The present invention relates to a motor control device, and a brake fluid pressure control device for a vehicle.
Conventionally, there is a known motor control technique that uses a PWM (Pulse Width Modulation) signal to modulate a pulse width (see, for example, Patent Literature Document 1, FIG. 3).
In Patent Literature Document 1, when electricity is fed to a motor, voltage control is performed using a full operation process (full operation time TanstMax) and a cyclic operation process with a PWM signal (period TTakt).
In the meantime, the PWM control may suffer from increased generation of heat because, for example, fast switching is required between ON and OFF during the low rotational speed control with high frequency, and an amount of loss increases so that loads applied on FET (Field Effect Transistors) increase.
An object of the present invention is to provide a motor control device that is equipped with a technology for performing low rotational speed control on the motor while suppressing generation of heat, and provide a brake fluid pressure control device for a vehicle equipped with such technology.
The invention according to claim 1 is directed to a motor control device that includes a drive control device configured to perform an ON/OFF control on a motor, and a voltage obtaining device configured to obtain a voltage across terminals of the motor. The drive control device is configured such that when a motor drive signal of the motor is OFF and the voltage across the terminals of the motor, which is obtained by the voltage obtaining device, has dropped and reached a target voltage, the drive control device sets an immediately following ON time based on an OFF time, which is time from when the motor drive signal is made OFF to when the target voltage is reached, and switches the motor drive signal to ON from OFF. The drive control device is also configured to switch the motor drive signal to OFF from ON when the ON time has elapsed upon switching of the motor drive signal to ON from OFF.
The invention according to claim 2 is directed to the motor control device of claim 1, wherein as the OFF time becomes longer, the immediately following ON time is set to be shorter than when the OFF time is short. A sum of the OFF time and the immediately following ON time, which is one-period-equivalent time, is set to be longer than when the OFF time is short.
The invention according to claim 3 includes a main body that has a fluid pressure circuit therein, a motor attached to the main body, a motor control device according to claim 1 configured to control the motor, and a control valve means configured to control the fluid pressure circuit.
In the invention of claim 1, when the voltage across the terminals of the motor, which is obtained by the voltage obtaining device, has dropped and reached the target voltage, the drive control device sets the immediately following ON time on the basis of the OFF time, which is from when the motor drive signal is made OFF to when the target voltage is reached, and switches the motor drive signal to ON from OFF. The drive control device switches the motor drive signal to OFF when the ON time has elapsed. Unlike the cyclic control (PWM control) of the prior art, the drive control device performs the ON/OFF control with the target voltage of when the voltage across the terminals of the motor has dropped, and with the ON time based on the immediately preceding OFF time with reference to, for example, a time setting map. Therefore, it is possible to carry out the low-rotational-speed control on the motor while suppressing heat generation.
In the invention of claim 2, as the OFF time becomes longer, the immediately following ON time is set to be shorter. Also, a sum of the OFF time and the immediately following ON time, which is one-period-equivalent time, becomes longer than when the OFF time is short. Accordingly, the OFF time becomes longer and the ON time becomes shorter as the rotational speed of the motor becomes lower, for example. Also, a sum of the OFF time and the immediately following ON time, which is one-period-equivalent time, becomes longer. Therefore, it is possible to drive the motor with appropriate actuation time (drive time) in accordance with the rotational speed of the motor.
The invention of claim 3 includes a main body that has a fluid pressure circuit therein, a motor attached to the main body, a motor control device configured to control the motor, and a control valve means configured to control the fluid pressure circuit. Therefore, it is possible to reduce the operation noises and vibrations of the motor and pumps, which are driven (actuated) by the motor, in the brake fluid pressure control device for a vehicle, thereby improving the qualities of the product. When the fluid pressure is high at the pump discharge end, for example, during the fluid pressure control, greater loads act on the motor than when the fluid pressure is low, and the voltage across the terminals drops faster upon switching of the drive signal to OFF from ON. Thus, the OFF time becomes shorter. However, if the OFF time is short, the immediately following ON time is set to be long. Therefore, it is possible to sufficiently increase the motor rotational speed after switching the drive signal to ON, and appropriately drive the motor in accordance with the fluid pressure.
An embodiment of the present invention will be described below with reference to the accompanying drawings.
As shown in
The fluid pressure unit 50 includes the first master cylinder 12 to pressurize a working fluid in response to an operation of a brake lever 11 and generate fluid pressure, a first reservoir 13 to temporarily reserve the working fluid that is released from the front wheel brake 14, a first inlet control valve 15 (control valve means of the present invention), which is a normally open solenoid valve disposed on a fluid pressure passage from the first master cylinder 12 to the front wheel brake 14, a first outlet control valve 16 (control valve means of the present invention), which is a normally closed solenoid valve disposed on the fluid pressure passage from the first master cylinder 12 to the front wheel brake 14, and a first pump 17 to receive the working fluid from the first reservoir 13 and return it toward the first master cylinder 12.
