JP3096793B2 - Electric power steering device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electric power steering apparatus for assisting a steering operation with electric power.

[0002]

2. Description of the Related Art A vehicle speed detector detects a vehicle speed.
A steering torque applied to the steering wheel is detected by a torque detector, and when the detected torque exceeds a predetermined dead zone, a drive current determined according to the detected torque and the detected vehicle speed is passed to a steering assist motor. There has been developed an electric power steering device that drives the motor, assists the force required for steering the vehicle by its rotational force, and provides the driver with a light steering feeling.

[0003] The control of the steering assist force is performed based on the calculation result of a control unit such as a CPU. In order to guarantee the safety of the system against abnormal operation such as runaway of the control unit, for example, the CPU is controlled by each CPU. Main CPU and sub with separate power circuit
Conventionally, a dual system with a CPU has been proposed.

In an electric power steering apparatus having a dual CPU, a main CPU obtains a drive current value of a motor based on a detected torque and a detected vehicle speed, and controls a steering assist force based on the current value. By performing the same arithmetic processing as the main CPU, and comparing the arithmetic processing result with the arithmetic processing result of the main CPU, the input / output of the main CPU is monitored, and the abnormality of the main CPU is detected. . When the sub CPU detects an abnormality in the main CPU, the sub CPU
U performs stop control of the motor, fail-safe control for ensuring the safety of the system, and the like.

[0005] In the electric power steering apparatus having a dual CPU as described above, basically, the main CPU controls the steering assist force and the sub CPU monitors the main CPU. Watchdog pulse communication is performed between the main CPU and sub CPU, and one CPU
By monitoring the CPU watchdog pulse,
Each CPU monitors each other's operation status.

[0006]

However, in the conventional electric power steering apparatus as described above, since the main CPU and the sub CPU that perform watchdog pulse communication have separate power supply circuits, the power supply voltage is low. If they differ, one CPU may cause the other CPU to latch up. For this reason, CPUs with separate power supply circuits
The conventional electric power steering apparatus having a heavy system has a problem that the operation becomes unstable.

[0007] The present invention has been made in view of such circumstances, and has as its object to provide an electric power steering device that enables a dual control unit to perform stable operation.

[0008]

An electric power steering apparatus according to the present invention is an electric power steering apparatus having two control units for steering assist control which communicate with each other. A power supply; means for detecting an overvoltage of the power supply; and means respectively connected to the two control units and resetting operation of the control units for a predetermined time after activation of the respective control units. And

[0009]

According to the present invention, since the power supplies of the two control units are common and the power supply voltages of the two control units are equal, one of the control units is connected to the other in connection with communication between the control units. There is no fear that latch-up may occur in the control unit of the first embodiment. Further, if the voltage of the power supply becomes excessive, it is detected, so that it is possible to perform predetermined control such as fail-safe control based on the detection result. Further, means for resetting the operation of the control unit for a predetermined time after the activation of the control unit is provided.
Since the two control units are separately connected to each other, there is no danger that two CPUs will run away simultaneously due to the failure of one reset circuit. With such a configuration, the two control units operate stably.

[0010]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an electric power steering apparatus according to the present invention (hereinafter referred to as the present invention apparatus) will be specifically described with reference to the drawings showing the embodiments.

FIG. 1 is a block diagram showing a steering assist motor of an electric power steering apparatus according to the present invention and a control system of a clutch for transmitting the power to a steering wheel. 1 in the figure
Is a main CPU which is a first control unit for performing steering assist control;
Denotes a sub CPU which is also a second control unit, 3 denotes a torque detector, 4 denotes a vehicle speed detector, 7 denotes a motor for assisting steering, and 8 denotes a clutch for connecting and disconnecting between the motor 7 and the steering wheel. ing.

The power supply terminals of the main CPU 1 and the sub CPU 2 are supplied with a drive power supply voltage V _CC from a constant power supply circuit 10. Further, the main CPU 1 and the sub CPU 2 read the detected torque from the torque detector 3 via the interface 5 and the detected vehicle speed from the vehicle speed detector 4 via the interface 6, respectively, and perform arithmetic processing based on these, not shown. The motor drive circuit 19 controls the drive current of the motor 7 and the forward and reverse rotation directions of the motor 7 through a control line.

Each of 13, 14 to 16 is a two-input AND gate. The output of the excessive monitoring circuit 11 is input to one input terminal of the AND gate 13 via the inverting element 12, and the output signal of the AND gate 14 is input to the other input terminal. Is a fail-safe relay 18
It is connected to the.

A signal from the main CPU 1 is inputted to one input terminal of each of the AND gates 14 to 16, and a signal from the sub CPU 2 is inputted to each other input terminal. The output terminal of the AND gate 14 is connected to one input terminal of the AND gate 13, the output terminal of the AND gate 15 is connected to the motor drive circuit 19 of the motor 7, and the output terminal of the AND gate 16 is connected to the clutch drive circuit of the clutch 8. 21 each connected.

