JP2005009639A - Braking device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a brake device capable of reducing the influence caused by the difference in temperature conditions, and being effectively used under environment temperature of a wide range. <P>SOLUTION: This brake device has an electric caliper 10 including a thrust mechanism 105 for pressing brake pads 14, 15 to a disc rotor 11, and an electric actuator 19 for driving the thrust mechanism 105, and a control means 100 for controlling the braking force by supplying the electric current based on a brake command signal to the electric actuator 19. The control means 100 calculates a coefficient of viscosity of the thrust mechanism 105, and adjusts a value of electric current supplied to the electric actuator 19 on the basis of the brake command signal, on the basis of the coefficient of viscosity. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an electric brake device used for braking a vehicle.
[0002]
[Prior art]
As an electric brake device used for braking a vehicle, an electric caliper that includes a thrust mechanism that presses a brake pad against a disc rotor and an electric actuator that drives the thrust mechanism, and an electric current corresponding to a braking instruction signal are electrically driven. Some have control means for controlling the braking force supplied to the actuator (see, for example, Patent Document 1).
[0003]
[Patent Document 1]
JP 2003-14018 A
[0004]
[Problems to be solved by the invention]
By the way, it is assumed that the brake device for a vehicle is used under a wide range of environmental temperatures from low temperature to high temperature. For example, the viscosity change of the lubricant enclosed in the thrust mechanism is caused by the difference in temperature conditions. There is not a little influence such as.
[0005]
Therefore, an object of the present invention is to provide a brake device that can reduce the influence due to the difference in temperature conditions and, as a result, can be used well under a wide range of environmental temperatures.
[0006]
[Means for Solving the Problems]
In order to achieve the above object, an invention according to claim 1 is directed to an electric caliper that includes a thrust mechanism that presses a brake pad against a disc rotor and an electric actuator that drives the thrust mechanism, and a current corresponding to a braking instruction signal. And a control unit that controls the braking force supplied to the electric actuator, wherein the control unit calculates a viscosity coefficient of the thrust mechanism and supplies the electric actuator to the electric actuator according to the braking instruction signal. It has the electric current value adjustment means which adjusts a value according to the said viscosity coefficient, It is characterized by the above-mentioned.
[0007]
As a result, the current value adjusting means calculates the viscosity coefficient of the thrust mechanism that presses the brake pad against the disc rotor, and sets the current value according to the braking instruction signal supplied to the electric actuator that drives the thrust mechanism to the difference in temperature condition. Since the adjustment is made according to the viscosity coefficient that is easily influenced by the temperature, the influence due to the difference in temperature condition can be reduced.
[0008]
According to a second aspect of the present invention, in the first aspect of the present invention, the electric caliper is provided with position detecting means for detecting a movement position of the brake pad by the thrust mechanism, and the current value adjusting means is The thrust mechanism is driven at a constant speed within a range in which the brake pad does not press the disk rotor based on the output of the position detection means, and the viscosity coefficient of the thrust mechanism is based on the current value to the electric actuator at the time of the driving. Viscosity coefficient estimating means for calculating
[0009]
Thus, the viscosity coefficient estimating means drives the thrust mechanism at a constant speed within a range in which the brake pad does not press the disc rotor based on the output of the position detecting means for detecting the moving position of the brake pad by the thrust mechanism. Since the viscosity coefficient of the thrust mechanism is calculated based on the current value to the electric actuator at the time, the viscosity coefficient can be calculated more accurately. Therefore, since the current value according to the braking instruction signal supplied to the electric actuator is adjusted according to the viscosity coefficient calculated more accurately, the influence due to the difference in temperature condition can be reliably reduced.
[0010]
The invention according to claim 3 is the invention according to claim 2, wherein the viscosity coefficient estimating means drives the thrust mechanism by switching to a plurality of different constant speeds, and the current value to the electric actuator at each driving time And the viscosity coefficient of the thrust mechanism is calculated based on the constant speed and the current value at the time of each drive.
[0011]
Thus, the viscosity coefficient estimating means switches the thrust mechanism to a plurality of different constant speeds within a range in which the brake pad does not press the disc rotor, based on the output of the position detecting means for detecting the moving position of the brake pad by the thrust mechanism. It drives, detects the current value to the electric actuator at the time of each drive, and calculates the viscosity coefficient of the thrust mechanism based on each constant speed and each current value, so that the viscosity coefficient can be calculated more accurately. Therefore, since the current value according to the braking instruction signal supplied to the electric actuator is adjusted according to the viscosity coefficient calculated more accurately, the influence due to the difference in temperature condition can be further reliably reduced.
[0012]
The invention according to claim 4 is the invention according to claim 2 or 3, wherein the control means has a brake sign detection means for detecting a sign of the addition of the braking force in advance, and the braking force is added by the brake sign detection means. The viscosity coefficient of the thrust mechanism is calculated by the viscosity coefficient estimating means when a sign of this is detected.
[0013]
As a result, the viscosity coefficient of the thrust mechanism is calculated by the viscosity coefficient estimation means when the sign of the braking force detection is detected by the brake sign detection means, so the viscosity coefficient is calculated under conditions close to the time when the braking force is applied. Can do. Therefore, since the current value according to the braking instruction signal supplied to the electric actuator is adjusted with the latest viscosity coefficient at the time when the braking force is applied, for example, the influence when a difference in temperature condition occurs in a short time is reduced. And the influence due to the difference in temperature condition can be reduced more reliably.
