JP2015058923A - Shift lever device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a shift lever device which can reduce a portion in which members for detecting the position of the shift lever is installed, while ensuring the reliability.SOLUTION: A shift lever device includes a detent, a first magnet 51 provided on a second slide member 33 which moves forward and backward linked with the movement of the shift lever and a first sensor 61 provided on the base portion 31 facing to a second slide member 33. The first magnet 51 is located between the position of the first magnet 51 corresponding to the N position and the position of the first magnet 51 corresponding to the D position. The first sensor 61 has a first detection unit 61A in which the signal to be output is switched from L to H when the magnetic field above a predetermined value is applied to the frontal direction and a second detection unit 61B in which the signal to be output is switched from L to H when the magnetic field above a predetermined value is applied to the rear direction.

Description

  The present invention relates to a shift lever device having a moderation mechanism.

  2. Description of the Related Art Conventionally, a shift lever device including a shift lever that can move to a plurality of positions is known that includes a moderation mechanism that applies a load to the operation of the shift lever when the shift lever moves between the positions. . The shift lever device uses a sensor to detect the position of the shift lever.

  For example, the shift lever device disclosed in Patent Document 1 includes an interlocking portion that interlocks with the movement of the shift lever and a fixing portion that faces the interlocking portion. The interlocking portion is provided with a detected portion, and the fixed portion is provided with one sensor at a position facing the detected portion when the shift lever is located at each position. In this shift lever device, when the shift lever stops at a certain position, the detected portion is opposed to a sensor provided corresponding to the position, so that the position of the shift lever is detected.

JP 2008-44393 A

  However, in the technique described above, since one sensor is provided at least for each position, there is a problem that the number of places where the sensors are installed increases.

  Therefore, an object of the present invention is to provide a shift lever device that can reduce the number of places where members for detecting the position of the shift lever are installed while ensuring the reliability of the detection result.

  In order to achieve the above-described object, a shift lever device of the present invention has a shift lever configured to be movable to a first position and a second position, a convex portion, and an engaging portion that engages with the convex portion. The moderation mechanism is configured to apply a load to the operation of the shift lever when the shift lever passes through the convex portion when the shift lever passes through an intermediate portion between the first position and the second position. A mechanism, an interlocking portion that interlocks with the movement of the shift lever, a fixed portion that faces the interlocking portion, and a magnetic field that is provided in the interlocking portion and faces a first direction that is one of the moving directions of the interlocking portion. , A magnet arranged to generate a magnetic field directed in a second direction opposite to the first direction, a magnetic sensor provided in the fixed portion and capable of detecting the magnetic field, and an output of the magnetic sensor Based on the above A control unit for determining a position of the trevor, and the magnetic sensor corresponds to the first magnet position and the second position which are positions of the magnet corresponding to the first position in the moving direction of the interlocking unit. The magnetic sensor is disposed between the first magnet position and the magnetic sensor, and the magnetic sensor outputs a signal output from the first state when a magnetic field having a predetermined strength or more is applied in the first direction. A first detection unit that switches to a second state, and a second detection unit that switches a signal output when a magnetic field of a predetermined strength or more is applied in the second direction from the third state to the fourth state; The first detection unit has the magnet shifted by a predetermined distance to the first magnet position side from the intermediate magnet position, which is the position of the magnet when the engaging part gets over the top of the convex part. When the output signal is The second detection unit switches a signal to be output when the magnet is displaced by a predetermined distance from the intermediate magnet position to the second magnet position side. It is characterized by being configured to switch from the state to the fourth state.

  The shift lever device of the present invention includes a shift lever configured to be movable between a first position and a second position, a convex portion, and an engaging portion that engages with the convex portion. A moderation mechanism configured to apply a load to the operation of the shift lever when the engaging portion gets over the convex portion when passing through an intermediate portion between the first position and the second position; and the shift lever An interlocking portion that interlocks with the movement of the interlocking portion, a fixing portion that faces the interlocking portion, a magnetic field that is provided in the fixing portion and faces a first direction that is one of the moving directions of the interlocking portion, and the first direction. A magnet arranged to generate a magnetic field directed in a second direction opposite to the magnetic field, a magnetic sensor provided in the interlocking unit and capable of detecting the magnetic field, and the shift lever based on the output of the magnetic sensor Positions A control unit for determining, wherein the magnetic sensor corresponds to the first sensor position corresponding to the first position and the magnetic position corresponding to the second position in the moving direction of the interlocking unit. The magnetic sensor is disposed between a second sensor position that is a position of the sensor, and the magnetic sensor outputs a signal output from the first state to the second state when a magnetic field having a predetermined strength or more is applied in the first direction. A first detector that switches to a state of (2), and a second detector that switches from a third state to a fourth state when a magnetic field having a predetermined strength or more is applied in the second direction. In the first detection unit, the magnetic sensor is displaced by a predetermined distance toward the first sensor position from the intermediate sensor position, which is the position of the magnetic sensor when the engaging part gets over the top of the convex part. When the output signal Is switched from the first state to the second state, and the second detection unit outputs a signal when the magnetic sensor deviates a predetermined distance from the intermediate sensor position toward the second sensor position. Is configured to switch from the third state to the fourth state.

  According to the shift lever device configured as described above, since the first position and the second position can be detected by one magnetic sensor, the required reliability is ensured, and 1 for each position. Compared to a configuration in which two sensors are installed, it is possible to reduce the number of magnetic sensor and magnet installation locations for detecting the position of the shift lever.

