JP2017206156A - Shifter - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a shifter capable of improving position precision of a shift position of a shift body.SOLUTION: A shifter 10 is provided with a shift lever 14, which is rotated to change a shift position of the shift lever 14. Further, a boss part 28 and a lock pin 30 are rotated according to the shift position of the shift lever 14, and the shift position of the shift lever 14 is detected. Here, the shift lever 14 is provided with the boss part 28 and the lock pin 30 in one body. The shift position of the shift lever 14 can therefore be detected with high precision.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a shift device in which a shift position of a shift body is changed by moving the shift body.

  In the shift lever device of Patent Document 1, the shift lever is movable in the shift direction and the select direction, and the shift position of the shift lever is changed by the movement of the shift lever. The shift lever device is provided with a synchronization link, and the shift lever is engaged with the synchronization link. The synchronization link is provided with a connection lever, and the movement position of the connection lever is detected, and the shift position of the shift lever is detected.

  Further, the shift lever device is provided with a control lever, and the shift lever is engaged with the control lever. Further, it is understood that when the connecting member is connected to the control lever, the moving position of the connecting member is detected and the shift position of the shift lever is detected.

  Here, in such a shift lever device, it is preferable that the detection accuracy of the shift position of the shift lever can be improved.

JP 2008-183937 A

  The present invention has been made in view of the above-described facts, and an object of the present invention is to provide a shift device that can improve the detection accuracy of the shift position of the shift body.

  The shift device according to claim 1 is provided in the shift body that is moved in one direction and the other direction to change a shift position, and the shift position is detected and the shift position of the shift body is detected. And a second detection unit that is provided on the shift body and that is connected to a connection member and detects a shift position of the shift body by detecting a movement position of the connection member.

  In the shift device according to the first aspect, the shift position of the shift body is changed by moving the shift body in one direction and the other direction. Further, the movement position of the first detection unit is detected, and the shift position of the shift body is detected. Further, the connecting member is connected to the second detection unit, and the shift position of the shift body is detected by detecting the moving position of the connecting member.

  Here, the 1st detection part and the 2nd detection part are provided in the shift body. For this reason, the positional accuracy of the first detection unit and the second detection unit with respect to the shift body can be improved, and the detection accuracy of the shift position of the shift body can be increased.

  The shift device according to claim 2 is the shift device according to claim 1, wherein the movement position of the first detector is detected to detect a plurality of shift positions of the shift body, and the movement position of the connecting member. Is detected, and the specific shift position of the shift body is detected.

  The shift device according to claim 2, wherein the movement position of the first detection unit is detected to detect a plurality of shift positions of the shift body, and the movement position of the connecting member is detected to detect the specific shift position of the shift body. Is done. Thereby, a plurality of shift positions of the shift body and a specific shift position of the shift body can be detected.

  According to a third aspect of the present invention, in the shift device according to the first or second aspect, the peripheral surface includes a spherical surface, and the support includes a support portion that is supported so as to be movable in one direction and the other direction. .

  In the shift device according to the third aspect, the shift body is supported so as to be movable in one direction and the other direction. The peripheral surface of the support part is formed into a spherical shape, whereby the support accuracy of the shift body can be increased, and the placement accuracy of the first detection unit and the second detection unit can be increased.

  A shift device according to a fourth aspect of the present invention is the shift device according to any one of the first to third aspects, wherein the shift device extends from the shift body and includes the first detection unit and the second detection unit. Includes outing.

  In the shift device according to the fourth aspect, the shift body is provided with the extending portion, and the extending portion is provided with the first detection portion and the second detection portion. For this reason, the detection accuracy of the shift position of the shift body using the first detection unit and the second detection unit can be increased.

  According to the present invention, it is possible to improve the detection accuracy of the shift position of the shift body.

It is a perspective view which shows the principal part of the shift lever apparatus which concerns on this Embodiment. It is an expanded view which shows an operation hole. It is the front view which looked at the shift lever from the front side.

  FIG. 1 is a perspective view of a shift lever device 10 serving as a shift device according to the present embodiment as viewed from the front and diagonally upward to the left. In each figure, the upper side of the shift lever device 10 is indicated by an arrow UP, the front of the shift lever device 10 is indicated by an arrow FR, and the left side of the shift lever device 10 is indicated by an arrow LH. Yes.

  The shift lever device 10 according to the present embodiment is a so-called gate-type and by-wire type. The shift lever device 10 is of a floor type, and is installed on the floor of the passenger compartment in the vehicle width direction inside the driver's seat (not shown) of the vehicle (automobile). The left side and the upper side are respectively directed to the front, left and upper sides of the vehicle.