[0014]
According to a fifth aspect of the present invention, there is provided an electric caliper including a thrust mechanism that presses a brake pad against a disc rotor, an electric actuator that drives the thrust mechanism, and a position detection unit that detects a moving position of the brake pad by the thrust mechanism. And a control unit that controls a braking force by supplying a current corresponding to a braking instruction signal to the electric actuator, wherein the control unit is configured such that the brake pad is based on an output of the position detecting unit. Current value adjusting means for adjusting a current value corresponding to a braking instruction signal supplied to the electric actuator based on a current value to the electric actuator when the thrust mechanism is driven at a constant speed within a range where the disk rotor is not pressed. It is characterized by having.
[0015]
As a result, the current value adjusting means drives the thrust mechanism at a constant speed within a range in which the brake pad does not press the disk rotor, based on the output of the position detecting means for detecting the movement position of the brake pad by the thrust mechanism. Since the current value according to the braking instruction signal supplied to the electric actuator is adjusted based on the current value to the electric actuator at the time, the influence due to the difference in temperature condition can be surely reduced.
[0016]
DETAILED DESCRIPTION OF THE INVENTION
A brake device according to an embodiment of the present invention will be described below with reference to the drawings.
[0017]
As shown in FIG. 1, the brake device of this embodiment is an electric disc brake device having an electric caliper 10.
[0018]
The electric caliper 10 has a caliper body 12 disposed on one side in the axial direction of a disk rotor 11 that rotates with a wheel (not shown). The caliper body 12 is formed in a substantially C shape and straddles the disk rotor 11. The claw portion 13 extending to the opposite side is integrally coupled. Brake pads 14 and 15 are provided on both sides of the disk rotor 11 in the axial direction. The brake pads 14 and 15 are supported by a carrier 16 fixed on the vehicle body side so as to be movable along the axial direction of the disc rotor 11, and transmit braking torque to the carrier 16. 12 is guided so as to be slidable along the axial direction of the disk rotor 11 by a slide pin (not shown) attached to the carrier 16.
[0019]
A caliper-shaped case 18 is coupled to the caliper body 12, and an electric motor (electric actuator) 19 and a position detector (position detection means) 20 are included in the case 18. On the other hand, the caliper body 12 includes a ball ramp mechanism (rotation-linear motion conversion mechanism) 21 that converts the rotational motion of the electric motor 19 into a linear motion and a differential gear reduction mechanism (deceleration) that amplifies the rotational torque of the electric motor 19. Mechanism) 22 is included. A cover 23 is attached to the rear end of the case 18.
[0020]
The electric motor 19 includes a stator 25 fixed to the inner periphery of the case 18, and a rotor 28 inserted into the stator 25 and rotatably supported by the case 18 by bearings 26 and 27. The position detector 20 includes a resolver stator 29 fixed to the case 18 side and a resolver rotor 30 attached to the rotor 28. Based on the relative rotation of these, the rotational position of the rotor 28 of the electric motor 19 (hereinafter referred to as the motor position). (In other words, the movement positions of the brake pads 14 and 15 are detected).
[0021]
The ball ramp mechanism 21 includes an annular first disk 32 and second disk 33, and a plurality of balls 34 interposed therebetween. The first disk 32 is rotatably supported by the caliper body 12 by a bearing 35, and a cylindrical portion 36 that is inserted into the rotor 28 is integrally formed. A cylindrical sleeve 37 having a smaller diameter than the cylindrical portion 36 is integrally formed on the second disk 33, and the sleeve 37 is inserted into the cylindrical portion 36.
[0022]
For example, three ball grooves 38 and 39 each having an arc shape extending along the circumferential direction are formed on the opposing surfaces of the first disk 32 and the second disk 33 of the ball ramp mechanism 21. These ball grooves 38 and 39 are extended in the range of an equal central angle (for example, 90 °) and inclined in the same direction. Then, a ball 34 is inserted between the ball grooves 38 and 39 formed in the first disk 32 and the second disk 33, and the ball grooves 38 and 39 are moved by the relative rotation of the first disk 32 and the second disk 33. As the ball 34 rolls, the first disk 32 and the second disk 33 are relatively displaced in the axial direction. At this time, when the first disk 32 rotates counterclockwise with respect to the second disk 33, they are displaced in the direction of separating.
[0023]
A piston 40 is provided between the second disk 33 and the brake pad 14. The piston 40 has a cylindrical member 42a in which a screw portion 41 is formed on the outer periphery. The cylindrical member 42a is inserted into the sleeve 37 of the second disk 33 and is screwed into a screw portion 43 formed on the inner periphery thereof. The cylindrical member 42a is fitted with a two-side chamfered portion (not shown) of a shaft 45 attached to the case 18 via a bracket 44, and its rotation is restricted. Further, the piston 40 has a substantially disk-shaped pressing member 42b that is connected to the shaft 45 of the cylindrical member 42a in a state in which the rotation is restricted on the opposite side. A thrust sensor 46 that detects a piston thrust received by the piston 40 is provided between the cylindrical member 42a and the pressing member 42b.
