JP5048585B2 - Brake device - Google Patents

Description

  The present invention relates to a brake device capable of anti-lock brake control of driving wheels and driven wheels, and regenerative braking and hydraulic braking of the driving wheels to hydraulically brake the driven wheels.

In a vehicle brake device having drive wheels driven by an electric motor, when regenerative braking is not performed, wheels are braked with the brake hydraulic pressure generated by the master cylinder, and when regenerative braking is performed, hydraulic braking is performed. In order to increase the energy recovery efficiency by lowering the ratio and increasing the ratio of regenerative braking, the output of the brake fluid pressure lower than the value corresponding to the operation amount of the brake pedal is output according to Patent Document 1 below. It is known.
JP 2005-162138 A

  By the way, in the above-mentioned conventional one, not only the brake fluid pressure supplied to the driving wheel to be regeneratively braked but also the brake fluid pressure to be supplied to the driven wheel not to be regeneratively braked at the time of executing the regenerative braking. As a result, the driven wheel cannot generate the braking force that should be originally generated, and the braking feeling felt by the driver may deteriorate.

  The present invention has been made in view of the above-described circumstances, and harmonizes the regenerative braking of the driving wheel and the hydraulic braking of the driving wheel and the driven wheel so that both the driving wheel and the driven wheel can be accurately braked. With the goal.

In order to achieve the above object, according to the first aspect of the present invention, a master cylinder capable of generating a brake fluid pressure by a driver's braking operation and a driving wheel driven or regeneratively braked by an electric motor are provided. Driving wheel wheel cylinder for pressure braking, driven wheel wheel cylinder for hydraulic braking of the driven wheel , normally open type in-valve for opening and closing between the master cylinder and each wheel cylinder, and opening and closing between each wheel cylinder and the reservoir It has a normally closed outlet valve, the brake by releasing the brake fluid in the wheel cylinder by opening the and the outlet valves closed the inlet valves to the reservoir through the outlet valve and vacuum available-for the ABS hydraulic, capable electrohydraulic pressure generates brake fluid pressure by an electric actuator during the regenerative braking performed And a raw device, the braking device is arranged the ABS device between the master cylinder and the driving-wheel wheel cylinder and said driven wheel wheel cylinder, and said ABS unit and the driving-wheel wheel cylinder The electric hydraulic pressure generating means is disposed between the regenerative braking and the in-valve corresponding to the driving wheel wheel cylinder is closed, and the regenerative braking is performed on the driven wheel wheel cylinder. A brake device is proposed in which the continuous out valve is opened so that the brake fluid supplied to the wheel cylinder for the driven wheel is partially released to the reservoir side .

  According to the invention described in claim 2, in addition to the configuration of claim 1, the electric hydraulic pressure generating means includes a rear hydraulic chamber and a front hydraulic chamber, the rear hydraulic chamber and the front hydraulic chamber. A rear piston and a front piston which are slidably fitted to the rear side of the partial hydraulic chamber, respectively, and the rear hydraulic chamber and the front hydraulic chamber are moved forward by the electric actuator. And a first restricting means for restricting a maximum distance between the rear piston and the front piston, and a second restricting means for restricting a retreat limit of the front piston. A featured braking device is proposed.

  The wheel cylinders 16 and 20 of the embodiment correspond to the wheel cylinder for driving wheels of the present invention, and the wheel cylinders 17 and 21 of the embodiment correspond to the wheel cylinder for driven wheels of the present invention. The motor cylinder 23 corresponds to the electric hydraulic pressure generating means of the present invention.

According to the first aspect of the present invention, when normal hydraulic braking is performed, the brake hydraulic pressure generated by the master cylinder by the driver's operation is applied to the wheel cylinder for the driving wheel and the wheel cylinder for the driven wheel via the ABS device. To brake the driving wheel and the driven wheel. At this time, if the driving wheel or the driven wheel is in locking tendency, it is possible to ABS system is activated to suppress the lock by reducing the brake fluid pressure from the master cylinder.