  In the shift lever device described above, the control unit is configured such that the position of the shift lever is set on the condition that both the signal output from the first detection unit and the signal output from the second detection unit are switched. It is desirable to be configured to determine that switching has occurred between the first position and the second position.

  According to this, since the operation feeling obtained by the moderation mechanism matches the position determination by the control unit, the shift lever can be operated without a sense of incongruity.

  In the shift lever device described above, it is preferable that the magnetic sensor is configured as one component.

  In the shift lever device described above, since the first detection unit and the second detection unit are provided at one location, the magnetic sensor can be configured as one component in this way. And by comprising in this way, the assembly operation | work which installs a magnetic sensor becomes easy.

  According to the present invention, while ensuring the required reliability, the number of magnetic sensors and magnets for detecting the position of the shift lever is reduced compared to a configuration in which one sensor is installed for each position. be able to.

It is a disassembled perspective view which shows the shift lever apparatus which concerns on one Embodiment of this invention. It is a figure which shows the position of the gate of a cover member, and a shift lever. It is the bottom view (a) of a moderation member, and the perspective view (b) which shows the convex part of a moderation member. It is a left view of a shift lever apparatus. It is a rear view of a shift lever device. It is a figure which shows a 1st magnet, a 1st sensor, a 2nd sensor, and a control part when a shift lever is located in N position. It is a figure (b) which shows a 2nd magnet, a 3rd sensor, and a control part when a shift lever is located in N position. It is the figure (a) which shows the relationship between the magnetic field of a 1st detection part, and an output, and the figure (b) which shows the relationship between the magnetic field of a 2nd detection part, and an output. It is a figure which shows a 1st magnet, a 1st sensor, and a 2nd sensor when a shift lever passes the intermediate part of N position and D position. It is a figure which shows a 1st magnet, a 1st sensor, and a 2nd sensor when a shift lever is located in D position. It is a figure which shows a 1st magnet, a 1st sensor, and a 2nd sensor when a shift lever passes the intermediate part of N position and R position. It is a figure which shows a 1st magnet, 1st sensor, and 2nd sensor when a shift lever is located in R position. It is a map which shows the combination of the position of a shift lever, and the output of a 1st sensor, a 2nd sensor, and a 3rd sensor. It is a figure which shows the 3rd magnet and 4th sensor in a modification, Comprising: The figure (a) which shows when a shift lever is located in R position, and the time when a shift lever passes the intermediate part of P position and R position. It is a figure (b) shown. It is a figure which shows the 3rd magnet and 4th sensor when a shift lever is located in P position.

  Next, an embodiment of the present invention will be described with reference to the drawings as appropriate. In the following description, front and rear, left and right, and top and bottom are based on a driver who drives a vehicle including a shift lever device.

  As shown in FIG. 1, the shift lever device 1 mainly includes a lever member 10, a cover member 20, a sensor unit 30, and a moderation mechanism 40.

  The lever member 10 includes a shift lever 11 operated by the driver, a frame 12 with the shift lever 11 fixed to the upper portion, a support member 13 that supports the frame 12, and an engagement portion provided on the upper portion of the frame 12. It mainly has an engaging member 14 as an example.

  The frame 12 can swing left and right with respect to the support member 13 around a shaft portion 12A supported by the support member 13. The frame 12 has a boss 15 projecting rearward at the lower end. Further, the frame 12 has a cylindrical portion 16 on the upper surface where an engaging member 14 of a moderation mechanism 40 described later is disposed.

  And the frame 12 has the opening part 12B penetrated in the left-right direction, and the support member 13 is arrange | positioned inside it.

  The support member 13 is supported by a housing (not shown) and can swing back and forth around the shaft portion 13A. The support member 13 is provided so as to protrude in the left-right direction from the frame 12, and an arm 17 extending downward is provided at the left end. The lower end of the arm 17 is provided at substantially the same height as the boss 15 of the frame 12.

  The lever member 10 configured as described above is constantly urged toward a posture (N position described later) such that the shift lever 11 stands vertically by an urging means (for example, a spring) (not shown). The lever member 10 may have a weight distribution such that the shift lever 11 always stands vertically due to its own weight.

  The cover member 20 is a cover that covers the upper portion of the frame 12. The cover member 20 is formed with a gate 21 with which the shift lever 11 is engaged.

  As shown in FIG. 2, the gate 21 is formed to be movable to five positions as the shift lever 11 moves along the gate 21. Specifically, the gate 21 includes three positions where the shift lever 11 is aligned in the front-rear direction, specifically, a reverse position (R position), a neutral position (N position) as an example of the first position, It can move to a travel position (D position) as an example of the second position. The gate 21 can also move to a parking position (P position) where the shift lever 11 is shifted to the right from the R position and a low speed position (L position) where the shift lever 11 is shifted to the right from the D position. . The P position and the L position are arranged at the same position in the left-right direction.

  Returning to FIG. 1, the moderation mechanism 40 includes an engagement member 14 provided on the frame 12 of the lever member 10 and a moderation member 22 provided on the cover member 20.

  The engaging member 14 is a rod-like member extending in the vertical direction, and the upper end has a hemispherical shape. The engaging member 14 is disposed in the cylindrical portion 16 of the frame 12, so that the engaging member 14 can be moved back and forth and right and left integrally with the shift lever 11 and can be moved in the vertical direction along the cylindrical portion 16. . The engaging member 14 is urged upward by a compression coil spring 18 provided in the cylindrical portion 16.

