KR20090078998A - Electronic parking brake system - Google Patents

Abstract

An electronic parking brake system is provided to satisfy consumer's various desires by forming low-priced ECU by forming an actuator to be operable using one force sensor and several digital logics. An electronic parking brake system includes an actuator which operates a parking brake electrically to pull or push a parking brake cable and to operate a parking brake accessory to compress or release a brake shoe to or from a drum, thereby to restrict or release the parking brake, wherein the actuator comprises a motor(41) rotating forward and backward, a movement converter converting a rotational motion of the motor into a rectilinear motion, a spindle(44) connected with a parking cable and rotated by the movement converter to move horizontally to pull or release the parking cable, a magnet(45) installed to the end of the spindle, a force sensor(46) outputting different signals according to the separation distance from the magnet to sense the location change of the spindle, a first replay installed to the input side of the motor and a fourth replay installed to the output side of the motor to rotate the motor forward to pull the parking cable, a second relay installed to the input side of the motor and a third relay installed to the output side of the motor to rotate the motor backward to release the parking cable, and replay drivers switching on or off the first, second, third and fourth relays respectively according to the output value of the force sensor, the ignition key signal and the operating signal of a parking switch to rotate the motor forward or backward.

Description

Electronic Parking Brake System

1 is a block diagram of an electronic parking brake system according to an embodiment of the present invention.

2 is a view showing a schematic configuration of the actuator of FIG.

3 is a view for explaining the operation of the force sensor of FIG.

4 is a diagram illustrating a driving circuit for driving the motor of FIG. 2.

5 is a view for explaining the operation of the motor of FIG.

* Description of the symbols for the main functions of the drawings *

10: parking switch 20: EPB ECU

30: parking brake 31: parking cable

32: parking brake attachment 40: actuator

41: motor 42: gearbox

43: screw nut 44: spindle

45: magnet 46: force sensor

The present invention relates to an electronic parking brake system, and more particularly, to an electronic parking brake system that automatically locks the parking brake when the vehicle is stopped to maintain the stopped state of the vehicle.

In general, there are parking brakes in the brake system, usually referred to as hand brakes or side brakes, which keep the vehicle stationary. The parking brake is operated by the driver operating the parking lever provided at one side of the driver's seat inside the vehicle, and the rear wheel brake assembly connected to the cable is maintained by pulling the parking lever and pulling the cable connected thereto. To ensure the braking force and, on the contrary, release the parking lever to release the cable so that the braking force is released.

However, since the parking brake operation method according to the parking lever operation is operated only by the driver's will, if the vehicle is parked without the parking lever being inadvertently pulled out by the driver, the vehicle itself rolls down from the ramp, causing an unexpected accident. There is a problem to make, and the driver has to operate the parking lever every time when parking or starting the operation, its use is very cumbersome, especially the weak women or the elderly have a problem that the use is more cumbersome.

Therefore, in recent years, an electronic parking brake (EPB) system which electronically controls the driving of the parking brake has been used. Even if the driver does not manually activate the parking brake, the EPB system operates automatically to keep the car parked or stopped when the vehicle is stopped or when the vehicle may be pushed back on the hill.

Such EPB systems are described in Korean Patent Laid-Open Publication No. 2006-11377 and European Patent Publication EP1158198.

In general, an EPB system consists of a mechanical actuator and an electronic ECU. The ECU consists of an MCU, several sensor interfaces, a motor driver and a communication module. However, low-cost ECUs need to be constructed according to requirements. Configurations using MCUs increase driver convenience and safety, but sometimes do not require these features. Thus, it could not meet the various needs of consumers.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and an object of the present invention is to configure an inexpensive ECU by enabling an actuator to be driven using one force sensor and a plurality of digital logics for detecting an operation of an actuator. It is possible to provide an electronic parking brake system that can be configured to meet various needs of consumers.

In the electronic parking brake system of the present invention for achieving the above object, in the electronic parking brake system including an actuator to activate or deactivate the parking brake in accordance with the operation of the parking switch by the driver to pull or release the parking cable, The actuator is a motor capable of forward and reverse rotation, motion switching means for converting the rotational motion of the motor into linear motion, and connected to the parking cable and rotated by the motion switching means to move left and right to pull or unwind the parking cable. A spindle, a magnet installed at one end of the spindle, and one force sensor for detecting a change in position of the spindle by outputting a different signal according to a separation distance from the magnet, and for pulling the parking cable. To rotate the motor forward A first relay provided on an input side and a fourth relay provided on an output side of the motor, a second relay provided on an input side of the motor to reversely rotate the motor to release the parking cable, and a third relay provided on an output side of the motor And a relay driver for turning on or off the first to fourth relays respectively by an output value of the force sensor, an ignition key signal, and an operation signal of the parking switch to rotate the motor forward or reverse. It features.

The relay driver is a first relay driver which is a buffer gate which outputs the parking signal of the parking switch to the first relay as it is, and AND outputs the logical sum of the ignition key signal and the release signal of the parking switch to the second relay. A second relay driver serving as a gate, and a third relay driver serving as an AND gate for outputting a logic sum of a release signal of the parking switch and a state signal output from the force sensor when the spindle position is a parking position; And a fourth relay driver which is an AND gate for outputting a logic sum of the state signal output from the force sensor to the fourth relay when the parking signal of the parking switch and the spindle position are the parking release position.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings.