The main CPU 1 and the sub CPU 2 monitor each other's watchdog pulse signal WDP, and output a high-level signal to each of the AND gates 14, 15 and 16 when it is determined that they are normal. As a result, the excessive monitoring circuit 11
When it is determined that the voltage supplied from the constant power supply circuit 10 is not excessive, the fail-safe relay 18 is turned on, and power is supplied from the power supply 17 to the motor drive circuit 19 and the clutch drive circuit 21. Become. Further, the AND gate 15 is turned on, the motor drive circuit 19 is operated, the motor 7 is controlled to be driven based on the control signals from the main CPU 1 and the sub CPU 2, and the AND gate 16 is turned on, and the clutch is turned on. The drive circuit 21 is activated, and the clutch 8 is engaged.

The voltage of the constant power supply circuit 10 is the same as that of the main CPU 1 described above.
And a first power-on reset circuit 23 for performing a power-on reset of the sub CPU 2 and the main CPU 1, and a second power-on reset circuit 26 for performing a power-on reset of the sub CPU 2. And an excessive monitoring circuit 11 for monitoring the application of an excessive voltage to the sub CPU 2.

The excessive monitoring circuit 11 outputs a low level signal when the voltage value of the constant power supply circuit 10 does not exceed the predetermined value, and outputs a high level signal when the voltage value of the constant power supply circuit 10 exceeds the predetermined value. It is supposed to.

Motor drive circuit 19, clutch drive circuit 21
Are connected in parallel to a power supply 17 via a fail-safe relay 18, respectively. The motor drive circuit 19 is connected to a current detection circuit 20 for detecting a drive current of the motor 7, and supplies the detected drive current to the main CPU 1 and the sub CPU 2.

The clutch drive circuit 21 includes a clutch 8
A clutch monitoring circuit 22 for detecting the terminal voltage (or driving current of the clutch 8) and monitoring the operating state of the clutch 8 is connected, and the clutch monitoring circuit 22 detects the value of the terminal voltage (or driving current). Engagement of the clutch 8 based on
Detachment state is judged, and the judgment result is sent to the main CPU 1, sub
It is given to CPU2.

As described above, the main CPU 1 and the sub CPU 2 communicate with each other a watchdog pulse signal WDP for monitoring the operation state of each other. 1. Sub CP
The output from U2 is to the first and second watchdog timers 24 and 25, which are external circuits. From the first power-on reset circuit 23, the first watchdog timer 24 to the main CPU 1 via the AND gate 27, and from the second power-on reset circuit 26, the second watchdog timer 25 to the sub CPU via the AND gate 28. 2, a reset signal RES bar for resetting them is input.

The first watchdog timer 24 has a main CP
The frequency of the watchdog pulse signal WDP output at a predetermined period from U1 is measured, and the measured value of the frequency is compared with a predetermined reference value. When it does not coincide with the high level, that is, when an abnormal state occurs, it becomes low level, and is connected to each input terminal of the AND gate 27 together with the output of the first power-on reset circuit 23. The output terminal is connected to a terminal of the main CPU 1 and supplies a reset signal RES to this terminal.

The first power-on reset circuit 23 is
This circuit is intended to prevent abnormal operation when the main CPU 1 is started by resetting the operation of the main CPU 1 until the oscillator of the main CPU 1 starts normal operation when the CPU 1 starts. After the voltage of the constant power supply circuit 10 rises to the rated value, the output signal is at a low level until a predetermined time elapses, and the output signal is at a high level after the predetermined time elapses. .

On the other hand, the second watchdog timer 25
The frequency of the watchdog pulse signal WDP output from the CPU 2 at a predetermined cycle is measured, and the measured value of the frequency is compared with a predetermined reference value. When it does not coincide with the high level, that is, when an abnormal state occurs, it is set to the low level. The output is connected to each input terminal of the AND gate 28 together with the output of the second power-on reset circuit 26. The output terminal is connected to the terminal of the sub CPU 2 and supplies a reset signal RES to this terminal.

The second power-on reset circuit 26 includes a sub-CP
This circuit is intended to prevent abnormal operation when the sub CPU 2 starts by resetting the operation of the sub CPU 2 until the oscillator of the sub CPU 2 starts normal operation when the U 2 starts. Thus, the output signal is at a low level until a predetermined time elapses after the voltage of the constant power supply circuit 10 has risen to the rated value, and the output signal is at a high level after the predetermined time elapses.

Therefore, the output signal of the AND gate 27 is output to the first watchdog timer 24 or the first power-on reset circuit.
When any of the signals supplied from 23 goes low, the signal goes low, and a reset signal RES bar is applied to the terminal of the main CPU 1. This allows the main CPU 1 to start when the main CPU 1 starts or the main CPU 1 1 is reset when the watchdog pulse signal WDP is abnormal,
The signals applied to the AND gates 14 to 16 become low level.