The fluid pressure unit 50 also includes the second master cylinder 22 to pressurize the working fluid in response to an operation of a brake pedal 21 and generate fluid pressure, a second reservoir 23 to temporarily reserve the working fluid that is released from the rear wheel brake 24, a second inlet control valve 25 (control valve means of the present invention), which is a normally open solenoid valve disposed on a fluid pressure passage from the second master cylinder 22 to the rear wheel brake 24, a second outlet control valve 26 (control valve means of the present invention), which is a normally closed solenoid valve disposed on the fluid pressure passage from the second master cylinder 22 to the rear wheel brake 24, a second pump 27 to receive the working fluid from the second reservoir 23 and return it toward the second master cylinder 22, and a motor 28 to actuate the first pump 17 and the second pump 27.
The brake fluid pressure control device for a vehicle 10 also includes a drive control device 32 to control opening and closing of the first and second inlet control valves 15 and 25 and opening and closing of the first and second outlet control valves 16 and 26, and a voltage obtaining device 33 to obtain a voltage across terminals of the motor. The drive control device 32 and the voltage obtaining device 33 constitute, in combination, the control device 30 (will be described later in detail).
A fluid pressure circuit 20a having the above-described configuration is formed in a main body 20. The motor 28 is attached to (or arranged in) the main body 20. The control device 30 controls the valves 15, 16, 25 and 26 of the fluid pressure circuit 20a.
Now, the operations and functions of the brake fluid pressure control device for a vehicle 10 will be described. It should be noted that the operations and functions of a first system from the brake lever 11 to the front wheel brake 14 are the same as those of a second system from the brake pedal 21 to the rear wheel brake 24. Thus, the first system will only be described.
Firstly, fundamental operations during normal braking and ABS (Antilock Braking System) control will be described. The brake fluid pressure control device for a vehicle 10 has a function to switch between a normal state during the normal braking and states (reduced-pressure state, a holding state, and an increased-pressure state) during the ABS control.
During the normal braking: in the normal state (i.e., when no current is fed to the first inlet control valve 15 and the first outlet control valve 16), the master cylinder 12 communicates with the front wheel brake 14 (the first inlet control valve 15 is open), and the front wheel brake 14 is disconnected from the reservoir 13 (the first outlet control valve 16 is closed). As the brake lever 11 is manipulated, the working fluid pressure is applied to the front wheel brake 14 from the master cylinder 12 through the first inlet control valve 15 to brake the wheel.
During the ABS control; when the vehicle's wheel is about to lock, the control device 30 switches among the reduced-pressure state, the holding state and the increased-pressure state so as to perform the ABS control.
In the reduced-pressure state of the ABS control, a current flows to the first inlet control valve 15 and the second outlet control valve 16 such that the master cylinder 12 is disconnected from the front wheel brake 14 (first inlet control valve 15 is closed), and the front wheel brake 14 communicates with the reservoir 13 (first outlet control valve 16 is open). The working fluid flowing to the front wheel brake 14 is released to the reservoir 13 through the first outlet control valve 16, and therefore the working fluid pressure acting on the front wheel brake 14 is reduced.
In the holding state of the ABS control, the current flows to the first inlet control valve 15 only, the master cylinder 12 is disconnected from the front wheel brake 14, and the front wheel brake 14 is disconnected from the reservoir 13 (the first inlet control valve 15 and the first outlet control valve 16 are closed). The working fluid is confined in the fluid passage closed by the front wheel brake 14, the first inlet control valve 15 and the first outlet control valve 16, and the working fluid pressure acting on the wheel brake is maintained at a constant value.
In the increased-pressure state of the ABS control, the feeding of the current to the first inlet control valve 15 and the first outlet control valve 16 is halted, the master cylinder 12 communicates with the front wheel brake 14 (the first inlet control valve 15 is open), and the front wheel brake 14 is disconnected from the reservoir 13 (the first outlet control valve 16 is closed).
As a result, the fluid pressure of the front wheel brake 14 is increased by the working fluid pressure from the first master cylinder 12. During the ABS control, the control device 30 activates the motor 28 so that the first pump 17 is activated. Accordingly, the working fluid, which is temporarily reserved in the reservoir 13, is caused to return toward the first master cylinder 12.
A block diagram of the control device 30 will now be described.
The control device 30 has the drive control device 32 to control the opening and closing of the first and second inlet control valves 15 and 25, and perform the ON/OFF control on the motor 28 (to control turning on and off of the motor 28), and also has the voltage obtaining device 33 to obtain a voltage across the terminals of the motor 28.
Next, the motor drive control of the control device 30 will be described.
Subsequently, the motor drive signal is switched to OFF from ON at the time t3 when the ON time Ton1 has elapsed. Then, the voltage VM across the terminals of the motor 28 gradually drops again. Eventually, the voltage VM across the terminals reaches the target voltage VT at the time t4 when the time Toff2 has elapsed. It should be noted that the dropping speed (OFF time) of the voltage VM across the terminals changes with variations in the outside environment and other factors, and in this embodiment we assume that Toff1 is smaller than Toff2. At the time t4, the immediately following ON time Ton2 is set on the basis of the immediately preceding OFF time Toff2, and the motor drive signal is switched to ON from OFF. Then, the motor drive signal is switched to OFF from ON at the time t5 when the ON time Ton2 has elapsed.