  The shift lever device 10 is provided with a resin-made substantially rectangular parallelepiped box-shaped housing 12 (plate) as a locking body, and the housing 12 is fixed to the floor of the passenger compartment. Further, the shift lever device 10 is provided with a shift lever 14 as a shift body. The shift lever 14 is provided with a lever main body 16 as a shift member and a base end portion 18 (ball shaft) as a support portion, and the base end portion 18 has a spherical surface 18A. The base end portion 18 is connected to one end portion of the lever main body 16 in the longitudinal direction, and the lever main body 16 and the base end portion 18 are integrated.

  An opening 12 </ b> A is formed in the upper wall of the housing 12, the base end 18 side of the shift lever 14 is inserted into the opening 12 </ b> A, and the base end 18 is disposed in the housing 12. The housing 12 is provided with a bearing member 20 as a support member, and the bearing member 20 is attached to the inside of the housing 12. The bearing member 20 has a bottomed cylindrical shape, and the opening of the bearing member 20 is directed upward. Further, the inner peripheral surface 20A including the bottom surface of the bearing member 20 has a substantially hemispherical shape.

  A base end portion 18 is fitted to the bearing member 20, and the base end portion 18 is supported by a peripheral surface 18 </ b> A being slidable on an inner peripheral surface 20 </ b> A of the bearing member 20. As a result, the shift lever 14 is supported in the housing 12 via the bearing member 20 and can be rotated (moved) about the center of curvature of the base end portion 18. As for the turning direction of the shift lever 14, the front-rear direction is the shift direction, and the left-right direction is the select direction.

  The base end portion 18 is integrally formed with a rectangular columnar projection 18B, and the projection 18B protrudes rearward from the peripheral surface 18A of the base end portion 18. A notch (guide groove) (not shown) is formed in the housing 12 (bearing member 20), and the protrusion 18B is inserted into the notch. Thereby, the rotation of the protrusion 18B in the vertical direction and the rotation around the central axis are permitted by the notch, and the shift direction of the shift lever 14 and the rotation in the select direction are guided.

  A cover member (not shown) is provided above the housing 12, and the upper wall of the cover member is exposed to the vehicle interior and an operation hole 22 (see FIG. 2) is formed. The shift lever 14 is inserted through the operation hole 22, and the shift lever 14 is rotated in the operation hole 22 in the shift direction and the select direction.

  The operation hole 22 is formed with a first hole 22A and a second hole 22B, each of which is a long hole. The longitudinal direction of each of the first hole 22A and the second hole 22B is the front-rear direction. . The second hole 22B is disposed adjacent to the left (or right) of the first hole 22A, and the rear end portion of the first hole 22A and the central portion in the longitudinal direction of the second hole 22B. And communicated with each other.

  The shift position of the shift lever 14 is the P (parking) position, R (reverse) position, N (neutral) position, and D (drive) as specific shift positions in order from the front end portion to the rear end portion of the first hole 22A. Is in position. Further, the shift position of the shift lever 14 is such that the center portion in the front-rear direction of the second hole 22B is set to the M (manual) position, and the front end portion of the second hole 22B is set to the-(minus) position. The rear end portion of the hole 22B is in the + (plus) position.

  The shift position is changed to the P position, the R position, the N position, and the D position by rotating the shift lever 14 in the first hole 22A in the shift direction. Further, the shift lever 14 is rotated in the shift direction in the 22nd hole 22B, whereby the shift position is changed to the M position, the − position, and the + position. Further, the shift lever 14 is rotated in the select direction (leftward) from the D position of the first hole 22A, so that the shift position is changed to the M position of the second hole 22B, and the M position of the second hole 22B. , The shift position is changed to the D position of the first hole 22A.

  On the other hand, as shown in FIG. 1, the shift lever 14 is provided with an arm portion 24 as an extending portion, and the arm portion 24 is formed in a substantially flat plate shape and is integrally formed with the shift lever 14. ing. The arm portion 24 is formed on the base end portion 18 side of the shift lever 14 and protrudes forward from the end portion of the shift lever 14 on the base end portion 18 side, and the tip end portion extends downward. Has been. The distal end of the arm portion 24 is disposed below the proximal end portion 18 (bearing member 20). Thus, the arm portion 24 is provided on the front side of the base end portion 18 so as to avoid the base end portion 18 and the bearing member 20, and the arm portion 24 rotates around the center of curvature of the base end portion 18. Is done.

  A boss portion 28 as a first detection portion is provided on the front wall surface 26 of the arm portion 24, and the boss portion 28 projects forward from a central portion in the vertical direction of the arm portion 24. The boss portion 28 is turned up and down when the shift lever 14 is turned in the shift direction, and is turned left and right when the shift lever 14 is turned in the select direction. Further, the pivot position of the boss portion 28 corresponds to the shift position of the shift lever 14.

