JP2020133697A - Range switching device and parking mechanism - Google Patents

Abstract

To improve the detection accuracy of an angle detection device for detecting a rotation angle of a manual shaft even if an assembling error arises between the manual shaft and a case, and wobbling occurs during operation.SOLUTION: A range switching device comprises a rotating body 47 having a manual shaft 44 whose rotation angle is set by a selected shift range, and a detent lever 40 integrated with the manual shaft 44, and rotatable with the manual shaft 44 as a center. The range switching device also comprises an axial-direction regulation part 101 for regulating the movement of the manual shaft 44 in an axial direction while permitting the relative rotation of a rotation angle sensor 70 with respect to the rotating body 47 in a rotation direction Dr of the manual shaft 44, and a rotation-direction regulation part 102 for regulating the rotation of the manual shaft 44 in the rotation direction Dr while permitting the movement of the rotation angle sensor 70 to case 3c in the axial direction Dr of the manual shaft 44.SELECTED DRAWING: Figure 3

Description

This technique relates to a range switching device and a parking mechanism mounted on a vehicle such as an automobile.

Conventionally, in an automatic transmission mounted on a vehicle such as an automobile, the shift range is switched by operating a shift lever, and is switched to, for example, a forward range or a reverse range, or a parking range or a neutral range. For example, when the shift lever is switched to the parking range, the operation of the shift lever causes the parking pole to engage with the parking gear fixed to the output shaft of the automatic transmission, locking the rotation of the output shaft and preventing the rotation of the wheels. To do.

As a range switching device that operates a parking mechanism by selecting, for example, a parking range with a shift lever, a mechanical type and a so-called parking-by-wire type are known. In a mechanical range switching device, the shift lever and the parking pole are mechanically connected via a manual shaft or a detent lever, and the shift lever is switched to the parking range to mechanically move the parking pole to the parking position. .. Further, in the parking-by-wire type range switching device, the shift lever functions as an electric switch, and the parking pole is hydraulically moved to the parking position via, for example, a detent lever according to the on / off of this switch. Even in the parking-by-wire type range switching device, a manual shaft directly connected to the detent lever may be provided in order to forcibly release the parking lock from the outside in the event of a failure.

Further, there is known a range switching device that detects whether the parking mechanism is in the parking state or the parking release state by providing a rotation angle sensor (angle detection device) on the manual shaft (see Patent Document 1). In this range switching device, the rotation angle sensor is used to detect the rotation angle of the manual shaft to detect the position of the parking pole and detect whether the parking mechanism is in the parking state or the parking release state. are doing. This rotation angle sensor is fixedly attached to the case of the automatic transmission and can detect the relative rotation with the manual shaft.

Japanese Unexamined Patent Publication No. 2003-139231

However, in the range switching device described in Patent Document 1 described above, a rotation angle sensor for detecting the rotation angle of the manual shaft is fixedly attached to the case of the automatic transmission. For this reason, due to assembly errors between the manual shaft and the case and rattling during operation, the manual shaft swings significantly in the axial direction, and the rotor of the rotation angle sensor moves significantly in the axial direction and comes into contact with the sensor case or the like. It is necessary to secure a large movable range of the rotor of the rotation angle sensor, especially in the axial direction, so as not to cause erroneous detection. For this reason, the movable range of the rotor of the rotation angle sensor becomes large. For example, in the case of a rotation angle sensor in which a magnet is used as the rotor and a magnetic field is detected by a fixed magnetic sensor, the magnetic field is in the axial direction. Since it fluctuates greatly, there is a risk that the detection accuracy will decrease.

Therefore, it is necessary to provide a range switching device and a parking mechanism that can improve the detection accuracy of the angle detection device that detects the rotation angle of the manual shaft even if there is an assembly error between the manual shaft and the case or rattling during operation. It is the purpose.

This range switching device is integrated with a case, a manual shaft rotatably provided with respect to the case, and a rotation angle set by a shift range selected from a plurality of shift ranges, and the manual shaft. A rotating body having a detent lever that can rotate around the manual shaft, an angle detecting device that detects the rotation angle of the manual shaft with respect to the case, and the angle detecting device with respect to the rotating body. An axial regulation unit that restricts movement in the axial direction of the manual shaft while allowing relative rotation in the rotation direction of the manual shaft, and an angle detection device with respect to the case, the shaft of the manual shaft. It is provided with a rotation direction regulating unit that regulates the rotation of the manual shaft in the rotation direction while allowing the movement in the direction.

Further, the parking mechanism includes the range switching device described above, a parking gear driven and connected to the wheels, a parking pole that can mesh with the parking gear, a parking rod, and a cam provided on the parking rod. The parking rod has an urging member that urges the cam toward the parking pole, and the parking rod is such that the cam urged by the urging member presses the parking pole. Is movable to a parking meshing position in which the cam is urged toward the parking gear and a parking release position in which the cam is separated from the parking pole to disengage the parking pole and the parking gear. The detent lever can be moved by switching the parking rod between the parking meshing position and the parking release position by rotation, and the parking pole is engaged with and disengaged from the parking gear via the parking rod by rotation of the detent lever. As a result, the parking state in which the rotation of the wheels is locked and the parking release state in which the rotation of the wheels is unlocked are switched.

