocated, and a parking position (parking position) is assigned to one end of the shift gate. When the shift lever is positioned at this parking position, a lock pin that is driven by an actuator is applied to the engagement protrusion formed on the shift lever, and the shift lever is locked so that it cannot move from the parking position to another position. .
[0004]
In recent years, a shift-by-wire automatic transmission has been developed as a shift device, which converts a shift lever switching operation into an electrical switching signal, activates an actuator according to the signal, and switches the manual shift valve using the actuator. Has been. In a shift-by-wire automatic transmission, a shift position can be selected by operating a shift lever with a light force, and a shift range can be easily switched by an electrical switching signal.
[0005]
[Problems to be solved by the invention]
However, since the shift lever of the shift-by-wire automatic transmission can be operated with a light force, even if there is no willingness to operate the shift lever, the shift lever is moved and moved by just touching the shift lever lightly. There is a possibility that an operation signal may be transmitted. For example, while the vehicle is traveling forward, the shift lever may be moved to a selected position that indicates a reverse state, and a signal for switching to the reverse state may be transmitted.
[0006]
The present invention was made in view of the above, an object thereof is to provide a shifting device capable of preventing a malfunction of the selection operation means in a predetermined state of the vehicle.
[0007]
[Means for Solving the Problems]
In order to achieve the object, according to the first aspect of the present invention, a selection operation means operated to select a connection state of a gear train of an automatic transmission of a vehicle, and a selection state of the selection operation means are detected. In the shift device including a selection state detection unit and a lock unit that locks the selection operation unit so that the selection operation unit cannot be moved, the lock unit includes the selection operation unit in a predetermined state and the vehicle having a predetermined condition. The selection operation means is configured to be lockable, and the selection operation means is a momentary type that returns to the reference position when the operation force is released, and the selection operation means is provided to be tiltable in multiple directions from the reference position. The selection operation means is provided with a first engagement portion that engages in a concavo-convex relationship, and the lock means can be engaged in a concavo-convex relationship with the first engagement portion of the selection operation means. The second engagement portion is provided, said locking means, and summarized in that the locking also tilted impossible in either direction of the multidirectional at the reference position said selection operation means. According to the present invention, since the selection operation means is in a predetermined state and the selection operation means is locked when the vehicle is in a predetermined condition, malfunction of the selection operation means is prevented. For example, the automatic transmission gear train connection state is a forward or reverse traveling state, and the selection operation means is locked when the vehicle travels at a predetermined speed or higher, thereby preventing erroneous operation of the selection operation means. Is done. Here, the selection operation means is locked in any direction from the reference position by the engagement of the pair of first and second engaging portions.
[0009]
The invention according to claim 2 is the gist of the invention according to claim 1 , wherein the lock means is installed on the opposite side of the main body of the selection operation means with respect to the base of the selection operation means. To do. According to this invention, the space on the opposite side to the main body of the selection operation means is effectively utilized.
[0010]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an embodiment in which the present invention is embodied in a configuration in which a selector device is provided on a vehicle floor console and operated by a shift lever will be described with reference to FIGS.
[0011]
FIG. 3 is a schematic perspective view of the front part in the vehicle.
As shown in FIG. 3, the selection device 1 constituting the shift device is integrated with the floor console F, and a shift lever 3 as a selection operation means is provided so as to protrude from the floor console F. The selection device 1 includes a cross-shaped shift gate 2a on a panel 2, and a shift lever 3 is provided with an intersection position as an origin position S0 as a reference position.
[0012]
The shift device includes a stationary type in which the shift lever is held at the selected position, and a momentary type in which the selected position is selected and returns to the origin position. The shift device of this embodiment can be operated by releasing the hand from the shift lever 3 during operation. It is a momentary type that returns to the origin position S0.
[0013]
FIG. 1A is a schematic exploded perspective view of the selection device 1, and FIG. 1B is a schematic cross-sectional view of a base portion and a holder of the shift lever 3. 2A is a cross-sectional view of the selection device 1, and FIG. 2B is a cross-sectional view of the selection device 1 with the shift lever 3 locked. As shown in FIGS. 1A and 1B, the selection device 1 includes a panel 2, a shift lever 3, a holder 4, a holder case 5, and a solenoid 6 as a locking means. In FIG. 1A, the holder case 5 is omitted. Further, as shown in FIGS. 2A and 2B, the panel 2 constitutes a lid of the case 7.
