KR20000007221U - Master cylinder of vehicle brake - Google Patents

Abstract

The present invention relates to a master cylinder of a vehicle brake device, the purpose of which is to form a second piston and a retainer integrally, and to form a ring groove on the first piston so that the second piston can be returned to the return spring provided in the booster. The push rod is provided with a master cylinder of a brake device for a vehicle provided with a collet spring detachable from a ring groove, and includes a first spring and a second spring installed between the first piston and the second piston to restore the first piston. A retainer formed integrally with the second piston to protrude toward the spring side, an opening groove formed so that the push rod can be inserted into the other side of the first piston having a stem installed on one side to pull the retainer, and an outer circumferential direction on the inner surface of the opening groove. Ring grooves formed in the concave indentation, a plurality of elastic surface and the elastic surface yarns projecting to the outer circumferential side to be inserted into the ring groove Connect and is configured to be provided with a collet spring consisting of a holding surface coupled to the push rod.

Description

Master cylinder of vehicle brake

The present invention relates to a master cylinder of a vehicle brake apparatus, and more particularly, to a master cylinder of a vehicle brake apparatus in which the second piston provided therein is returned by the return spring of the booster when the master cylinder is operated.

1 is a longitudinal sectional view showing a conventional master cylinder, which will be described with reference to the following.

One side of the brake pedal (not shown) installed in the driver's seat of the vehicle is connected to the booster 10 to amplify the force applied to the master cylinder 30. The booster 10 includes a diaphragm 15 that divides the inner space of the sealed case to form the positive pressure chamber 11 and the transformer chamber 12, and controls the inflow of air into the open central portion on the rear side to change the pressure. The valve body 16 for opening and closing the seal 12, and the pedal shaft 17 is linked by the brake pedal (not shown) and thus one end is coupled to the diaphragm 15 to receive the force of displacement, The other end is provided with a push rod 18 is connected to the master cylinder (30). Moreover, it consists of the return spring 19 etc. which return the push rod 18 and the diaphragm 15 between the front inner surface and the diaphragm 15. As shown in FIG. The booster 10 maintains the constant pressure chamber 11 and the transformer chamber 12 in a vacuum state when not in operation, and when the brake pedal (not shown) is pressed, external air passes through the valve body 16. The differential pressure between the positive pressure chamber 11 and the transformer chamber 12 is generated while flowing into the transformer chamber 12. As a result, the operable diaphragm 15 is pushed toward the positive pressure chamber 11 so that the push rod 18 is advanced toward the master cylinder 30 with a force amplified by the force applied to the pedal shaft 17 by the driver. When the force applied to the pedal shaft 17 is released, the push rod 18 and the diaphragm 15 are returned to their original state by the return spring 19.

The master cylinder 30 is provided with a body 40 whose rear side is opened so that the push rod 18 of the booster 10 protruding outward can be inserted. The upper side of the body 40 is provided with an oil tank (20) provided with oil supply pipes (21, 22) in the front, rear, these two oil supply pipes (21, 22) are the front wheel and the rear wheel in the master cylinder (30) The wheel cylinders (not shown) will be provided to generate hydraulic pressure, respectively.

Inside the body 40, a first piston 50 is installed to the booster 10 side and connected to the push rod 18, and the first spring 55 and the front of the first piston 50 are installed. The second piston 60 and the second spring 68 are provided, and a stop ring 45 is installed at the rear side of the opened body 40 to prevent the outside of the components installed therein.

In addition, a first discharge pipe connected to a rear wheel cylinder (not shown) is provided in the first hydraulic chamber 41 in which the first spring 55 is installed between the first piston 50 and the second piston 60. 42 is provided, the front wheel-side wheel cylinder (not shown) in the second hydraulic chamber (43) provided with a second spring (68) between the second piston (60) and the inside of the front side of the closed body (40). Is connected to the second discharge pipe 44 is provided.

The first piston 50 is provided with an opening groove 52 opened therein toward the push rod 18. The push rod 18 is inserted into the opening groove 52 to be in close contact with the push rod 18 when the push rod 18 moves forward. The first and second sealing members 51a and 51b are installed at the front and rear sides, and the cutoff hole communicating with the rear oil supply pipe 22 of the oil tank 20 is provided at the front and rear of the first sealing member 51a at the front side. 53 and a supplementary hole 54 are provided.