  The moderation member 22 is a member with which the engagement member 14 is engaged, and is fixed to the lower surface of the cover member 20. As shown in FIG. 3, the moderation member 22 has a plurality of convex portions 24 with which the engagement member 14 engages on the surface facing the engagement member 14, that is, the bottom surface. The plurality of convex portions 24 are provided on the movement locus of the engaging member 14 when the shift lever 11 is operated, and are an intermediate position between the P position and the R position, an intermediate position between the R position and the N position, and an N position. One is arranged at each of the intermediate position of the D position and the intermediate position of the D position and the L position. And the top part 24A of each convex part 24 is arrange | positioned in the center part between two adjacent positions.

  In the present invention, the top portion is the highest portion of the convex portion, and in this embodiment, the top portion is formed in a linear shape extending in a direction orthogonal to the moving direction of the engaging member 14. The top portion may be a flat surface.

  In the moderation mechanism 40, when the shift lever 11 passes through an intermediate portion between two adjacent positions, the engaging member 14 moves over the convex portion 24 while being pressed against the bottom surface of the moderation member 22 by the compression coil spring 18. A load can be applied to the operation of the lever 11.

  As shown in FIG. 1, the sensor unit 30 is a unit that is disposed below the lever member 10 and includes a plurality of magnets and a plurality of sensors described later. The sensor unit 30 includes a base portion 31 as an example of a fixed portion, a first slide member 32 that is slidable to the left and right with respect to the base portion 31, and a slidable back and forth with respect to the base portion 31. It has mainly the 2nd slide member 33 as an example of the provided interlocking | linkage part. Further, on the base portion 31, a first guide portion 34 that guides the sliding movement of the first slide member 32 and a second guide portion 35 that guides the sliding movement of the second slide member 33 are provided.

  The first slide member 32 has a box-shaped holding portion 32A and a pair of clamping portions 32B that extend upward from the holding portion 32A and face each other in the left-right direction. The pair of sandwiching portions 32B sandwich the boss 15 of the lever member 10 in the left-right direction.

  The second slide member 33 includes a box-shaped holding portion 33A and a pair of clamping portions 33B that extend upward from the holding portion 33A and face each other in the left-right direction. The pair of sandwiching portions 33B sandwich the lower end of the arm 17 of the lever member 10 in the front-rear direction.

The first guide portion 34 is provided so as to sandwich the holding portion 32A of the first slide member 32 in the front-rear direction, and extends in the left-right direction.
The second guide part 35 is provided so as to sandwich the holding part 33A of the second slide member 33 in the left-right direction, and extends in the front-rear direction.

  In the shift lever device 1 configured as described above, as shown in FIG. 4, when the shift lever 11 is tilted back and forth, the frame 12 and the support member 13 integrally swing back and forth. At this time, the boss 15 of the frame 12 swings back and forth between the pair of sandwiching portions 32 </ b> B of the first slide member 32. Further, the arm 17 of the support member 13 engages with the pair of clamping portions 33 </ b> B of the second slide member 33 and moves back and forth together with the second slide member 33. Specifically, when the shift lever 11 falls to the front side, the second slide member 33 moves to the rear side. When the shift lever 11 is tilted rearward, the second slide member 33 moves to the front side.

  As shown in FIG. 5, when the shift lever 11 is tilted to the right, the frame 12 swings with respect to the support member 13, and the upper portion of the frame 12 moves to the right and the lower portion moves to the left. At this time, the boss 15 of the frame 12 engages with the pair of sandwiching portions 32 </ b> B of the first slide member 32 and moves to the left together with the first slide member 32.

Next, a configuration for detecting the position of the shift lever 11 will be described.
As shown in FIGS. 6 and 7, the shift lever device 1 includes a first magnet 51, a first sensor 61 and a second sensor 62 for detecting the movement of the shift lever 11 in the front-rear direction, and the left-right direction of the shift lever 11. Are further provided with a second magnet 52 and a third sensor 63 for detecting the movement of the control unit 70, and a control unit 70.

  As shown in FIG. 6, the first magnet 51 includes a pair of front and rear magnets, and is fixed to the holding portion 33 </ b> A of the second slide member 33.

  The first magnet 51 moves back and forth as the second slide member 33 is interlocked with the movement of the shift lever 11, and the M1 position (position in FIG. 6) as an example of the first magnet position corresponding to the N position. M2 position (position in FIG. 10) as an example of the second magnet position corresponding to the D position and L position moved forward from the M1 position, and M3 corresponding to the R position and P position moved backward from the M1 position. It can move to a position (position in FIG. 12). The first magnet 51 has an M4 position (position in FIG. 9) as an example of an intermediate magnet position that is an intermediate position between the M1 position and the M2 position, and an M5 position (FIG. 11) that is an intermediate position between the M1 position and the M3 position. It is also possible to move to (position).

  The M4 position is a position when the engaging member 14 gets over the top 24A of the convex portion 24 when the shift lever 11 passes through the intermediate portion between the N position and the D position, and the M5 position is the shift lever. 11 is a position at which the engaging member 14 gets over the top 24A of the convex portion 24 when passing through an intermediate portion between the N position and the R position.

  The first magnet 51 generates a magnetic field that faces a front direction (first direction) that is one of the moving directions of the second slide member 33 and a magnetic field that faces a rear direction (second direction) opposite to the front direction. In order to occur, the magnetic poles (S pole and N pole) are arranged in such a posture that the direction in which the magnetic poles (S pole and N pole) are aligned is orthogonal to the moving direction of the second slide member 33.

  When the first magnet 51 is located at the M1 position, it applies a magnetic field having a predetermined strength or more to the first sensor 61 in the forward direction and applies a magnetic field having a predetermined strength or more to the second sensor 62 in the backward direction. It has become. Further, when the first magnet 51 moves to the M2 position side from the M1 position, it applies a magnetic field of a predetermined strength or more to the second sensor 62 in the backward direction, and moves to the M3 position side from the M1 position. In addition, a magnetic field having a predetermined strength or more is applied to the first sensor 61 in the forward direction.

