JP2013022972A - Electric steering lock device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electric steering lock device in which heat damage due to overheating of an electric motor is prevented with a simple constraction without increasing cost.SOLUTION: The electric steering lock device performs unlock processing in a normal mode by controlling an electric motor based upon a preset electric power supply holding time in which electric power supply to the electric motor and an electric power supply stop time in which the electric power supply is stopped. If movement of a lock bolt to an unlock position is not detected although the unlock processing in the normal mode is performed on receiving an unlock command from an operator, the mode of unlock processing to be executed with a next unlock command from the operator is switched to a motor overheat protection mode in which an electric power supply holding time is set to be shorter than the electric power supply holding time in the normal mode, in order that a duty ratio calculated from the electric power supply holding time and electric power supply stop time is smaller than a duty ration in the normal mode.

Description

  The present invention relates to an electric steering lock device for electrically locking the rotation of a steering wheel when a vehicle is parked.

  In recent years, some vehicles are equipped with an electric steering lock device for electrically locking the rotation of the steering wheel during parking for the purpose of preventing theft. The electric steering lock device includes a lock bolt that can move between a lock position that engages with a steering shaft of a vehicle and an unlock position that releases the engagement, an electric motor that moves the lock bolt, Control means for controlling energization to the electric motor to perform lock / unlock processing, and position detection means electrically connected to the control means and capable of detecting that at least the lock bolt is in the unlock position ing.

  In such an electric steering lock device, when the driver turns off the engine ON / OFF switch while the engine is in operation, the upper ECU on the vehicle body side that has detected this stops the engine and the safety is confirmed. A lock request is made to the electric steering lock device. When the electric steering lock device receives the lock request, the electric motor is driven and controlled by a control means such as a microcomputer, and the electric motor moves the lock bolt to engage the steering shaft. Lock the rotation of the steering wheel.

  On the other hand, when the driver turns on the engine ON / OFF switch while the engine is stopped, the host ECU that has detected this makes an unlock request to the electric steering lock device. When the electric steering lock device receives the unlock request, the electric motor is driven and controlled by the control means, the lock bolt is moved by the electric motor to disengage the lock bolt from the steering shaft, and the steering wheel Is unlocked to enable steering operation.

  By the way, in such an electric steering lock device, if the lock and unlock are frequently repeated within a short time, there is a possibility that a thermal damage such as the coil being disconnected due to overheating of the electric motor may occur.

  Therefore, in Patent Document 1, when it is determined that the value calculated from the relational expression having the operation time of the electric motor as an element is larger than a predetermined stop threshold, the operation of the electric motor is forcibly stopped. When the calculated value is larger than a predetermined invalid threshold value, an electric steering lock device has been proposed in which an operation request for an electric motor is invalidated.

JP 2004-217002 A

  The heat damage caused by overheating of the electric motor in the electric steering lock device is presented in Patent Document 1 (because of overheating of the electric motor due to frequent repetition of locking and unlocking in a short time) In addition, a case where the lock bolt is strongly engaged with the steering shaft (so-called biting) can be considered. In such a case, the lock bolt cannot be pulled out of the steering shaft with the driving force of the electric motor, and the electric motor becomes overloaded and an excessive current flows through the electric motor, so the electric motor generates heat. . If the unlocking operation is repeated until the lock bolt is removed from the steering shaft, the electric motor becomes hot, and there is a possibility that heat damage such as disconnection of the coil of the electric motor may occur.

  In order to solve the above problem, it is conceivable to use an electric motor incorporating an overheat protection device made of bimetal or the like. However, there is a problem that such an electric motor is large and expensive.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide an electric steering lock device that can prevent the occurrence of heat damage due to overheating of an electric motor with a simple configuration without increasing costs. It is to provide.

In order to achieve the above object, the invention according to claim 1
A lock bolt movable between a lock position for engaging with a steering shaft of the vehicle and an unlock position for releasing the engagement;
An electric motor for moving the lock bolt;
Control means for controlling energization to the electric motor to perform lock / unlock processing;
Position detecting means electrically connected to the control means and capable of detecting that at least the lock bolt is in the unlock position;
In the electric steering lock device with
The control means includes
Control the electric motor based on the energization maintaining time for energizing the electric motor set in advance and the energization pause time for de-energizing to perform the unlocking process in the normal mode,
If it is not possible to detect the movement of the lock bolt to the unlock position despite receiving the unlock command from the driver and performing the unlock process in the normal mode, the next unlock from the driver is performed. The energization maintaining time is set to the energization maintaining time in the normal mode so that the duty ratio calculated from the energization maintaining time and the energization stop time is smaller than the duty ratio in the normal mode. The motor overheat protection mode is set shorter than the maintenance time.

