JP4651234B2 - Vehicle control device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a vehicle control device used in a vehicle having an electric means for switching a shift range (shift stage), and more particularly to a shift range switching device for a transmission.
[0002]
[Prior art]
For example, in a vehicle equipped with an automatic transmission currently on the market (hereinafter referred to as A / T), the shift range is switched by a driver operating a shift lever mechanically linked to A / T. Yes. Therefore, even when the power supply to the vehicle is cut off due to the battery terminal being disconnected during traveling, the driver can reliably switch to the parking range by operating the shift lever.
[0003]
However, in a system in which the shift range is switched by electrical means, that is, a shift-by-wire system (hereinafter referred to as SBW), there is no way to switch the shift range when power supply is cut off. That is, in the state where power is not supplied, even if the driver operates the shift lever to the parking range (hereinafter referred to as the P range), the P range is not actually obtained. In this case, the driver thinks that the driver has entered the P range by his / her own operation, and may leave the vehicle. At this time, if the vehicle is on a slope, there is a risk that the vehicle will start unintentionally under the influence of gravity.
[0004]
Even if the driver can recognize that he is not in the P range, the side brake is a friction-type auxiliary brake and is not a reliable alternative to the P range. It is necessary to do this, and it is impossible to leave the driver's seat, so it is impossible to cope with reconnecting the battery terminals or requesting rescue.
[0005]
As a means to solve the above problem, it is conceivable to install an auxiliary battery. However, it is difficult to install an auxiliary battery because it is difficult to secure a mounting space and to manage the remaining amount of the battery and to increase the cost. There was a need to solve the above-mentioned problems by mechanical means rather than the purpose.
[0006]
[Problems to be solved by the invention]
The present invention has been made in view of the above problems, and in a vehicle having an electric means for switching a shift range (shift stage), a vehicle stop state is automatically secured when power supply is cut off. It is to provide a vehicle control device having mechanical means to operate.
[0007]
[Means for Solving the Problems]
The present invention provides a vehicle control device described in each of the claims as means for solving the above-described problems.
[0008]
According to the vehicle control device of the first aspect, in the vehicle having the electric means for switching the shift range (shift stage), when the power supply is cut off for some reason, the power supply is cut off. It is possible to automatically stop the vehicle by driving the vehicle fixing means with the energy of the energy storage means. As a result, even when the shift range cannot be switched because the power supply is cut off in the vehicle that switches the shift range by electric means, the vehicle can be surely kept in a stopped state, and the vehicle The danger caused by moving can be avoided.
[0009]
According to the vehicle control device of the second aspect, in the vehicle having an automatic transmission that switches the shift range by electric means, when the power supply is cut off for some reason, the power supply is cut off. This is detected, and the shift range switching mechanism of the automatic transmission is driven by the energy of the energy accumulating means to automatically switch to the parking range, thereby ensuring the stop state of the vehicle. As a result, even when the shift range of the automatic transmission cannot be switched to the parking range because the power supply is cut off, the vehicle can be surely kept in a stopped state, and the vehicle moves unintentionally. The danger caused by can be avoided.
[0010]
According to the vehicle control device of the third aspect, in the vehicle having the transmission that switches the shift range by electric means, when the power supply is cut off for some reason, the power supply is cut off. It is possible to detect and automatically switch the shift range of the transmission to an arbitrary shift range by the energy of the energy storage means, and to secure the stop state of the vehicle. Thus, for example, even when the shift range of the transmission cannot be switched because the power supply is cut off in the automatic manual transmission that switches the shift range (shift stage) by electric means, the shift range is automatically set to 1. By switching to an arbitrary shift range such as speed or reverse gear, the vehicle can be reliably kept in a stopped state, and the danger caused by the vehicle moving unintentionally can be avoided.
[0011]
According to the vehicle control device of claim 4, in the vehicle having an electric means for switching the shift range, when the supply of power is cut off for some reason, it is detected that the supply of power is cut off, By releasing the energy of the energy storage means, the rotation of the output shaft of the transmission can be locked, and the vehicle can be automatically stopped. As a result, even when the shift range cannot be switched because the power supply is cut off in the vehicle that switches the shift range by electric means, the vehicle can be surely kept in a stopped state, and the vehicle The danger caused by moving can be avoided.
[0012]
According to the vehicle control device of the fifth aspect, in the vehicle having the electric means for switching the shift range, when the power supply is cut off for some reason, the spring is stored in the energy accumulation state such as the compression or expansion state. The supply of electric power to the electromagnetic driving means that has been locked is cut off, and the energy stored in the spring is automatically released, whereby the vehicle fixing means is driven to ensure the stop state of the vehicle. As a result, even when the shift range cannot be switched because the power supply is cut off in the vehicle that switches the shift range by electric means, the vehicle can be surely kept in a stopped state, and the vehicle The danger caused by moving can be avoided.