  As shown in FIG. 7, the second magnet 52 includes a pair of left and right magnets, and is fixed to the holding portion 32 </ b> A of the first slide member 32.

  The second magnet 52 moves to the left and right as the first slide member 32 is interlocked with the movement of the shift lever 11, and moves to the left from the M6 position corresponding to the R position, the N position, and the D position. It is also possible to move to the M7 position corresponding to the P position and L position and the M8 position which is an intermediate position between the M6 position and the M7 position. In the M8 position, when the shift lever 11 passes through the intermediate portion between the R position and the P position, or when the shift member 11 passes through the intermediate portion between the D position and the L position, the engaging member 14 is the top of the convex portion 24. This is the position when getting over 24A.

  The second magnet 52 generates a magnetic field facing the left direction (first direction) which is one of the moving directions of the first slide member 32 and a magnetic field facing the right direction (second direction) opposite to the left direction. In order to occur, the magnetic poles (S pole and N pole) are arranged in such a posture that the direction in which the magnetic poles (S pole and N pole) are aligned is orthogonal to the moving direction of the first slide member 32. When the second magnet 52 is located at the M6 position, the second magnet 52 applies a predetermined magnetic field to the third sensor 63 in the left direction. A magnetic field is applied.

  As shown in FIGS. 6 and 7, the first sensor 61, the second sensor 62, and the third sensor 63 are magnetic sensors capable of detecting a magnetic field.

  The first sensor 61 is fixed to the base portion 31 between the M1 position and the M2 position in the moving direction of the second slide member 33, that is, at a position facing the first magnet 51 at the M4 position. The second sensor 62 is fixed to the base 31 in the moving direction of the second slide member 33 between the M1 position and the M3 position, that is, at a position facing the first magnet 51 at the M5 position. The third sensor 63 is fixed to the base portion 31 between the M6 position and the M7 position in the moving direction of the first slide member 32, that is, at a position facing the second magnet 52 at the M8 position.

  The first sensor 61 includes a first detection unit 61A and a second detection unit 61B, and is configured as one component. Similarly, the second sensor 62 and the third sensor 62 have first detection units 62A and 63A and second detection units 62B and 63B, respectively, and are configured as one component. The first detectors 61A, 62A, 63A and the second detectors 61B, 62B, 63B are, for example, giant magnetoresistive elements. The first detectors 61A, 62A, 63A and the second detectors 61B, 62B, 63B may be Hall elements or anisotropic magnetoresistive elements.

  As shown in FIG. 8A, the first detectors 61A and 62A of the first sensor 61 and the second sensor 62 output a signal that is output when a magnetic field having a predetermined strength or more is applied in the forward direction. It is configured to switch from L being the state 1 to H being the second state. In addition, the first detection unit 63A of the third sensor 63 is configured so that the output signal is switched from L to H when a magnetic field having a predetermined strength or more is applied in the left direction.

  As a result, the first detection unit 61A of the first sensor 61 causes the first magnet 51 to deviate by a predetermined distance from the M4 position facing the first sensor 61 to the M1 position side (rear side) (engaging member 14). However, when the first switching position P1 shown in FIG. 6 is passed from the D position side to the N position side, the output signal is switched from L to H. In addition, the first detection unit 62A of the second sensor 62 is configured such that the first magnet 51 is displaced by a predetermined distance from the M5 position facing the second sensor 62 to the M3 position side (rear side) (the engagement member 14 is When the second switching position P2 shown in FIG. 6 is passed from the N position side to the R position side), the output signal is switched from L to H. Then, the first detection unit 63A of the third sensor 63 is configured such that the second magnet 52 is displaced by a predetermined distance from the M8 position facing the third sensor 63 to the M7 position side (right side) (the engaging member 14 is When the third switching position P3 shown in FIG. 7 is passed from the P position side to the R position side), the output signal is switched from L to H.

  In addition, each 1st detection part 61A, 62A, 63A has the characteristic that the magnetic field when the signal to output switches from H to L and the magnetic field when it switches from L to H are different, as shown to Fig.8 (a). However, each first detection unit may have the same magnetic field when the output signal is switched from H to L and the magnetic field when the signal is switched from L to H.

  As shown in FIG. 8 (b), the second sensor 61B, 62B of the first sensor 61 and the second sensor 62 outputs a signal that is output when a magnetic field with a predetermined strength or more is applied in the backward direction. 3 is switched from L which is the state 3 to H which is the fourth state. In addition, the second detection unit 63B of the third sensor 63 is configured so that the output signal is switched from L to H when a magnetic field having a predetermined strength or more is applied in the right direction.

  As a result, the second detection unit 61B of the first sensor 61 causes the first magnet 51 to deviate a predetermined distance from the M4 position facing the first sensor 61 to the M2 position side (front side) (the engagement member 14 is When the fourth switching position P4 shown in FIG. 6 is passed from the N position side to the D position side), the output signal is switched from L to H. Further, the second detection unit 62B of the second sensor 62 is configured such that the first magnet 51 is displaced by a predetermined distance from the M5 position facing the second sensor 62 to the M1 position side (front side) (the engaging member 14 is When the fifth switching position P5 shown in FIG. 6 is passed from the R position side to the N position side), the output signal is switched from L to H. Then, the second detection unit 63B of the third sensor 63 is configured so that the second magnet 52 is displaced by a predetermined distance from the M8 position facing the third sensor 63 to the M6 position side (right side) (the engagement member 14 is When the sixth switching position P6 shown in FIG. 7 is passed from the R position side to the P position side), the output signal is switched from L to H.