A time setting map to set the ON time in accordance with the OFF time will be described below.
As the OFF time Toff becomes longer, a sum of the OFF time Toff and the immediately following ON time Ton, i.e., time equivalent to one period, is set to be longer than when the OFF time Toff is short.
Such time setting map ensures the minimum ON time even if the pressure of the master cylinder 12 is low. For example, if the fluid pressure on the pump discharge end is high during the fluid pressure control, a larger load acts on the motor than when the fluid pressure is low. Thus, the voltage across the terminals also quickly drops after the drive signal is switched to OFF from ON, and the OFF time becomes shorter. However, as the OFF time becomes shorter, the immediately following ON time is set to be longer. Accordingly, it is possible to sufficiently increase the motor rotational speed upon switching to ON, and it is possible to appropriately drive the motor depending upon the fluid pressure.
The control executed by the above-described brake fluid pressure control device for a vehicle 10 will be described below with reference to the flowchart. The motor actuation starts when, for example, the motor actuation conditions are met during the fluid pressure control, and the processing shown in
As shown in
If it is determined at ST02 that the voltage across the terminals has dropped and reached the target voltage (YES), then the drive control device 32 obtains the time from the time of making the motor drive signal OFF to the time of reaching the target voltage VT (i.e., the immediately preceding OFF time Toff), and sets the ON time Ton on the basis of the immediately preceding OFF time Toff by using the time setting map MP shown in
The above-described control is not the cyclic control (PWM control) of the prior art, but performs the ON/OFF control on the motor drive signal with the target voltage when the voltage across the terminals of the motor 28 drops, and with the ON time Ton based on the immediately preceding OFF time Toff with reference to the time setting map stored in the drive control device 32. In other words, because the above-described control detects the lower limit (target voltage) of the voltage across the terminals, and sets the ON time Ton on the basis of the immediately preceding OFF time Toff, it is possible to perform the low rotational speed control on the motor while suppressing generation of the heat as much as possible.
In addition, it is possible to reduce the operation noises and vibrations of the motor 28 and the pumps 17 and 27, which are driven by the motor 28, in the brake fluid pressure control device for a vehicle 10 equipped with the control device 30 configured to perform the above-described control. Thus, it is possible to improve the qualities of the product. When the fluid pressure is high at the pump discharge end, for example, during the fluid pressure control, greater loads act on the motor than when the fluid pressure is low, and the voltage across the terminals drops faster upon switching of the drive signal to OFF from ON. Accordingly, the OFF time becomes shorter. However, if the OFF time is short, the immediately following ON time is set to be long. Thus, it is possible to sufficiently increase the motor rotational speed after switching the drive signal to ON, and appropriately drive the motor in accordance with the fluid pressure.
It should be noted that although the embodiment has described an example in which the brake fluid pressure control device for a vehicle is applied to a motorcycle, a vehicle equipped with the brake fluid pressure control device for a vehicle is not limited to the motorcycle.
The present invention is advantageously applied to the brake fluid pressure control device mounted on the motorcycle.
Number | Date | Country | Kind |
---|---|---|---|
JP2016-073541 | Mar 2016 | JP | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/JP2017/007925 | 2/28/2017 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2017/169474 | 10/5/2017 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
5487593 | Potts | Jan 1996 | A |
5704766 | Fennel | Jan 1998 | A |
6188947 | Zhan | Feb 2001 | B1 |
6299260 | Hachtel | Oct 2001 | B1 |
6315369 | Hirose | Nov 2001 | B1 |
6499813 | Wandel | Dec 2002 | B1 |
7021725 | Kokubo | Apr 2006 | B2 |
7644995 | Haller | Jan 2010 | B2 |
8746810 | Atsushi | Jun 2014 | B2 |
20030091343 | Chen | May 2003 | A1 |
20050069418 | Kokubo | Mar 2005 | A1 |
20120112524 | Shibata | May 2012 | A1 |
20140060038 | Nomura | Mar 2014 | A1 |
Number | Date | Country |
---|---|---|
2001-225734 | Aug 2001 | JP |
2002-506406 | Feb 2002 | JP |
2005-096613 | Apr 2005 | JP |
2005-96613 | Apr 2005 | JP |
2006-256413 | Sep 2006 | JP |
2006-256413 | Sep 2006 | JP |
2008-006901 | Jan 2017 | JP |
Entry |
---|
Australian First Examination Report dated Mar. 6, 2019, 3 pages. |
European Search Report dated Oct. 23, 2019, 6 pages. |
International Search Report, dated May 16, 2017 (May 16, 2017), 2 pages. |
Number | Date | Country | |
---|---|---|---|
20190092296 A1 | Mar 2019 | US |