According to this range switching device and the parking mechanism, it is possible to improve the detection accuracy of the angle detection device that detects the rotation angle of the manual shaft even if there is an assembly error between the manual shaft and the case or rattling during operation.

The schematic diagram which shows the vehicle which mounted the drive device for a vehicle which concerns on embodiment. The side view which shows the parking mechanism of the drive device for a vehicle which concerns on embodiment. The perspective view which shows the range switching device of the drive device for a vehicle which concerns on embodiment. It is a figure which shows the rotation angle sensor of the drive device for a vehicle which concerns on embodiment, (a) is a perspective view, (b) is a sectional view.

Hereinafter, the present embodiment will be described with reference to FIGS. 1 to 4 (b). First, a schematic configuration of a vehicle 1 equipped with an automatic transmission 3 which is an example of a vehicle drive device will be described with reference to FIG. As shown in FIG. 1, for example, an FF type (front engine / front drive) vehicle 1 includes an engine (E / G) 2, an automatic transmission 3 that shifts the driving force of the engine 2, and an automatic transmission 3. It includes wheels 7 that are rotationally driven by a speed-shifted driving force. The automatic transmission 3 includes a torque converter (T / C) 4 connected to the engine 2, a transmission mechanism (T / M) 5 connected to the torque converter 4, and a hydraulic control device (T / M) for hydraulically controlling them. It includes a V / B) 6 and an ECU (control unit) 9. Further, the speed change mechanism 5 is adapted to transmit a driving force to the wheels 7 via the output shaft 8, and includes a parking mechanism 10 capable of locking the output shaft 8.

In the present embodiment, the FF type engine vehicle is applied as the vehicle 1, but the vehicle is not limited to this, and any vehicle provided with the parking mechanism 10 hydraulically controlled by the hydraulic control device 6 may be used. For example, an FR type (front engine / rear drive) engine vehicle may be applied, or the vehicle is not limited to the engine vehicle, and a hybrid vehicle equipped with an engine and a rotary electric machine, an electric vehicle, or the like may be applied.

The ECU 9 has, for example, a CPU, RAM, ROM, etc., reads a program stored in the ROM, etc., and performs various calculations by the CPU while temporarily storing data in the RAM, and the hydraulic control device 6 Outputs an electrical command to. For example, a shift lever position sensor 91 and a rotation angle sensor (angle detection device) 70 that detects the rotation angle of the manual shaft 44 described later are connected to the ECU 9. In the present embodiment, for example, a shift lever 92 arranged in the driver's seat switches between a parking (P) range and a non-parking range (neutral (N) range, drive (D) range, reverse (R) range, etc.). The shift range can be selected by operating it. Then, when the shift lever 92 is switched in this way, the shift lever position sensor 91 detects the position of the shift lever 92, converts it into an electrical signal, and inputs it to the ECU 9 in a so-called shift-by-wire system (parking range). (Also referred to as a parking-by-wire system) is applied. In the present embodiment, it has been described that the range is selected by the shift lever 92, but the present invention is not limited to this. For example, it can be configured to select a range by button operation, or it is configured to apply a parking-by-wire system that is operated by a parking switch that simply switches the operation of the parking mechanism 10 instead of switching the shift range. You may.

The hydraulic control device 6 generates a line pressure by a primary regulator valve (not shown) connected to an oil pump (not shown). The line pressure is supplied and discharged as hydraulic oil to the oil chamber 24f (see FIG. 2) of the hydraulic actuator 20 described later of the parking mechanism 10 via a solenoid valve (not shown). By controlling the primary regulator valve and the solenoid valve, the ECU 9 can control the supply and discharge of hydraulic oil to the oil chamber 24f of the hydraulic actuator 20 of the parking mechanism 10 and the operating pressure. In the present embodiment, the line pressure is supplied to and discharged from the parking mechanism 10 as hydraulic oil, but the present invention is not limited to this, and other hydraulic pressure such as SLU pressure may be used as hydraulic oil.

Next, the parking mechanism 10 will be described with reference to FIGS. 2 and 3. The parking mechanism 10 is arranged inside or outside the transmission case (hereinafter referred to as a case) 3c of the automatic transmission 3 (see FIG. 1). Then, the parking mechanism 10 locks any of the rotation shafts of the speed change mechanism 5 based on the electric signal output according to the operation position (shift range) of the shift lever 92 (see FIG. 1), and the rotation shaft of the rotation shaft It is configured as a so-called shift-by-wire type parking mechanism 10 for releasing the lock.