[0014]
The shift lever 3 includes a rod portion 3a as a main body of the selection operation means, a knob 3b is provided at the distal end of the rod portion 3a, and a spherical shape as a base portion of the selection operation means having a larger diameter than the rod portion 3a at the proximal end. A portion 3c is provided. Four guide protrusions 3d are formed in a cross shape on the spherical portion 3c. The guide protrusion 3d is formed on a plane that includes the center of the spherical portion 3c and is orthogonal to the rod portion 3a. The tip of the guide protrusion 3d is formed in a substantially spherical shape. The spherical portion 3c is formed with a locking concave portion (engaging concave portion) 3e as a first engaging portion on the side opposite to the rod portion 3a (below the spherical portion 3c). The locking recess 3e is formed to extend in a straight line passing through the center of the spherical portion 3c.
[0015]
As shown in FIG. 2, the holder 4 is installed in the case 7. The holder 4 is formed with an accommodating recess 4a and four guide grooves 4b. The guide groove 4b is formed in a cross shape at a position facing the shift gate 2a. In the accommodating recess 4a, the spherical portion 3c is accommodated so as to be slidably rotatable in a state in which each guide protrusion 3d is engaged with each guide groove 4b. The spherical portion 3c is supported horizontally with one pair of guide projections 3d engaged with the guide grooves 4b, and the other pair of guide projections 3d slides inside the guide grooves 4b, thereby accommodating recesses 4a. Is rotated by a predetermined angle. The shift lever 3 is tilted along the cross-shaped shift gate 2a by the rotation of the spherical portion 3c. The shift lever 3 is configured to return to the origin position S0 when the operating force of the shift lever 3 is released by a spring (not shown) provided between the rod portion 3a and the case 7.
[0016]
A through hole 4 c is formed on the lower surface of the holder 4. The through hole 4c is formed at a position facing the locking recess 3e in a state where the shift lever 3 is located at the origin position S0.
[0017]
The holder 4 is attached to the case 7 via a holder case 5. The holder case 5 is formed in a box shape, covers the upper surface and side surfaces of the holder 4, and has a hole 5b formed in the center on the upper wall 5a of the holder case. The upper wall 5a holds the peripheral portion of the hole 5b so that the spherical portion 3c is engaged with the spherical portion 3c, and the spherical portion 3c is not detached from the accommodating recess 4a.
[0018]
A solenoid 6 is installed below the holder 4. The solenoid 6 is installed such that a plunger (not shown) reciprocates in the vertical direction. At the tip of the plunger, a locking pin 6a is provided as a second engaging portion that engages with the first engaging portion in an uneven relationship. The locking pin 6 a passes through a substantially cylindrical rigid guide 6 b provided on the upper surface of the solenoid 6. When the solenoid 6 is energized, the locking pin 6a is moved upward and passes through the through hole 4c and is fitted into the locking recess 3e, so that the shift lever 3 is locked at the origin position S0 and moved to another position. It becomes impossible to move.
[0019]
The shift lever 3 is operated to shift from the origin position S0 in a substantially front / rear / left / right cross direction (up / down / left / right direction in FIG. 5A). More specifically, as shown in FIG. 5A, the selection device 1 performs the shift operation from the origin position S0 to the right first position S1, from the origin position S0 to the left second position S2, and to the origin position S0. 4 shift operations for shifting the shift lever 3 from the rear position (downward in the figure) to the third position S3 and from the origin position S0 to the fourth position S4 forward (upward in the figure) can be performed. ing. The shift lever 3 is operated with a light force during the selection operation.
[0020]
Sensors 8a to 8d (shown in FIG. 4) for detecting that the shift lever 3 has been shifted from the origin position S0 to the selection positions S1 to S4 are provided at the selection positions S1 to S4 of the selection device 1, respectively. The output signal from each sensor is configured to be transmitted to the SBW-ECU 11 (electronic control device for shift control). The sensors 8a to 8d and the SBW-ECU 11 constitute a selection state detection unit. A gear train connection state (P, N, D, R) described later is assigned to each of the selection positions S1 to S4.