[0024]
The screw portion 41 of the cylindrical member 42 of the piston 40 and the screw portion 43 of the sleeve 37 of the second disk 33 form an irreversible screw, and the piston 40 moves even if a force acts in the axial direction. However, the second disk 33 is moved counterclockwise to move toward the disk rotor 11 side.
[0025]
An elastic member 49 is interposed between spring receivers 47 and 48 formed on the outer peripheral portion of the shaft 45 and the inner peripheral portion of the sleeve 37 of the second disc 33, respectively, and the second disc 33 causes the ball 34 to be It is urged to be sandwiched between one disk 32. The shaft 45 is attached to the bracket 44 by an adjustment screw 50 and a lock nut 51.
[0026]
A controller (control means, current value adjustment means, viscosity coefficient estimation means, brake sign detection means) 100 is connected to the electric motor 19, the position detector 20, and the thrust sensor 46. The controller 100 is connected to a pedal sensor 102 that detects an operation amount of a brake pedal 101 that is operated by a driver according to a braking intention, and a brake switch 103 that detects whether or not the brake pedal 101 is operated. A pedal sensor signal (braking instruction signal) from the pedal sensor 102 and a brake switch signal from the brake switch 103 are input. As the pedal sensor 102, a pressure sensor that detects an operation amount of the brake pedal 101 by pressure, a displacement sensor that detects an operation amount of the brake pedal 101 by displacement, or the like is used.
[0027]
The controller 100 mainly detects the detection result of the pedal sensor 102, that is, the operation amount of the brake pedal 101, the detection result of the position detector 20, that is, the actual piston position corresponding to the rotational position of the electric motor 19, and the current value of the electric motor 19. By controlling the electric motor 19 based on the detection result of the thrust sensor 46, that is, the actual piston thrust, control is performed so that the piston thrust becomes the target thrust.
[0028]
A cylindrical spring holder 67 is attached to the outer periphery of the tip of the sleeve 37 of the second disk 33. One end portion of the spring holder 67 engages with the tip end portion of the cylindrical portion 36 of the first disk 32 to limit the relative rotation thereof to a certain range. A coil spring 69 is wound around the spring holder 67, and the coil spring 69 is twisted with a predetermined set load, one end of which is coupled to the spring holder 67, and the other end of the first disk 32. It is coupled to the cylindrical portion 36 (the coupling portion is not shown).
[0029]
Next, the basic operation of the electric caliper 10 of the brake device of the present embodiment configured as described above will be described.
[0030]
In the non-braking state, the ball 34 of the ball ramp mechanism 21 is at the deepest end of the ball grooves 38 and 39, and the first disk 32 and the second disk 33 are closest. When generating the braking force, the controller 100 rotates the rotor 28 of the electric motor 19 clockwise. Then, the rotational torque of the rotor 28 is amplified by the differential gear reduction mechanism 22 and transmitted to the first disk 32.
[0031]
The rotational force of the first disk 32 is transmitted to the second disk 33 via the coil spring 69. Before the piston 40 presses the brake pads 14 and 15, almost no axial load acts on the piston 40, and the resistance generated in the screw portions 41 and 43 between the piston 40 and the second disk 33 is small. The set load of the coil spring 69 causes the second disk 33 to rotate integrally with the first disk 32, causing relative rotation between the second disk 33 and the piston 40, and the piston 40 is moved by the action of the screw portions 41 and 43. A thrust is generated to move forward toward the disk rotor 11 side.
[0032]
Then, the piston 40 comes into contact with one brake pad 14 and presses it against the disk rotor 11, and the caliper body 12 moves along the slide pin of the carrier 16 by the reaction force, so that the claw portion 13 moves to the other brake. The pad 15 is pressed against the disk rotor 11.
[0033]
After the brake pads 14 and 15 are pressed against the disk rotor 11, a large axial load acts on the piston 40 due to the reaction force, so that the resistance of the screw portions 41 and 43 increases and the coil spring 69 is set. When the load exceeds the load, the rotation of the second disk 33 is stopped. As a result, the coil spring 69 is bent and relative rotation occurs between the first disk 32 and the second disk 33 of the ball ramp mechanism 21. As a result, the ball 34 rolls in the ball grooves 38 and 39 to advance the second disk 33 and the piston 40 together (that is, linear movement), and the piston 40 further pushes the brake pads 14 and 15 against the disk rotor 11. wear.
[0034]
Here, the differential gear reduction mechanism 22 and the ball ramp mechanism 21 that move the piston 40 forward and backward by the rotation of the electric motor 19 as described above constitute the thrust mechanism 105 that presses the brake pads 14 and 15 against the disk rotor 11. A lubricant such as grease is applied to the relative rotating portion of the thrust mechanism 105.
[0035]
In this thrust mechanism 105, since the viscous resistance generated by the lubricant varies greatly depending on the temperature, the electric caliper 10 is reduced in response due to an increase in the viscous resistance at a low temperature, and the electric caliper due to a decrease in the viscous resistance at a high temperature. In this embodiment, in order to reduce the influence of a decrease in the control stability of the controller 10, a controller that mainly controls the braking force by supplying a current corresponding to the pedal sensor signal output from the pedal sensor 102 to the electric motor 19. At 100, an estimated value of the viscosity coefficient of the thrust mechanism 105 is calculated, and control is performed to adjust the current value supplied to the electric motor 19 in accordance with the viscosity coefficient.