The second piston 60 is provided with a second sealing member (61a, 61b) is installed in the front, rear side, the sliding hole 62 of the long hole is provided in the middle of the body 40 in the sliding hole 62 Stop pins 63 are fixed to the upper and lower sides of the inner side. In addition, a supply hole 64 communicating with the front side oil supply pipe 21 of the oil tank 20 is provided above the sliding hole 62, and a supply hole 64 is provided at the front side of the sliding hole 62. A center valve 65 is provided to open and close the oil supplied through the second hydraulic chamber 43. The center valve 65 is provided with an operation pin 66 which is elastically supported toward the stop pin 63 side, which is open when pressed in close contact with the stop pin 63 inside the sliding hole 62. It is to be closed when spaced apart.

On the other hand, between the first piston 50 and the second piston 60 is provided with a weaker elastic force than the second spring 68 so that the first piston 50 can operate before the second piston 60 first The spring 55 is installed, the retainer 70 is provided on the front side of the first spring 55, and the fixing plate 80 is provided on the rear side. That is, the retainer 70 provided on the second piston 60 side is formed to protrude toward the first piston 50 side and the inside thereof is hollow, and the front side of the outer circumference faces the second piston 60. On the rear side, the first spring 55 is seated. The fixing plate 80 is in close contact with the front side of the first piston 50 to support the first spring 55, and is fixed to the first piston 50 by the stem 90. The stem 90 controls the length of the first spring 55 to regulate the distance between the first piston 50 and the second piston 60, and is inserted into the retainer hole 71 formed in the retainer 70. Although sliding, the rear side is formed with a screw portion 92 is inserted and fixed in the screw groove 258 provided on the front side of the first piston 50, the front side is a head portion 91 that extends inside the retainer hole 71 Is made of.

In the conventional master cylinder 30 configured as described above, when the push rod 18 of the booster 10 pushes the first piston 50 of the master cylinder 30 to generate pressure, the front side of the first piston 50 is provided. The first sealing member (51a) is installed at the same time to compress the fluid while passing through the cut-off hole 53, to block the flow of oil into the first hydraulic chamber (41). At this time, as the replenishment hole 54, the oil at the rear side of the first piston 50 flows back into the oil tank 20 to reduce the compressive resistance generated by the movement of the first piston 50.

Due to the operation of the first piston 50, the oil is compressed in the first hydraulic chamber 41 to push the second piston 60, and the first spring 55 is equal to the elastic force of the second spring 68. Until it is compressed, it pushes the retainer 70. This causes the second piston 60 to be pushed out. At this time, the operation pin 66 of the center valve 65 installed in the second piston 60 is spaced apart from the stop pin 63 so that the second spring 68 is installed. The oil supply to the second hydraulic chamber 43 is cut off. Due to this operation, hydraulic pressure is generated in the first hydraulic chamber 41 and the second hydraulic chamber 43, and the wheels on the front wheel and the rear wheel side are connected to the first discharge pipe 42 and the second discharge pipe 44 connected thereto. Hydraulic pressure is supplied to a cylinder (not shown) to operate a brake (not shown).

Upon release of pressure after operation of the brake (not shown), the push rod 18 is returned by the return spring 19, the first piston 50 by the first spring 55, and the second piston. Numeral 60 is to return to the original state by the second spring (68). That is, since the push rod 18, the first piston 50, and the second piston 60 are separated from each other, the push rod 18, the first piston 50, and the second piston 60 are in close contact with each other during the operation of the master cylinder 30. It is returned by the restoring force of the spring.

However, in the conventional master cylinder configured as described above, in order to secure durability according to the repeated operation of the spring and to secure the minimum length when it is compressed, the mounting length should be ensured more than a certain length according to the working load.

In other words, when the length of the hydraulic chamber in which the spring is installed is short, the compression ratio of the spring installed therein is increased, so that the elastic force of the spring decreases during the repeated operation of the spring. In order to secure the minimum length of the hydraulic cylinder, the length of the hydraulic chamber is increased, and thus, the total length of the master cylinder is increased.

In this way, since the total length of the master cylinder is increased, the material cost is increased compared to the short master cylinder under the same conditions, which is disadvantageous in processing and the like. In addition, the incidence of the reverse operation of the master cylinder and the booster due to the collision between the parts in the engine room during the collision of the vehicle, and the difficulty of installation due to the interference with the peripheral parts when installing the engine cylinder of the master cylinder There was this.