  According to a second aspect of the present invention, in the first aspect of the present invention, the energization maintaining time in the motor overheat protection mode is an unlocking amount that ensures movement of the lock bolt from the lock position to the unlock position under a predetermined condition. It is characterized in that it is set shorter than the lock guarantee energizing time.

  According to a third aspect of the present invention, in the first or second aspect of the present invention, the unlock operation time comprising the energization maintaining time and the energization stop time is the same in the normal mode and the motor overheat protection mode. An energization stop time in the motor overheat protection mode is set.

The invention according to claim 4 is the invention according to any one of claims 1 to 3, wherein the control means includes a host ECU that receives an unlock command from the driver, and a lock / unlock from the host ECU. A microcomputer for controlling the energization of the electric motor to execute a lock / unlock process when receiving the operation signal, the energization maintaining time is controlled by the microcomputer, and the energization stop time is controlled by the host ECU; And
The upper ECU waits until the unlock operation time elapses when the unlock command is received within a predetermined unlock operation time after starting the unlock process, and the unlock operation time elapses. The energization stop time is set by starting an unlocking process later.

  According to the invention of claim 1, when the unlock command from the driver is received and the unlock process in the normal mode is performed, the movement of the lock bolt to the unlock position cannot be detected, that is, If it is determined that the lock bolt is caught in the steering shaft, the next unlocking mode is switched from the normal mode to the motor overheat protection mode, and the duty ratio of the electric motor is smaller than that in the normal mode. Thus, even when the unlocking process is repeatedly performed by the driver, the electric motor is prevented from overheating and the occurrence of thermal damage such as coil disconnection is prevented. be able to. And since such an effect is acquired by switching the mode of an unlock process, use of the electric motor etc. which incorporated the overheat protection apparatus becomes unnecessary, and it can avoid an enlargement and cost increase.

  By the way, the energization maintaining time of the electric motor in the normal mode is sufficient for the lock bolt to move from the locked position to the unlocked position by one unlocking process, and can satisfy the conditions that can ensure high responsiveness. The shortest time is set. In order to reduce the duty ratio of the electric motor (= energization maintaining time / unlock operation time) while maintaining this energization maintenance time, the energization stop time may be extended. However, if the power supply stop time is extended, the unlock operation time ( = Energization maintenance time + energization stop time) becomes longer, and the responsiveness to the driver becomes worse.

  In the present invention, the energization maintaining time of the electric motor in the motor overheat protection mode is made shorter than that in the normal mode to reduce the duty ratio of the electric motor, so that the entire unlocking operation time can be shortened, Heat generation of the electric motor can be suppressed without impairing responsiveness to the person.

  In general, the torque of an electric motor decreases as the temperature rises. In the present invention, in the motor overheat protection mode, the energization maintenance time is shortened, and the electric motor is operated when the temperature is lower and the torque is higher. Since the lock bolt is moved from the lock position to the unlock position by performing this operation a plurality of times, the unlock process can be performed efficiently.

  According to the invention described in claim 2, since the energization maintaining time in the motor overheat protection mode is set shorter than the unlock guarantee energization time, the lock bolt cannot be moved to the unlock position in one unlock process. In some cases, the responsiveness to the driver (for example, the time from when the driver operates the engine ON / OFF switch until a warning such as unlock failure lights up) is lost by shortening the unlock operation time. Accordingly, the lock bolt can be reliably moved to the unlock position by the driver's multiple unlock operations without causing the driver to feel uncomfortable.

  According to the invention of claim 3, by making the unlock operation time in the motor overheat protection mode the same as that in the normal mode, the response time to the driver can be made constant, and the driver feels uncomfortable. Never give.

  According to the fourth aspect of the present invention, when the host ECU receives an unlock command within a predetermined unlock operation time after starting the unlock process, the host ECU waits until the unlock operation time elapses. Since the energization stop time is set by starting the unlock process after the unlock operation time elapses, the host ECU can manage the energization stop time and the unlock operation time, and control the duty ratio of the electric motor. Can be easily performed.

It is a longitudinal section showing the locked state of the electric steering lock device concerning the present invention. It is a longitudinal section showing the unlocking state of the electric steering lock device concerning the present invention. It is a control system block diagram of the electric steering lock device concerning the present invention. It is a timing chart which shows the processing flow of the electric steering lock device concerning the present invention.

  Embodiments of the present invention will be described below with reference to the accompanying drawings.

[Configuration of electric steering lock device]
FIG. 1 is a longitudinal sectional view showing a locked state of an electric steering lock device according to the present invention, FIG. 2 is a longitudinal sectional view showing an unlocked state of the electric steering lock device, and the electric steering lock device 1 shown in FIG. Is used to lock / unlock the rotation of a steering shaft (steering wheel) (not shown), and the housing 2 includes a case 3 made of a non-magnetic metal (for example, magnesium alloy), and the case 3. It is comprised by the metal lid 4 which covers a lower surface opening part.