The parking mechanism 10 includes a parking gear 11, a parking pole 12, a parking rod 13, a cam 14, a support roller 15, a cam spring (biasing member) 16, a detent lever 40, a hydraulic actuator 20, and magnetic. It includes a lock device 30 and a rotation angle sensor 70. The parking gear 11 has a plurality of teeth 11a and is attached to any of the rotating shafts (for example, the output shaft 8) of the automatic transmission 3. That is, the parking gear 11 is driven and connected to the wheel 7. The parking pole 12 has a protrusion 12a that can mesh with the parking gear 11 and is urged to be separated from the parking gear 11 by a spring (not shown). In the parking mechanism 10, the output shaft 8 of the automatic transmission 3 is locked by engaging the protrusion 12a of the parking pole 12 with the recess between the two adjacent teeth 11a of the parking gear 11.

The parking rod 13 is provided so as to be reciprocally movable along the longitudinal direction. The cam 14 is formed in a tubular shape and is provided so as to be movable in the axial direction of the parking rod 13. The support roller 15 is rotatably supported by, for example, the case 3c and holds the cam 14 together with the parking pole 12. One end of the cam spring 16 is supported by the parking rod 13, and the cam 14 is urged toward the parking pole 12 so as to press the parking pole 12 against the parking gear 11. The hydraulic actuator 20 can reciprocate the parking rod 13 by swinging the detent lever 40 connected to the parking rod 13. The magnetic lock device 30 can regulate the reciprocating movement of the parking rod 13 by restricting the reciprocating movement of the piston rod 21 described later of the hydraulic actuator 20. As the parking gear 11, the parking pole 12, the parking rod 13, the cam 14, the support roller 15, and the cam spring 16, all known configurations can be applied.

That is, in the parking mechanism 10, the parking rod 13 has a parking meshing position in which the cam 14 urged by the cam spring 16 presses the parking pole 12 to urge the parking pole 12 toward the parking gear 11, and a cam. 14 is movable to and from the parking release position where the parking pole 12 and the parking gear 11 are disengaged from the parking pole 12.

The detent lever 40 is formed in a substantially L shape and has a first free end portion 41 and a second free end portion 42. The corners of the detent lever 40 (base ends of the first and second free end portions 41 and 42) are rotatably supported by, for example, a manual shaft 44 supported by the case 3c. The first free end portion 41 is rotatably connected to the base end portion of the parking rod 13. The second free end portion 42 is formed with an engaging recess (recess) 43 that can be engaged with a pin (engagement shaft) 60 attached to a detent spring 50 (see FIG. 3) supported by, for example, the case 3c. There is. The engaging recess 43 is provided on the outer edge of the detent lever 40 at least corresponding to the parking range (first shift range), and has a shape recessed in the radial direction of the detent lever 40. Further, the detent lever 40 can move the parking rod 13 by switching between the parking meshing position and the parking release position by rotation.

As shown in FIG. 3, the detent spring 50 is composed of a leaf spring, the base end portion 52 is fixed to the case 3c, and the tip end portion 51 holds the pin 60. As a result, the detent spring 50 supports the pin 60 with respect to the case 3c and urges the pin 60 in the direction of engaging with the engaging recess 43. The pin 60 is supported by the tip portion 51 of the detent spring 50 with the center line along the axial direction Da. In this embodiment, a roller 61 is provided around the pin 60. However, the roller 61 may not be provided. The pin 60 engages the engaging recess 43 corresponding to the parking range when the parking range is selected and engages as the parking range is changed to a non-parking range (neutral range, forward range, etc.). It separates from the joint recess 43.

The manual shaft 44 is rotatably provided with respect to the case 3c, and is provided so that the rotation angle is set by a shift range selected from a plurality of shift ranges. Further, the detent lever 40 is integrated by press-fitting the manual shaft 44, and is provided so as to be rotatable around the manual shaft 44. Further, in the present embodiment, the manual shaft 44 and the detent lever 40 form an integrated rotating body 47.

As shown in FIG. 2, the hydraulic actuator 20 automatically shifts gears controlled by the ECU 9 (see FIG. 1) based on an electric signal output according to the operation position (shift range) of the shift lever 92 (see FIG. 1). It is configured to operate by the hydraulic pressure from the hydraulic pressure control device 6 (see FIG. 1) of the machine 3. The hydraulic actuator 20 is provided in a support structure fixed to the case 3c, and includes a piston rod 21 and a piston 22.

The piston rod 21 is connected to the second free end portion 42 of the detent lever 40 and is supported by the case 3c so as to be movable in the axial direction. A connecting recess 21r extending from the tip side toward the base end side is formed at the tip end portion of the piston rod 21, and a second free end portion 42 of the detent lever 40 is inserted into the connecting recessed portion 21r. There is. An elongated hole 45 is formed in the detent lever 40 so as to be located in the connecting recess 21r, and a connecting pin 46 supported by the tip end portion of the piston rod 21 is inserted into the elongated hole 45. Further, a hole portion 21h is formed near the central portion in the axial direction of the piston rod 21, and a roller 23 is arranged inside the hole portion 21h.