[0013]
According to the vehicle control device of the sixth aspect, when the power supply is cut off once and the energy of the energy storage means is released, the electric means for switching the shift range automatically when the power supply is restored. Energy is stored in the energy storage means to obtain a predetermined energy storage state. As a result, the vehicle control device is surely operable (non-operating state) simultaneously with the recovery of power supply without any special operation by the driver.
[0014]
According to the vehicle control device of the seventh aspect, in a vehicle having an automatic transmission that switches the shift range by electric means, when the power supply is cut off once and the energy of the energy storage means is released, After the supply is restored, until the first forward range is selected, the selected range is maintained by energizing the electrical means for switching the shift range, and the first forward range is selected first. Sometimes, energy is automatically stored in the energy storage means by an electric means for switching the shift range, and a predetermined energy storage state is obtained. As a result, the vehicle control device can be returned to a non-operating state without any special operation by the driver, and an operation for returning the vehicle control device to the non-operating state is not required particularly when the power supply is restored. .
[0015]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the drawings, the same or similar components are denoted by common reference numerals.
[0016]
FIG. 1 shows a system configuration diagram of a shift range switching device of an automatic transmission having an automatic parking range switching mechanism, which is an embodiment of a vehicle control device of the present invention. The actuator 1 includes a motor 101, a reduction gear 102, and an incremental encoder position sensor 103. The output shaft portion of the reduction gear 102 is a manual shaft 401 of the automatic transmission (A / T) 4. It is connected to the A / T 4 so that the manual shaft 401 can be rotated by the actuator 1 (see FIGS. 4A and 4C). Further, in the present embodiment, an automatic parking range (P range) switching mechanism 8 is provided between the A / T 4 and the reduction gear 102 so that the manual shaft 401 passes therethrough. Reference will be made later.
[0017]
As shown in FIG. 1, an actuator control circuit 2 is connected to the actuator 1, and this actuator control circuit 2 includes a motor control unit 201, a counter 202, and a signal input unit 204. The signal input means 204 is connected to receive a shift signal from the illustrated shift switch 3 and receives a brake signal and a vehicle speed signal from other signal output means (not shown).
[0018]
An ignition switch (IG) 7, a relay 6, and a battery 5 are connected to the motor control unit 201 of the actuator control circuit 2 through the relay 6. The battery 5 is charged by an alternator (not shown) when the engine is driven, and plays a role of supplying electric power to the actuator control circuit 2. The power supply to the actuator control circuit 2 is switched between supply and interruption by the relay 6 according to the ON / OFF state of the IG 7.
[0019]
FIG. 2 is a perspective view illustrating a schematic configuration of a shift range switching mechanism including a connecting portion between the manual shaft 401 and the A / T 4. As shown in FIG. 2, a detent plate 402, which is a substantially fan-shaped member having a circular arc portion, is attached to the manual shaft 401 so that the manual shaft 401 penetrates the vicinity of the essential part of the sector. The manual shaft 401 is connected to the spool valve 404 and the rod 406 via the detent plate 402. One end of the rod 406 is connected to the detent plate 402, and the other end is engaged with a claw member 407 having a projection 409 that engages with the park gear 408. A portion 410 is provided. Further, a detent spring 403 is provided so as to engage with the corrugation of the arc portion of the detent plate 402 to constitute a detent mechanism, and the end engaging portion of the detent spring 403 is corrugated of the arc portion of the detent plate 402. The detent plate 402 is locked by entering the recess and acts to hold the position.
[0020]
In this configuration, when the manual shaft 401 is rotated by the actuator 1, the spool valve 404 slides in the manual valve 405 via the detent plate 402, the hydraulic circuit is switched, and the A / T4 shift range is switched. When the energization of the actuator 1 is stopped after the operation of the actuator 1 is completed, the shift range switched by the above detent mechanism is maintained. The switching to the P range is performed by rotating the manual shaft 401 to a position corresponding to the P range. That is, the rotation of the manual shaft 401 causes the rod 406 to be pushed through the detent plate 402 in the direction of arrow A in FIG. 2, so that the end of the rod 406 opposite to the end connected to the detent plate 402 The claw member 407 is pushed up in the direction of arrow B in FIG. As a result, the park gear 408 fixedly attached to the output shaft of the A / T 4 is engaged with the projection 409 of the claw member 407, and the drive shaft of the vehicle is mechanically locked to the P range. Switching is achieved.
[0021]
Next, the configuration of the automatic P range switching mechanism 8 of the shift range switching device of the present embodiment will be mainly described with reference to FIGS. 3 and 4. FIG. 3 is a configuration diagram schematically showing a schematic configuration of the automatic P range switching mechanism 8, and shows the automatic P range switching mechanism 8 in a non-operating state (more specifically, when the IG 7 is OFF). ing. In FIG. 3, L, 2, D, N, R, and P indicate each shift range and indicate the relationship between the rotational position of the manual shaft 401 and the shift range. Incidentally, FIG. 3 shows a state in which the manual shaft 401 is at the rotation position of the L range (L range position).