The present invention is to solve this problem, the purpose is to form a second piston and a retainer integrally, and to form a ring groove on the first piston so that the second piston can be returned to the return spring provided in the booster In addition, the push rod is to provide a master cylinder of the brake device for a vehicle provided with a collet spring detachable to the ring groove.

1 is a longitudinal sectional view showing a conventional master cylinder and a booster.

2 is a longitudinal sectional view showing a master cylinder and a booster according to the present invention.

3 is an enlarged cross-sectional view of the first piston and the push rod according to the present invention.

4 is a perspective view of a collet spring according to the present invention.

5 is another embodiment of the present invention.

6 is another embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

110: booster 118: push rod 119: return spring

120: oil tank 200: master cylinder 250: first piston

255: first spring 259: ring groove 260: second piston

270: retainer 280: collet spring

The present invention for achieving the above object, the reciprocating push rod and the booster is provided with a return spring to return the push rod, one side is coupled to the booster and one end of the push rod can be inserted into the inside A body of an opened master cylinder, a first piston having an opening groove into which the push rod is inserted to be moved forward by the push rod in the body, and fixed to protrude on a side to which the first piston is moved forward A stem provided with a head at a protruding end, a retainer provided with a retainer hole to be pulled by the head when the stem is inserted and slid in the backward movement of the first piston, and the first to generate hydraulic pressure to the retainer side The second piston is provided to be moved forward by the forward movement of the piston, the second blood Hydraulic pressure is generated in the first hydraulic chamber and the first hydraulic chamber formed between the ton and the first piston, so that the second piston and the body are closed to generate hydraulic pressure when the second piston is moved forward. In a brake device for a vehicle having a second hydraulic chamber formed between the other side, the first spring is provided between the first piston and the second piston so as to recover the first piston, protrudes toward the first spring side A ring groove recessed in an circumferential direction on an inner surface of the opening groove of the first piston into which the push rod is inserted to move the second piston and the second piston to be moved forward; A fixed surface coupled between the plurality of elastic surfaces protruding to the outer circumferential side and the elastic surface so as to be inserted into the ring groove and coupled to the push rod. A collet spring is provided, and when the push rod is moved forward, the first piston and the second piston are interlocked so that hydraulic pressure is generated in the first hydraulic chamber and the second hydraulic chamber, and the push rod is retracted by the restoring force of the return spring. The first piston may be returned by the restoring force of the return spring and the restoring force of the first spring, and the second piston may be returned by the restoring force of the return spring.

Hereinafter, with reference to the accompanying drawings will be described in detail an embodiment according to the present invention.

2 is a longitudinal sectional view showing a master cylinder and a booster according to the present invention. 3 is an enlarged cross-sectional view of the first piston and the push rod according to the present invention. 4 is a perspective view of a collet spring according to the present invention. 5 is another embodiment of the present invention, and FIG. 6 is another embodiment of the present invention.

One side of the brake pedal (not shown) installed in the driver's seat of the vehicle is connected to the booster 110 to amplify the force applied to the master cylinder 200. The booster 110 divides the inner space of the sealed case to form a positive pressure chamber 111 and a transformer chamber 112, and controls the inflow of air into the open center of the rear side to transform the transformer. The valve body 116 to open and close the seal 112, and the pedal shaft 117 linked by the brake pedal (not shown) and thus one end is coupled to the diaphragm 115 to receive the force of displacement, The other end is provided with a push rod 118 is connected to the master cylinder (200). Moreover, it consists of the return spring 119 etc. which return the push rod 118 and the diaphragm 115 between the front inner surface and the diaphragm 115. As shown in FIG. The booster 110 maintains the positive pressure chamber 111 and the transformer chamber 112 in a vacuum state when not in operation, and when the brake pedal (not shown) is pressed, external air passes through the valve body 116. The differential pressure between the positive pressure chamber 111 and the transformer chamber 112 is generated while flowing into the transformer chamber 112. As a result, the operable diaphragm 115 is pushed toward the positive pressure chamber 111 and the push rod 118 is advanced toward the master cylinder 200 with a force amplified by the force applied to the pedal shaft 117 by the driver. When the force applied to the pedal shaft 117 is released, the push rod 118 and the diaphragm 115 are returned to their original state by the return spring 119.