[0036]
Next, the control contents of the controller 100 will be described with reference to the flowchart of FIG. The control shown in this flowchart is a process executed at regular control cycles.
[0037]
First, the controller 100 reads a brake switch signal output from the brake switch 103 in step SA1, and the brake pedal 101 is operated and the brake switch 103 is turned on or the brake pedal 101 is not operated and the brake switch 103 is turned off. Judge whether it is. If the brake switch 103 is turned on in step SA1, the process proceeds to step SA2, and if not, the process proceeds to step SA6.
[0038]
In step SA2, a pedal sensor signal output from the pedal sensor 102 is read in order to generate a braking force according to the operation of the brake pedal 101. Then, based on the pedal operation amount that is the operation amount of the brake pedal 101 indicated by the pedal sensor signal, the target piston thrust to be generated in the piston 40 by a preset function is calculated, and then the process proceeds to step SA3.
[0039]
In step SA3, the motor position of the electric motor 19 when the electric motor 19 is driven in the direction in which the piston thrust is generated to move the piston 40 in the direction of the disk rotor 11 and the brake pads 14 and 15 start to contact the disk rotor 11 is determined. A certain pad contact position correction process is performed, and then the process proceeds to step SA4. This correction processing is performed based on the signal of the thrust sensor 46. For example, the motor position of the electric motor 19 detected by the position detector 20 when the signal of the thrust sensor 46 reaches the zero point voltage is padded. For example, it is stored as a contact position.
[0040]
In Step SA4, the current viscosity coefficient of the thrust mechanism 105 stored in the controller 100 is read, and then the process proceeds to Step SA5. This current viscosity coefficient is the one most recently calculated and stored in step SA13 described later. This viscosity coefficient is a parameter that varies depending on the environmental temperature of the electric caliper 10 and is mainly due to the temperature characteristics of the lubricant in the propulsion mechanism 105. As described above, the viscosity coefficient increases at low temperatures and increases the response of the electric caliper 10. Is reduced at a high temperature to cause a decrease in the control stability of the electric caliper 10 and so on, the electric caliper 10 is controlled in accordance with the viscosity coefficient in order to reduce these effects.
[0041]
In Step SA5, the electric power for generating the target piston thrust in the piston 40 from the target piston thrust calculated in Step SA2 and the thrust sensor signal indicating the actual piston thrust of the piston 40 read from the thrust sensor 46 which is a feedback value. A target motor current value (control amount), which is a current value for the motor 19, is calculated, and then the process proceeds to step SA16. The target motor current value for piston thrust control calculated in step SA5 is adjusted according to the viscosity coefficient.
[0042]
The calculation of the current value will be described by taking the case of PID control as an example. When PID control is applied, the controller 100 calculates the proportional gain Kp from the deviation between the target piston thrust and the actual piston thrust as shown in FIG. Then, the integral gain Ki is calculated from the integral value of the deviation between the target piston thrust and the actual piston thrust, and the differential gain Kd is calculated from the differential value of the deviation between the target piston thrust and the actual piston thrust. The control gain K, which is the sum of these, is adjusted according to the viscosity coefficient to obtain a target motor current value for controlling the electric motor 19.
[0043]
Here, according to the control map as shown in FIG. 4, the control motor is adjusted so that the control gain K increases proportionally as the viscosity coefficient increases to obtain the target motor current value. That is, the larger the viscosity coefficient, the larger the viscous resistance in the thrust mechanism 105 and the lower the response of the electric caliper 10, so the control gain K is increased to increase the target motor current value, while the smaller the viscosity coefficient, the thrust mechanism. Since the viscous resistance in 105 is small and the control stability of the electric caliper 10 is lowered, the control gain K is reduced to reduce the target motor current value. In this way, control is performed such that the responsiveness and control stability of the electric caliper 10 that varies depending on the environmental temperature are kept constant.
[0044]
If the brake pedal 101 is not operated in step SA1 and the brake switch 103 is turned off, a throttle switch signal output from a throttle switch (not shown) is read in step SA6, for example, a throttle pedal (not shown) is operated. It is determined whether the throttle switch is turned on or whether the throttle switch is turned off without operating the throttle pedal. In step SA6, if the throttle switch is on, the process proceeds to step SA7, and if not, the process proceeds to step SA8.
[0045]
That is, when it is detected in step SA6 that the throttle switch is turned on, it is estimated that the driver does not operate the brake pedal 101, and the coefficient calculation process for performing the viscosity coefficient calculation process in step SA7. The flag is set and the process proceeds to step SA8.