The piston 22 is integrally molded with the piston rod 21 at the base end portion of the piston rod 21. A piston chamber 24 is formed in the case 3c, and the piston 22 is movably supported in the axial direction of the piston rod 21 by the inner wall surface of the piston chamber 24. The piston chamber 24 is divided into an oil chamber 24f and a spring chamber 24s by the piston 22. The oil chamber 24f communicates with the oil hole 24h formed in the case 3c, and the hydraulic pressure from the hydraulic control device 6 is supplied through an oil passage or an oil hole 24h (not shown). A return spring 25 is arranged in the spring chamber 24s, and the piston 22 is urged by the return spring 25 from the spring chamber 24s side toward the oil chamber 24f side.

In the hydraulic actuator 20 described above, when hydraulic oil is supplied from the oil hole 24h to the oil chamber 24f, the piston rod 21 moves against the elastic force of the return spring 25. As a result, the detent lever 40 rotates counterclockwise in FIG. 2 around the manual shaft 44, the parking rod 13 moves, the pressing of the parking pole 12 by the cam 14 is released, and the parking gear 11 and parking are released. The engagement with the pole 12, that is, the lock of the output shaft 8 of the automatic transmission 3 is released. On the other hand, when the oil pressure in the oil chamber 24f drops and the oil is discharged from the oil hole 24h, the piston 22 is urged by the return spring 25 to come into close contact with or come into contact with the bottom of the oil chamber 24f. As a result, the detent lever 40 rotates clockwise around the manual shaft 44 in FIG. 2, the parking rod 13 moves, the parking pole 12 is pressed by the cam 14, and the parking gear 11 and the parking pole 12 That is, the output shaft 8 of the automatic transmission 3 is locked. As described above, in the present embodiment, the rotation of the wheel 7 is locked and the rotation of the wheel 7 is performed by engaging and disengaging the parking pole 12 with the parking gear 11 via the parking rod 13 by the rotation of the detent lever 40. Can be switched to the unlocked parking release state.

The magnetic lock device 30 is used when the oil pressure supplied to the oil chamber 24f of the hydraulic actuator 20 drops as the engine 2 of the vehicle 1 and the oil pump driven by the engine 2 stop due to, for example, an idle stop. , The piston rod 21 and the piston 22 are restricted from moving to the lock side by the elastic force of the return spring 25, and are used to prevent the transition from the parking lock release state to the parking lock state. The magnetic lock device 30 includes a lock shaft 31 that can come into contact with a roller 23 provided on the piston rod 21, and a magnetic portion 32 that can lock the lock shaft 31 by magnetic force.

Next, the rotation angle sensor 70 will be described in detail with reference to FIGS. 3 to 4 (b). The rotation angle sensor 70 is provided so as to detect the rotation angle of the manual shaft 44 with respect to the case 3c. The rotation angle sensor 70 has a case body (sensor case) 71, a cover 72 of the case body 71, a connector portion 73 having a shape protruding sideways from the case body 71, and a shape protruding sideways from the case body 71. A guide portion 74 and an axial direction regulating portion 101 provided on the cover 72 are provided. The case body 71 and the cover 72 are provided with through holes 70h through which the manual shaft 44 rotatably penetrates. The guide portion 74 is provided with a long hole-shaped guide hole 74h whose longitudinal direction is the direction intersecting the rotation direction Dr. The details of the guide hole 74h will be described later.

The case main body 71 houses a circuit board 76, a Hall IC (sensor unit) 77, and a rotor 78 press-fitted into a manual shaft 44 penetrating the through hole 70h. The circuit board 76 is connected to the ECU 9 (see FIG. 1) by a connector (not shown) attached to the connector portion 73. The rotor 78 is composed of a large number of magnets arranged in the circumferential direction. Therefore, according to the rotation angle sensor 70, the hall IC 77 detects the change in the magnetic field due to the rotation of the rotor 78 having the magnet due to the rotation of the manual shaft 44, thereby detecting the rotation angle of the manual shaft 44 with respect to the case 3c. be able to. In the present embodiment, as the rotation angle sensor 70, a sensor of a method in which a rotor 78 having a magnet is rotated and detected by a hall IC 77 is applied, but the present invention is not limited to this, and for example, a rotary encoder or a rotary encoder or the like is applied. A resolver or the like may be applied.