  The case 3 is formed in a rectangular box shape, and an arcuate recess 3a is formed in the upper portion thereof, and a cylindrical steering column (not shown) is fitted into the recess 3a. It is fixed to the steering column by an arcuate bracket (not shown) to be worn. Although not shown, the steering shaft is inserted into the steering column, a steering wheel is connected to the upper end of the steering shaft, and the lower end of the steering shaft is connected to a steering gear box. When the driver rotates the steering wheel, the rotation is transmitted to the steering gear box through the steering shaft, the steering mechanism is driven, and the pair of left and right front wheels are steered to perform the required steering.

  The housing 2 is formed with a lock member storage portion 2A and a substrate storage portion 2B. The lock member storage portion 2A and the substrate storage portion 2B communicate with each other by an elongated communication portion 2C extending in the vertical direction. .

  A lock member 5 is stored in the lock member storage portion 2A. The lock member 5 includes a substantially cylindrical driver 6 in which a male screw portion 6a is engraved on the outer periphery of the lower end portion, and an upper and lower portion in the driver 6. It is comprised with the plate-shaped lock bolt 7 accommodated so that a movement was possible. Here, a long hole 7a that is long in the vertical direction is formed in the lock bolt 7, and the lock bolt 7 is connected to the driver 6 by a pin 8 that is inserted laterally into the long hole 7a.

  The lock bolt 7 is fitted in a rectangular lock bolt insertion hole 3b formed in the case 3 so as to be movable up and down, and is always moved upward by a spring 9 which is compressed between this and the partition wall 6b of the driver 6. Usually, the lower part of the long hole 7 a of the lock bolt 7 is engaged with the pin 8 so that the lock bolt 7 moves up and down together with the driver 6.

  Further, an arm 6A as a horizontally extending engaging portion and an anti-rotation portion 6B which is long in the vertical direction are integrally formed at opposite locations on the upper outer periphery of the driver 6, and the arm 6A is formed in the housing 2 (case 3). ) Formed in the communication portion 2 </ b> C formed so as to be movable up and down, and the rotation preventing portion 6 </ b> B engages with an engagement groove 3 c formed in the case 3 to prevent the driver 6 from rotating. A magnet storage portion 6c having a rectangular cross section is formed at the tip of the arm 6A, and a quadrangular prism-shaped magnet 10 is stored in the magnet storage portion 6c by press-fitting.

  Further, a cylindrical gear member 11 is rotatably accommodated in the lock member accommodating portion 2A formed in the housing 2, and the lower outer periphery of the gear member 11 is erected on the inner surface (upper surface) of the lid 4. The gear holding cylinder portion 4a is held rotatably. And the worm gear 11a is formed in the lower outer periphery of this gear member 11, and the internal thread part 11b is formed in the inner periphery.

  The lower part of the driver 6 is inserted into the gear member 11, and the male screw part 6 a formed on the outer periphery of the lower part of the driver 6 is the female screw part formed on the inner periphery of the gear member 11. 11b meshes. A spring 12 is contracted between a cylindrical spring receiver 4b formed at the center of the gear holding cylinder 4a of the lid 4 and a partition wall 6b of the driver 6, and the lock member 5 (the driver 6 and the lock 6 are locked). The bolt 7) is always biased upward by the spring 12.

  An electric motor 13 is housed horizontally in the lock member housing portion 2A formed in the housing 2, and a small-diameter worm 14 is formed on the output shaft 13a of the electric motor 13, and the worm 14 Is meshed with the worm gear 11 a formed on the outer periphery of the gear member 11. Here, the worm 14 and the worm gear 11 a constitute a drive mechanism that converts the rotational force of the output shaft 13 a of the electric motor 13 into the advancing and retracting force of the lock member 5.

  On the other hand, a substrate 15 is stored in the substrate storage portion 2B formed in the housing 2 so that the inner surface thereof is parallel to the operation direction of the lock member 5. Hall elements 16 and 17 which are magnetic detection sensors are provided at positions corresponding to the lock position, and a position detection means is constituted by these Hall elements 16 and 17 and the magnet 10, and this position detection means will be described later. Thus, the position (lock / unlock position) of the lock member 5 (lock bolt 7) is detected.

  Next, the operation (lock / unlock operation) of the electric steering lock device 1 configured as described above will be described.

  In a state where the engine (not shown) is stopped, as shown in FIG. 1, the lock bolt 7 of the lock member 5 is at the upper limit lock position, and the upper end portion thereof is recessed from the lock bolt insertion hole 3b of the case 3 to the recess 3a. And is engaged with a steering shaft (not shown). In this state, the rotation of the steering shaft is locked, and in this locked state, a steering wheel (not shown) cannot be rotated, thereby preventing the vehicle from being stolen.