The master cylinder 200 is provided with a body 240 in which the rear side is opened so that the push rod 118 of the booster 110 protruding to the outside may be inserted to be in close contact with the booster 110. The upper side of the body 240 is provided with an oil tank 120 is provided with oil supply pipes (121, 122) in the front, rear, these two oil supply pipes (121, 122) are the wheel cylinders of the front wheel and rear wheel in the master cylinder (200) It is provided to be able to generate a hydraulic pressure to each).

Inside the body 240, a first piston 250 is installed toward the booster 110 and connected to the push rod 118, and a first spring 255 is provided in front of the first piston 250. The stem 290, the retainer 270, and the second piston 260 are provided at the front thereof. A stop ring 245 is installed at the rear side of the opened body 240 to prevent the first piston 250 from being separated and at the same time, to prevent the outside of the components installed therein.

In addition, a first discharge pipe connected to a rear wheel cylinder (not shown) is provided in the first hydraulic chamber 241 in which the first spring 255 is installed between the first piston 250 and the second piston 260. 242 is provided, the second hydraulic chamber (243) formed between the second piston 260 and the inside of the front side of the closed body 240 is connected to the front wheel side wheel cylinder (not shown) The discharge pipe 244 is provided.

In addition, the first sealing member 251 is installed on the front and rear outer circumferential sides of the first piston 250, the front and rear of the first sealing member 251 in front of the communication with the rear oil supply pipe of the oil tank 120. Cutoff holes 253 and supplementary holes 254 are provided. In addition, second sealing members 261a and 261b are installed at the front and rear outer circumferential sides of the second piston 260, and a sliding hole 262 is formed in the middle of the second piston 260 to penetrate up and down. The inside of the sliding hole 262 is provided with a stop pin 263 penetrating the sliding hole 262 to be fixed to the upper and lower sides of the body 240. The upper side of the sliding hole 262 is provided with a supply hole 264 in communication with the front side oil supply pipe 121 of the oil tank 120, the front side of the sliding hole 262 is provided with a supply hole 264 A center valve 265 is provided to open and close the oil supplied to the sliding hole 262 through the second hydraulic chamber 243. The center valve 265 is opened when the operating pin 266 is elastically supported toward the stop pin 263 is pressed in close contact with the stop pin 263 in the sliding hole 262, It is intended to be closed when spaced apart.

Meanwhile, in the present invention, the retainer 270 provided between the first piston 250 and the second piston 260 to return the second piston 260 to the return spring 119 provided in the booster 110. ) Is integrally formed with the second piston 260, and a ring groove 259 and a collet spring 280 are provided between the first piston 250 and the push rod 118 to be formed by the push rod 118. The first piston 250 and the second piston 260 are interlocked. This will be described in detail as follows.

First, a retainer 270 is provided at the front side of the first spring 255. The retainer 270 is formed integrally with the second piston 260 and protrudes toward the first piston 250 so that the inside thereof is provided in a hollow shape, and the retainer (270) protrudes toward the first piston 250 so as to face each other. A retainer hole 271 that communicates the inside and the outside of the 270 is provided, and both sides of the outer circumferential surface are opened to provide a stem 290 to be described later. That is, since the retainer 270 is formed integrally with the second piston 260, the retainer 270 is provided to be able to interlock with the second piston 260 in the forward and backward directions.

In addition, a fixing plate 230 supporting the first spring 255 is installed at the first piston 250 corresponding to the retainer 270. As a result, the first spring 255 installed between the first piston 250 and the second piston 260 through the retainer 270 and the fixing plate 230 is a first piston 250 and a second piston 260. ) Is restored when the space is compressed.

In addition, the stem 290, which is installed to allow the first piston 250 to pull the retainer 270, is provided with a screw portion 292 at one end thereof, and is coupled to the screw groove 258 on the front side of the first piston 250, The intermediate end fixed and extending therefrom is provided to be able to slide in the retainer hole 271, and the other end inserted into the retainer 270 is larger than the diameter of the retainer hole 271 so that the first piston 250 is formed. When moving forward, it is advanced due to the sliding of the intermediate stage, and the head portion 291 so that the first piston 250 can be retracted toward the push rod 118 and the retainer 270 can be pulled over the retainer hole 271 when returning. ) Is provided.