Here, the manual shaft 44 is rotatably supported by a needle bearing (not shown) or the like with respect to the case 3c. Therefore, the manual shaft 44 is slightly allowed to swing in the axial direction Da. On the other hand, when the rotation angle sensor 70 is fixed to the case 3c by screwing or the like, the manual shaft 44 becomes large in the axial direction Da due to an assembly error between the manual shaft 44 and the case 3c and rattling during operation. If it swings, the magnetic field of the rotor 78 fluctuates greatly in the axial direction Da, so that the detection accuracy may decrease. Therefore, in the present embodiment, the rotation angle sensor 70 is not fixed to the case 3c by screwing or the like, and the error in the axial direction Da and the rotation direction Dr between the rotation angle sensor 70 and the manual shaft 44 is increased. An axial direction regulating section 101 and a rotational direction regulating section 102 are provided so as to make the size smaller.

First, since the rotation angle sensor 70 is not fixed to the case 3c, it is necessary to regulate the relative movement of the manual shaft 44 and the rotation angle sensor 70 in the axial direction Da. Therefore, the axial regulation unit that regulates the rotation angle sensor 70 from moving in the axial Da of the manual shaft 44 while allowing the rotating body 47 to rotate relative to the rotational direction Dr of the manual shaft 44. 101 is provided.

The axial regulation portion 101 includes a support portion 101a protruding from the surface 72a of the cover 72 along the center line C1 of the manual shaft 44, and a flange-shaped regulation end formed along the surface 72a from the tip end portion of the support portion 101a. It has a portion 101b and a part of the surface 72a facing the regulation end portion 101b. That is, the surface 72a of the cover 72 and the regulation end 101b are provided so as to face each other, and a groove penetrating in the rotation direction Dr is formed between them. The edge of the detent lever 40 is inserted into the groove between the surface 72a of the cover 72 and the regulation end 101b without hindering the rotation of the detent lever 40.

The height of the support portion 101a along the center line C1 is set to be slightly larger than the thickness of the detent lever 40. As a result, the axial regulation unit 101 moves in the axial Da of the manual shaft 44 while allowing the rotation angle sensor 70 to rotate relative to the rotating body 47 in the rotational direction Dr of the manual shaft 44. Can be regulated. That is, in the present embodiment, the detent lever 40 is provided so as to be sandwiched between the surface 72a of the cover 72 and the regulation end 101b without being hindered from moving in the rotation direction Dr. These regulation end portions 101b and the surface 72a of the cover 72 facing each other correspond to a sandwiching portion, and the sandwiching portion is provided so as to sandwich the detent lever 40 in the axial direction Da on the outer side of the case body 71. The movement in the axial direction Da is regulated while allowing the rotation of 40 in the rotation direction Dr.

In the present embodiment, the detent lever 40 is sandwiched between the surface 72a of the cover 72 and the regulation end 101b, but the present invention is not limited to this, and a member having a U-shaped cross section and facing each other. May be attached to the surface 72a so that the detent lever 40 is sandwiched between the facing surfaces. Further, the length of the rotational direction Dr of the axial regulation unit 101 is not particularly limited as long as it does not interfere with the detent lever 40. If it is long, the strength when pressed from the detent lever 40 can be increased, and if it is short, the strength of the installation location can be increased. The degree of freedom can be increased.

In the present embodiment, since the rotation angle sensor 70 is not fixed to the case 3c by screwing or the like, the rotation angle sensor 70 is supported by the manual shaft 44 supported by the case 3c. Then, since the detent lever 40 and the rotation angle sensor 70 are interlocked with the axial direction Da by the axial direction regulation unit 101, the rotation angle sensor 70 also moves with the movement of the axial direction Da of the rotating body 47. .. As a result, the relative deflection of the axial Da between the manual shaft 44 and the rotation angle sensor 70 is suppressed, so that the detection accuracy of the rotation angle sensor 70 can be improved.

Further, if the rotation angle sensor 70 rotates with respect to the rotation of the manual shaft 44 with respect to the case 3c, it becomes difficult to detect the rotation angle of the manual shaft 44 with high accuracy. On the other hand, the rotation angle sensor 70 is not fixed in the axial direction Da with respect to the case 3c as described above. Therefore, the rotation direction regulating unit 102 that restricts the case 3c from rotating in the rotation direction Dr of the manual shaft 44 while allowing the rotation angle sensor 70 to move in the axial direction Da of the manual shaft 44. Provided.

The rotation direction regulating portion 102 has a pin 60 and a guide hole (engagement portion) 74h of the guide portion 74 of the rotation angle sensor 70. The pin 60 is provided with the center line along the axial direction Da, and is a pin whose movement is restricted in the rotation direction Dr with respect to the case 3c. In the present embodiment, the pin 60 here is integrally provided on the extension of the pin 60 that can be engaged with the engaging recess 43 of the detent lever 40 described above, and is, for example, a single member. .. The guide hole 74h of the guide portion 74 has an elongated hole shape that allows the pin 60 to move as the pin 60 engages and disengages from the engaging recess 43 while being urged by the detent spring 50. The guide hole 74h is engaged with the pin 60 to regulate the rotation of the rotation angle sensor 70 with respect to the case 3c. As a result, the rotation direction regulating unit 102 restricts the case 3c from rotating in the rotation direction Dr of the manual shaft 44 while allowing the case 3c to move in the axial direction Da of the manual shaft 44. To do. The shape of the guide hole 74h is preferably linear, for example, and has a width such that the pin 60 supported by the detent spring 50 and rotating is not interfered with. However, the shape of the guide hole 74h is not limited to a linear shape, and may be, for example, an arc shape that matches the swivel locus of the pin 60 that is supported by the detent spring 50 and swivels.