During regenerative braking of the drive wheel, the brake fluid pressure transmitted from the master cylinder to the drive wheel wheel cylinder is cut off by the ABS device (that is, the in-valve corresponding to the drive wheel wheel cylinder) , and the drive wheel is regeneratively braked to save energy. The recovery efficiency can be increased. Then, just regenerative braking in the case of insufficient braking force of the drive wheels, by electric liquid pressure generating means to operate the driving-wheel wheel cylinder by brake fluid pressure generated, generating a braking force required for the drive wheel Can be made. At this time, since the brake fluid pressure of the master cylinder is supplied to the driven wheel wheel cylinder via an ABS device (that is, an in-valve corresponding to the driven wheel wheel cylinder) , while improving the energy recovery efficiency by regenerative braking, Necessary and sufficient braking force can be generated for both the driving wheel and the driven wheel.

Also, during regenerative braking of the drive wheel, the brake fluid pressure transmitted from the master cylinder to the drive wheel wheel cylinder is cut off by the ABS device as described above, so that the stroke of the braking operation is reduced correspondingly and the feeling is reduced. However, in the present invention, the brake fluid supplied to the driven wheel wheel cylinder at the time of regenerative braking is partially released to the reservoir by appropriately opening the out valve connected to the driven wheel wheel cylinder. Therefore, the stroke of the braking operation can be increased by that amount to prevent the feeling from deteriorating. Further, since the stroke of the braking operation is ensured by using the reservoir of the ABS device in this way, a special stroke simulator is not required, which can contribute to cost reduction.

  According to the second aspect of the present invention, when the ABS device is operated to reduce the brake hydraulic pressure of the wheel cylinder communicating with the front hydraulic pressure chamber, the front hydraulic pressure chamber is also reduced, so the front piston moves forward. As a result, there is a problem that the volume of the rear hydraulic chamber increases and the brake hydraulic pressure of the wheel cylinder communicating with the rear hydraulic chamber also decreases, but the maximum distance between the rear piston and the front piston does not increase. Thus, since it is connected by the 1st control means, the increase in the volume of a rear hydraulic pressure chamber can be prevented, and the braking force of the wheel cylinder connected to this rear hydraulic pressure chamber can be secured.

  On the other hand, when the ABS device is actuated and the brake hydraulic pressure of the wheel cylinder communicating with the rear hydraulic pressure chamber is reduced, the rear hydraulic pressure chamber is also reduced. Therefore, the front piston is retracted to reduce the volume of the front hydraulic pressure chamber. Although there is a problem that the brake hydraulic pressure of the wheel cylinder that increases and communicates with the front hydraulic pressure chamber is also reduced, the front hydraulic pressure chamber is restricted because the front piston is regulated by the second regulating means. The braking force of the wheel cylinder communicating with the front hydraulic pressure chamber can be ensured by preventing the volume of the cylinder from increasing.

  Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

  1 and 2 show an embodiment of the present invention. FIG. 1 is a hydraulic circuit diagram of a vehicle brake device, and FIG. 2 is a longitudinal sectional view of a motor cylinder.

  As shown in FIG. 1, a tandem master cylinder 11 having a negative pressure booster 10 includes two hydraulic chambers 13A and 13B that output brake hydraulic pressure in accordance with the pedaling force of the driver stepping on the brake pedal 12. One hydraulic chamber 13A is connected to the wheel cylinders 16 and 17 of the disc brake devices 14 and 15 of the left front wheel and the right rear wheel, for example, via the fluid paths Pa, Pb, Pc and Pd (first system). The other hydraulic chamber 13B is connected to the wheel cylinders 20 and 21 of the disc brake devices 18 and 19 of the right front wheel and the left rear wheel, for example, via the fluid paths Qa, Qb, Qc and Qd (second system). The

  An ABS (anti-lock brake system) device 24 is disposed between the liquid paths Pa, Qa and the liquid paths Pb, Pd; Qb, Qd.