  When the driver turns on an engine ON / OFF switch (not shown) from the above state, the electric motor 13 is activated, the rotation of the output shaft 13a is decelerated by the worm 14 and the worm gear 11a, and the direction is changed to a right angle to change the gear. Since the gear member 11 is rotated by being transmitted to the member 11, the driver 6 in which the male screw portion 6 a that engages with the female screw portion 11 b carved on the inner periphery of the gear member 11 is formed by the spring 12. Moves down against the force. When the driver 6 moves down in this way, the lock bolt 7 connected to the driver 6 by the arm 6A and the pin 8 formed integrally with the driver 6 moves down.

  As described above, when the arm 6A of the driver 6 moves down and the lock bolt 7 reaches the lower limit unlock position as shown in FIG. 2, the magnetic force of the magnet 10 is detected by the Hall element 17 to drive the electric motor 13. Is stopped, and the upper end of the lock bolt 7 is retracted into the lock bolt insertion hole 3b of the case 3, so that the engagement of the lock bolt 7 with the steering shaft is released. As a result, the steering shaft is unlocked and unlocked, and the steering wheel can be turned by the driver, allowing the vehicle to travel.

  Then, when the vehicle stops and the driver turns off the engine by turning off the engine ON / OFF switch, the electric motor 13 is activated in reverse to reverse the output shaft 13a. Then, the rotation of the electric motor 13 is transmitted to the gear member 11 through the worm 14 and the worm gear 11a, and the driver 6 is moved upward due to the reverse rotation of the gear member 11, and the arm 6A formed integrally with the driver 6 The lock bolt 7 connected to the driver 6 by the pin 8 moves up.

  Thus, when the arm 6A of the driver 6 moves up as described above and the center of the magnet 10 reaches the detection range near the lock position, the magnetic force of the magnet 10 is detected by the Hall element 16 and the electric motor 13 is driven. 1 and the upper end portion of the lock bolt 7 protrudes from the recess 3a of the case 3 and engages with a steering shaft (not shown) as shown in FIG. Theft of the vehicle is prevented. If the engagement of the lock bolt 7 with the engagement groove of the steering shaft is not performed satisfactorily, the pin 8 can move within the long hole 7a formed in the lock bolt 7. Since the lock bolt 7 moves downward against the urging force of the spring 9, an excessive load does not act on the lock bolt 7.

[System configuration of electric steering lock device]
Next, the system configuration of the electric steering lock device 1 will be described with reference to FIG.

  FIG. 3 is a system configuration diagram of the electric steering lock device 1 according to the present invention. An ECU 18 is provided as control means on the electric steering lock device 1 side, and a host ECU 19 which is also control means is mounted on the vehicle body side. Yes. The host ECU 19 is electrically connected to an engine ON / OFF switch (not shown) that is operated by the driver, and the host ECU 19 includes timer means and storage means (not shown).

  The ECU 18 includes a motor drive control unit 21 that controls the movement of the lock member 5 by switching / cutting off the polarity of the drive current supplied from the battery (BATT) 20 as a power source to the electric motor 13, and the motor drive. A microcomputer (microcomputer) 22 that controls the control unit 21 to lock / unlock the electric motor 13 and a power supply path from the battery 20 to the motor drive control unit 21 and the microcomputer 22 are cut off / conducted. A first switch part 23, a second switch part 24, and the like, which are power regulation means, are provided. The first switch unit 23 and the second switch unit 24 are provided in series in the power supply path.

  Here, the motor drive control unit 21 includes a lock relay 25 and an unlock relay 26, and a lock relay drive circuit 27 and an unlock relay drive circuit that drive and control the lock relay 25 and the unlock relay 26 according to commands from the microcomputer 22, respectively. 28. Further, the microcomputer 22 detects a position detection circuit (LOCK) 29 for detecting the lock position of the lock member 5 (lock bolt 7) and the unlock position by the Hall elements 16 and 17 (see FIGS. 1 and 2). A position detection circuit (UNLOCK) 30 is connected, and storage means 31 such as an EEPROM is connected. The microcomputer 22 has a timer means 32 built therein. Further, between the microcomputer 22 and the host ECU 19, LIN communication such as a lock / unlock command signal and a failure state is performed via the communication circuit 33.

  Thus, the microcomputer 22, the electric motor 13, the lock relay 25, the unlock relay 26, the position detection circuit (LOCK) 29, the position detection circuit (UNLOCK) 30 and the communication circuit 33 are supplied from the first and second switch units. Therefore, when the first and second switch portions 23 and 24 are turned off, the power supply to the microcomputer 22 is cut off and the microcomputer 22 is inactivated. A constant voltage output circuit 34 and a reset circuit 35 are provided in the middle of the power supply path from the second switch unit 24 to the microcomputer 22.

  On the other hand, the power of the host ECU 19 and the ignition device (ignition) of the engine (not shown) is taken in front of the first and second switch parts 23 and 24, and the IG power supply line for supplying power to the ignition device On the way, an IG relay 36 that is driven and controlled by the host ECU 19 is provided, and an IG power source (ignition power source) is controlled by the host ECU 19.