[0022]
FIG. 4 is a schematic diagram of an output shaft portion of the actuator 1 (that is, an output shaft portion of the reduction gear 102) and a connection portion between the automatic P range switching mechanism 8 (a plate member 802 described in detail later) and the manual shaft 401. 4 (a) is a longitudinal sectional view of the connecting portion, and FIGS. 4 (b) and 4 (c) are line BB and line C in FIG. 4 (a), respectively. It is a cross-sectional view along -C.
[0023]
The automatic P range switching mechanism 8 includes a torsion coil spring 801, a plate member 802, a first solenoid device 803, and a second solenoid device 804, where the first solenoid device 803 is a solenoid 808. The second solenoid device 804 includes a solenoid 809, a pin 807, and a detent mechanism 810.
[0024]
3 and 4, the plate member 802 is shown as a member in which a substantially sector-shaped plate-shaped member having one concave portion in the arc portion is provided on a part of the outer peripheral surface of the cup-shaped member. Is rotatably supported by the housing. A torsion coil spring 801 is attached to the plate member 802 and urges the plate member 802 to rotate from the L range to the P range (the direction of arrow D in FIG. 3). When the automatic P range switching mechanism 8 is in an inoperative state as shown in FIG. 3, the pin 806 of the first solenoid device 803 engages with the concave portion provided in the arc portion of the plate member 802, and the plate The rotation of the member 802 is prevented and the plate member 802 is maintained in the inoperative position.
[0025]
At the center of the cup-shaped member constituting the plate member 802 (that is, the rotation center portion of the plate member 802), a hole 812 having a shape in which the upward and downward sectors are partially overlapped is provided. The manual shaft 401 passes through the hole 812, and the manual shaft 401 has a pair of opposing sides parallel to each other in a portion passing through the plate member 802, as shown in FIGS. 3 and 4. And the other pair is an arc, and has a cross-sectional shape corresponding to the arc portion of the hole 812. In this embodiment, as shown in FIG. 4C, the output shaft portion of the reduction gear 102 is also provided with a hole 112 having the same shape as the hole 812 of the plate member 802, and the plate member 802 is provided therein. A manual shaft 401 having the same cross-sectional shape as the cross-sectional shape of the portion passing through the hole 812 is inserted. Therefore, the normal shift range is switched by driving the actuator 1 and rotating the reduction gear 102 so that the plane portion of the inner wall of the hole 112 provided in the output shaft portion of the reduction gear 102 is the plane portion of the manual shaft 401. Is engaged by rotating the manual shaft 401. That is, for example, when the reduction gear 102 is rotated counterclockwise in FIG. 4C, the upper right gap and the lower left gap of the manual shaft 401 are gradually narrowed, and the plane of the inner wall of the hole 112 at these locations. The portion and the flat portion of the manual shaft 401 are engaged to rotate the manual shaft 401 counterclockwise, and the shift range is switched. The reduction gear 102 rotates in the reverse direction when switching to the desired shift range is completed, and returns to the initial predetermined rotation position shown in FIG.
[0026]
As can be seen from FIG. 3, the shape and orientation of the hole 812 is such that the manual shaft 401 does not interfere with the plate member 802 when the automatic P range switching mechanism 8 is in an inoperative state as shown in FIG. The shape and orientation are such that it can rotate from the L range to the P range. With this configuration, when the actuator 1 switches the normal shift range, the manual shaft 401 engages with the plate member 802 and the plate member 802 biased by the torsion coil spring 801 is moved. Therefore, the torsion coil spring 801 can prevent the load on the actuator 1 from increasing. In the example shown in FIG. 3, since the rotation angle from the L range to the P range is 60 °, the central angle of the sector forming the hole 812 of the plate member 802 needs to be 60 ° or more.
[0027]
Further, in the present embodiment, as described above, the relationship between the hole 112 in the output shaft portion of the reduction gear 102 and the cross-sectional shape of the manual shaft 401 inserted therethrough penetrates the hole 812 of the plate member 802. It is the same as the relationship with the cross-sectional shape of the manual shaft 401, and the reduction gear 102 is returned to the predetermined rotational position shown in FIG. 4C in the normal state after the shift range is switched. Even if the automatic P range switching mechanism 8 is operated, the manual shaft 401 and the reduction gear 102 are not engaged, and when the automatic P range switching mechanism 8 is operated, a load is applied to reversely move the actuator 1, that is, the reduction gear 102. It has no configuration.
[0028]
The first solenoid device 803 includes a pin 806 of the first solenoid device 803, a forward position where the tip of the pin 806 is engaged with the recess provided in the arc portion of the plate member 802, and the tip of the pin 806 is the plate. The member 802 is moved between the retracted position deviating from the concave portion provided in the arc portion of the member 802. The first solenoid device 803 includes the biasing spring 805 as described above, and this spring 805 causes the pin 806 of the first solenoid device 803 to move in the direction of arrow E in FIG. 3 (that is, toward the retracted position). Energized. When the IG7 is turned on and energized, the solenoid 808 of the first solenoid device 803 moves its pin 806 in the direction opposite to the arrow E (ie, toward the advanced position) against the biasing force of the spring 805.