  As shown in FIGS. 6 and 7, the control unit 70 is a device that controls each part of the vehicle according to a preset program or the like, and includes a CPU (Central Processing Unit), a RAM (Random Access Memory), and a ROM (Read). Only Memory). The control unit 70 is configured to determine the position of the shift lever 11 based on the outputs of the first sensor 61, the second sensor 62, and the third sensor 63. In addition, the control part 70 may be installed in the housing | casing of the shift lever apparatus 1, may be provided outside the housing | casing of the shift lever apparatus 1, for example, may be installed in the vehicle body.

  Specifically, the control unit 70 stores a map showing combinations of positions and outputs of the sensors 61, 62, and 63 as shown in FIG. 13, and outputs from this map and the sensors 61, 62, and 63. The position of the shift lever 11 is determined based on the transmitted signal.

  Further, as can be seen from the map of FIG. 13, the control unit 70 is provided on condition that both the signal output from the first detection unit 61 </ b> A of the first sensor 61 and the signal output from the second detection unit 61 </ b> B are switched. As a result, it is determined that the position of the shift lever 11 is switched between the N position and the D position, and both the signal output from the first detection unit 62A of the second sensor 62 and the signal output from the second detection unit 62B are switched. On the condition that the position of the shift lever 11 is switched between the N position and the R position. Further, the control unit 70 sets the shift lever 11 to the R position on condition that both the signal output from the first detection unit 63A of the third sensor 63 and the signal output from the second detection unit 63B are switched. It is configured to determine that switching has occurred between the P position or between the D position and the L position.

The operation of the shift lever device 1 configured as described above will be described.
When the shift lever 11 is located at the N position, as shown in FIGS. 6 and 7, the first magnet 51 is located at the M1 position between the first sensor 61 and the second sensor 62, and the second magnet 52 is It is located at the position M6 arranged on the right side of the third sensor 63.

  In this state, a magnetic field having a predetermined strength or higher is applied to the first sensor 61 in the forward direction, and a magnetic field having a predetermined strength or higher is applied to the second sensor 62 in the rear direction. Accordingly, in the first sensor 61, the signal output from the first detection unit 61A is H, and the signal output from the second detection unit 61B is L. In the second sensor 62, the first detection unit 62A. The signal output from L is L, and the signal output from the second detector 62B is H.

  The third sensor 63 is applied with a magnetic field with a predetermined strength or more in the left direction. Thereby, in the 3rd sensor, the signal which the 1st detection part 63A outputs is H, and the signal which the 2nd detection part 63B outputs is L.

  The control unit 70 determines that the shift lever 11 is in the N position based on signals output from the first sensor 61, the second sensor 62, and the third sensor 63 (see FIG. 13).

  When the shift lever 11 is tilted backward from the N position toward the D position, as shown in FIG. 9, the first magnet 51 moves forward from the M1 position toward the M2 position. At this time, when the first magnet 51 moves forward from the M1 position, the forward magnetic field applied to the first sensor 61 is weakened, and the signal of the first detection unit 61A of the first sensor 61 is switched from H to L. .

  When the shift lever 11 is moved from the N position to the D position, the second sensor 62 is still applied with a magnetic field having a strength of a predetermined level or more in the backward direction. The signal output from the detector 62A remains L, and the signal output from the second detector 62B remains H. Further, when the shift lever 11 is moved from the N position to the D position, the shift lever 11 is not moved to the left and right, so that the third sensor 63 outputs when the shift lever 11 is located at the D position. The signal is similar to the N position.

  When the shift lever 11 is in an intermediate portion between the N position and the D position, that is, when the engaging member 14 passes through the top 24A of the convex portion 24, the first magnet 51 is located at the M4 position facing the first sensor 61. Then, a downward magnetic field is applied to the first sensor 61. At this time, the signal of the first detection unit 61A of the first sensor 61 maintains L, and the signal of the second detection unit 61B also maintains L.

  As shown in FIG. 10, when the shift lever 11 further moves to the D position side and the engaging member 14 passes the fourth switching position P4, the first magnet 51 is shifted from the M4 position to the M2 position side by a predetermined distance. At this time, a predetermined or higher magnetic field is applied to the first sensor 61 in the backward direction. Thereby, the signal of the 2nd detection part 61B of the 1st sensor 61 switches from L to H.

  As described above, when both the signal output from the first detection unit 61A of the first detection unit 61 and the signal output from the second detection unit 61B are switched, the control unit 70 switches the first sensor 61, the second sensor 62, and Based on the signal output from the third sensor 63, it is determined that the shift lever 11 is in the D position (see FIG. 13).

  When the shift lever 11 is positioned at the D position, a magnetic field greater than or equal to a predetermined value is applied to the first sensor 61 and the second sensor 62 in the backward direction, so that signals output from the first sensor 61 and the second sensor 62 are output. The determination by the control unit 70 is also maintained at the D position.

  When the shift lever 11 is moved from the D position toward the N position, the first magnet 51 moves backward from the M2 position toward the M1 position. At this time, the signal output from the second detection unit 61B of the first sensor 61 is switched from H to L. When the engaging member 14 passes the first switching position P1, the first magnet 51 is shifted from the M4 position to the M1 position side by a predetermined distance. At this time, the signal output from the first detection unit 61A of the first sensor 61 is switched from L to H. Thereby, the control part 70 determines with the shift lever 11 being in N position (refer FIG. 13).