  A locking pin 30 as a second detection unit is provided at the lower end (tip) of the arm unit 24, and the locking pin 30 protrudes leftward from the left surface of the arm unit 24. The locking pin 30 is rotated in the front-rear direction when the shift lever 14 is rotated in the shift direction, and is rotated in the left-right direction when the shift lever 14 is rotated in the select direction (FIG. 3). Further, the rotation position of the locking pin 30 corresponds to the shift position of the shift lever 14.

  The arm portion 24 is inserted into the housing 12, and the boss portion 28 and the locking pin 30 are disposed in the housing 12.

  One end of a shift cable 32 as a connecting member is connected to the locking pin 30 of the arm portion 24 in the housing 12. The shift cable 32 is biased so as to pull the locking pin 30 rearward, and the other end is connected to second detection means (inhibitor switch) provided in a transmission (not shown) of the vehicle. Thereby, the shift cable 32 is moved in the longitudinal direction when the shift lever 14 is rotated. Further, the movement position of the shift cable 32 when the shift position of the shift lever 14 is set to the P position is detected by the inhibitor switch. Thus, when the inhibitor switch detects the P position of the shift lever 14, the operation (start) of the vehicle engine is permitted, whereas when the inhibitor switch does not detect the P position of the shift lever 14. The operation (starting) of the vehicle engine is prohibited.

  A rectangular opening 34 </ b> A is formed in the front wall 34 of the housing 12. The boss portion 28 of the arm portion 24 is inserted into the opening portion 34A, and the boss portion 28 is rotatable in the opening portion 34A.

  The shift lever device 10 is provided with a detection mechanism 36 as first detection means, and the detection mechanism 36 is disposed on the front wall 34 of the housing 12. A sensor cover 38 having a substantially rectangular box shape is provided in the detection mechanism 36, and a rectangular opening 40 </ b> A is formed in a bottom plate 40 (rear plate) of the sensor cover 38. The sensor cover 38 is attached to the housing 12 such that the longitudinal direction is the vertical direction and the opening 40A communicates with the opening 34A of the front wall 34. The opening 34A is opened by the opening 40A. Yes.

  A slider 42 is disposed on the sensor cover 38, and the slider 42 has a rectangular box shape. The longitudinal direction of the slider 42 is the vertical direction, and the slider 42 is movable in the left-right direction. The bottom plate 44 (rear plate) of the slider 42 is formed with a long hole 44A that is long in the vertical direction.

  A magnet body 46 that is a member to be detected is disposed on the slider 42. The magnet body 46 has a substantially rectangular parallelepiped shape with a magnet (not shown) fixed by insert molding, and the tip of the boss portion 28 is rotatably connected to the magnet body 46. For this reason, the magnet body 46 is rotated in the vertical direction and the horizontal direction integrally with the boss portion 28. At this time, the boss portion 28 is rotated in the vertical direction, whereby the magnet body 46 is guided by the slider 42 and moved in the vertical direction. Further, when the boss portion 28 is rotated in the left-right direction, the slider 42 is moved in the left-right direction in the sensor cover 38 together with the magnet body 46.

  A rectangular box-shaped sensor case 48 is provided in front of the sensor cover 38, and the sensor case 48 has a longitudinal direction in the vertical direction and an opening side in the sensor cover 38 side. It is assembled. Accordingly, the sensor cover 38 is covered with the sensor case 48, and the slider 42 and the magnet body 46 are accommodated in the internal space between the sensor cover 38 and the sensor case 48.

  In the sensor case 48, a detection board 50 as a detection body is attached on the front side of the magnet body 46, and the detection board 50 is opposed to the magnet body 46 in the entire movement range of the magnet body 46. Detection elements (Hall elements) are arranged on the detection substrate 50, and the position of the magnet body 46 (magnetic force generated by the magnet) moved according to the shift position of the shift lever 14 is detected by the detection element. The detection board 50 is electrically connected to the transmission of the vehicle, and the shift range of the transmission is changed to a shift range corresponding to the shift position of the shift lever 14 detected by the detection board 50.

Next, the operation of this embodiment will be described.
In the shift lever device 10 having the above configuration, the shift position of the shift lever 14 is changed by rotating the shift lever 14 in the shift direction and the select direction. In the detection mechanism 36, the shift lever 14 is rotated in the shift direction and the select direction, and the magnet body 46 is moved, whereby the detection element of the detection substrate 50 detects the position of the magnet body 46, and the shift lever 14. The shift position is detected. Further, when the shift lever 14 is rotated and the shift cable 32 is moved, the inhibitor switch detects the moving position of the shift cable 32 and the P position of the shift lever 14 is detected.