[0029]
The second solenoid device 804 also includes a pin 807 of the second solenoid device 804 and an end portion of the pin 807 that engages with a rear end surface of the pin 806 of the first solenoid device 803 (that is, an end portion that engages with a recess of the plate member 802). The front end of the pin 807 is moved between a retreat position where the front end of the pin 807 is disengaged from the rear end surface of the pin 806 of the first solenoid device 803. The solenoid 809 of the second solenoid device 804 moves its pin 807 in both directions of the arrow F in FIG. 3 (ie, the direction toward the forward position) and the opposite direction (ie, the direction toward the reverse position) by energization. In addition, the position after the movement is maintained by the detent mechanism 810 even when the energization is stopped. Therefore, if the pin 807 of the second solenoid device 804 is disposed at the forward position when the pin 806 of the first solenoid device 803 is at the forward position, the pin 806 is turned on even when the energization of the solenoid 808 of the first solenoid device 803 is stopped. Since the tip end portion of the pin 807 comes into contact with the rear end surface of the pin 806, the pin 806 is held at the advanced position against the biasing force of the biasing spring 805.
[0030]
Hereinafter, the operation of the automatic P range switching mechanism 8 will be described in more detail with reference to FIGS. 5 and 6.
[0031]
FIG. 5 shows an integrated structure of the actuator 1 and the automatic P range switching mechanism 8. FIG. 5 (a) is an internal structure diagram when viewed from the lower surface, and FIG. It is sectional drawing along line AA of 5 (a). FIG. 5 shows the non-operating state of the automatic P range switching mechanism 8 when the IG 7 is OFF as in FIG. 3 (however, the viewpoint is upside down in FIGS. 3 and 5A). The arrangement of the components is mirror image.) FIG. 6 is a view similar to FIG. 5, but shows a state in which the automatic P range switching mechanism 8 is activated. The automatic P range switching mechanism shown in FIG. 3 and the automatic P range switching mechanism shown in FIGS. 5 and 6 have basically the same configuration, but in the automatic P range switching mechanism shown in FIG. The pin 806 of the first solenoid device 803 engages with a recess provided in the arc portion of the plate member 802 to hold the automatic P range switching mechanism in the non-operating position, as shown in FIGS. In the automatic P range switching mechanism, the pin 806 of the first solenoid device 803 protrudes and engages forward in the urging direction by the torsion coil spring 801 of the plate member 802 to hold the automatic P range switching mechanism 8 in the inoperative position. It is different in point.
[0032]
When IG7 is turned on, first, the solenoid 808 of the first solenoid device 803 is energized, and the pin 806 of the first solenoid device 803 holds the forward position as shown in FIG. The plate member 802 is held in the inoperative position. Next, the solenoid 809 of the second solenoid device 804 is energized, and the pin 807 of the second solenoid device 804 is moved to the retracted position. Therefore, in a state where IG7 is turned on, the pin 806 is held at the forward movement position against the urging force of the urging spring 805 by energizing the solenoid 808 of the first solenoid device 803 so that the plate member 802 is moved. Holding in the non-operating position. Therefore, while the power is supplied to the solenoid 808 of the first solenoid device 803, the plate member 802 is held in the non-operating position, and therefore the automatic P range switching mechanism 8 does not switch to the P range.
[0033]
Next, when the IG is turned off, the solenoid 809 of the second solenoid device 804 is energized and the pin 807 moves to the forward position before the energization of the solenoid 808 of the first solenoid device 803 is stopped. Thus, the tip of the pin 807 is brought into contact with the rear end surface of the pin 806 of the first solenoid device 803. As a result, even when the energization of the solenoid 808 of the first solenoid device 803 is stopped, the pin 806 of the first solenoid device 803 is held at the forward movement position, and the plate member 802 is held at the non-operation position. After the pin 807 of the second solenoid device 804 moves to the advance position, the power supply of the actuator control circuit 2 is turned off, and the energization to the solenoid 808 of the first solenoid device 803 is stopped. As described above, the second solenoid device 804 includes a detent mechanism, and the position of the pin 807 of the second solenoid device 804 is maintained even after the energization is stopped. In this way, the IG 7 shown in FIG. 5 described above can be returned to the OFF state.
[0034]
In the state where the IG7 is ON, for example, when the supply of power is cut off due to some reason such as disconnection of the terminal of the battery 5, the first solenoid device 803 resists the biasing force of the biasing spring 805. Since the energization to the solenoid 808 of the first solenoid device 803 that has held the pin 806 in the forward position is stopped, the pin 806 is moved to the retracted position (arrow E in FIG. 5A) by the action of the biasing spring 805. And the plate member 802 is disengaged from the plate member 802, and the torsion coil spring 801 causes the plate member 802 to move in the direction of the arrow D (that is, in the direction from the L range to the P range (in FIG. 5 (a) and FIG. 6 (a) (counterclockwise direction)), and thereby the manual shaft 401 is rotated to the P range position so that the P Switching to di is achieved (see FIG. 6). Note that the rotation of the manual shaft 401 due to the rotation of the plate member 802 causes the holes 812 (illustrated in FIGS. 5 and 6) of the plate member 802 by the rotation of the plate member 802, as is apparent from FIGS. None (refer to FIG. 3) and the planar portion of the inner wall of the manual shaft 401 passing through the hole 812 are engaged and rotated.