  When the shift lever 11 is tilted forward from the N position toward the R position, the first magnet 51 moves backward from the M1 position toward the M3 position as shown in FIG. At this time, as shown in FIG. 11, the backward magnetic field applied to the second sensor 62 is weakened by the first magnet 51 moving backward from the M1 position, and the second detection unit 62B of the second sensor 62 outputs it. The signal to be switched is switched from H to L.

  Note that when the shift lever 11 is moved from the N position to the R position, the first sensor 61 is still applied with a magnetic field having a predetermined strength or more in the forward direction. The signal output from the detector 61A remains L, and the signal output from the first detector 61A remains H. Further, when the shift lever 11 is moved from the N position to the R position, the third lever 63 outputs when the shift lever 11 is located at the R position because the shift lever 11 is not moved left and right. The signal is similar to the N position.

  When the shift lever 11 is in the middle between the N position and the R position, that is, when the engaging member 14 passes the top 24A of the convex portion 24, the first magnet 51 is positioned at the M5 position facing the second sensor 62. Then, a downward magnetic field is applied to the second sensor 62. At this time, the signal of the second detection unit 62B of the second sensor 62 maintains L, and the signal of the first detection unit 62A also maintains L.

  As shown in FIG. 12, when the shift lever 11 further moves to the R position side and the engaging member 14 passes the second switching position P2, the first magnet 51 is shifted from the M5 position to the M3 position side by a predetermined distance. At this time, a predetermined or higher magnetic field is applied to the second sensor 62 in the forward direction. As a result, the signal of the first detection unit 61A of the second sensor 62 is switched from L to H.

  As described above, when both the signal output from the first detection unit 62A of the second detection unit 62 and the signal output from the second detection unit 62B are switched, the control unit 70 switches the first sensor 61, the second sensor 62, and Based on the signal output from the third sensor 63, it is determined that the shift lever 11 is in the R position (see FIG. 13).

  When the shift lever 11 is positioned at the R position, a predetermined or higher magnetic field is applied to the first sensor 61 and the second sensor 62 in the forward direction, so that signals output from the first sensor 61 and the second sensor 62 are output. The determination by the control unit 70 is also maintained at the R position.

  When the shift lever 11 is moved from the R position toward the N position, the first magnet 51 moves forward from the M3 position toward the M1 position. At this time, the signal output from the first detection unit 61A of the second sensor 62 is switched from H to L. When the engaging member 14 passes the fifth switching position P5, the first magnet 51 is shifted from the M5 position to the M1 position side by a predetermined distance. At this time, the signal output from the second detection unit 62B of the first sensor 61 is switched from L to H. Thereby, the control part 70 determines with the shift lever 11 being in N position (refer FIG. 13).

  As shown in FIG. 7, when the shift lever 11 is tilted to the right from the R position to the P position or from the D position to the L position, the second magnet 52 moves to the left from the M6 position to the M7 position. At this time, when the second magnet 52 moves to the left of the M6 position, the left magnetic field applied to the third sensor 63 is weakened, and the signal of the first detector 61A of the third sensor 63 switches from H to L. .

  Note that when the shift lever 11 is moved from the R position to the P position or from the D position to the L position, the first sensor 61 and the second sensor 62 output because the shift lever 11 does not move back and forth. The signal is the same as the R position when moving from the R position to the P position, and is the D position when moving from the D position to the L position.

  When the engaging member 14 passes through the top 24 </ b> A of the convex portion 24, the second magnet 52 is located at the position M <b> 8 facing the third sensor 63, and a downward magnetic field is applied to the third sensor 63. At this time, the signal of the first detection unit 63A of the third sensor 63 maintains L, and the signal of the second detection unit 63B also maintains L.

  When the shift lever 11 further moves to the P position or L position side and the engaging member 14 passes through the sixth switching position P6, the second magnet 62 is shifted from the M8 position to the M7 position side by a predetermined distance. At this time, a predetermined magnetic field or more is applied to the third sensor 63 in the right direction. Thereby, the signal of the 2nd detection part 63B of the 3rd sensor 63 switches from L to H.

  As described above, the control unit 70 switches between the first sensor 61, the second sensor 62, and the signal output from the first detection unit 63A of the third detection unit 63 and the signal output from the second detection unit 63B. It is determined from the signal output from the third sensor 63 that the shift lever 11 is in the P position or the L position (see FIG. 13).

  When the shift lever 11 is located at the P position or the L position, a magnetic field greater than or equal to a predetermined value is applied to the third sensor 63 in the right direction. Therefore, the signal output from the third sensor 63 is maintained, and the control unit 70 Judgment is also maintained.

  When the shift lever 11 is moved from the P position to the R position or from the L position to the D position, the third magnet 53 moves backward from the M7 position to the M6 position. At this time, the signal output from the second detection unit 63B of the third sensor 63 is switched from H to L. When the engaging member 14 passes the third switching position P3, the second magnet 62 is shifted from the M8 position to the M6 position by a predetermined distance. At this time, the signal output from the first detection unit 63A of the third sensor 63 is switched from L to H. Thereby, the control unit 70 determines that the shift lever 11 is in the R position or the D position (see FIG. 13).

The effect of the shift lever device 1 configured as described above will be described.
As described above, the shift lever device 1 can detect two adjacent positions by the first sensor 61, the second sensor 62, or the third sensor 63 disposed at a position corresponding to the intermediate portion. It is possible to reduce the number of sensor installation locations for detecting the position of the shift lever 11 as compared with the configuration in which one sensor is installed for each position while ensuring the reliability.