[0021]
As shown in FIG. 4, the vehicle transmission control device 12 includes a selection device 1, an SBW-ECU 11, a shift position indicator 13, a transmission hydraulic actuator 14, a range position detector 15, a brake switch 16, and vehicle speed detection means. A vehicle speed sensor 17 and a solenoid drive circuit 18 are provided. The selector device 1, the solenoid 6, the sensors 8a to 8d, the SBW-ECU 11, the shift hydraulic actuator 14, the vehicle speed sensor 17, and the solenoid drive circuit 18 constitute a shift device.
[0022]
The transmission hydraulic actuator 14 is a component of an automatic transmission (hereinafter referred to as a transmission) 21 as an automatic transmission, and includes an electromagnetic control valve (not shown) operated by an electric signal, and is supplied from a hydraulic pump. Each electromagnetic control valve controls the supply and discharge of oil to switch the gear train connection state. The connection state of the gear train is switched to a neutral state (neutral) N, a parking state (parking) P, a traveling state (drive) D, and a reverse state (reverse) R.
[0023]
The range position detector 15 is provided in the housing of the transmission 21, detects the gear train connection state (P, N, D, R) and transmits the detection signal to the SBW-ECU 11.
[0024]
The SBW-ECU 11 includes a microcomputer (not shown). The microcomputer executes a control program stored in advance to control the gear shift hydraulic actuator 14 to switch the gear train connection state. The SBW-ECU 11 controls the shift hydraulic actuator 14 based on the operation signal from the selection device 1 and the detection signal from the range position detector 15.
[0025]
As shown in FIG. 4B, the shift position indicator 13 displays that the connection state of the transmission 21 is the parking state P, and also displays that the connection state is the neutral state N. A neutral display unit 13b, a reverse display unit 13c that displays that the vehicle is in the reverse state R, and a travel display unit 13d that displays that the vehicle is in the travel state D are provided.
[0026]
The shift position indicator 13 controls display of each display unit 13a to 13d based on a control signal transmitted from the SBW-ECU 11. The parking display unit 13a is controlled to be lit when the SBW-ECU 11 is in the parking state P when the transmission 21 is connected, and the neutral display unit 13b is controlled to be lit when the connection state is also in the neutral state N. The Similarly, the reverse display portion 13c is controlled to be lit when the connected state is in the reverse state R, and the traveling display portion 13d is controlled to be lit when the traveling state is in the traveling state D in the automatic transmission mode.
[0027]
The brake switch 16 transmits a brake signal to the SBW-ECU 11 when the brake pedal is operated. The vehicle speed sensor 17 detects the vehicle speed and transmits a vehicle speed signal to the SBW-ECU 11. The SBW-ECU 11 is configured so that the connection state of the transmission 21 is the traveling state D and the vehicle speed is set in advance so that the traveling state D is not connected to the backward traveling state R when the vehicle speed is equal to or higher than the predetermined speed. When the speed exceeds the predetermined speed, the lock signal L is continuously transmitted to the solenoid drive circuit 18 (shift lock in the forward movement state D). When the vehicle speed is lower than the predetermined speed, the transmission of the lock signal L is stopped.
[0028]
Next, the operation of the shift device will be described.
As shown in FIG. 2A, when the shift lever 3 is shifted from the origin position S0 to the first position S1, the SBW-ECU 11 changes the gear train connection state to the parking state based on the electrical signal from the selection device 1. Switch to P. The connection state is switched to the neutral state N when the origin position S0 is the second position S2, the travel state D is switched when the third position S3 is the same, and the reverse state R is switched when the fourth position S4 is the same. Here, the traveling state D is a connection state in an automatic traveling mode in which connection states having different gear ratios in the gear train are automatically selected. In this automatic travel mode, the transmission electronic control unit (ECT-ECU) 22 connected to the SBW-ECU 11 switches and controls the gear train connection state based on the vehicle speed and the throttle opening based on the known control contents. The Note that when the connection state of the transmission 21 is the same as the connection state newly selected by the shift operation, the connection state of the transmission 21 remains unchanged.