EPB system types include cable puller type, motor-on-caliper type, and hydraulic parking brake type depending on the operating method. If not, if the vehicle is stopped or the vehicle may be pushed back at the start of the hill, the vehicle is automatically operated to maintain the parking state or the stopped state of the car.

Hereinafter, the cable puller type EPB system will be described as an example.

As shown in FIG. 1, even when the driver does not manually operate the parking brake, the vehicle is automatically operated when the vehicle is stopped or when the vehicle may be pushed back at the start of the hill. The EPB system is mounted to maintain the state.

The EPB system includes an external force for parking on the parking switch 10, the EPB ECU 20 which performs overall electronic parking brake control according to the operation signal of the parking switch 10, and the rear left and right wheels RL and RR, respectively. It is provided with a parking brake 30 that acts, and an actuator 40 for driving according to the control signal of the EPB ECU 20 to restrain the parking brake 30 to restrain the rotation of the wheel.

The parking switch 10 is turned on or off by the driver and transmits a command for releasing the restrained state of the parking brake 20 or a command for restraining the parking brake 20 to the EPB ECU 40.

The parking brake 30 has a parking brake cable 31 having one end connected to the actuator 40 to transmit external force to the left and right rear wheels Wrl and Wrr, and a parking brake accessory 32 connected to the parking cable 31. ) The parking brake accessory 32 has a brake shoe connected to the other end of the parking cable 31 and a padded shoe and a brake shoe lever for pressing the brake shoe onto the drum to generate a braking force.

The actuator 40 electrically operates the parking brake 20 to pull or push the parking brake cable 21 to operate the parking brake accessory 22 to squeeze or depress the brake shoe to the drum to release the parking brake 20. ) Or unconstrain.

When the parking switch 10 is turned on, the EPB ECU 20 recognizes the command as releasing the restrained state of the parking brake 20, drives the actuator 40 to push the parking cable 31 to drum the brake shoe. The release of the parking brake 20 is released by squeezing the pressure. In addition, when the parking switch 10 is turned off, the EPB ECU 20 recognizes the command to restrain the parking brake 30 and drives the actuator 40 to pull the parking brake cable 21 to drum the brake shoe. Re-compress on the parking brake 20 is restrained again.

As shown in FIG. 2, the actuator 40 is configured to control the parking brake 30 by pulling the parking cable 31 into a parking state (APPLY) or by releasing the parking state (RELEASE). 41, a storage box 42, a screw nut 43, a spindle 44 and a force sensor 46 are provided. When the motor 41 rotates forward, the storage box 42 and the screw nut 43 move to the right while the spindle 44 rotates forward. When the motor 41 rotates backward, the memory box 42 and the screw The nut 44 moves the spindle 44 to the left while rotating in reverse. Although not shown in the spindle 44, the parking cable 31 is configured to operate in conjunction with the movement movement of the spindle 44 through a fastening means such as an equalizer or a movement switching means. For example, when the vehicle is moved to the left side, the parking cable 31 is pulled, and when it returns to its original position, the parking cable 31 is released.

A magnet 45 is installed at one end of the spindle 44, and one end of the spindle 44 having the magnet 45 installed thereon detects the position of the spindle 44 to detect a parking braking force. Is connected to. The force sensor 46 is provided with a control circuit 46a installed in the casing to be spaced apart from the magnet 45 by a predetermined distance and outputting different signals according to the distance from the magnet 45.

As shown in FIG. 3, the force sensor 46 outputs a force release limit bit (FRLB) as "1" when the spindle 44 is at a release point. At this time, the parking state signal (Force Apply Limit Bit; FALB) is output as "0". On the other hand, the force sensor 46 outputs a parking state signal (Force Apply Limit Bit; FALB) as "1" when the spindle 44 is in the parking position (Apply Point). At this time, from the parking release point of view, the parking release status signal (Fforce Release Limit Bit (FRLB)) is output as "0".

The motor 41 is supplied with battery power by the first to fourth relays of the H-BRIDGE (H-bridge) type which is usually used for the forward and reverse rotation driving of the motor 41. The first to fourth relays are turned on or off by the relay driver to pull or release the parking cable 31 by turning the motor 41 forward or reverse to activate or deactivate the parking brake 30.

As shown in FIG. 4, the relay driver is a first relay driver relay_drv1 which is a buffer gate that outputs the parking signal of the parking switch to the first relay as it is by signals of the ignition key, the parking switch, and the force sensor 46. ), A second relay driver (relay_drv2) which is an AND gate for outputting a logical sum of the ignition key signal and the release signal of the parking switch to the second relay, the inversion signal of the parking release state signal of the force sensor 46, and the parking switch. And a third relay driver (relay_drv3), which is an AND gate for outputting the logical sum of the cancel signal of the signal to the third relay, and the logical sum of the inverted signal of the parking state signal of the force sensor 46 and the parking signal of the parking switch. And a fourth relay driver (relay_drv4) which is an AND gate to be outputted to the.