  In addition, since the number of installation locations of the sensor for detecting the position of the shift lever 11 is reduced, the installation location of elements for protecting the sensor such as a capacitor and a resistor connected to the sensor can also be reduced.

  Then, the control unit 70, in one of the first sensor 61, the second sensor 62, and the third sensor 63, outputs a signal output from the first detection unit 61A, 62A, 63A and the second detection unit 61B, 62B. , 63B, on the condition that both of the signals output are switched, it is determined that the position of the shift lever 11 has been switched, so that the shift is performed after the engaging member 14 has passed over the top 24A of the convex portion 24. It is determined that the position of the lever 11 has been switched. As a result, the operational feeling obtained by the moderation mechanism 40 matches the position determination by the control unit 70, so that the driver can operate the shift lever 11 without a sense of incongruity.

  Since each of the first sensor 61, the second sensor 62, and the third sensor 63 is configured as one component, the assembling work for installing the sensors 61, 62, 63 is simplified.

  As mentioned above, although embodiment of this invention was described, this invention is not limited to the said embodiment. About a concrete structure, it can change suitably in the range which does not deviate from the meaning of this invention.

  In the embodiment, the first sensor 61 is disposed at the center between the M1 position and the M2 position in the moving direction of the second slide member 33. However, the arrangement location of the first sensor 61 is not limited to this. . Since the first detector 61A and the second detector 61B of the first sensor 61 can adjust the strength of the magnetic field when switching the output signal between H and L, the first sensor 61 2 In the moving direction of the slide member 33, the slide member 33 may be disposed at a position slightly deviated from the central portion between the M1 position and the M2 position.

  The same applies to the second sensor 62 and the third sensor 63, and the second sensor 62 is disposed at a position slightly deviated from the central portion between the M1 position and the M3 position in the moving direction of the second slide member 33. Alternatively, the third sensor 63 may be disposed at a position slightly deviated from the central portion between the M6 position and the M7 position in the moving direction of the first slide member 32.

  In the said embodiment, although the 1st sensor 61 was comprised as one component with the 1st detection part 61A and the 2nd detection part 61B, the structure of a 1st sensor is not limited to this. The first sensor 61 may have a first detection unit and a second detection unit as separate components. In this case, the first detector and the second detector are arranged close to each other.

  The 2nd sensor 62 and the 3rd sensor 63 are the same, and may have the 1st detection part and the 2nd detection part as separate parts, respectively.

  In the said embodiment, the 1st magnet 51 and the 2nd magnet 52 are fixed to the 1st slide member 32 and the 2nd slide member 33 (interlocking part), and each sensor 61, 62, 63 is attached to the base part 31 (fixed part). Although fixed, the configuration of the shift lever device 1 is not limited to this. For example, as shown in FIG. 14A, a third sensor 63 having the same configuration as that of the above embodiment is fixed to the first slide member 32, and a third magnet 53 is fixed to the base portion 31. It may be.

  Specifically, the third sensor 63 moves to the left and right as the first slide member 32 is interlocked with the movement of the shift lever 11, and corresponds to the R position, the N position, and the D position (first position). A position (position in FIG. 14A), a second sensor position (position in FIG. 15) corresponding to the P position or the L position (second position) moved to the left from the first sensor position, and the first sensor. It is also possible to move to an intermediate sensor position (position of FIG. 14B) that is an intermediate position between the position and the second sensor position. The intermediate sensor position is such that when the shift lever 11 passes through the intermediate portion between the R position and the P position, or when the shift member 11 passes through the intermediate portion between the D position and the L position, the engaging member 14 This is the position when getting over the top 24A.

  The third magnet 53 is composed of one magnet, and is located between the first sensor position and the second sensor position in the moving direction of the first slide member 32, that is, at a position facing the third sensor 63 at the intermediate sensor position. Has been placed.

  The third magnet 53 is configured such that the direction in which the magnetic poles (the S pole and the N pole) are aligned is orthogonal to the moving direction of the first slide member 32 so as to generate a magnetic field facing the left direction and a magnetic field facing the right direction. Arranged in a posture, a magnetic field greater than or equal to a predetermined value is applied to the third sensor 63 positioned at the first sensor position, and a magnetic field greater than or equal to a predetermined value is applied to the third sensor 63 positioned at the second sensor position. It is like that.

  In the shift lever device 1 configured as described above, when the shift lever 11 is positioned at the R position, the N position, or the D position, a magnetic field having a predetermined strength or more is applied to the third sensor 63 in the right direction. Accordingly, the signal output from the first detection unit 63A is L, and the signal output from the second detection unit 63B is H.

  When the shift lever 11 is moved from the R position to the P position or from the D position to the L position, the third sensor 63 moves to the left from the first sensor position toward the second sensor position. At this time, as shown in FIG. 14B, the rightward magnetic field applied to the third sensor 63 is weakened, and the signal output from the second detection unit 63B is switched from H to L.

  When the third sensor 63 deviates from the intermediate sensor position to the second sensor position side by a predetermined distance or more, a predetermined magnetic field is applied to the third sensor 63 in the left direction. As a result, the signal output by the first detection unit 63A is switched from L to H.

  When the shift lever 11 is located at the P position or the L position, the third sensor 63 is located at the second sensor position as shown in FIG. At this time, since a predetermined magnetic field is applied to the third sensor 63 in the left direction, the signal output from the first detection unit 63A is H, and the signal output from the second detection unit 63B is L.

  When the shift lever 11 is moved from the P position to the R position or from the L position to the D position, the third sensor 63 moves to the right from the second sensor position toward the first sensor position. At this time, the leftward magnetic field applied to the third sensor 63 is weakened, and the signal output from the first detection unit 63A is switched from H to L.