[0029]
Further, when the accelerator pedal is depressed and the vehicle speed exceeds a predetermined speed when the transmission 21 is in the running state D, the SBW-ECU 11 sends the solenoid drive circuit 18 to the solenoid drive circuit 18 based on the vehicle speed signal transmitted from the vehicle speed sensor 17. A lock signal L is transmitted. When the lock signal L is transmitted, the solenoid drive circuit 18 excites the solenoid 6 to move the plunger upward, and the lock pin 6a is fitted into the lock recess 3e as shown in FIG. 2 (b). Therefore, the shift lever 3 is locked in a state where it is located at the origin position S0. The lock signal L is continuously transmitted while the vehicle speed is equal to or higher than the predetermined speed, and the solenoid 6 is continuously excited during that time, so that the shift lever 3 is kept locked while the forward speed of the vehicle is equal to or higher than the predetermined speed.
[0030]
When the vehicle speed becomes lower than the predetermined speed, transmission of the lock signal L is stopped, the solenoid 6 is de-energized, the plunger is moved downward, the lock pin 6a is pulled out from the lock recess 3e, and the shift lever 3 is The lock is released.
[0031]
This embodiment has the following effects.
(1) In the shift lever 3, when the gear train is connected in the forward traveling state D and the vehicle speed is equal to or higher than the predetermined speed, the lock pin 6a is fitted in the lock recess 3e, and from the origin position S0 to another selected position S1 The shift operation to ~ S4 is locked. Therefore, the malfunction of the shift lever 3 to the other selected positions S1 to S4 in the traveling state D can be prevented.
[0032]
(2) Since the locking recess 3e is formed so as to extend in a direction different from the cross direction in which the shift lever 3 tilts, the locking recess 3e is provided on the shift lever, for example, as in the shift lever disclosed in JP-A-10-59132. Unlike the configuration in which the lock pin is applied to the engagement protrusion and the lock pin stops the movement of the engagement protrusion and locks in only one direction, the operation of the shift lever 3 in any direction is locked by one lock pin 6a. it can.
[0033]
(3) Since the solenoid 6 is installed below the shift lever 3, the space below the shift lever 3 can be used effectively without protruding in the left-right direction.
(4) Since the locking recess 3e for fitting the locking pin 6a is formed in the spherical portion 3c having a diameter larger than that of the rod portion 3a, for example, it is shifted compared to the case where the locking recess is formed in the rod portion 3a. Durability (life) can be ensured without reducing the strength of the lever 3. Further, a fitting projection as a first engagement portion is formed on the rod portion 3a or the spherical portion 3c, and a second engagement portion is fitted on the plunger of the solenoid 6 with the fitting projection of the spherical portion 3c. The structure which locks compared with the structure etc. which provide the fitting member in which the fitting recessed part as these were formed can be formed easily.
[0034]
(5) Since the shift lever 3 only moves to the selected position and transmits an electrical signal to the SBW-ECU 11, it can be easily reduced in size as compared with a configuration in which a gear is mechanically selected.
[0035]
In addition, embodiment is not restricted above, For example, you may change as follows.
-In above-mentioned embodiment, although the recessed part 3e for a lock | rock was formed in the rod part 3a opposite side (downward) of the spherical part 3c, you may form in the lateral side of the spherical part 3c. For example, as shown in FIG. 6A, it is formed on the same plane as the surface on which the guide protrusion 3d is disposed, and is adjacent to the locking recess 3e so as to lock the tilt of the shift lever 3 in the cross direction. The guide projection 3d is formed so that the angle with the guide projection 3d is approximately 45 °. And the solenoid 6 is installed in the left-right direction of the spherical part 3c so that the locking pin 6a may be fitted in the locking recess 3e.
[0036]
-In above-mentioned embodiment, although the recessed part 3e for a lock | rock was formed in the spherical part 3c, you may form in the rod part 3a. For example, as shown in FIG. 6B, a lock through hole 3f as a first engagement portion is formed in the vicinity of the spherical portion 3c of the rod portion 3a, and the lock pin 6a is provided in the lock through hole 3f. The solenoid 6 is installed on the upper surface of the holder case 5 so as to penetrate and fit.