In addition, between the first piston 250 and the push rod 118 and the ring groove 259 formed in the first piston 250 so as to interlock the first piston 250 and the push rod 118 and The collet spring 280 is coupled to the push rod 118 to be detachably attached to the ring groove 259, and the ring groove 259 is opened to the push rod 118 in the first piston 250. A circular groove recessed in the outer peripheral surface side of the inlet side of the groove 252, the cross section is provided in a quadrangle, chamfered to the outside of the opening groove 252 in which the ring groove 259 is formed, the collet spring 280 Facilitates the insertion of

The collet spring 280 is provided to be detachably attached to the ring groove 259, and is coupled to the ring groove 259 as a coupling force that can link the first piston 250 and the second piston 260. It is provided to be separated from the ring groove 259 when receiving more force, the structure is bent in one direction by bending the outer surface of the metal plate provided in a circular shape, one end is connected to the inner surface and the other end is formed as a free end The outer surface is to generate an elastic force to the inside and outside. The bent outer surface of the collet spring 280 is a plurality of elastic surfaces 283 formed with projections 284 protruding to the outer circumferential side to be inserted into the ring groove 259, and between each elastic surface 283 It is cut and provided so as to generate an elastic force, respectively, and the protrusion part 284 is formed of a triangle whose cross section protrudes to the outside, and the protruding vertex is in close contact with the outer circumferential side inside the ring groove 259 and both sides of the vertex are ring grooves ( 259) close to the outside of the inlet. A fixing surface 281 connected to one end of each elastic surface 283 is provided inside the elastic surface 283. The fixed surface 281 is a circular plate and has a coupling hole 282 formed therethrough so as to be coupled to the outer circumference of the push rod 118 at the center thereof.

The extension member 130 is provided on the outside of the push rod 118 to be coupled to the collet spring 280 to be interlocked with the first piston 250. The extension member 130 is provided with an adjusting portion 131 is screwed with the inner side of the push rod 118 to adjust the length of the push rod 118 and the outer end is formed in a hemispherical opening groove 252 It will be in close contact with the inner surface of the. In addition, two adjusting nuts 132 are provided between the adjusting part 131 and the outer front end to fix and fix the fixing surface 281 of the collet spring 280 therebetween. That is, the adjusting part 131 of the extension part adjusts the external extension length of the extension part and the push rod 118 and transfers the position of the collet spring 280 by adjusting two adjustment nuts 132 provided at the outside thereof. It is prepared to be adjusted backwards.

The master cylinder 200 of the present invention configured as described above, when the push rod 118 of the booster 110 pushes the first piston 250 of the master cylinder 200 to generate pressure, the front of the first piston 250 The first sealing member 251 installed at the side compresses the fluid and passes the cutoff hole 253 to block oil from flowing into the first hydraulic chamber 241. At this time, as the refilling hole 254, the oil generated at the rear of the first piston 250 due to the forward movement of the first piston 250 while the oil at the rear side of the first piston 250 flows back to the oil tank 120. Will reduce the resistance.

The oil is compressed in the first hydraulic chamber 241 by the forward movement of the first piston 250. As a result, the retainer 270 integrally formed with the second piston 260 is compressed while the first spring 255 is compressed. At this time, the operation pin 266 of the center valve 265 installed in the second piston 260 is spaced apart from the stop pin 263 to block the oil supply to the second hydraulic chamber 243. Due to this operation, hydraulic pressure is generated in the first hydraulic chamber 241 and the second hydraulic chamber 243, and the wheels at the front wheel and the rear wheel side are connected to the first discharge pipe 242 and the second discharge pipe 244 connected thereto. Hydraulic pressure is supplied to a cylinder (not shown) to operate a brake (not shown).

When the pressure is released after the brake (not shown), the push rod 118 is returned by the return spring 119, and the first piston 250 provided to interlock with the push rod 118 is the push rod 118. And the first spring 255 returns to its original state. At this time, since the first piston 250 and the second piston 260 are returned by the first spring 255, the first piston 250 and the second piston 260 can be quickly interlocked. Due to the return of the first piston 250, the head 291 of the stem 290 coupled to the front side of the first piston 250 pulls the retainer 270, and is formed integrally with the retainer 270. The two pistons 260 are moved back to return to their original state. That is, the push rod 118, the first piston 250, and the second piston 260 are returned to their original state by the return spring 119 provided in the booster 110. The first spring 255 is returned more quickly and at the same time the linkage with the second piston 260 is made faster, thereby improving the overall response of the master cylinder 200.