  Then, when the third sensor 63 is shifted from the intermediate sensor position to the first sensor position side by a predetermined distance or more, a predetermined magnetic field is applied to the third sensor 63 in the right direction. As a result, the signal output by the second detection unit 63B is switched from L to H.

  When the shift lever 11 is positioned at the R position or the D position, the third sensor 63 moves to the first sensor position. At this time, the signal output from the first detection unit 63A is L, and the signal output from the second detection unit 63B is H.

  As described above, even in such a configuration, the signal output from the first detection unit 63A of the third sensor 63 and the signal detected by the second detection unit 63B are R position or D position and P position or L. Each position can be detected because it differs depending on the position.

  In the above embodiment, the engaging member 14 is pressed against the moderation member 22 by the compression coil spring 18. However, the configuration of the moderation mechanism 40 is not limited to this, and the moderation member 22 is pressed against the engagement member 14 with a spring. The convex portion of the moderation member 22 may be configured by a spring.

  In the above embodiment, the engaging member 14 is held by the frame 12 and moves together with the shift lever 11. However, the configuration of the moderation mechanism 40 is not limited to this. For example, the moderation member 22 may be fixed to the frame 12 and moved together with the shift lever 11, and the engagement member 14 may be provided on the cover member 20.

  In the said embodiment, although the 2nd slide member 33 provided separately from the lever member 10 was illustrated as an interlocking | linkage part, the structure of an interlocking | linkage part is not limited to this. For example, the interlocking unit may be provided integrally with the lever member 10.

DESCRIPTION OF SYMBOLS 1 Shift lever apparatus 11 Shift lever 14 Engagement member 22 Moderation member 24 Convex part 24A Top part 31 Base part 32 1st slide member 33 2nd slide member 40 Moderation mechanism 51 1st magnet 52 2nd magnet 53 3rd magnet 61 1st Sensor 61A 1st detection part 61B 2nd detection part 62 2nd sensor 62A 1st detection part 62B 2nd detection part 63 3rd sensor 63A 1st detection part 63B 2nd detection part 70 Control part

Claims (4)

A shift lever configured to be movable between a first position and a second position;
A projecting portion and an engaging portion that engages with the projecting portion, and when the shift lever passes through an intermediate portion between the first position and the second position, the engaging portion A moderation mechanism configured to load the operation of the shift lever by getting over,
An interlocking portion interlocking with the movement of the shift lever;
A fixing portion facing the interlocking portion;
Provided in the interlocking portion and arranged to generate a magnetic field that faces a first direction that is one of the moving directions of the interlocking portion and a magnetic field that faces a second direction opposite to the first direction. A magnet,
A magnetic sensor provided in the fixed portion and capable of detecting a magnetic field;
A control unit for determining the position of the shift lever based on the output of the magnetic sensor,
The magnetic sensor has a first magnet position corresponding to the first position and a second magnet position corresponding to the second position corresponding to the first position in the moving direction of the interlocking unit. Placed between
The magnetic sensor includes: a first detection unit that switches a signal output from a first state to a second state when a magnetic field having a predetermined strength or more is applied in the first direction; A second detector that switches from a third state to a fourth state when a magnetic field having a predetermined strength or more is applied;
The first detection unit outputs an output when the magnet is displaced by a predetermined distance from the intermediate magnet position, which is the position of the magnet when the engagement portion gets over the top of the convex portion, toward the first magnet position. When the signal to be switched from the first state to the second state, the second detection unit outputs when the magnet is shifted a predetermined distance from the intermediate magnet position to the second magnet position side. A shift lever device, wherein the signal is configured to switch from the third state to the fourth state. A shift lever configured to be movable between a first position and a second position;
A projecting portion and an engaging portion that engages with the projecting portion, and when the shift lever passes through an intermediate portion between the first position and the second position, the engaging portion A moderation mechanism configured to load the operation of the shift lever by getting over,
An interlocking portion interlocking with the movement of the shift lever;
A fixing portion facing the interlocking portion;
The fixed portion is disposed so as to generate a magnetic field that faces a first direction that is one of movement directions of the interlocking portion and a magnetic field that faces a second direction opposite to the first direction. A magnet,
A magnetic sensor provided in the interlocking unit and capable of detecting a magnetic field;
A control unit for determining the position of the shift lever based on the output of the magnetic sensor,
The magnetic sensor has a first sensor position that is a position of the magnetic sensor corresponding to the first position and a second sensor position that is a position of the magnetic sensor corresponding to the second position in the moving direction of the interlocking unit. Placed between and
The magnetic sensor includes: a first detection unit that switches a signal output from a first state to a second state when a magnetic field having a predetermined strength or more is applied in the first direction; A second detector that switches from a third state to a fourth state when a magnetic field having a predetermined strength or more is applied;
When the magnetic sensor is shifted a predetermined distance from the intermediate sensor position, which is the position of the magnetic sensor when the engaging portion gets over the top of the convex portion, to the first sensor position side The output signal is switched from the first state to the second state, and the second detection unit detects that the magnetic sensor has shifted a predetermined distance from the intermediate sensor position toward the second sensor position. A shift lever device configured to switch the output signal from the third state to the fourth state.   The control unit is configured such that the position of the shift lever is the first position and the second position on condition that both the signal output from the first detection unit and the signal output from the second detection unit are switched. The shift lever device according to claim 1, wherein the shift lever device is configured to determine that the switch has been made.   The shift lever device according to any one of claims 1 to 3, wherein the magnetic sensor is configured as one component.

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