[0046]
On the other hand, when it is detected in step SA6 that the throttle switch is off, it is estimated that the driver will immediately operate the brake pedal 101 (that is, a sign of the addition of braking force is detected), and the viscosity coefficient is detected. The process proceeds to step SA8 without setting the coefficient calculation process flag for performing the calculation process. In other words, since there are few states in which the driver does not operate either the accelerator pedal or the brake pedal 101, the operation of the brake pedal 101 is not detected in step SA1, and the operation of the throttle pedal is not detected in step SA6. From this, a sign of braking force addition is detected. Here, in addition to the detection of the sign of the addition of the braking force using the throttle switch, in the case of a brake device that applies the braking force and controls the vehicle movement regardless of the driver's operation of the brake pedal 101, this You may perform using the signal of vehicle motion control.
[0047]
In step SA8, if the coefficient calculation process flag is not set, the process proceeds to a process for controlling the motor position of the electric motor 19 after step SA9. If the coefficient calculation process flag is set, the viscosity coefficient after step SA12 is set. The process proceeds to a process for controlling the speed of the electric motor 19 for the calculation of.
[0048]
If the coefficient calculation processing flag is not set in step SA8, in step SA9, the pad contact position obtained in step SA3 is set as the target motor position that is the target motor position of the electric motor 19, and then The process proceeds to step SA10. Here, the target motor position is not the pad contact position itself obtained in step SA3, but a position returned from the pad contact position by a predetermined amount in the piston thrust release direction for moving the piston 40 in the opposite direction with respect to the disk rotor 11. It is also good. In step SA9, the target motor position is set at a position where the brake pads 14, 15 do not press the disc rotor 11.
[0049]
In step SA10, the current viscosity coefficient of the thrust mechanism 105 stored in the controller 100 is read, and then the process proceeds to step SA11. This viscosity coefficient is the one most recently calculated and stored in step SA13 described later.
[0050]
In step SA11, the motor position of the electric motor 19 is determined from the target motor position set in step SA9 and the actual motor position that is the actual motor position of the electric motor 19 read from the position detector 20 that is a feedback value. A target motor current value (control amount) that is a current value for the electric motor 19 for setting the position is calculated, and then the process proceeds to Step SA16. The target motor current value for motor position control calculated in step SA11 is also adjusted according to the viscosity coefficient in the same manner as the target motor current value for piston thrust control calculated in step SA5.
[0051]
If the coefficient calculation processing flag is set in step SA8, the motor speed of the electric motor 19 is calculated in step SA12, and then the process proceeds to step SA13. This motor speed is calculated by differentiating the motor position of the electric motor 19 with respect to time.
[0052]
In step SA13, a viscosity coefficient calculation process for calculating the viscosity coefficient of the thrust mechanism 105 is performed using the motor speed calculated in step SA12 (steps SB1 to SB11 described later), and then the process proceeds to step SA14. Here, when the operation of the accelerator pedal is detected in step SA6, the brake pads 14 and 15 are returned to the positions where the disc rotor 11 is not pressed. Therefore, the operation of the accelerator pedal is detected in step SA6. The viscosity coefficient calculation process of step SA13 that is executed thereafter is executed when the brake pads 14 and 15 are in a range where the disk rotor 11 is not pressed.
[0053]
In step SA14, the viscosity coefficient calculated in the viscosity coefficient calculation process in step SA13 is read, and then the process proceeds to step SA15.
[0054]
In step SA15, a target motor speed (described later) set in the viscosity coefficient calculation process in step SA13 and an actual motor speed that is a time derivative of the actual motor position of the electric motor 19 read from the position detector 20 that is a feedback value. Then, a target motor current value (control amount) that is a current value for the electric motor 19 for setting the motor speed of the electric motor 19 to the target motor speed is calculated, and then the process proceeds to Step SA16. The target motor current value for motor speed control calculated in step SA15 is also adjusted according to the viscosity coefficient in the same manner as the target motor current value for piston thrust control calculated in step SA5.
[0055]
In step SA16, the target motor current value set in the step executed immediately before among step SA5, step SA11, and step SA15 is caused to flow to the electric motor 19.
The above is the control content of the controller 100 executed at a constant control cycle.
[0056]
Next, details of the viscosity coefficient calculation process in step SA13 will be described with reference to the flowchart of FIG.
[0057]
In step SB1, the current target motor speed stored in the controller 100 is read, and it is determined whether or not the target motor speed is a predetermined value V2. If the target motor speed is not the predetermined value V2, the process proceeds to step SB2, and if the target motor speed is the predetermined value V2, the process proceeds to step SB6. The current target motor speed is set and stored at the most recently executed step among steps SB3, SB5, SB7 and SB10 described later.
[0058]
If it is determined in step SB1 that the current target motor speed is not the predetermined value V2, the target motor speed is set in advance after the target motor speed is the predetermined value V1 and the target motor speed is the predetermined value V1 in step SB2. It is determined whether or not a certain time has passed. If the target motor speed is the predetermined value V1 and the predetermined time has elapsed, the process proceeds to step SB4. Otherwise, the process proceeds to step SB3, and the target motor speed is set to the predetermined value V1.
[0059]
In step SB4, the current motor current for driving the electric motor 19 is read and stored as the motor current I1, and then the process proceeds to step SB5. Here, an average value, a moving average value, and a median filter (a filter that arranges samples for a certain time in ascending order and outputs a median value) of the motor current may be stored as the motor current I1. .
[0060]
In step SB5, the target motor speed is set to a predetermined value V2 different from the predetermined value V1.