[0035]
When the power is restored after the automatic P range switching mechanism 8 is activated, the plate member 802 can be wound up by the actuator 1 and returned to the inoperative position. The automatic P range switching mechanism 8 may be returned to the non-operating state by operating the actuator 1 and the first solenoid device 803 immediately after the power supply is restored. Alternatively, it may be performed when the power is first switched to the forward stage such as the L, 2 or D range after the power supply is restored. In other words, when the automatic P range switching mechanism 8 is in the operating state (here, before the plate member 802 is completely returned to the non-operating position, the plate member 802 is engaged by the pin 806 of the first solenoid device 803. In this case, the rotation position of the manual shaft 401 can be maintained against the urging force of the torsion coil spring 801 by energizing the actuator 1 even after the power is restored. For example, when the first switched range is the R range, the rotation position of the manual shaft 401 corresponding to the selected range, that is, the R range can be maintained by energizing the actuator 1. Thereafter, when switching to the forward stage range such as L, 2 or D range, the actuator 1 is driven to the position corresponding to the L range and the solenoid 808 of the first solenoid device 803 is energized to move the pin 806 to the forward position. And the plate member 802 is locked at the non-operating position to return the automatic P range switching mechanism 8 to the non-operating state, and at the next moment, the actuator 1 is driven to the originally supported range. By taking such means, it is possible to return the automatic P range switching mechanism 8 to the non-operating state without feeling a time lag or performing a special operation by the driver.
[0036]
Here, the automatic P range switching mechanism 8 is configured to use two solenoids. However, the automatic P range switching mechanism 8 may be operated each time the IG 7 is turned OFF, and each time the IG 7 is turned ON. If the automatic P range switching mechanism 8 is returned to the non-operating state by the above-described means, the second solenoid device 804 can be omitted in the above-described embodiment.
[0037]
In the above-described embodiment, the relationship between the hole 112 in the output shaft portion of the reduction gear 102 and the cross-sectional shape of the manual shaft 401 inserted therein is also the cross-section of the hole 812 in the plate member 802 and the manual shaft 401 passing therethrough. Although it is the same as the relationship with the shape and there is a gap between the flat portion of the inner wall of the hole 112 and the flat portion of the manual shaft 401, a configuration in which this gap is eliminated may be used. In this case, when the automatic P range switching mechanism 8 is operated, the actuator 1, that is, the reduction gear 102 is reversely moved, so that the automatic P range switching mechanism 8 is reliably connected when the supply of power is cut off. This is contrary to the requirement to operate, and as a result, the torsion coil spring 801 needs to be strengthened. However, the response when switching the shift range by the actuator 1 is improved by the amount of no gap.
[0038]
Next, another embodiment 8 ′ of the automatic P range switching mechanism that can be incorporated as the automatic P range switching mechanism 8 of the shift range switching device of the automatic transmission shown in FIG. 1 will be described with reference to FIG. . Since the automatic P range switching mechanism 8 'is similar in structure to the automatic P range switching mechanism 8 described above, the description of the same parts will be omitted, and the description will focus on the parts different from the automatic P range switching mechanism 8. To do.
[0039]
FIG. 7 is a view similar to FIG. 5 and FIG. 6 and shows an integrated actuator 1 and automatic P range switching mechanism 8 ′. FIG. FIG. 7B is a sectional view taken along line AA in FIG. FIG. 7 shows an inoperative state of the automatic P range switching mechanism 8 ′ when the IG 7 is ON.
[0040]
The automatic P range switching mechanism 8 ′ shown in FIG. 7 includes a torsion coil spring 801, a plate member 852, a solenoid device 853, and an L-shaped hook 1000, where the solenoid device 853 is A solenoid 856, a pin 854, and a biasing spring 855 are provided.
[0041]
In FIG. 7, the plate member 852 is shown as a member having a rod-like portion on the outer peripheral surface of the cup-like member, and this is rotatably supported by the housing of the actuator 1. A torsion coil spring 801 is attached to the plate member 852 and urges the plate member 852 to rotate in the direction of arrow D in FIG. 7A (ie, from the L range to the P range). .
[0042]
The L-shaped hook 1000 is rotatably supported by the housing of the actuator 1 at its bent portion, and engages with the rod-shaped portion of the plate member 852 at one end thereof to lock the plate member 852 in the non-operating position. A protrusion 857 is provided.