  The structure of the ABS device 24 is well known, and is the same as the first system of the disc brake devices 14 and 15 for the left front wheel and the right rear wheel and the second system of the disc brake devices 18 and 19 for the right front wheel and the left rear wheel. A structure is provided. As a representative example, the first system of the disc brake devices 14 and 15 for the left front wheel and the right rear wheel will be described. In valves 42 and 42 each composed of a pair of normally-open electromagnetic valves between the liquid path Pa and the liquid paths Pb and Pd. Between the liquid passages Pb and Pd on the downstream side of the in-valves 42 and 42 and the reservoir 43, the out-valves 44 and 44, which are normally closed electromagnetic valves, are disposed. A check valve 49 is connected to each in-valve 42 in parallel. A hydraulic pump 47 sandwiched between a pair of check valves 45 and 46 is disposed between the reservoir 43 and the liquid path Pa. The hydraulic pump 47 is driven by an electric motor 48.

  A motor cylinder 23 is disposed between the fluid passages Pb and Qb on the downstream side of the ABS device 24 and the fluid passages Pc and Qc on the upstream side of the wheel cylinders 16 and 20 of the disc brake devices 14 and 18 for the left and right front wheels. The

  The electric actuator 31 that drives the motor cylinder 23 includes an electric motor 32, a drive bevel gear 33 provided on the output shaft of the electric motor 32, a driven bevel gear 34 that meshes with the drive bevel gear 33, and a ball screw mechanism that is operated by the driven bevel gear 34. 35. A rear piston 38A and a front piston 38B urged in a backward direction by a pair of return springs 37A and 37B are slidably disposed in a cylinder main body 36 of the motor cylinder 23. The rear piston 38A and the front piston A rear hydraulic chamber 39A and a front hydraulic chamber 39B are defined on the front surface of 38B. The rear hydraulic chamber 39A communicates with the fluid paths Pb and Pc via the ports 40A and 41A, and the front hydraulic chamber 39B communicates with the fluid paths Qb and Qc via the ports 40B and 41B.

  When the electric motor 32 is driven in one direction, the rear and front pistons 38A and 38B move forward via the drive bevel gear 33, the driven bevel gear 34, and the ball screw mechanism 35, and the rear and front hydraulic chambers 39A and 39B. The brake hydraulic pressure generated in the engine can be output to the fluid paths Pc and Qc via the ports 41A and 41B.

  As is clear from FIG. 2, the rear piston 38 </ b> A slidably fitted to the rear portion of the cylinder body 36 of the motor cylinder 23 includes a front first cup seal 51 and a rear second cup seal 52. In the state where the retracted end is regulated by the circlip 53, the port 40A connected to the fluid path Pb opens to the rear hydraulic chamber 39A in front of the first cup seal 51. When the rear piston 38A slightly advances and the first cup seal 51 passes through the port 40A, the brake fluid pressure is generated in the rear fluid pressure chamber 39A at that moment.

  The front piston 38B slidably fitted to the front portion of the cylinder body 36 of the motor cylinder 23 includes a front third cup seal 54 and rear fourth and fifth cup seals 55 and 56. A long hole 38a that penetrates between the third cup seal 54 and the fourth cup seal 55 in the diametrical direction is slidably fitted to the pin 57 fixed to the cylinder body 36. The on-off valve 58 provided in the front piston 38B is formed at a portion where the recess 38b formed at the front end of the front piston 38B communicates with the elongated hole 38a and a portion where the communication hole 38c opens into the recess 38b. The valve seat 38d, the valve head 59 with the head portion 59a facing the valve seat 38d so as to be seatable, and the leg portion 59b slidably fitted in the communication hole 38c, and the front piston 38B are fitted to the front end. And a valve spring 61 that is contracted between the spring seat 60 and the head portion 59a of the valve body 59. The pin 57 and the long hole 38a restrict the retracted end of the front piston 38B, and constitute the second restricting means 66 of the present invention.

  The front piston 38 </ b> B is urged rearward by a return spring 37 </ b> B, and the front end of the long hole 38 a is restricted to a retracted end that contacts the pin 57. In this state, the leg portion 59b of the valve body 50 abuts on the pin 57, the head portion 59a is separated from the valve seat 38d, and the back chamber between the front hydraulic chamber 39B and the third and fourth cup seals 54, 55 Communicates through the communication hole 38c. When the front piston 38B slightly advances, the valve body 59 guided through the leg 59b through the communication hole 38c is urged rearward by the elastic force of the valve spring 61, and the head 59a is seated on the valve seat 38d. Brake fluid pressure is generated in the front fluid pressure chamber 39B.