[0061]
When it is determined in step SB1 that the current target motor speed is the predetermined value V2, in step SB6 the target motor speed is set to a predetermined value V2 and set in advance after the target motor speed becomes the predetermined value V2. It is determined whether or not a certain time has passed. If the target motor speed is the predetermined value V2 and the predetermined time has elapsed, the process proceeds to step SB8. Otherwise, the process proceeds to step SB7, and the target motor speed is set to the predetermined value V2.
[0062]
In step SB8, the current motor current to the electric motor 19 is stored as I2, and then the process proceeds to step SB9. Here, also in this case, the average value of the motor current within a certain time, the moving average value, the output value of the median filter, and the like may be stored as the motor current I2.
[0063]
Here, for example, after the braking is performed, when the operation of the brake pedal 101 is released and then the throttle pedal is operated, step SA1, step SA6, step SA7, step SA8, step SA12, and step SA13 are changed to this. It is executed in order. Then, in the processing from step SB1 to SB8 in step SA13, for example, as shown in FIG. 6, the target motor speed is not V2 in step SB1 and the predetermined constant time has not elapsed in step SB2 at the initial stage after the release of braking. Thus, first, at step SB3, the target motor speed V1 is set (at time t0). Then, the electric motor 19 is moved backward from the pad contact position at the motor speed V1 until the predetermined fixed time elapses in step SB2 (from time t0 to time t1). When a predetermined fixed time has elapsed, the process proceeds from step SB2 to step SB4, and the motor current I1 at that time is stored (at time t1). In step SB5, a target motor speed V2 different from V1 is set. Then, the electric motor 19 is moved backward at the motor speed V2 until a predetermined fixed time elapses in step SB6 (from time t1 to time t2). When a predetermined fixed time has elapsed, the process proceeds from step SB6 to step SB8, and the motor current I2 at that time is stored (at time t2).
[0064]
In step SB9, the viscosity coefficient of the thrust mechanism 105 is calculated from the above motor speeds V1, V2 and motor currents I1, I2, and then the target motor speed is set to 0 in step SB10 and the coefficient calculation processing flag is reset. To do.
[0065]
Here, in step SB9, for example, assuming that the motor currents I1 and I2 at room temperature with respect to the motor speeds V1 and V2 and the motor currents at low temperatures are I1 ′ and I2 ′, these motor current values are the ambient temperature of the electric caliper 10. Accordingly, as shown in FIGS. 6C and 6D, the relationship of I1 <I1 ′ and I2 <I2 ′ is established. Then, as shown in FIG. 7, the motor speed is plotted on the horizontal axis and the motor current is plotted on the vertical axis, and the points (V1, I1) and (V2, I2) are plotted and connected by a straight line, and (V1, I1) When plotting the ') and (V2, I2') points and connecting them with straight lines, differences occur in the slopes of the straight lines at normal temperature and low temperature, and the respective viscosity coefficients can be obtained from the respective slopes. That is, when the torque constant is kt, the viscous resistance [Nm] is obtained by kt (I1-I2), and the viscosity coefficient [Nm / (rad / s)] is kt (I1-I2) / (V1- Since it is obtained in V2), the slope of the straight line multiplied by the torque constant kt is the viscous resistance. Instead of obtaining the viscosity coefficient from two points with two speeds as described above, it is possible to calculate by calculating an approximate straight line from the values of three or more points with three or more speeds using the least square approximation method or the like. The accuracy of the viscosity coefficient can be increased. The viscosity coefficient is obtained by dividing the motor torque by the motor speed, and approximates to the value obtained by dividing the current value by the motor speed. Therefore, the viscosity coefficient can be calculated using this value. If the viscosity coefficient is obtained with a plurality of motor speeds, the influence of no-load torque can be eliminated.
[0066]
The viscous resistance calculated in step SA13 as described above is used to adjust the piston thrust control control gain, that is, the target motor current value in step SA5, the motor position control control gain, that is, the target motor current value, and step SA15 in step SA11. Is used to adjust the control gain of the motor speed control, that is, the target motor current value. The control gain of the vehicle motion control may be adjusted using the viscosity coefficient of the thrust mechanism 105 calculated in this way.
[0067]
According to the brake device of the present embodiment described above, the controller 100 calculates the viscosity coefficient of the thrust mechanism 105 that presses the brake pads 14 and 15 against the disc rotor 11, and moves to the electric motor 19 that drives the thrust mechanism 105. Since the current value according to the supplied braking instruction signal is adjusted according to the viscosity coefficient that is easily affected by the difference in temperature condition, the influence due to the difference in temperature condition can be reduced.
[0068]
That is, the controller 100 controls the thrust mechanism 105 within a range in which the brake pads 14 and 15 do not press the disc rotor 11 based on the output of the position detector 20 that detects the movement positions of the brake pads 14 and 15 by the thrust mechanism 105. The thrust mechanism 105 is driven by switching to a different speed, specifically, a plurality of different constant speeds V1, V2, and based on the constant speeds V1, V2 at the time of each drive and the current values I1, I2 to the electric motor 19. Since the viscosity coefficient is calculated, the viscosity coefficient can be calculated more accurately. Therefore, since the current value supplied to the electric motor 19 is adjusted according to the viscosity coefficient calculated more accurately according to the pedal sensor signal output from the pedal sensor 102, the influence due to the difference in temperature condition is further increased. It can be surely reduced. Therefore, accuracy can be ensured even under a wide range of environmental temperatures, and it can be used more reliably.