The case 3c, the rotating body 47, the rotation angle sensor 70, the axial direction regulation unit 101, and the rotation direction regulation unit 102 as described above constitute the range switching device 100.

The operation of switching between the parking state and the parking release state by the parking mechanism 10 described above will be described focusing on the operation of the range switching device 100. When the shift lever 92 is switched from the non-parking range to the parking range, the detent lever 40 is rotated in the clockwise direction in FIG. 2 by the operation of the hydraulic actuator 20. Along with this, the parking rod 13 moves, the parking pole 12 presses the parking gear 11, and the output shaft 8 of the automatic transmission 3 is locked. Further, the rotation of the detent lever 40 also rotates the manual shaft 44, the rotation of the rotor 78 is detected by the hall IC 77, and the detection result is transmitted to the ECU 9. On the other hand, when the shift lever 92 is switched from the parking range to the non-parking range, the detent lever 40 is rotated in the counterclockwise rotation direction in FIG. 2 by the operation of the hydraulic actuator 20. Along with this, the parking rod 13 moves, the parking pole 12 releases the pressing of the parking gear 11, and the output shaft 8 of the automatic transmission 3 is unlocked. Further, the rotation of the detent lever 40 also rotates the manual shaft 44, the rotation of the rotor 78 is detected by the hall IC 77, and the detection result is transmitted to the ECU 9.

In these operations, when the manual shaft 44 moves in the axial direction Da with respect to the case 3c, the detent lever 40 also moves in the same axial direction Da along with the manual shaft 44. Then, the rotational angle sensor 70 also moves in the axial direction Da along with the detent lever 40 by the axial direction regulating unit 101 sandwiching the detent lever 40. Therefore, the relative movement of the manual shaft 44 and the rotation angle sensor 70 in the axial direction Da is suppressed, so that the amount of relative movement of the magnetic field generated from the rotor 78 in the axial direction Da to the hole IC 77 is reduced to reduce the rotation angle. Detection accuracy can be improved. Further, since the axial direction regulating unit 101 does not regulate the detent lever 40 in the rotation direction Dr, the rotation of the detent lever 40 is not hindered.

Further, since the rotation direction regulating unit 102 is provided, the rotation angle sensor 70 is regulated in the rotation direction Dr by the pin 60 supported by the detent spring 50 in the case 3c. Therefore, the rotation of the rotation angle sensor 70 with respect to the case 3c in the rotation direction Dr is suppressed, so that the detection accuracy of the rotation angle can be improved. Further, since the rotation direction regulating unit 102 does not regulate the rotation angle sensor 70 in the axial direction Da, the movement of the rotation angle sensor 70 in the axial direction Da is not hindered.

As described above, according to the range switching device 100 according to the present embodiment, since the axial direction regulating unit 101 and the rotational direction regulating unit 102 are provided, the assembly error between the manual shaft 44 and the case 3c and the operation time Even if there is rattling, the detection accuracy of the rotation angle sensor 70 that detects the rotation angle of the manual shaft 44 can be improved.

Further, according to the range switching device 100 according to the present embodiment, the axial regulation portion 101 sandwiches the edge portion of the detent lever 40 in the groove formed between the surface 72a of the cover 72 and the regulation end portion 101b. It is provided as. As a result, it is possible to regulate the movement of the detent lever 40 in the axial direction Da while allowing the detent lever 40 to rotate in the rotational direction Dr with a simple configuration integrally molded with the cover 72.

Further, according to the range switching device 100 according to the present embodiment, the rotation direction regulating unit 102 has a pin 60 fixed to the case 3c and a guide hole 74h integrated with the rotation angle sensor 70. Therefore, the rotation direction regulating unit 102 restricts the case 3c from rotating in the rotation direction Dr of the manual shaft 44 while allowing the rotation angle sensor 70 to move in the axial direction Da of the manual shaft 44. can do.

Further, according to the range switching device 100 according to the present embodiment, the pin 60 is formed of the same member obtained by extending the engaging shaft fixed to the detent spring 50 for preventing the detent lever 40 from rotating. It is not necessary to newly provide a dedicated pin for forming the rotation direction regulation unit 102, and the rotation direction regulation unit 102 can be provided while suppressing an increase in the number of parts.

