KR100580492B1 - brake system with hydraulic boosting function - Google Patents

Abstract

The present invention provides a more stable braking performance by utilizing the hydraulic power driving function without the negative pressure generated in the intake system of the engine, so that the back pressure action required to supply high pressure hydraulic fluid to each wheel side brake mechanism during braking is achieved. The goal is to make it possible.

In order to achieve the above object, the present invention, the master cylinder 12 for promoting the generation of the braking signal pressure of a variable size in accordance with the amount of rotation of the brake pedal 10 is depressed during braking; An accumulator 14 for filling high-pressure hydraulic oil; A relay valve (16) which opens and closes by the signal pressure supplied from the master cylinder (12), and delivers the high pressure hydraulic oil supplied from the accumulator (14) to each wheel side brake mechanism; It is characterized in that it comprises a main hydraulic pump 18 that operates to deliver a high pressure hydraulic fluid to the accumulator 14 during braking.

Description

Brake system with hydraulic boosting function

1 is a block diagram showing a hydraulic power brake device according to the present invention.

2 is a block diagram showing the main part of FIG.

    <Description of Symbols for Main Parts of Drawings>

10-Brake Pedal 12-Master Cylinder

14-accumulator 16-relay valve

18-main hydraulic pump 20-transmission

22-multi-plate clutch 24-sub hydraulic pump

26-control unit

The present invention relates to a hydraulic power brake device, and more particularly, to a brake device capable of implementing a stable braking performance when braking with a hydraulic power boost function.

Generally, a vehicle is provided with a brake device for decelerating or completely stopping the vehicle speed while driving. In such a brake device, the operation required to start the operation is performed by the driver's depression of the brake pedal. Providing an appropriate braking pressure to the side brake mechanism is accomplished by a master cylinder that functions to generate a braking pressure, including a booster.

In this case, the power boosting device is usually configured to be able to use the negative pressure generated in the intake system of the engine or the vacuum pressure generated by driving the vacuum pump provided separately.

However, in case of using a power booster that uses the intake negative pressure of the engine or the vacuum pressure driven by the vacuum pump, 100% of the difference between the atmospheric pressure (1 bar) and the vacuum pressure (0 bar; based on the full vacuum for convenience) is used. Even if the force action is the limit.

That is, in a situation such as a long downhill road or continuous braking while driving at high speeds, rapid consumption of vacuum pressure occurs, and such rapid consumption of vacuum pressure causes an increase in pedal effort by the driver. It is accompanied by a problem that makes it difficult to occur.

In addition, if the proper braking force is not generated, there is a risk of directing a dangerous situation such as a collision.

Accordingly, the present invention has been made in view of the above-mentioned point, and the hydraulic power required to supply high-pressure hydraulic fluid to each wheel side brake mechanism during braking does not use the negative pressure generated in the intake system of the engine, The purpose is to enable a more stable braking performance by using the power boost function.

The present invention for achieving the above object,

A master cylinder for generating a braking signal pressure having a variable magnitude in accordance with the amount of rotation of the brake pedal depressed during braking;

Accumulators filled with high-pressure hydraulic fluid;

A relay valve which opens and closes according to the signal pressure supplied from the master cylinder, and delivers the high pressure hydraulic oil supplied from the accumulator to the respective wheel side brake mechanisms;

It characterized in that it comprises a main hydraulic pump that operates to deliver a high pressure hydraulic fluid to the accumulator during braking.

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

As shown in FIG. 1, the present invention provides a brake pedal 10 depressed during a braking operation by a driver and a master cylinder generating a brake signal pressure having a variable magnitude depending on the degree of depression of the brake pedal 10. 12) the accumulator 14 filling and storing a predetermined amount of high pressure hydraulic oil therein, and opening / closing by the signal pressure supplied from the master cylinder 12 during braking, The relay valve 16 which delivers the stored high pressure hydraulic oil to each wheel side brake mechanism is provided.

The main hydraulic pump 18 is operated to deliver high pressure hydraulic oil to the accumulator 14 during braking, and the power intermittent unit interlocks the drive of the main hydraulic pump 18 with the output of the power train system, The hydraulic control unit of the power control unit is configured to be operated by receiving a part of the high-pressure hydraulic oil to be sent to each wheel side brake mechanism (not shown) in accordance with the opening of the relay valve 16.

To this end, the power control unit is composed of a multi-plate clutch 22 installed between the output shaft 20a of the transmission 20 and the input shaft 18a of the main hydraulic pump 18, as shown in FIG. The multi-plate clutch 22 is fastened by receiving a part of the high-pressure hydraulic oil sent to each wheel side brake mechanism when braking, so that the input shaft 18a of the main hydraulic pump 18 is the output shaft 20a of the transmission 20. ) Can be linked to.

In addition, the multi-plate clutch 22 is connected to a conduit L2 branched from the brake conduit L1 disposed between the relay valve 16 and each wheel side brake mechanism.

On the other hand, the accumulator 14 is provided so as to partition the liquid storage chamber 14a in which the high-pressure working oil is stored and the gas storage chamber 14b in which the inert gas is stored, based on the diaphragm 14d. The liquid storage chamber 14a is provided with a pressure detection sensor 14c capable of detecting the internal pressure.

Herein, the gas stored in the gas storage chamber 14b enables the discharge operation to the high-pressure working oil stored in the liquid storage chamber 14a. Particularly, the inert gas is adopted because of the characteristics of the inert gas and the high pressure. This is to use the characteristics that there is no risk of explosion or deterioration due to external impact during compression.