  By the way, in the present embodiment, as described above, the first and second switch portions 23 and 24 are provided as power regulating means for cutting off / conducting the power supply path from the battery 20 to the motor drive control unit 21 and the microcomputer 22. However, since the first and second switch sections 23 and 24 are ON / OFF controlled by the host ECU 19, the power supply of the microcomputer 22 is controlled by the host ECU 19.

  Therefore, when the host ECU 19 controls the one side of the first and second switch units 23 and 24 to be ON and the other side is OFF, the microcomputer is sufficient if these first and second switch units 23 and 24 are normal. However, if the power supply of the microcomputer 22 is not cut off at this time, it can be determined that the switch part 23 or 24 on the other side that is OFF-controlled is out of order. For this reason, it is possible to detect a failure of the first and second switch sections 23 and 24 with a simple configuration without providing a dedicated failure detection circuit or the like. Here, as shown in FIG. 3, the IG power line is connected to the first switch unit 23, and the power supply signal output from the host ECU 19 is input to the second switch unit 24. The IG power source input to the first switch unit 23 is inverted and controlled in the first switch unit 23. When the IG power source is turned on by the host ECU 19, the first switch unit 23 is turned off and the IG power source is turned off. If it has been done, the first switch unit 23 is turned on. This is because the electric steering lock device 1 can be operated by turning on the first switch portion 23 in the state where the engine cannot be started and the IG power source is OFF, and in the state where the engine can be started, the first switch This is because the electric steering lock device 1 is made inoperable by turning off the portion 23.

  Thus, in the electric steering lock device 1 according to the present invention, the unlocking process for moving the lock bolt 7 from the lock position to the unlock position is performed. In the normal mode, the preset electric motor 13 is set. The electric motor 13 is controlled on the basis of the energization maintaining time for maintaining the energization and the energization suspending time for stopping the energization.

[Unlock processing (in normal mode)]
Here, the flow of the unlocking process in the normal mode (when the lock bolt 7 is pulled out) of the electric steering lock device 1 will be described with reference to the timing chart shown in FIG. The numbers 1) to 27) given in FIG. 4 correspond to the numbers 1) to 27) given for the following processing items.

  1) When the driver turns on the engine ON / OFF switch while the engine is stopped, the host ECU 19 outputs a power supply signal to turn on the second switch unit 24 to supply power to the electric steering lock device 1. Here, since the IG power supply is cut off while the engine is stopped, the first switch unit 23 is in the ON state. The host ECU 19 also starts a timer (2.5 seconds) for setting the unlock processing time of the electric motor 13.

  2) The host ECU 19 exchanges an encryption code with the microcomputer 22 and transmits an encrypted unlock operation signal (normal mode).

  3) Upon receiving the unlock operation signal, the microcomputer 22 starts a timer (1 second) for setting the energization maintaining time of the electric motor 13 and turns on the unlock relay 26 via the unlock relay drive circuit 28. The signal is transmitted to unlock the electric motor 13.

  4) When the lock bolt 7 moves from the lock position to the unlock position, the microcomputer 22 detects that the lock bolt 7 has moved to the unlock position by the position detection circuit (UNLOCK) 30, and turns on the unlock relay 26. The signal is turned off to cut off the power supply to the electric motor 13. In this case, the electric motor 13 is turned off in a time (0.7 seconds) shorter than the energization maintaining time (1 second) by the timer monitoring. The energization time (0.7 seconds) of the electric motor 13 at this time varies within a range not exceeding an unlock guarantee energization time (1 second), which will be described later, depending on the voltage and temperature of the battery 20.

  5) The microcomputer 22 transmits an unlock confirmation signal (a signal indicating whether or not the lock bolt 7 has moved to the unlock position) to the host ECU 19.

  6) The host ECU 19 displays the result of whether or not the unlocking process has succeeded on an indicator (not shown) (for example, the green light indicates success, the red light blinks).

  7) The host ECU 19 turns off the power supply signal and turns off the second switch unit 24 to shut off the power supply to the electric steering lock device 1.

  8) In the case of “successful unlocking process”, the host ECU 19 turns on the IG relay 36 to turn on the IG power source, and performs an engine start process.

  9) When the host ECU 19 is “unlock process failure”. 1) If the driver detects the operation of the engine ON / OFF switch within 2.5 seconds from the start of the timer in 1), the microcomputer waits until 2.5 seconds have elapsed, and after 2.5 seconds has elapsed, the microcomputer The process of 1) is started for 22 and the next lock process is performed.

[Lock processing (in normal mode)]
Next, the flow of the lock process in the normal mode of the electric steering lock device 1 will be described below with reference to FIG.

  10) When the driver turns off the engine ON / OFF switch while the engine is operating, the host ECU 19 turns off the IG relay 36, shuts off the IG power supply, and stops the engine.