  In order to reduce the volume of the rear hydraulic chamber 39A and generate the brake hydraulic pressure, the rear piston 38A can approach the front piston 38B, but the maximum distance is regulated by the first regulating means 62. The first restricting means 62 includes a spring seat 63 fixed to an annular protrusion 38e formed at the rear end of the front piston 38B by a caulking portion 63a, and a rear end of a guide portion 63b extending in a cylindrical shape rearward from the caulking portion 63a. A head 64a is engaged with the hole 63c, and a rear end thereof is configured by a bolt 64 that is screwed into a front end of the rear piston 38A to fix the spring seat 65.

  Normally, the rear piston 38A and the front piston 38B are urged away from each other by the elastic force of the return spring 37A that is contracted between the front and rear spring seats 63, 65, and the head of the bolt 64 is urged. 64a abuts around the hole 63c of the spring seat 63 and the distance between the rear piston 38A and the front piston 38B is regulated to the maximum distance, but the bolt 64 slides along the hole 63c, so that the rear piston 38A Is accessible to the front piston 38.

  Wheel speed sensors Sa that detect the wheel speed of each wheel are connected to an electronic control unit (not shown) that controls the operation of the ABS device 24.

  Next, the operation of the embodiment of the present invention having the above configuration will be described.

  During normal braking, the brake fluid pressure generated in the hydraulic chamber 13A of the master cylinder 11 when the driver steps on the brake pedal 12 is the in-valve 42 opened from the fluid path Pa to one of the ABS devices 24 → the fluid path Pb → The brake hydraulic pressure generated in the hydraulic chamber 13A of the master cylinder 11 is transmitted to the left front wheel wheel cylinder 16 through the port 40A → rear hydraulic chamber 39A → port 41A → liquid passage Pc of the motor cylinder 23. The fluid is transmitted from the fluid path Pa to the wheel cylinder 17 of the right rear wheel through the other opened in-valve 42 of the ABS device 24 → the fluid path Pd.

  The brake fluid pressure generated in the fluid pressure chamber 13B of the master cylinder 11 when the driver steps on the brake pedal 12 is the in-valve 42 opened from the fluid passage Qa to the one of the ABS device 24 → the fluid passage Qb → the motor cylinder 23. The brake fluid pressure generated by the fluid pressure chamber 13B of the master cylinder 11 is transmitted to the fluid path Qa while being transmitted to the wheel cylinder 20 of the right front wheel through the route of the port 40B → the front fluid pressure chamber 39B → the port 41B → the fluid path Qc. Is transmitted to the wheel cylinder 21 of the left rear wheel through the other opened in-valve 42 → liquid passage Qd of the ABS device 24.

  As described above, the four-wheel wheel cylinders 16, 17, 20, and 21 are operated by the brake fluid pressure generated by the master cylinder 11 at the normal time.

  When it is detected that the slip ratio of any wheel has increased due to the output of the wheel speed sensor Sa during braking by the brake hydraulic pressure generated by the master cylinder 11 described above, the ABS tends to be locked. The device 24 is activated to prevent the wheels from locking.

  That is, when a predetermined wheel tends to be locked, the in-valve 42 connected to the wheel cylinder of the disc brake device of the wheel is closed and the transmission of the brake fluid pressure from the master cylinder 11 is shut off, and the out-valve 44 is opened. The wheel does not lock by performing a pressure reducing action to release the brake fluid pressure of the wheel cylinder to the reservoir 43 and a holding action to close the out valve 44 and hold the brake fluid pressure of the wheel cylinder. So as to reduce the braking force.

  As a result, when the wheel speed recovers and the slip ratio decreases, the braking force of the wheel is increased by opening the in-valve 42 and increasing the brake fluid pressure of the wheel cylinder. When the wheel becomes locked again by this pressure increasing action, the pressure reduction, holding, and pressure increasing are executed again, and the maximum braking force can be generated while suppressing the wheel lock by repeating the operation. In the meantime, the brake fluid that has flowed into the reservoir 43 is returned to the upstream fluid paths Pa and Qa by the hydraulic pump 47.