[0037]
The rod portion 3a is not provided with the lock through-hole 3f, but the plunger 6 of the solenoid 6 is provided with an engagement member having a bifurcated tip that sandwiches and engages the rod portion 3a instead of the lock pin 6a. The shift lever 3 may be locked by engaging the rod portion 3a with the recess.
[0038]
In the above embodiment, the shift lever 3 is locked by fitting the lock pin into the lock recess or the lock through hole, but the spherical portion 3c is pressed by the lock member having the spherical portion. You may make it the structure locked by this. For example, as shown in FIGS. 6C and 6D, two substantially hemispherical lock members 31 are accommodated in the enlarged accommodating recess 4a so as to face each other and cover the spherical portion 3c. The inner surface 31a of each lock member 31 that presses the spherical portion 3c is formed to be the same spherical surface as the spherical portion 3c. Each lock member 31 is formed with a long hole-like through hole 31b extending vertically so as to be penetrated by the guide protrusion 3d.
When the lock is released, the lock member 31 is not in contact with the spherical portion 3c and the guide projection 3d. Two pairs of racks 31c are formed under the lock members 31 so as to face each other, and each rack 31c is engaged with two pinions 32b provided on the rotating shaft 32a of the motor 32, respectively. The lock member 31 and the motor 32 constitute a lock means. When the motor 32 is rotated forward, both lock members 31 press the spherical portion 3c with the inner side surface 31a to lock the shift lever 3, and when the motor 32 is rotated reversely, both lock members 31 are separated from the spherical portion 3c. The lock is released.
[0039]
A polyhedral shape portion having a corner is provided instead of the spherical portion 3c at the base end of the rod portion 3a, and the inner surface of the lock member 31 is formed to be a polyhedron shape surface having the same shape as the outer shape of the polyhedron shape portion. Also good. In this case, the locking member 31 is pressed so as to sandwich the corners of the polyhedron-shaped portion, so that it is more reliably locked. In the unlocked state, the polyhedral shape portion is formed small so as not to come into contact with the lock member 31, and the polyhedral shape portion is supported by engaging the guide protrusion 3d with the guide groove 4b.
[0040]
-It is not restricted to the case of FIG.6 (c), (d), You may provide the polyhedron shape part which has a corner | angular part instead of the spherical part 3c.
The spherical recess 3e is formed in the spherical portion 3c, and the locking pin 6a is not provided in the plunger of the solenoid 6, but the locking projection as the first engaging portion is provided in the spherical portion 3c, and the solenoid An engaging member having a locking concave portion as a second engaging portion that fits with the locking protrusion may be attached to the plunger 6.
[0041]
In the above embodiment, the shift lever 3 is set to be locked so as not to be operated to the other selected positions S1 to S4 in the traveling state D that moves forward at a predetermined speed or higher. For example, it may be set to be locked so as not to be operated to the other selected positions S1 to S4 in the reverse state R in which the vehicle moves backward at a predetermined speed or more.
In this case, as in the above embodiment, the SBW-ECU 11 is locked to the solenoid drive circuit 18 when the connection state of the transmission 21 is the reverse state R and the vehicle speed is equal to or higher than a preset predetermined speed. The transmission of the lock signal L is stopped when the signal L is continuously transmitted and the vehicle speed is lower than the predetermined speed.
[0042]
In the above embodiment, the SBW-ECU 11 is set to determine the transmission of the lock signal L based on the signal from the vehicle speed sensor 17, but is not limited to the signal from the vehicle speed sensor 17, and other sensors, You may set so that transmission of the lock signal L may be judged based on the signal from a switch. For example, it is set so that transmission of the lock signal L is determined based on a signal from an acceleration sensor that detects a state in which the acceleration of the vehicle is equal to or higher than a predetermined acceleration.
[0043]
The shift lever 3 is not limited to being set to be locked in a forward or reverse traveling state of the vehicle, but a so-called parking lock function (the shift device is locked when the connection state of the transmission 21 is the parking state P). And the function of releasing the lock when the brake pedal is depressed may be set. For example, the SBW-ECU 11 continues to transmit the lock signal L to the solenoid drive circuit 18 when the connection state of the transmission 21 is the parking state P, and transmits the lock signal L when the brake signal is received from the brake switch 16. Set to stop.