  11) The 1st switch part 23 will be in an ON state in response to interruption | blocking of IG power supply. The host ECU 19 outputs a power supply signal, turns on the second switch unit 24, and supplies power from the battery 20 to the electric steering lock device 1.

  12) The host ECU 19 exchanges an encryption code with the microcomputer 22, and transmits an encrypted lock operation signal to the microcomputer 22.

  13) When receiving the lock operation signal from the host ECU 19, the microcomputer 22 starts a timer (1 second) for setting the energization maintaining time, and transmits an ON signal to the lock relay 25 via the lock relay drive circuit 27. The electric motor 13 is operated.

  14) When the lock bolt 7 moves from the unlock position to the lock position, the microcomputer 22 detects that the lock bolt 7 has moved to the lock position by the position detection circuit (LOCK) 29, and the ON signal to the lock relay 25 is detected. To turn off the power to the electric motor 13.

  15) The microcomputer 22 transmits a lock confirmation signal (a signal indicating whether or not the lock bolt 7 has moved to the lock position) to the host ECU 19.

  16) The host ECU 19 displays the result of whether or not the locking process has been successful on an indicator (not shown) provided in the electric steering lock device 1 (for example, the green light indicates success, the red light blinks).

  17) The host ECU 19 turns off the power supply signal and turns off the second switch unit 24 to shut off the power supply to the electric steering lock device 1.

  In this locking process, since the load on the electric motor 13 is smaller than in the unlocking process, the operation time (2.5 seconds or the like) of the electric motor 13 is not set unlike the unlocking process.

[Unlock processing (Normal mode: When the lock bolt cannot be pulled out)]
Next, the flow of the unlocking process when the lock bolt 7 cannot be pulled out in the normal mode of the electric steering lock device 1 will be described with reference to FIG.

  In this unlocking process, among the unlocking processes 1) to 9) when the lock bolt 7 is pulled out, the process of 4) is changed to the following process 18), and the other 1) to 3) and 5 are performed. There is no change in the processing of) to 9).

  18) When the lock bolt 7 is engaged with the steering shaft and does not move to the unlock position, the microcomputer 22 can detect that the lock bolt 7 has moved to the unlock position by the position detection circuit (UNLOCK) 30. Therefore, when the position of the lock bolt 7 is detected, the electric motor 13 is not cut off. When the normal maintenance time timer (1 second) elapses, the ON signal to the unlock relay 26 is turned OFF and the electric motor is turned off. The power supply to 13 is cut off.

  For example, as shown in FIG. 4 (b), when the energization maintenance time (unlock guaranteed energization time) is set to 1 second, the unlock operation time is set to 2.5 seconds, and the energization stop time is set to 1.5 seconds. The duty ratio (= energization maintaining time / unlock operation time) of the motor 13 is 1 / 2.5 = 0.4. Here, the unlock guarantee energization time is relative to the average time energized until the unlocking is completed when the electric motor 13 is temporarily operated when the temperature and the voltage of the battery 20 are lowered to such an extent that the engine does not start. It is set to a slightly larger value with a margin.

  By the way, in the electric steering lock device 1 according to the present invention, the host ECU 19 receives the unlock command from the driver and performs the unlock process in the normal mode, but the lock bolt 7 is moved to the unlock position. When the movement cannot be detected, the unlocking process mode executed by the next unlocking command from the driver is changed to the duty ratio calculated from the energization maintenance time and the energization stop time from the duty ratio in the normal mode. Therefore, the motor overheat protection mode is set so that the energization maintaining time is set shorter than the energization maintaining time in the normal mode.

  Here, the energization maintaining time in the motor overheat protection mode is set shorter than the unlock guarantee energization time for guaranteeing the movement of the lock bolt 7 from the lock position to the unlock position under a predetermined condition.

  Further, in this embodiment, the power supply suspension time in the motor overheat protection mode is set so that the unlock operation time composed of the energization maintenance time and the energization suspension time is the same in the normal mode and the motor overheat protection mode described later. Is done.

  Further, in the present embodiment, the energization maintaining time is controlled by the microcomputer 22 and the energization stop time is controlled by the host ECU 19, but the host ECU 19 starts the unlock process within a predetermined unlock operation time. When the unlock command is received, it waits until the unlock operation time elapses, and the energization stop time is set by starting the unlock process after the unlock operation time elapses.

[Unlock processing (motor overheat protection mode)]
Next, the flow of the unlocking process in the motor overheat protection mode (when the lock bolt 7 cannot be pulled out) of the electric steering lock device 1 will be described with reference to FIG.

  19) When the driver turns on the engine ON / OFF switch while the engine is stopped, the host ECU 19 outputs a power supply signal and turns on the second switch unit 24 to turn on the power from the battery 20 to the electric steering lock device 1. Supply. At this time, since the IG power supply is OFF, the first switch unit 23 is in the ON state. The host ECU 19 also starts a timer (2.5 seconds) for setting the unlock processing time of the electric motor 13.