The operation of the relay driver will be described with reference to FIG. 5. First, when the driver turns the parking switch on for parking, the parking signal HIGH is input to the first relay driver relay_drv1 and the first relay is driven. Turn ON.

In addition, the parking signal HIGH is input to one end of the AND gate of the fourth relay driver relay_drv4, and the other end of the parking signal HIGH is an inversion signal of the parking state signal FALB of the force sensor 46. Is entered. Therefore, "HIGH" is output from the AND gate of the fourth relay driver relay_drv4 to turn on the fourth relay. At this time, since the spindle 44 is initially located in the parking release position, the parking state signal FALB of the force sensor 46 is "LOW", and its reversal signal is "HIGH", so that the "HIGH" signal value is zero. It is input to the other end of the AND gate of the 4 relay driver relay_drv4. In addition, since the spindle 44 is initially located in the parking release position, the parking release state signal FRLB of the force sensor 46 is "HIGH", and its reversal signal is "LOW", so that the "LOW" signal value is The third relay is not turned on, even though the AND gate of the third relay driver relay_drv3 is input.

As the first relay and the fourth relay are operated, a closed circuit is formed in which the battery power is connected to the first relay, the motor 41, the fourth relay, and the ground, so that the motor 41 rotates forward and the spindle 44 is stored. While rotating to one side by the box 42 and the screw nut 43, the parking cable 31 is pulled to activate the parking brake.

On the other hand, when the driver turns on the vehicle and turns off the parking switch to release the parking, the ignition key signal HIGH and the parking release signal HIGH are input to the second relay driver relay_drv2 to turn on the second relay. ON). At this time, the first relay and the fourth relay are turned OFF.

In addition, the parking release signal HIGH is input to one end of the AND gate of the third relay driver relay_drv3, and the other side "HIGH" which is an inverted signal of the parking release signal FRLB of the force sensor 46 is input to the other end. Is input. Therefore, "HIGH" is output from the AND gate of the third relay driver relay_drv3 to turn on the third relay. At this time, since the spindle 44 is moved from the parking release position to the parking position, the parking release state signal FRLB of the force sensor 46 is "LOW", and its reversal signal is "HIGH", and therefore, "HIGH". The signal value is input to the other end of the AND gate of the third relay driver relay_drv3. In addition, since the spindle 44 is moved from the parking release position to the parking position, the parking state signal FALB of the force sensor 46 is "HIGH", and its reversal signal is "LOW", so the "LOW" signal. Although the value is input to the AND gate of the second relay driver relay_drv2, the fourth relay is not turned on.

As the second relay and the third relay are operated, a closed circuit is formed in which battery power is connected to the second relay, the motor 41, the third relay, and the ground, so that the motor 41 rotates in reverse, and the spindle 44 While rotating to the original position by the storage box 42 and the screw nut 43, the parking cable 31 is released to release the parking brake.

As described in detail above, according to the present invention, according to the present invention, according to the switching operation of the parking switch for the operation of the parking cable by pulling or unwinding the parking cable by the operation of the actuator of the actuator of the spindle moving rotationally installed The actuators are driven using force sensors and multiple digital logics to drive four relays driven by the H-BRIDGE type to forward and reverse the motors of the actuators, eliminating many of the functions in expensive EPB systems and merely parking brakes. It is possible to provide a low cost EPB system for drivers who only want to activate and deactivate the device, which can satisfy various needs of consumers.

Claims (2)

An electronic parking brake system comprising an actuator for pulling or releasing a parking cable according to an operation of a parking switch by a driver to activate or deactivate the parking brake. The actuator is a forward and reverse rotation motor, the movement switching means for converting the rotational movement of the motor into a linear movement, connected to the parking cable and rotated by the movement switching means to move left and right to pull or unwind the parking cable A spindle installed, a magnet installed at one end of the spindle, and one force sensor for detecting a change in position of the spindle by outputting a different signal according to a separation distance from the magnet, A first relay provided at an input side of the motor and a fourth relay provided at an output side of the motor to rotate the motor forward to pull the parking cable; A second relay provided at an input side of the motor and a third relay provided at an output side of the motor to reversely rotate the motor to release the parking cable; Electronic parking brake including a relay driver to turn on or off the first relay to the fourth relay, respectively by the output value of the force sensor, the ignition key signal and the operation signal of the parking switch to rotate the motor forward or reverse rotation system. The first relay driver of claim 1, wherein the relay driver is a buffer gate that outputs the parking signal of the parking switch to the first relay as it is, and the logical sum of the ignition key signal and the release signal of the parking switch. A second relay driver, which is an AND gate output to a second relay, and an AND for outputting a logic sum of a release signal of the parking switch and a status signal output from the force sensor when the spindle position is a parking position to the third relay; A third relay driver serving as a gate, and a fourth relay driver serving as an AND gate for outputting a logical sum of a state signal output from the force sensor to the fourth relay when the parking signal of the parking switch and the spindle position are in the parking release position. Electronic parking brake system included.

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