[0043]
The solenoid device 853 is disposed so that the tip of the pin 854 contacts the end portion of the L-shaped hook 1000 opposite to the end portion having the projection 857. An urging spring 855 is disposed in contact with the rear end surface of the pin 854, and the pin 854 is urged in the direction of arrow E ′ in FIG. 7A to provide a gap between the tip of the pin 854 and the L-shaped hook. Make sure that does not occur. When the solenoid 856 of the solenoid device 853 is energized, the pin 854 is urged in the direction of arrow E ′ in FIG. 7A, and the urging force of the urging spring 855 and the urging force of the solenoid 856 of the solenoid device 853 are combined. The end of the L-shaped hook 1000 is pressed with the applied force.
[0044]
In the above-described configuration, in the automatic P range switching mechanism 8 ′, the protrusion 857 provided at one end of the L-shaped hook 1000 is engaged with the tip of the rod-shaped portion of the plate member 852 as shown in FIG. Then, the plate member 852 biased by the torsion coil spring 801 is held in the non-operating position. This is because the solenoid 856 of the solenoid device 853 is energized and the pin 854 is moved by the arrow in FIG. It is configured so as to be possible only when it is biased in the direction of E ′. That is, when the solenoid 856 is energized, the generated urging forces of the solenoid 856, the urging spring 855, and the torsion coil spring 801 of the solenoid device 853 are bar-shaped of the protrusion 857 of the L-shaped hook 1000 and the plate member 852. Although the engagement with the tip of the portion is maintained, the engagement is set so as to be disengaged when the energization of the solenoid 856 is stopped. That is, when the solenoid 856 of the solenoid device 853 is energized and the pin 854 is urged together with the urging spring 855 in the direction of the arrow E ′, the solenoid 856 and the urging spring 855 of the solenoid device 853 are pinned. The force for urging 854 to rotate the L-shaped hook 1000 counterclockwise in FIG. 7A causes the plate member 852 to move as indicated by the arrow D in FIG. 7A by the urging force of the torsion coil spring 801. , So that the tip of the rod-shaped portion of the plate member 852 pushes up the protrusion 857 of the L-shaped hook 1000, thereby exceeding the force to rotate the L-shaped hook 1000 clockwise in FIG. The engagement between the protrusion 857 of the L-shaped hook 1000 and the tip of the rod-shaped portion of the plate member 852 is maintained. On the other hand, when the energization of the solenoid 856 of the solenoid device 853 is stopped, only the urging spring 855 urges the pin 854 in the direction of the arrow E ′, and the L-shape is applied by the urging force of the torsion coil spring 801. The above force to rotate the hook 1000 in the clockwise direction in FIG. 7A causes the biasing spring 855 to urge the pin 854 to try to rotate the L-shaped hook 1000 in the counterclockwise direction in FIG. 7A. As a result, the engagement between the projection 857 of the L-shaped hook 1000 and the tip of the rod-shaped portion of the plate member 852 is disengaged.
[0045]
Next, the operation of the automatic P range switching mechanism 8 ′ will be described with reference to FIG. FIG. 8A shows a case where IG7 is ON, as in FIG. 7. In this case, the solenoid 856 of the solenoid device 853 is energized, and the pin 854 is moved together with the biasing spring 855 in FIG. 8A. It is energized in the direction of arrow E ′. Accordingly, the force of the solenoid 856 and the biasing spring 855 of the solenoid device 853 biasing the pin 854 to rotate the L-shaped hook 1000 counterclockwise in FIG. 8A is the biasing force of the torsion coil spring 801. As a result, the force to rotate the L-shaped hook 1000 clockwise in FIG. 8A is exceeded, and the engagement between the protrusion 857 of the L-shaped hook 1000 and the tip of the rod-shaped portion of the plate member 852 is maintained. The plate member 852 is held in the inoperative position.
[0046]
In the state where the IG7 of FIG. 8A is ON, when the power supply is cut off for some reason, such as the terminal of the battery 5 being disconnected, as shown in FIG. The energization of the solenoid 856 is stopped, and only the biasing spring 855 biases the pin 854 in the direction of arrow E ′, and the biasing force of the torsion coil spring 801 causes the L-shaped hook 1000 to be watched in FIG. The force of the urging spring 855 urges the pin 854 to exceed the force of the L-shaped hook 1000 to rotate counterclockwise in FIG. The protrusion 857 of the L-shaped hook 1000 is disengaged from the tip of the rod-shaped portion of the plate member 852 so that the bar-shaped portion of the plate member 852 pushes up the portion 857. . As a result, the automatic P range switching mechanism 8 'operates, and the torsion coil spring 801 causes the plate member 852 to rotate in the direction of arrow D in FIG. 8B (ie, from the L range to the P range). As a result, the manual shaft 401 is rotated to the P range position, and switching to the P range is achieved (see FIG. 8C). Note that the rotation of the manual shaft 401 due to the rotation of the plate member 852 causes the plane portion of the inner wall of the hole 812 of the plate member 852 and the hole 812 to be rotated by the rotation of the plate member 852, as is apparent from each drawing of FIG. This is performed by engaging and rotating the planar portion of the manual shaft 401 that passes therethrough.