[0044]
In the above embodiment, the shift lever 3 is a momentary type. However, the shift lever 3 may be changed to a stationary type that is held at the selected position even when the operating force applied to the shift lever 3 is released. In this case, the shape of the shift gate may be linear as in JP-A-10-59132, and the shift lever may be operated linearly. Then, the shift lever may be locked by extending the engagement member having a bifurcated tip from the direction perpendicular to the direction in which the shift lever moves and sandwiching the rod portion in the concave portion of the bifurcated portion.
[0045]
The shape of the shift gate in the case of the stationary type may be a cross shape like the shift gate 2a in the case of the momentary type. In this case, for example, the shift lever is tilted so that the locking recess and the locking pin face each other when the shift lever 3 is tilted so that the lock lever can be locked while being held at the selected position. The locking recess is formed in the spherical portion 3c by shifting the distance.
[0046]
-You may form the through-hole for a lock | rock in the spherical part 3c instead of the recessed part 3e for a lock | rock.
In the above embodiment, the selection device 1 is provided on the floor console F, but may be provided on the column S (shown in FIG. 3). Moreover, you may provide in the instrument panel 41 (illustrated in FIG. 3) etc.
[0047]
Next, the technical idea that can be grasped from the above embodiment will be added below.
(1) In the shift device , the locking means is a solenoid.
[0048]
(2) In the shift device , the lock means has a surface having the same shape as the surface of the base portion of the selection operation means, a lock member that presses the base portion on the surface, and a motor that drives the lock member; It has.
[0049]
【The invention's effect】
As described above in detail, according to the invention described in claim 1 or claim 2 , it is possible to prevent malfunction of the selection operation means in a predetermined state of the vehicle.
[Brief description of the drawings]
FIG. 1A is a schematic exploded perspective view of a selection device, and FIG. 1B is a schematic cross-sectional view showing a base portion and a holder of a shift lever.
2A is a schematic cross-sectional view of a selection device, and FIG. 2B is a schematic cross-sectional view when a shift lever is locked.
FIG. 3 is a schematic perspective view showing a selection device and a shift position indicator.
FIG. 4 is a schematic diagram showing a vehicle transmission control device.
5A is a plan view showing a shift gate of a selection device, and FIG. 5B is a front view showing a shift position indicator.
6A is a schematic perspective view showing another locking means, FIG. 6B is a schematic sectional view showing another locking means, FIG. 6C is a schematic exploded perspective view showing another locking means, and FIG. Is a schematic cross-sectional view.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Select device which comprises shift apparatus, 3 ... Shift lever as selection operation means 3a ... Rod part as main body of selection operation means, 3c ... Spherical part as base of selection operation means, 3e ... 1st Locking recess as engaging portion, 3f... Locking through hole as first engaging portion, 6. Solenoid as locking means constituting shift device, 6a... Locking pin as second engaging portion , 8a to 8d ... sensors constituting the selection state detection means constituting the shift device, 11 ... same shift control electronic control unit (SBW-ECU), 14 ... shift hydraulic actuators constituting the shift device, 17 ... same vehicle speed Vehicle speed sensor as detecting means, 18 ... solenoid drive circuit constituting shift device, 21 ... automatic transmission as automatic transmission (transmission) , The locking member constituting the 31 ... locking means 32 ... same motor.

Claims (2)

A selection operation means operated to select a connection state of a gear train of an automatic transmission of a vehicle, a selection state detection means for detecting a selection state of the selection operation means, and a lock for locking the selection operation means to be immovable A shift device comprising means,
The locking means is configured to be able to lock the selection operation means when the selection operation means is in a predetermined state and the vehicle is in a predetermined condition ,
The selection operation means is a momentary type that returns to the reference position when the operation force is released, and the selection operation means is provided so as to be tiltable in multiple directions from the reference position, and the selection operation means is related to an unevenness. A first engagement portion is provided, and the lock means is provided with a second engagement portion that can be engaged with the first engagement portion of the selection operation means in an uneven relationship,
The shift device is characterized in that the selection operation device locks the selection operation device so as not to tilt in any of the multi-directional directions at the reference position .   The shift device according to claim 1, wherein the lock unit is installed on a side opposite to a main body of the selection operation unit with respect to a base of the selection operation unit.

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