[0069]
In addition, the said embodiment can also be changed as follows.
[0070]
When the vehicle control system including the controller 100 is turned on by turning on the ignition key, the above-described viscosity coefficient calculation process is performed regardless of the operation of the brake pedal 101 only when it is confirmed that the vehicle is stopped. Here, in a vehicle equipped with an automatic transmission, the stoppage of the vehicle can be confirmed by detecting with the shift position switch that the shift position is in the P (parking) range. In vehicles equipped with a manual transmission, the shift position switch detects that the shift position is in the neutral position, the clutch pedal switch is turned off to detect that the clutch pedal is not operated, and the parking brake. When the switch is turned on and the parking brake is operated, it can be confirmed that the vehicle is stopped.
[0071]
In this way, if the above-described viscosity coefficient calculation process is performed at the time of starting the vehicle control system in addition to the operation of the brake pedal 101, the influence due to the difference in temperature conditions can be further reduced, and a wide range of environmental temperatures can be reduced. Accuracy can be secured even under.
[0072]
The above viscosity coefficient calculation processing is performed when it is estimated in advance that the brake pedal 101 is operated. For example, as shown in FIG. 8, when the throttle switch is turned on and the presence of the throttle pedal operation is detected (time t3), the motor position of the electric motor 19 is set in the piston thrust release direction with respect to the pad contact position. It controls so that it may be located in the position returned quantitatively. Then, when the throttle switch is switched from ON to OFF and the throttle pedal is switched from being operated to not being operated (t4), it is estimated that the operation of the brake pedal 101 by the driver is performed immediately (that is, a sign of adding braking force). ) To perform viscosity coefficient calculation processing. That is, the electric motor 19 is driven in the direction of piston thrust generation at the motor speed of the predetermined value V1, and the electric motor 19 is moved to the piston at the motor speed of the predetermined value V2 different from the predetermined value V1 at the time (t5) after the elapse of the predetermined time. Drive in the direction of thrust generation. Then, the viscosity coefficient of the thrust mechanism is calculated from the motor speeds V1, V2 and the motor currents I1, I2 at the respective motor speeds in the same manner as described above. By controlling the motor position of the electric motor 19 to be the pad contact position at the end of driving at the motor speed V2 (t6), there will be no response delay even if the brake pedal 101 is operated thereafter. . In addition to detecting the sign of the addition of braking force by switching the throttle switch from on to off, it may be performed using a throttle opening sensor or a vehicle body speed. Further, in the case of a brake device that uses a brake device to apply a braking force to control the vehicle motion regardless of the driver's operation of the brake pedal 101, the vehicle motion control sign signal may be used. .
[0073]
Thus, if the viscosity coefficient of the thrust mechanism 105 is calculated when the controller 100 detects the sign of the addition of the braking force, the viscosity coefficient can be calculated under a condition close to the time when the braking force is applied. Therefore, since the current value supplied to the electric motor 19 is adjusted with the latest viscosity coefficient at the time of applying the braking force, for example, it is possible to reduce the influence when the temperature condition is different in a short time. It is possible to further reliably reduce the influence of the difference. Therefore, accuracy can be ensured even under a wide range of environmental temperatures, and it can be used more reliably.
[0074]
In this case, even if a condition for detecting the sign of the addition of braking force and performing the viscosity coefficient calculation process is satisfied, the viscosity coefficient calculation process is not performed unless a predetermined time has elapsed since the previous process. Anyway. Thereby, it can prevent that a viscosity coefficient calculation process is performed frequently and power consumption increases.
[0075]
【The invention's effect】
As described above in detail, according to the first aspect of the invention, the current value adjusting means calculates the viscosity coefficient of the thrust mechanism that presses the brake pad against the disk rotor, and supplies the viscosity coefficient to the electric actuator that drives the thrust mechanism. Since the current value according to the braking instruction signal is adjusted according to the viscosity coefficient that is easily affected by the difference in temperature condition, the influence due to the difference in temperature condition can be reduced. Therefore, accuracy can be ensured even under a wide range of environmental temperatures, and it can be used satisfactorily.
[0076]
According to the second aspect of the present invention, the viscosity coefficient estimating means uses the thrust mechanism within a range in which the brake pad does not press the disc rotor based on the output of the position detecting means for detecting the moving position of the brake pad by the thrust mechanism. Since the viscosity coefficient of the thrust mechanism is calculated based on the current value to the electric actuator at the time of driving at the speed, the viscosity coefficient can be calculated more accurately. Therefore, since the current value according to the braking instruction signal supplied to the electric actuator is adjusted according to the viscosity coefficient calculated more accurately, the influence due to the difference in temperature condition can be reliably reduced. Therefore, accuracy can be ensured even under a wide range of environmental temperatures, and it can be reliably used.