  20) When the “unlock process failure” occurs twice consecutively in the previous unlock process, the host ECU 19 exchanges an encryption code with the microcomputer 22 and an encrypted unlock operation signal (motor Send overheat protection mode).

  21) When the microcomputer 22 receives the unlock operation signal from the host ECU 19, the microcomputer 22 starts a timer (0.5 seconds) for setting the energization maintaining time, and sends it to the unlock relay 26 via the unlock relay drive circuit 28. An ON signal is transmitted to unlock the electric motor 13.

  22) If the microcomputer 22 cannot detect that the lock bolt 7 has moved to the unlock position by the position detection circuit (UNLOCK) 30, the microcomputer 22 will unlock when the energization maintenance time timer (0.5 seconds) elapses. The ON signal to the lock relay 26 is turned OFF to cut off energization to the electric motor 13.

  23) The microcomputer 22 transmits to the host ECU 19 an unlock confirmation signal (a signal indicating whether or not the lock bolt 7 has moved to the unlock position).

  24) The host ECU 19 displays whether or not the unlocking process is successful on an unillustrated indicator (for example, success is lit in green, failure is flashing in red).

  25) The host ECU 19 turns off the power supply signal and turns off the second switch unit 24 to shut off the power of the electric steering lock device 1.

  26) In the case of “successful unlocking”, the host ECU 19 turns on the IG relay 36 and turns on the IG power to perform the engine starting process.

  27) In the case of “unlock process failure”, the host ECU 19 detects the operation of the engine ON / OFF switch by the driver within 2.5 seconds from the start of the timer in 19), and then determines that 2.5. The process waits until the second elapses, and after the elapse of 2.5 seconds, the microcomputer 22 starts the process 19) to perform the unlock process.

  In this motor overheat protection mode, the energization maintaining time is set to 0.5 seconds, the unlocking operation time is set to 2.5 seconds, and the energization stop time is set to 2.0 seconds. 5 / 2.5 = 0.2, which is set to be smaller than the duty ratio 0.4 in the normal mode.

  As described above, in the electric steering lock device 1 according to the present embodiment, the unlock position of the lock bolt 7 in spite of receiving the unlock command from the driver and performing the unlock process in the normal mode. If it is determined that the lock bolt 7 is caught in the steering shaft, the next unlock process mode is switched from the normal mode to the motor overheat protection mode, and the electric motor 13 Since the energization time to the electric motor 13 is shortened so that the duty ratio is smaller than that in the normal mode, the electric motor 13 is overheated even when the unlocking process is repeatedly performed by the driver. It is possible to suppress the occurrence of heat damage such as disconnection of the coil. And since such an effect is acquired by switching the mode of an unlock process, use of the electric motor etc. which incorporated the overheat protection apparatus becomes unnecessary, and it can avoid an enlargement and cost increase.

  In the present embodiment, since the energization maintaining time of the electric motor 13 in the motor overheat protection mode is made shorter than that in the normal mode to reduce the duty ratio of the electric motor 13, the entire unlocking operation time is shortened. It is possible to suppress the heat generation of the electric motor 13 without impairing the responsiveness to the driver.

  By the way, although the torque of the electric motor 13 generally decreases as the temperature rises, in the present embodiment, in the motor overheat protection mode, the energization maintaining time is shortened, and the electric motor 13 is operated when the temperature is lower and the torque is higher. Since the lock bolt 7 is moved from the locked position to the unlocked position by actuating 13 and performing this operation a plurality of times, the unlocking process can be performed efficiently.

  Further, in the electric steering lock device 1 according to the present embodiment, the energization maintaining time in the motor overheat protection mode is set shorter than the unlock guarantee energization time, so that the lock bolt 7 is unlocked in one unlock process. Although it may not be possible to move to the position, the responsiveness to the driver by shortening the unlocking operation time (for example, warning such as unlock failure after the driver operates the engine ON / OFF switch) Time) is not lost, and the lock bolt 7 can be reliably moved to the unlock position by the driver's multiple unlocking operations without causing the driver to feel uncomfortable.

  Furthermore, in this embodiment, since the unlock operation time in the motor overheat protection mode is made the same as that in the normal mode, the response time for the driver can be made constant, and the driver feels uncomfortable. There is nothing.

  In this embodiment, the energization maintaining time (normal mode) is 0.1 seconds, the energization maintaining time (motor overheat protection mode) is 0.5 seconds, the unlocking operation time is 2.5 seconds, and unlocking is guaranteed. Although the energization time is set as 1.0 second, this is just an example and is not limited to this value. For example, the energization maintenance time (motor overheat protection mode) and the unlock operation time The temperature of the electric motor 13 exceeds the predetermined value even when the duty ratio of the electric motor 13 calculated from the energization maintaining time (motor overheat protection mode) and the unlocking operation time is repeatedly subjected to the unlocking process. As long as the upper limit duty ratio calculated by a test or the like is not exceeded, it can be arbitrarily set.