Hereinafter, another embodiment of the present invention will be described. Another embodiment of the present invention is the same as the embodiment of the present invention except for the components other than the configuration for supplying oil to the first hydraulic chamber and the second hydraulic chamber uses the same name and the same reference numerals for the same parts, one embodiment The same components as in the example will be omitted.

The first piston 250 and the push rod 118 are connected by the ring groove 259 and the collet spring 280, the second piston 260 is provided integrally with the retainer 270. In addition, a first discharge pipe 242 connected to a rear wheel cylinder (not shown) is provided in the first hydraulic chamber 241 formed between the first piston 250 and the second piston 260. A second discharge pipe 244 connected to the front wheel side wheel cylinder (not shown) is provided in the second hydraulic chamber 243 formed between the second piston 260 and the inside of the front side of the closed body 240. do. In addition, a first cutoff hole 353 and a first supplementary hole 354 are provided in the first hydraulic chamber 241, and a second cutoff hole 453 and a second supplemental hole ( 454).

First, the first sealing member 251 is installed on the front and rear outer circumferential sides of the first piston 250, the front and rear of the first sealing member 251 on the front side of the rear oil supply pipe 122 of the oil tank 120 ) Is provided with a first cutoff hole 353 and a first supplementary hole 354. The first cut-off hole 353 is provided to open and close the oil supply port of the oil tank 120 and the first hydraulic chamber 241 according to the movement of the first piston 250, the first supplement hole 354 communicates a space between the outer peripheral surface of the rear side of the first piston 250 and the body 240 to the oil tank 120 so as to reduce the pressure resistance generated as the first piston 250 moves forward. It is prepared to be.

The second sealing members 261a and 261b are installed at the front and rear outer circumferential sides of the second piston 260, and the front and rear of the second sealing member 261a at the front side is provided with a rear oil supply pipe ( A second cutoff hole 453 and a second supplementary hole 454 communicating with 122 are provided. The second cut-off hole 453 is provided to open and close the oil supply port of the oil tank 120 and the second hydraulic chamber 243 provided in accordance with the movement of the second piston 260, the second supplement hole 454 communicates the space between the outer peripheral surface of the rear side of the second piston 260 and the body 240 to the oil tank 120 so as to reduce the pressure resistance generated as the second piston 260 moves forward. It is prepared to be.

The master cylinder 200 according to another embodiment of the present invention configured as described above is provided at the front side of the first piston 250 when the push rod 118 of the booster 110 pushes the first piston 250 of the master cylinder 200. The installed second sealing member 261a compresses the fluid and passes the first cutoff hole 353 to block the oil from flowing into the first hydraulic chamber 241. At this time, the oil at the rear side of the first piston 250 flows back into the oil tank 120 as the first supplementary hole 354 and is generated at the rear of the first piston 250 due to the forward movement of the first piston 250. This reduces the compression resistance. As the first piston 250 moves forward, the oil is compressed in the first hydraulic chamber 241, which causes the second piston 260 and the retainer 270 integrally formed thereon to be pushed out. The second sealing member 261a provided at the front side of the 260 compresses the fluid and passes the second cutoff hole 453 to block the oil from flowing into the second hydraulic chamber 243. At this time, the oil of the rear side of the second piston 260 flows back into the oil tank 120 as the second supplementary hole 454 and is generated at the rear of the second piston 260 due to the forward movement of the second piston 260. It will reduce the compression resistance.

When the pressure is released after the brake (not shown), the push rod 118, the first piston 250, and the second piston 260 are returned to their original state by the return spring 119 provided in the booster 110. The first piston 250 returns with the first spring 255 more quickly.

Hereinafter, another embodiment of the present invention will be described. Another embodiment of the present invention is the same parts except for the configuration of supplying oil to the first hydraulic chamber and the second hydraulic chamber is the same as the embodiment of the present invention, the same name and the same reference numerals are used for the same parts. The same components as in the embodiment will be omitted.