In addition, in the present invention, a sub-hydraulic pump 24 capable of supplying a high-pressure hydraulic fluid to the accumulator 14 is provided in case the normal operation of the main hydraulic pump 18 is impossible. The hydraulic pump 24 detects an internal pressure through the pressure detection sensor 14c provided in the liquid storage chamber 14a of the accumulator 14, and compares the pressure with a reference set value to reduce the pressure below the reference set value. If this is detected, driving is performed by the control part 26 which outputs an operation signal.

In addition, in the present invention, the accumulator 14 and the relay valve 16 are separately installed in the front and rear brake system, so that the braking pressure can be supplied to the front and rear wheel brake mechanisms, respectively, during braking. It is configured to be.

In addition, the relay valve 16 is provided with a drain line L3 in communication with the oil reservoir 28 to return the high-pressure hydraulic oil supplied from the accumulator 14.

Hereinafter, the operation of the hydraulic power brake device according to the present invention will be described in detail.

When the driver presses the brake pedal 10 during braking, the master cylinder 12 generates a signal pressure of a magnitude corresponding to the degree of depression and supplies the brake valve 10 to the relay valve 16. 16) performs opening and closing operation corresponding to the degree of the signal pressure and supplies high pressure hydraulic oil stored in the liquid storage chamber 14a of the accumulator 14 to the brake mechanism of each wheel, whereby braking is performed.

At this time, the supply of hydraulic oil to the multi-plate clutch 22 is accompanied by the supply of hydraulic oil to the multi-plate clutch 22 through a line L2 branched to the brake line L1 disposed between the relay valve 16 and each wheel side brake mechanism. And the input shaft 18a of the main hydraulic pump 18 receives the driving force from the output shaft 20a of the transmission 20 so that the liquid reservoir 14a of the accumulator 14 is engaged. High pressure hydraulic fluid is supplied into the tank.

In this case, the hydraulic fluid stored in the liquid storage chamber 14a of the accumulator 14 can be supplied to each of the wheel side brake mechanisms at the high pressure during braking, so that the hydraulic oil can be supplied to the high pressure state in the liquid storage chamber 14a. This is because in addition to the reason for being stored, the inert gas stored at high pressure in the gas storage chamber 14b serves as a kind of return spring, and the hydraulic oil in the liquid storage chamber 14a can be discharged under a high pressure.

When the pressure in the liquid storage chamber 14a of the accumulator 14 drops below a reference set value, the control unit 26 detects this via the pressure detection sensor 14c and supplies it to the sub-hydraulic pump 24. It will output the operation signal.

As a result, the high pressure hydraulic fluid can be always filled in the liquid reservoir 14a of the accumulator 14.

As described above, according to the hydraulically powered brake device according to the present invention, the hydraulic oil is supplied to each wheel side brake mechanism through the relay valve 16 according to the degree of depression of the brake pedal 10 by the driver during braking. In the above, the hydraulic fluid is not converted to a high pressure by the vacuum boosting type, but is converted to a high pressure state by the driving of the main hydraulic pump 18 to the sub hydraulic pump 24, so that more stable braking performance can be realized. It becomes possible.

That is, the power required for the braking action, such as during emergency braking or continuous braking during long downhill driving, does not depend on the unstable vacuum pressure as in the prior art, but creates an artificial pressure by driving the hydraulic pump. Since it is a mediation, it becomes possible to entail a stable braking action.

Claims (8)

A master cylinder 12 for generating a braking signal pressure of a variable size according to the amount of rotation of the brake pedal 10 repressed during braking, an accumulator 14 filled with high-pressure hydraulic oil, and the master cylinder 12 Relay valve 16 for opening / closing operation by the signal pressure supplied from the valve 14 and supplying the high-pressure hydraulic oil supplied from the accumulator 14 to each wheel side brake mechanism, and the high-pressure hydraulic oil is supplied to the accumulator 14 during braking. A main hydraulic pump (18) operative to deliver, and a sub-hydraulic pump (24) for delivering high pressure hydraulic oil to the accumulator (14) when the main hydraulic pump (18) fails; The main hydraulic pump (18) has an output shaft (20a) of the transmission (20) and an input shaft (18a) receiving power via a multi-plate clutch (22); The multi-plate clutch (22) is connected with a conduit (L2) branched from the brake conduit (L1) disposed between the relay valve (16) and each wheel side brake mechanism; The accumulator 14 has a liquid reservoir 14a and an inert gas for storing the high-pressure working oil supplied from the main hydraulic pump 18 to the sub-hydraulic pump 24 based on the diaphragm 14d therein. Each of the gas storage chambers 14b to be stored is partitioned, and a pressure detection sensor 14c for detecting an internal pressure is provided in the liquid storage chamber 14a; The driving of the sub hydraulic pump 24 detects the pressure in the liquid storage chamber 14a via the pressure detection sensor 14c, and compares it with a reference set value to detect the pressure below the reference set value. Hydraulic hydraulic brake device, characterized in that made by a control unit 26 for outputting a signal. delete delete delete delete delete The method of claim 1, The accumulator (14) and the relay valve (16) is a hydraulic hydraulic brake device, characterized in that installed separately in the front / rear brake system. The method of claim 1, Hydraulic relay brake device, characterized in that the relay valve (16) is provided with a drain line (L3) in communication with the oil reservoir (28) to return the high-pressure hydraulic oil supplied from the accumulator (14).

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