[0077]
According to the invention of claim 3, the viscosity coefficient estimating means includes a plurality of thrust mechanisms within a range in which the brake pads do not press the disc rotor, based on the output of the position detecting means for detecting the movement position of the brake pad by the thrust mechanism. Switch to different constant speeds, detect the current value to the electric actuator during each drive, and calculate the viscosity coefficient of the thrust mechanism based on each constant speed and each current value. Can be calculated. Therefore, since the current value according to the braking instruction signal supplied to the electric actuator is adjusted according to the viscosity coefficient calculated more accurately, the influence due to the difference in temperature condition can be further reliably reduced. Therefore, accuracy can be ensured even under a wide range of environmental temperatures, and it can be used more reliably.
[0078]
According to the fourth aspect of the present invention, the viscosity coefficient of the thrust mechanism is calculated by the viscosity coefficient estimating means when the sign of the braking force addition is detected by the brake sign detecting means. To calculate the viscosity coefficient. Therefore, since the current value according to the braking instruction signal supplied to the electric actuator is adjusted with the latest viscosity coefficient at the time when the braking force is applied, for example, the influence when a difference in temperature condition occurs in a short time is reduced. And the influence due to the difference in temperature condition can be reduced more reliably. Therefore, accuracy can be ensured even under a wide range of environmental temperatures, and it can be used more reliably.
[0079]
According to the fifth aspect of the present invention, the current value adjusting means is based on the output of the position detecting means for detecting the movement position of the brake pad by the thrust mechanism, so that the thrust mechanism is set within a range in which the brake pad does not press the disc rotor. Drives at speed and adjusts the current value according to the braking instruction signal supplied to the electric actuator based on the current value to the electric actuator at the time of the driving, thus reliably reducing the influence of differences in temperature conditions can do. Therefore, accuracy can be ensured even under a wide range of environmental temperatures, and it can be reliably used.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view of an electric caliper showing a brake device according to an embodiment of the present invention.
FIG. 2 is a flowchart showing the control contents of a controller in the brake device according to the embodiment of the present invention.
FIG. 3 is a control block diagram for calculating a target motor current value of a controller in the brake device according to the embodiment of the present invention.
FIG. 4 is a diagram illustrating a control map of a controller in the brake device according to the embodiment of the present invention.
FIG. 5 is a flowchart showing the control content of a viscosity coefficient calculation process of the controller in the brake device according to the embodiment of the present invention.
6 is a timing chart of the brake device according to the embodiment of the present invention, where (a) shows the motor position, (b) shows the motor speed, (c) shows the motor current value at normal temperature, ( d) shows the motor current value at a low temperature.
FIG. 7 is a characteristic diagram showing a motor current value with respect to a motor speed of the brake device according to the embodiment of the present invention.
FIG. 8 is a timing chart of a modification of the brake device according to the embodiment of the present invention, where (a) shows the state of the throttle switch, (b) shows the motor position, (c) shows the motor speed, (D) shows a motor current value, respectively.
[Explanation of symbols]
10 Electric caliper
11 Disc rotor
14,15 Brake pads
19 Electric motor (electric actuator)
20 position detector (position detecting means)
100 controller (control means, current value adjustment means, viscosity coefficient estimation means, brake sign detection means)
105 Thrust mechanism

Claims (5)

An electric caliper that includes a thrust mechanism that presses the brake pad against the disc rotor and an electric actuator that drives the thrust mechanism; and a control means that controls the braking force by supplying a current corresponding to a braking instruction signal to the electric actuator. In a brake device having
The control means includes a current value adjusting means for calculating a viscosity coefficient of the thrust mechanism and adjusting a current value supplied to the electric actuator in accordance with the braking instruction signal in accordance with the viscosity coefficient. Brake device. Position detection means for detecting the movement position of the brake pad by the thrust mechanism is provided in the electric caliper,
The current value adjusting means drives the thrust mechanism at a constant speed within a range in which the brake pad does not press the disk rotor based on the output of the position detecting means, and sets the current value to the electric actuator during the driving. The brake device according to claim 1, further comprising a viscosity coefficient estimating unit that calculates a viscosity coefficient of the thrust mechanism based on the viscosity mechanism. The viscosity coefficient estimating means drives the thrust mechanism by switching to a plurality of different constant speeds, detects a current value to the electric actuator at each drive, and detects the constant speed and the current value at each drive. The brake device according to claim 2, wherein a viscosity coefficient of the thrust mechanism is calculated based on The control means includes a brake sign detection means for detecting in advance a sign of braking force addition, and the viscosity coefficient estimating means detects the viscosity of the thrust mechanism when the brake sign detection means detects the sign of braking force addition. 4. The brake device according to claim 2, wherein a coefficient is calculated. An electric caliper that includes a thrust mechanism that presses the brake pad against the disc rotor, an electric actuator that drives the thrust mechanism, and a position detection means that detects the movement position of the brake pad by the thrust mechanism; A brake device having control means for controlling a braking force by supplying a current to the electric actuator;
The control unit is configured to perform the braking based on a current value to the electric actuator when the thrust mechanism is driven at a constant speed within a range where the brake pad does not press the disk rotor based on an output of the position detection unit. A brake device comprising current value adjusting means for adjusting a current value supplied to the electric actuator in accordance with an instruction signal.

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