The first piston 250 and the push rod 118 are connected by the ring groove 259 and the collet spring 280, the second piston 260 is provided integrally with the retainer 270. In addition, a first discharge pipe 242 connected to a rear wheel cylinder (not shown) is provided in the first hydraulic chamber 241 formed between the first piston 250 and the second piston 260. A second discharge pipe 244 connected to the front wheel side wheel cylinder (not shown) is provided in the second hydraulic chamber 243 formed between the second piston 260 and the inside of the front side of the closed body 240. do. In addition, a first center valve 565 and a second center valve 665 are provided in the first piston 250 and the second piston 260.

First, the first sealing member 251 is installed at the front and rear outer circumferential sides of the first piston 250, and the first sliding hole 562 having a long hole penetrating up and down is provided in the middle of the first piston 250. The first sliding hole 562 is provided with a first stop pin 563 penetrating the first sliding hole 562 to be fixed to the upper and lower sides of the body 240. The upper side of the first sliding hole 562 is provided with a first supply hole 564 in communication with the front side oil supply pipe 121 of the oil tank 120, the front side of the first sliding hole 562 A first center valve 565 is provided to open and close the oil supplied to the first sliding hole 562 through the first supply hole 564 into the first hydraulic chamber 241. When the first center valve 565 is pressed in close contact with the first stop pin 563 inside the first sliding hole 562 is provided with a first operating pin 566 elastically supported toward the first stop pin (563) side. It is intended to be closed when open and spaced apart.

In addition, second sealing members 261a and 261b are provided at the front and rear outer circumferential sides of the second piston 260, and the second sliding hole 662 of the long hole penetrates upward and downward in the middle of the second piston 260. The second sliding hole 662 is provided with a second stop pin 663 penetrating the second sliding hole 662 so as to be fixed to the upper and lower sides of the body 240. On the upper side of the second sliding hole 662, a second supply hole 664 communicating with the front side oil supply pipe 121 of the oil tank 120 is provided, and the front side of the second sliding hole 662 is provided. A second center valve 665 is provided to open and close the oil supplied to the second sliding hole 662 through the second supply hole 664 to the second hydraulic chamber 243. When the second center valve 665 is pressed in close contact with the second stop pin 663 in the second sliding hole 662, a second operation pin 666 is elastically supported toward the second stop pin 663 side. It is intended to be closed when open and spaced apart.

In addition, the other end of the stem 290 having one end of the head 291 is provided with a plurality of coupling legs 667 to be coupled to the first piston 250 provided with the first center valve 565, this coupling The legs 667 extend from the middle side of the stem 290 to the outer circumferential direction and are bent toward the first center valve 565, and the coupling legs 667 are spaced apart from each other by a predetermined distance therebetween. The oil is flowing. The outer side of the coupling leg 667 is provided to be close to the inside of the first hydraulic chamber 241 to support the other end of the first spring 255, one end of which is supported by the retainer 270.

The master cylinder 200 according to another embodiment of the present invention configured as described above has the first center valve installed in the first piston 250 when the first piston 250 is pushed by the push rod 118 of the booster 110. The first actuating pin 566 of 565 is spaced apart from the first stop pin 563 to block the oil supply to the first hydraulic chamber 241. As the oil is cut off, the hydraulic pressure is generated in the first hydraulic chamber 241 and the second piston 260 is pushed out, and the second operation pin 666 of the second center valve 665 installed in the second piston 260 is blocked. ) Is spaced apart from the second stop pin (663) and the oil supply to the second hydraulic chamber (243) is cut off to generate the hydraulic pressure. Accordingly, the hydraulic pressure generated in the first hydraulic chamber 241 and the second hydraulic chamber 243 is the wheel cylinders on the front and rear wheels (not shown) through the first discharge pipe 242 and the second discharge pipe 244. Is delivered to the brake to operate the brake (not shown).

When the pressure is released after the brake (not shown), the push rod 118, the first piston 250, and the second piston 260 are returned to their original state by the return spring 119 provided in the booster 110. The first piston 250 returns with the first spring 255 more quickly.

As described above, since the master cylinder 200 of the present invention does not have a separate spring for returning the second piston 260, a space for ensuring the durability of the spring and a space required for the minimum compression of the spring can be deleted. The length of the master cylinder 200 can be reduced, and since the first piston 250 is returned by the first spring 255 and the return spring 119, the response is improved.