  In the present embodiment, the host ECU 19 is configured so that the timer for setting the unlock operation time starts counting simultaneously with the power supply to the microcomputer 22, but is not limited to this. For example, the transmission of the unlock operation signal to the microcomputer 22 is set as “start of the unlock process”, and the count of the timer for setting the unlock operation time is started simultaneously with the transmission of the unlock operation signal to the microcomputer 22. May be. In this case, if the host ECU 19 detects the operation of the engine ON / OFF switch by the driver during the unlock operation time (2.5 seconds) from the start of the timer, the unlock operation time (2, 5 It may be configured to wait until the second (second) elapses and to return the unlock operation signal to the microcomputer 22 after the unlock operation time (2.5 seconds) has elapsed.

  Furthermore, in this embodiment, when “unlock process failure” occurs twice in the previous unlock process, the next unlock process is shifted to the motor overheat protection mode. However, the present invention is not limited to this. For example, an attack may be made so as to shift to the motor overheat protection mode by one “unlock process failure” just before, or three or more times immediately before. It may be configured to shift to the motor overheat protection mode due to “unlock processing failure”. Further, the present invention is not limited to the case where “unlock process failure” continues, but may be configured to shift to the motor overheat protection mode when a predetermined number of “unlock process failures” occur within a predetermined time.

DESCRIPTION OF SYMBOLS 1 Electric steering lock device 2 Housing 2A Housing lock member storage portion 2B Housing substrate storage portion 2C Housing communication portion 3 Case 3a Case recess 3b Case lock bolt insertion hole 3c Case engagement groove 4 Lid 4a Lid gear Holding cylinder 4b Lid spring holder 5 Locking member 6 Driver 6A Driver arm 6B Driver detent 6a Driver male thread 6b Driver partition 6c Driver magnet housing 7 Lock bolt 7a Lock bolt slot 8 Pin DESCRIPTION OF SYMBOLS 9 Spring 10 Magnet 11 Gear member 11a Worm gear 11b of gear member Female thread part of gear member 12 Spring 13 Electric motor 13a Output shaft of electric motor 14 Worm 15 Substrate 16, 17 Hall element 18 ECU
19 Host ECU
DESCRIPTION OF SYMBOLS 20 Battery 21 Motor drive control part 22 Microcomputer 23 1st switch part 24 2nd switch part 25 Lock relay 26 Unlock relay 27 Lock relay drive circuit 28 Unlock relay drive circuit 29 Position detection circuit (LOCK)
30 Position detection circuit (UNLOCK)
31 memory means 32 timer means 33 communication circuit 34 constant voltage circuit 35 reset circuit 36 IG relay

Claims (4)

A lock bolt movable between a lock position for engaging with a steering shaft of the vehicle and an unlock position for releasing the engagement;
An electric motor for moving the lock bolt;
Control means for controlling energization to the electric motor to perform lock / unlock processing;
Position detecting means electrically connected to the control means and capable of detecting that at least the lock bolt is in the unlock position;
In the electric steering lock device with
The control means includes
Control the electric motor based on the energization maintaining time for energizing the electric motor set in advance and the energization pause time for de-energizing to perform the unlocking process in the normal mode,
If it is not possible to detect the movement of the lock bolt to the unlock position despite receiving the unlock command from the driver and performing the unlock process in the normal mode, the next unlock from the driver is performed. The energization maintaining time is set to the energization maintaining time in the normal mode so that the duty ratio calculated from the energization maintaining time and the energization stop time is smaller than the duty ratio in the normal mode. An electric steering lock device that switches to a motor overheat protection mode that is set shorter than a maintenance time.   The energization maintaining time in the motor overheat protection mode is set shorter than an unlock guarantee energization time for guaranteeing movement of the lock bolt from a lock position to an unlock position under a predetermined condition. The electric steering lock device according to claim 1.   The energization stop time in the motor overheat protection mode is set so that the unlock operation time composed of the energization maintenance time and the energization stop time is the same in the normal mode and in the motor overheat protection mode. The electric steering lock device according to claim 1 or 2. The control means executes a lock / unlock process by controlling energization of the electric motor when receiving a lock / unlock operation signal from the host ECU and a lock / unlock operation signal from the host ECU. The energization maintenance time is controlled by the microcomputer, and the energization stop time is controlled by the host ECU,
The upper ECU waits until the unlock operation time elapses when the unlock command is received within a predetermined unlock operation time after starting the unlock process, and the unlock operation time elapses. The electric steering lock device according to any one of claims 1 to 3, wherein the energization stop time is set by starting an unlocking process later.

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