  Here, the shift lever 14 is integrally provided with a boss portion 28 and a locking pin 30. The boss portion 28 is in communication with the magnet body 46, and the magnet body 46 is moved integrally with the boss portion 28 by turning the shift lever 14. Further, a shift cable 32 is connected to the locking pin 30, and the locking pin 30 and the shift cable 32 are moved together by rotating the shift lever 14. Therefore, unlike the case where the boss portion 28 and the locking pin 30 are provided on separate members from the shift lever 14, each shift position of the shift lever 14 can be detected with high accuracy from the movement position of the boss portion 28, and The P position of the shift lever 14 can be detected with high accuracy.

  In addition, it is possible to eliminate the need for a separate member provided with the boss portion 28 and the locking pin 30, and to reduce the number of parts and to perform the assembly work because it is not necessary to enable the separate member and the shift lever 14 to be engaged. Easy to do.

  Further, the peripheral surface 18A of the base end portion 18 is spherical, and the shift lever 14 is supported at the base end portion 18 so as to be rotatable in the shift direction and the select direction. Thus, unlike the case where the rotation center axis when the shift lever 14 is rotated in the shift direction and the rotation center axis when the shift lever 14 is rotated in the select direction are provided separately, the shift lever 14 can be increased, the disposition accuracy of the boss portion 28 and the locking pin 30 can be increased, and the shift position of the shift lever 14 can be detected with higher accuracy using the boss portion 28 and the locking pin 30.

  Moreover, since the bearing member 20 supports the base end portion 18 from below, the support strength of the base end portion 18 can be increased. Thereby, the support accuracy of the shift lever 14 can be increased, and the shift position of the shift lever 14 can be detected with high accuracy by the boss portion 28 and the locking pin 30.

  Further, since the arm portion 24 provided with the boss portion 28 and the locking pin 30 is extended from the shift lever 14, an arrangement error of the boss portion 28 and the locking pin 30 with respect to the base end portion 18 can be reduced. Thereby, the arrangement | positioning precision of the boss | hub part 28 and the latching pin 30 can be made high, and the shift position of the shift lever 14 can be detected with high precision from the movement position of the boss | hub part 28 and the latching pin 30. In addition, since the arm portion 24 extends from the base end portion 18 side of the shift lever 14, it is possible to further reduce the arrangement error of the boss portion 28 and the locking pin 30 with respect to the base end portion 18. The shift position of the shift lever 14 can be detected with higher accuracy from the movement position of the locking pin 30.

  Even if the shift lever 14 is disposed at the − (minus) position, the shift cable 32 does not reach the position in the length direction of the shift cable 32 when the shift lever 14 is disposed at the P position. For this reason, the inhibitor switch can detect the P position of the shift lever 14.

  In the present embodiment described above, the shift cable 32 connected to the locking pin 30 is used to detect the movement of the shift lever 14 to the P position. However, the shift lever 14 is not limited to the P position. Other shift positions may be detected.

  Further, in the present embodiment, the shift lever 14 is provided with the base end portion 18 as a support portion, and the housing 12 is provided with the bearing member 20, but the present invention is not limited thereto. The shift lever 14 is provided with a bearing member 20 as a support portion, the housing 12 is provided with a support member (base end portion 18) having a spherical outer peripheral surface, and the support member is fitted to the bearing member 20 to shift the shift lever. 14 may be supported to be rotatable (movable) around the center of curvature of the outer peripheral surface of the support member. Furthermore, in the present embodiment, the base end portion 18 having a spherical surface is provided as the support portion. However, the present invention is not limited to this, and the support portion uses two shafts whose axes are orthogonal to each other. May be configured.

  Further, in the present embodiment, the shift lever 14 is provided with the boss portion 28 and the locking pin 30. However, the boss portion 28 may not be provided on the shift lever 14. In the present embodiment, the floor-type shift lever device 10 has been described as an example. However, the shift device is not limited to the floor surface in the passenger compartment, and is provided in other parts such as an instrument panel or a steering column of the vehicle. May be.

10 Shift lever device (shift device)
14 Shift lever (shift body)
18 Base end (support)
24 Arm part (extension part)
28 Boss part (first detection part)
30 Locking pin (second detection part)
32 Shift cable (connecting member)

Claims (4)

A shift body that is moved in one direction and the other direction to change the shift position;
A first detector that is provided on the shift body and detects a shift position of the shift body by detecting a movement position;
A second detection unit that is provided on the shift body, is connected to a connection member, detects a movement position of the connection member, and detects a shift position of the shift body;
Including shift device.   The movement position of the first detection unit is detected to detect a plurality of shift positions of the shift body, and the movement position of the connecting member is detected to detect a specific shift position of the shift body. The shifting device described.   The shift device according to claim 1, wherein a peripheral surface is formed into a spherical shape, and the shift body includes a support portion that is movably supported in one direction and the other direction.   The shift device according to any one of claims 1 to 3, further comprising an extension portion extending from the shift body and provided with the first detection portion and the second detection portion.