In the present embodiment, the case where the pin 60 is formed of the same member in which the engaging shaft fixed to the detent spring 50 for preventing the rotation of the detent lever 40 is extended is described, but this is limited to this. I can't. For example, a pin may be provided separately from the engaging shaft fixed to the detent spring 50. For example, the pin can be fixed to the case 3c along the axial direction Da. Further, in this case, since the pin does not move, the guide hole 74h does not have to have an elongated hole shape, and may be a perfect circular guide hole.

Further, in the present embodiment, the case where the axial direction regulating unit 101 and the rotational direction regulating unit 102 are applied to the range switching device 100 provided in the parking mechanism 10 has been described, but the present invention is not limited to this, and the forward range, It may be applied to a range switching device for switching a reverse range, a neutral range, and the like. Also in this case, even if there is an assembly error between the manual shaft 44 and the case 3c or rattling during operation, the detection accuracy of the rotation angle sensor 70 that detects the rotation angle of the manual shaft 44 can be improved. The detection of the selected shift range can be realized with high accuracy.

The present embodiment includes at least the following configurations. The range switching device (100) of the present embodiment is rotatably provided with respect to the case (3c) and the case (3c), and the rotation angle is set by a shift range selected from a plurality of shift ranges. A rotating body (47) having a manual shaft (44) to be formed, a detent lever (40) integrated with the manual shaft (44) and rotatable about the manual shaft (44), and the manual. An angle detection device (70) that detects the rotation angle of the shaft (44) with respect to the case (3c), and the angle detection device (70) rotates the manual shaft (44) with respect to the rotating body (47). The axial regulation unit (101) and the angle detection device (70) restrict the movement of the manual shaft (44) in the axial direction (Da) while allowing the manual shaft (44) to rotate relative to the direction (Dr). Rotation that restricts rotation of the manual shaft (44) in the rotation direction (Dr) while allowing the case (3c) to move in the axial direction (Da) of the manual shaft (44). It is provided with a direction control unit (102).

According to this configuration, the angle detection device (70) that detects the rotation angle of the manual shaft (44) even if there is an assembly error between the manual shaft (44) and the case (3c) or rattling during operation. The detection accuracy can be improved.

Further, in the range switching device (100) of the present embodiment, the angle detection device (70) includes a sensor unit (77) for detecting the rotation angle of the manual shaft (44) with respect to the case (3c), and the above. It has a sensor case (71) that accommodates the sensor unit (77) and through which the manual shaft (44) penetrates, and the axial regulation unit (101) has the detent on the outer portion of the sensor case (71). The lever (40) is provided so as to sandwich the lever (40) in the axial direction (Da), and the movement of the detent lever (40) in the axial direction (Da) is restricted while allowing the rotation of the detent lever (40) in the rotational direction (Dr). It has a sandwiching portion (101b, 72a) to be used.

According to this configuration, the axis of the manual shaft (44) is allowed to rotate relative to the rotating body (47) in the rotation direction (Dr) of the manual shaft (44). Movement in the direction (Da) can be restricted.

Further, in the range switching device (100) of the present embodiment, the rotation direction regulating unit (102) is provided with the center line along the axial direction (Da), and the case (3c) is described as described above. The pin (60) whose movement is restricted in the rotation direction (Dr) is provided on the angle detection device (70), and the pin (60) engages with the pin (60) to engage the case (3c) of the angle detection device (70). ) With an engaging portion (74h) that regulates rotation.

According to this configuration, the rotation direction regulating unit (102) allows the angle detection device (70) to move in the axial direction (Da) of the manual shaft (44) with respect to the case (3c). It is possible to regulate the rotation of the manual shaft (44) in the rotation direction (Dr).

Further, the range switching device (100) of the present embodiment is provided on the outer edge of the detent lever (40) corresponding to at least the first shift range, and has a shape recessed in the radial direction of the detent lever (40). The recess (43) and the center line are provided along the axial direction (Da), and when the first shift range is selected, the recess (43) corresponding to the first shift range is provided. An engaging shaft (60) that engages and disengages from the recess (43) as the first shift range is changed to a second shift range different from the first shift range. A detent spring (50) that supports the engaging shaft (60) with respect to the case (3c) and urges the engaging shaft (60) in a direction of engaging with the recess (43). The pin (60) is integrally provided on an extension of the engaging shaft (60), and the engaging portion (74h) is provided with the engaging shaft (60) by the detent spring (50). It has an elongated hole shape that allows the pin (60) to move as it engages and disengages from the recess (43) while being urged.

According to this configuration, the pin (60) is formed by the same member which extends the engaging shaft (60) fixed to the detent spring (50) for detenting the detent lever (40). It is not necessary to newly provide a dedicated pin for forming the rotation direction regulation unit (102), and the rotation direction regulation unit (102) can be provided while suppressing an increase in the number of parts.