  When the battery is not fully charged and can be charged with regenerative power, the left and right front wheels, which are drive wheels driven by the electric motor, are regeneratively braked. At this time, the brake fluid pressure is not transmitted from the master cylinder 11 to the left and right front wheel cylinders 16, 20 by closing the two in-valves 42, 42 connected to the fluid paths Pb, Qb of the ABS device 24. By braking the front wheels only by regenerative braking, the energy recovery efficiency can be maximized. At this time, the left and right rear wheels are braked by the brake fluid pressure generated by the master cylinder 11 as in the normal state.

  When the braking force of the left and right front wheels is insufficient only by regenerative braking, the left and right front wheel wheel cylinders 16 and 20 are operated by the brake fluid pressure generated by the motor cylinder 23 to assist in the shortage of braking force due to regenerative braking. To do.

  That is, when the electric actuator 31 of the motor cylinder 23 is operated and the rear and front pistons 38A and 38B move forward, brake hydraulic pressure is generated in the rear and front hydraulic chambers 39A and 39B. The brake fluid pressure is transmitted to the wheel cylinders 16 and 20 via the fluid passages Pc and Qc, and a braking force can be generated on the left and right front wheels.

  If the rear and front pistons 38A and 38B of the motor cylinder 23 are slightly advanced, the communication between the liquid passages Pb and Qb and the rear and front hydraulic chambers 39A and 39B is cut off. The brake fluid pressure generated by the pressure chambers 39A and 39B does not pass through the check valves 49 and 49 and is transmitted back to the master cylinder 11 side.

During the above-described regenerative braking of the front wheels, the brake fluid sent out by the master cylinder 11 is blocked by the ABS device 24 from the brake fluid to be supplied to the wheel cylinders 16 and 20 of the front wheels. There is a possibility that the pedal feeling will deteriorate due to the reduced stroke. Therefore, in the present embodiment, during regenerative braking, the brake fluid in the fluid passages Pd and Qd connected to the wheel cylinders 17 and 21 of the rear wheels is released to the reservoirs 43 and 43 by opening the out valves 44 and 44 as appropriate. The stroke of the brake pedal 12 is increased by that amount to prevent the pedal feeling from deteriorating.

  Thus, since the stroke of the brake pedal 12 is ensured using the reservoirs 43, 43 of the ABS device 24, a special stroke simulator is not required, which can contribute to cost reduction.

  By the way, for example, when the left front wheel tends to be locked, and the ABS fluid 24 is operated to reduce the brake hydraulic pressure supplied to the wheel cylinder 16 of the left front wheel, the rear hydraulic chamber 39A of the motor cylinder 23 is reduced. As the piston 38A moves backward, the volume of the front hydraulic chamber 39B increases, and the brake hydraulic pressure supplied to the wheel cylinder 20 of the right front wheel also decreases. However, in the present embodiment, the front end of the long hole 38a of the front piston 38B is engaged with the pin 57 to restrict the backward movement, that is, the second restriction means 66 functions, so that the front hydraulic chamber 39B is functioned. Therefore, the braking force of the wheel cylinder 20 of the right front wheel can be secured.

  Conversely, when the right front wheel tends to lock and the ABS device 24 operates and the brake hydraulic pressure supplied to the wheel cylinder 20 of the right front wheel is reduced, the front hydraulic chamber 39B of the motor cylinder 23 is reduced. As the part piston 38A moves forward, the volume of the rear hydraulic chamber 39A increases and the brake hydraulic pressure supplied to the wheel cylinder 16 of the left front wheel also decreases. However, in the present embodiment, the rear piston 38A and the front piston 38B are connected by the first restricting means 62 including the spring seat 63 and the bolt 64 so that the distance is not increased. The increase in volume can be prevented and the braking force of the wheel cylinder 16 of the left front wheel can be secured.