The output signal of the AND gate 28 is supplied to the second watchdog timer 25 or the second power-on reset circuit.
When any one of the signals supplied from 26 goes low, the signal goes low, and a reset signal RES bar is applied to the terminal of the sub CPU 2, whereby the sub CP
U2 is reset when the sub CPU 2 is activated or when the watchdog pulse signal WDP of the sub CPU 2 is abnormal, and the signals applied to the AND gates 14 to 16 become low level.

In such an electric power steering apparatus, the first watchdog timer 24 and the second watchdog timer 25 output the watchdog pulse signals WDP output from the main CPU 1 and the sub CPU 2 respectively. When the watchdog pulse signal WDP becomes abnormal, a low-level signal is output, and the first power-on reset circuit 23 and the second power-on reset circuit 26 operate when the main CPU 1 and the sub CPU 2 rise. A low level signal is output until the voltage from the constant power supply circuit 10 rises to the rated value and stabilizes, and a reset signal RES bar is applied to the terminals of the main CPU 1 and the sub CPU 2 via AND gates 27 and 28, respectively. And reset the main CPU 1 and sub CPU 2.

As a result, the outputs from the main CPU 1 and the sub CPU 2 to the AND gates 14 to 16 become low level. As a result, the fail safe relay 18 is turned off, and the motor drive circuit 19 and the clutch drive circuit 21 are turned off. The operating state is established, the motor 7 stops, the clutch 8 is disengaged, and no steering assist force is output, that is, the steering assist is prohibited.

If the excessive monitoring circuit 11 determines that the voltage from the constant power supply circuit 10 is excessive, the output from the excessive monitoring circuit 11 goes to a high level. 18 is turned off, the motor 7 is similarly stopped, and the clutch 8 is disengaged.

In the above-described embodiment, the case where the fail-safe relay 18 is turned off and the motor drive circuit 19 and the clutch drive circuit 21 are simultaneously turned off is described. Only the motor 7 is stopped in the non-operation state, only the clutch 8 is disengaged in the non-operation state of the clutch drive circuit 21, and only the fail-safe relay 18 is turned off to stop the motor 7.
Of course, the disengagement of the clutch 8 may be performed simultaneously.

The characteristic components of the apparatus of the present invention as described above are that the power supply (constant power supply circuit 10) of the main CPU 1 and the sub CPU 2 is shared, and that the main CPU 1 and the sub CPU 2 respectively. A power-on reset circuit (first power-on reset circuit 23, second power-on reset circuit 2
6) is connected, and the main CPU 1 and sub CPU
That is, the excessive monitoring circuit 11 is connected to the constant power supply circuit 10 as the second power supply.

Due to such features, the device of the present invention has the following advantages. Main CPU 1 and sub CPU
Since the two power supplies are shared, the phenomenon that one CPU causes latch-up of the other CPU due to the difference in power supply voltage is eliminated, and the number of power supply circuits can be reduced as compared with the conventional one, reducing manufacturing costs. it can. Since the power-on reset circuit is connected to each of the main CPU 1 and the sub CPU 2, even if one reset circuit fails, the two CPUs do not run out of control at the same time, ensuring safety. it can. Excessive monitoring circuit for constant power supply circuit 10
11 is provided, the main
Even if CPU 1 and sub CPU 2 run away at the same time,
The failsafe relay can be turned off to secure the system.

[0033]

As described in detail above, in the present invention, 2
Since the power supplies of the two control units are common and the power supply voltages of the two control units are equal, there is a possibility that one control unit may cause latch-up of the other control unit in connection with communication between the control units. When the voltage of the power supply becomes excessive, the state is detected, so that it is possible to perform predetermined control such as fail-safe control based on the detection result. Since the means for resetting the operation of the control unit for a predetermined time after startup is connected to each of the two control units, even if one reset circuit fails, the two CPUs do not run away at the same time and safety is ensured The present invention has excellent effects, for example, it is possible to secure

[Brief description of the drawings]

FIG. 1 is a block diagram showing a configuration of an electric power steering device according to the present invention.

[Explanation of symbols]

 1 Main CPU 2 Sub CPU 10 Constant power supply circuit 11 Excessive monitoring circuit 23 First power-on reset circuit 26 Second power-on reset circuit

──────────────────────────────────────────────────続 き Continuation of the front page (56) References JP-A-2-249762 (JP, A) JP-A-3-121974 (JP, A) JP-A-63-180562 (JP, A) (58) Field (Int.Cl. ⁷ , DB name) B62D 5/04 B62D 6/00

Claims (1)

(57) [Claims] 1. An electric power steering apparatus comprising two control units for steering assist control that communicate with each other, comprising: a common power supply for the two control units; a unit for detecting an overvoltage of the power supply; An electric power steering device comprising: means connected to each of the two control units; and means for resetting the operation of the control units for a predetermined time after the activation of each control unit.