Further, the parking mechanism (10) of the present embodiment meshes with the range switching device (100) described above, the parking gear (11) driven and connected to the wheel (7), and the parking gear (11). A possible parking pole (12), a parking rod (13), a cam (14) provided on the parking rod (13), and the cam (14) are urged toward the parking pole (12). The parking rod (13) has an urging member (16), and the cam (14) urged by the urging member (16) presses the parking pole (12). The parking meshing position for urging the parking pole (12) toward the parking gear (11) and the cam (14) separated from the parking pole (12) to separate the parking pole (12) and the parking gear (12). It is movable to and from the parking release position for releasing the engagement with 11), and the detent lever (40) can be moved by switching the parking rod (13) between the parking engagement position and the parking release position by rotation. The rotation of the detent lever (40) locks the rotation of the wheel (7) by engaging and disengaging the parking pole (12) with the parking gear (11) via the parking rod (13). The parking state is switched to the unlocked parking state in which the rotation of the wheel (7) is unlocked.

According to this configuration, in the range switching device (100) for switching between the parking range and the non-parking range in the parking mechanism (10), there is an assembly error between the manual shaft (44) and the case (3c) and rattling during operation. Even if there is, the detection accuracy of the angle detection device (70) that detects the rotation angle of the manual shaft (44) can be improved.

3c ... Case 7 ... Wheel 10 ... Parking mechanism 11 ... Parking gear 12 ... Parking pole 13 ... Parking rod 14 ... Cam 16 ... Cam spring (biasing member)
40 ... Detent lever 43 ... Engagement recess (recess)
44 ... Manual shaft 47 ... Rotating body 50 ... Detent spring 60 ... Pin (engagement shaft)
70 ... Rotation angle sensor (angle detection device)
71 ... Case body (sensor case)
72a ... Surface (sandwiched part)
74h ... Guide hole (engagement part)
77 ... Hall IC (sensor unit)
100 ... Range switching device 101 ... Axial direction regulation part 101b ... Regulation end part (sandwiching part)
102 ... Rotation direction regulation unit Da ... Axial direction of manual shaft Dr ... Rotation direction of manual shaft

Claims (5)

With the case
A manual shaft that is rotatably provided with respect to the case and whose rotation angle is set by a shift range selected from a plurality of shift ranges, and a manual shaft that is integrated with the manual shaft and can rotate around the manual shaft. Detent lever, with a rotating body,
An angle detection device that detects the rotation angle of the manual shaft with respect to the case, and
An axial regulation unit that restricts the angle detection device from moving in the axial direction of the manual shaft while allowing the rotating body to rotate relative to the rotation direction of the manual shaft.
The case is provided with a rotation direction regulating unit that restricts the case from rotating in the rotation direction of the manual shaft while allowing the case to move in the axial direction of the manual shaft.
Range switching device. The angle detection device includes a sensor unit that detects the rotation angle of the manual shaft with respect to the case, and a sensor case that houses the sensor unit and allows the manual shaft to penetrate.
The axial regulation unit is provided so as to sandwich the detent lever in the axial direction on the outer side of the sensor case, and allows the detent lever to rotate in the rotational direction while moving in the axial direction. Has a pinch to regulate,
The range switching device according to claim 1. The rotation direction regulation unit is
A pin provided with a center line along the axial direction and restricted from moving in the rotational direction with respect to the case.
The angle detection device is provided with an engaging portion that the pin engages with to regulate the rotation of the angle detection device with respect to the case.
The range switching device according to claim 1 or 2. A concave portion having a shape recessed in the radial direction of the detent lever, which is provided on the outer edge of the detent lever corresponding to at least the first shift range,
A center line is provided along the axial direction, and when the first shift range is selected, it engages with the recess corresponding to the first shift range, and the first shift range is the first shift range. An engaging shaft that separates from the recess as it is changed to a second shift range that is different from the shift range of 1.
A detent spring that supports the engaging shaft with respect to the case and urges the engaging shaft in a direction in which the engaging shaft is engaged with the recess is provided.
The pin is integrally provided on the extension of the engaging shaft.
The engaging portion has an elongated hole shape that allows the pin to move as the engaging shaft engages with and disengages from the recess while being urged by the detent spring.
The range switching device according to claim 3. The range switching device according to any one of claims 1 to 4, a parking gear driven and connected to a wheel, a parking pole that can mesh with the parking gear, a parking rod, and the parking rod are provided. It has a cam and an urging member that urges the cam toward the parking pole.
The parking rod has a parking meshing position in which the cam urged by the urging member presses the parking pole to urge the parking pole toward the parking gear, and the cam is from the parking pole. It is movable to and from the parking release position where the parking pole and the parking gear are disengaged from each other.
The detent lever can rotate to switch the parking rod between the parking meshing position and the parking release position, and the rotation of the detent lever causes the parking pole to engage and disengage the parking gear via the parking rod. By doing so, the parking state in which the rotation of the wheel is locked and the parking release state in which the rotation of the wheel is unlocked are switched.
Parking mechanism.

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