  As described above, according to the brake device of the present embodiment, when the driving wheel is not regeneratively braked, it functions as a hydraulic brake device provided with the normal ABS device 24 and when the driving wheel is regeneratively braked. In addition, while supplying the brake fluid pressure to the driven wheel, the supply of the brake fluid pressure to the drive wheel can be cut off, and the drive wheel can be braked only by regenerative braking to increase the energy recovery efficiency. When the braking force of the driving wheel is insufficient only by regenerative braking, the braking force necessary for the driving wheel can be generated by braking the driving wheel with the brake fluid pressure generated by the motor cylinder 23. Therefore, it is possible to generate a necessary and sufficient braking force for both the driving wheel and the driven wheel while improving the energy recovery efficiency by regenerative braking.

  The embodiments of the present invention have been described above, but various design changes can be made without departing from the scope of the present invention.

  For example, in the embodiment, the front wheel is the driving wheel and the rear wheel is the driven wheel, but the relationship can be reversed.

  The ABS device 24 according to the embodiment includes a brake fluid pressure control device (VSA device: vehicle stability assist device) having an ABS function.

Hydraulic circuit diagram of vehicle brake system Vertical section of motor cylinder

11 Master cylinder 16 Wheel cylinder (wheel cylinder for drive wheels)
17 Wheel cylinder (wheel cylinder for driven wheel)
20 Wheel cylinder (wheel cylinder for drive wheels)
21 Wheel cylinder (wheel cylinder for driven wheel)
23 Motor cylinder (electric hydraulic pressure generating means)
24 ABS device 31 Electric actuator 38A Rear piston 38B Front piston 39A Rear hydraulic chamber 39B Front hydraulic chamber
42 Normally open type in-valve 43 Reservoir
44 normally closed out valve 62 first restricting means 66 second restricting means

Claims (2)

A master cylinder (11) capable of generating brake fluid pressure by a driver's braking operation;
Wheel cylinders for driving wheels (16, 20) for hydraulically braking driving wheels driven or regeneratively braked by an electric motor;
A wheel cylinder (17, 21) for a driven wheel that hydraulically brakes the driven wheel;
A normally-open in-valve (42) that opens and closes between the master cylinder (11) and each wheel cylinder (16, 20; 17, 21), and between each wheel cylinder (16, 20; 17, 21) and the reservoir (43). Each of the wheel cylinders (16, 20; 17,) by closing the in-valve (42) and opening the out-valve (44). 21) vacuum available-for ABS system the brake fluid pressure by escape to the reservoir (43) via the outlet valve (44) the brake fluid in the (24),
Electric hydraulic pressure generating means (23) capable of generating brake hydraulic pressure by the electric actuator (31) during execution of the regenerative braking ,
In the brake device in which the ABS device (24) is disposed between the master cylinder (11), the drive wheel wheel cylinder (16, 20) and the driven wheel wheel cylinder (17, 21) ,
The electric hydraulic pressure generating means (23) is disposed between the ABS device (24) and the wheel cylinders (16, 20) for driving wheels ,
The regenerative braking is performed with the in-valve (42) corresponding to the drive wheel wheel cylinder (16, 20) closed, and at the time of the regenerative braking, the driven wheel wheel cylinder (17, 21). A brake device characterized in that the out valve (44) connected to the valve is opened so that the brake fluid supplied to the wheel cylinders (17, 21) for the driven wheels is partly released to the reservoir (43) side. .   The electric hydraulic pressure generating means (23) includes a rear hydraulic chamber (39A) and a front hydraulic chamber (39B), and a rear side of the rear hydraulic chamber (39A) and the front hydraulic chamber (39B). A rear piston (38A) and a front piston (38B), which are slidably fitted to each other, and the rear piston (38A) is advanced by the electric actuator (31) to advance the rear hydraulic chamber (39A). ) And the first hydraulic pressure chamber (39B) capable of generating brake hydraulic pressure, and the first regulating means (62) regulating the maximum distance between the rear piston (38A) and the front piston (38B). 2. The brake device according to claim 1, further comprising a second restricting means for restricting a backward limit of the front piston.

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