The present invention provides a retainer formed integrally with the second piston so that the second piston can be returned by using the restoring force of the return spring to restore the push rod instead of using a spring installed on the second piston to restore it. , Having a ring groove and a collet spring coupled to each other, the length necessary for the operation duration of the spring for returning the second piston and the length to ensure the minimum length when compressed, can be deleted, so that the total length of the master cylinder To be able to collapse. This reduces material costs and processing time, reduces the incidence of reverse operation of the master cylinder and booster due to collisions between components inside the engine room during a vehicle collision, and interferes with peripheral components when installing the engine cylinder of the master cylinder. There is an advantage that the installation is easy to reduce. In addition, since the restoring force of the return spring acts upon the return of the first piston returned by the first spring, the first piston is quickly returned, and the second piston linked thereto is quickly returned. This has the advantage of improving the responsiveness of the master cylinder.

Claims (4)

Booster provided with a return spring to return the push rod and the reciprocating motion, the body of the master cylinder coupled to the booster and one side is opened so that one end of the push rod can be inserted into the inside, the body of the A first piston having an opening groove into which the push rod is inserted so that the push rod can be moved forward by the push rod, the stem having a head at a protruding end thereof, fixed to protrude on a side to which the first piston moves forward, the stem A retainer having a retainer hole provided therein so as to be pulled by the head during the backward movement of the first piston, and being moved forward by the forward movement of the first piston generating hydraulic pressure to the retainer side; A second piston provided, a first formed between the second piston and the first piston A vehicle brake including a hydraulic chamber and a second hydraulic chamber formed between the second piston and the other closed side of the body to generate hydraulic pressure when the hydraulic pressure is generated in the first hydraulic chamber and the second piston moves forward. In the apparatus, A first spring provided between the first piston and the second piston so that the first piston can be restored, the second piston integrally formed with the retainer provided to protrude toward the first spring, and the second A ring groove recessed in an circumferential direction in an inner circumferential direction of the opening groove of the first piston into which the push rod is inserted to move the piston forward, and a plurality of elastic surfaces protruding to the outer circumferential side so as to be inserted into the ring groove; A collet spring consisting of a fixed surface coupled between the elastic surfaces and coupled to the push rod is provided, so that the first piston and the second piston are interlocked with each other when the push rod is advanced in the first hydraulic chamber and the second hydraulic chamber. When the hydraulic pressure is generated and the push rod is retracted by the restoring force of the return spring, the first piston is configured to recover the return spring. And wherein the force is returned by the restoring force of the first spring and the second piston, the master cylinder for a vehicle brake device characterized in that the return by the restoring force of the return spring. The method of claim 1, An oil tank provided on the outside of the body to supply oil to the first hydraulic chamber and the second hydraulic chamber, and between the oil tank and the first hydraulic chamber so as to be opened and closed according to the movement of the first piston. A cut-off hole provided, a sliding hole provided in the second piston to communicate with the oil tank, a stop pin fixed to the inside of the sliding hole, and an operation pin pressed or spaced apart from the stop pin is built in the sliding hole. The master cylinder of the brake device for a vehicle, characterized in that the center valve is provided inside the second piston to open and close between the hole and the second hydraulic chamber. The method of claim 1, An oil tank provided on the outside of the body to supply oil to the first hydraulic chamber and the second hydraulic chamber, and between the oil tank and the first hydraulic chamber so as to be opened and closed according to the movement of the first piston. The master cylinder of the brake device for a vehicle, characterized in that the first cut-off hole provided, the second cut-off hole provided in the body to open and close between the oil tank and the second hydraulic chamber in accordance with the movement of the second piston. . The method of claim 1, An oil tank provided outside the body to supply oil to the first hydraulic chamber and the second hydraulic chamber, a first sliding hole provided inside the first piston to communicate with the oil tank, and the first sliding. A first stop pin fixed to the inside of the hole and a first actuating pin pressed or spaced apart from the first stop pin are embedded to open and close the first sliding hole and the first hydraulic chamber. A first center valve installed at the second valve, a second sliding hole provided in the second piston to communicate with the oil tank, a second stop pin fixed to the second sliding hole, and the second stop pin. A second center valve is installed inside the second piston so that the second operating pin is pressed or spaced internally to open and close between the second sliding hole and the second hydraulic chamber. Ryangyong master cylinder of the brake unit.