[0047]
When the power is restored after the automatic P range switching mechanism 8 'operates, the plate is moved by the actuator 1 by means similar to those described in relation to the automatic P range switching mechanism 8 shown in FIGS. The member 852 is wound up, and the automatic P range switching mechanism 8 'can be returned to the non-operating state. When the plate member 852 is rolled up, as shown in FIG. 8D, the tip of the rod-shaped portion of the plate member 852 and the protrusion 857 of the L-shaped hook 1000 are shown in FIG. In the non-operating state of the automatic P range switching mechanism 8 ′, the side surfaces opposite to each other are in contact with each other, and the tip of the rod-shaped portion of the plate member 852 is the protrusion of the L-shaped hook 1000 The L-shaped hook 1000 is rotated clockwise in FIG. 8D so as to push up 857, and the plate member 852 reaches the inoperative position shown in FIG. 8A. Therefore, when the automatic P range switching mechanism 8 ′ is returned to the non-operating state, it is preferable that the solenoid 856 of the solenoid device 853 is not energized until the plate member 852 reaches the non-operating position. .
[0048]
Note that the automatic P range switching mechanism 8 'does not have a mechanism for holding the position of the pin 854 when the IG7 is turned off, so the automatic P range switching mechanism 8' is activated each time the IG7 is turned off. Will do. Therefore, every time the IG 7 is turned on again, the return operation to the inactive state described above is performed.
[0049]
Further, as is clear from the above description, in the automatic P range switching mechanism 8 ′, the movement of the tip of the rod-shaped portion of the plate member 852 along the arc at the time of operation and return to the non-operation state is performed. Since it is necessary to move the protrusion 857 of the L-shaped hook 1000 in a direction perpendicular to the moving direction, the tip of the rod-shaped portion of the plate member 852 and the shape of the protrusion 857 of the L-shaped hook 1000 are as described above. It is preferable to have a shape that facilitates easy operation. As an example of such a shape, the protrusion 857 of the L-shaped hook 1000 has an inclined surface on the side that comes into contact with the rod-shaped portion of the plate member 852 during operation and when returning to the non-operation state, The shape shown in FIG.7 and FIG.8 which has a curved surface in the side which the front-end | tip part of a rod-shaped part contacts the projection part 857 of the L-type hook 1000 at the time of an action | operation and the return | restoration to an inactive state is mentioned.
[0050]
Compared with the automatic P range switching mechanism 8 shown in FIGS. 5 and 6, the automatic P range switching mechanism 8 ′ has a single solenoid and the physique of the solenoid itself can be greatly reduced. The entire automatic P range switching mechanism 8 'can be downsized. In the automatic P range switching mechanism 8 ', the physique of the solenoid can be greatly reduced because the automatic P range switching mechanism 8' has an L-shaped hook 1000 or in the automatic P range switching mechanism 8 '. The urging spring 855 urges the pin 854 in the same direction as the solenoid 856 of the solenoid device 853 and acts to eliminate the gap with the L-shaped hook 1000, as shown in FIGS. In the automatic P range switching mechanism 8, the plate member 852 is not operated in the automatic P range switching mechanism 8 ′ due to the difference in configuration such that the biasing spring 805 biases the pin 806 in the opposite direction to the solenoid device 803. The biasing force that needs to be generated by the solenoid 856 of the solenoid device 853 and the amount of movement of the pin 854 in order to hold it in position are shown in FIGS. This is because extremely small compared to the amount of movement of the biasing force and the pin 806 needs to be generated by the solenoid device 803 to hold the automatic P-range switching mechanism 8 in which the plate member 802 in its inoperative position.
[0051]
In each of the automatic P range switching mechanisms 8 and 8 'described above, a solenoid is used. However, an electromagnetic driving unit such as an electromagnetic clutch may be used instead of the solenoid.
[0052]
In the above description, the range from the P range to the L range has been described as being switched by rotating the manual shaft 401 by the actuator 1 and operating the manual valve. However, the range from the P range to the D range is switched by the actuator 1 and below the D range. The shift range may be switched by a hydraulic circuit inside the A / T. In this case, the central angle of the sector forming the hole 812 provided in the plate member of the automatic P range switching mechanism is small (for example, about 40 °).
[0053]
Further, in the above-described embodiment, the automatic transmission is configured to be automatically switched to the P range. However, an automatic manual in which the shift range (shift stage) is switched using electrical means such as an electric actuator. It is good also as a structure which can be switched to arbitrary shift ranges, such as 1st speed or a reverse gear, in a transmission.
[Brief description of the drawings]
FIG. 1 is a system configuration diagram of a shift range switching device of an automatic transmission equipped with an automatic parking range switching mechanism, which is an embodiment of a vehicle control device of the present invention.
FIG. 2 is a perspective view showing a schematic configuration of a shift range switching mechanism including a connecting portion between a manual shaft and an automatic transmission.
FIG. 3 is a configuration diagram schematically showing a schematic configuration of the automatic P range switching mechanism of the first embodiment, in which the automatic P range switching mechanism is shown in an inoperative state.
4 shows a schematic configuration of an output shaft portion of an actuator (that is, an output shaft portion of a reduction gear) and a connection portion between a plate member of an automatic P range switching mechanism and a manual shaft. FIG. ) Is a longitudinal sectional view of the connecting portion, and FIGS. 4 (b) and 4 (c) are transverse sectional views taken along lines BB and CC in FIG. 4 (a), respectively. .
FIG. 5 shows an integrated actuator and automatic P-range switching mechanism according to the first embodiment, and FIG. 5 (a) is an internal structure diagram when viewed from the bottom surface; FIG. 5B is a cross-sectional view taken along line AA in FIG. In FIG. 5, the automatic P range switching mechanism is shown in a non-actuated state as in FIG.
FIG. 6 is a view similar to FIG. 5 and shows an integrated actuator and automatic P range switching mechanism of the first embodiment, and FIG. FIG. 6B is a cross-sectional view taken along line AA in FIG. 6A, and FIG. 6 shows the automatic P range switching mechanism in an activated state. ing.
FIG. 7 is a view similar to FIGS. 5 and 6 and shows an integrated actuator and an automatic P range switching mechanism of the second embodiment. FIG. It is an internal structure figure at the time of seeing from the lower surface, and FIG.7 (b) is sectional drawing along line AA of Fig.7 (a). In FIG. 7, the automatic P range switching mechanism is shown in a non-actuated state.
FIG. 8 is a schematic view showing the operation of the automatic P range switching mechanism of the second embodiment, and each figure shows (a) the non-operating state and (b) the start of operation of the automatic P range switching mechanism, respectively. (C) shows an operating state, and (d) shows a return to a non-operating state.
[Explanation of symbols]
1 ... Actuator
2 ... Actuator control circuit
3. Shift switch
4 ... Automatic transmission (A / T)
5 ... Battery
6 ... Relay
7 ... Ignition switch (IG)
8, 8 '... Automatic parking range (P range) switching mechanism
101 ... Motor
102 ... Reduction gear
103. Incremental encoder type position sensor
112 ... hole
201: Motor control unit 201
202 ... Counter
204 ... Signal input means
401 ... Manual shaft
402 ... Detent plate
403 ... Detent spring
404 ... Spool valve
405 ... Manual valve
406 ... Rod
407 ... Claw member
408 ... Park Gear
409 ... protrusion
410 ... taper part
801 ... Torsion coil spring
802, 852 ... Plate member
803 ... First solenoid device
804 ... Second solenoid device
805, 855 ... biasing spring
806, 807, 854 ... pin
808, 809, 856 ... Solenoid
810 ... Detent mechanism
812 ... hole
853 ... Solenoid device
857 ... Projection
1000 ... L-shaped hook

Claims (7)

A vehicle control device used in a vehicle having an electric means for switching a shift range,
Power supply state determination means for detecting that power supply has been cut off;
Energy storage means for storing energy in advance;
Energy release means for releasing energy of the energy storage means based on the determination result of the power supply state determination means;
Have a vehicle fixing means for fixing the vehicle stopped state,
Switching of the normal shift range by the electrical means is possible without acting on the energy storage means,
When it is detected by the power supply state determination means that the power supply has been cut off, the energy release means releases the energy stored in the energy storage means, thereby driving the vehicle fixing means and automatically A vehicle control device characterized by ensuring a stationary state of the vehicle.   When the power supply state determination unit detects that the power supply is cut off, the energy stored in the energy storage unit is released by the energy release unit, whereby the shift range switching mechanism of the automatic transmission is 2. The vehicle control device according to claim 1, wherein the vehicle control device is driven and automatically switched to a parking range to ensure a stopped state of the vehicle.   When it is detected by the power supply state determination means that the power supply is cut off, the energy stored in the energy storage means is released by the energy release means, thereby automatically changing the shift range of the transmission. The vehicle control device according to claim 1, wherein the vehicle is stopped by switching to an arbitrary shift range.   When it is detected by the power supply state determination means that the power supply is cut off, the energy stored in the energy storage means is released by the energy release means, thereby causing the output shaft of the transmission to rotate. The vehicle control device according to claim 1, wherein the vehicle control device is stopped to ensure a stopped state of the vehicle.   The energy storage means is a spring, and the energy release means is an electromagnetic drive means such as a solenoid or a clutch capable of locking the spring in an energy storage state such as a compression or extension state and releasing it from the state. The vehicle control device according to any one of claims 1 to 4, wherein when the supply of is cut off, the energy stored by the spring is automatically released.   Once the power supply is cut off and the energy stored in the energy storage means is released, the energy is automatically stored in the energy storage means by the electrical means for switching the shift range when the power supply is restored. The vehicle control device according to claim 1, wherein the vehicle control device is in a state.   Once the power supply is cut off and the energy storage means is released, after the power supply is restored, the selected range switches the shift range until the first forward range is selected. When the forward gear range is selected for the first time, the energy is automatically stored in the energy storage device by the electrical device for switching the shift range, and the predetermined energy storage state is obtained. The vehicle control device according to claim 2, wherein

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