JPH05319247A - Air brake system - Google Patents

Abstract

PURPOSE:To eliminate shortage of braking force when brake is applied by making it possible to supply the specified pressure which is lower than the pressure to be supplied when a selector valve is opened as control pressure for a pressure control valve when the selector valve which is opened or closed by operator is closed. CONSTITUTION:For example when load on vehicle is small and a selector valve 13 is changed over to the position communicating with atmospheric air by shutting off from an air reservoir 1, compressed air pressure to be supplied into a control chamber A of a pressure restriction valve 9 by a pressure reducing valve 15 is kept under the specified pressure lower than that of the air reservoir 1. A stepped piston 27 of the pressure restriction valve 9 is moved to an exhaust support 24 side due to the specified pressure, and a valve 33 makes input and output chambers C, B communicate irrespective of stepping on a brake pedal 5a. When brake starts to act, it is possible to increase pressure of a rear brake chamber 11 equally with pressure from a brake valve 5 which supplies pressure into the input chamber C of the pressure restriction valve 9 through a pipe passage 8. After that, it is possible to restrict increase rate to a lower rate than pressure of the brake valve 5 due to pressure reduction of the pressure restriction valve 9.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an air brake system which is mounted on a vehicle such as a truck or a bus and which can obtain a braking force according to the size of a loaded load.

[0002]

2. Description of the Related Art An air brake system of this type is disclosed in Japanese Patent Application Laid-Open No. 1-148650. This is a reservoir that stores compressed air, a brake valve that discharges compressed air from the reservoir according to the driver's operation, and a switching valve that is opened and closed by the driver separately from this brake valve. And a pressure limiting valve for deactivating compressed air supplied from the brake valve depending on the presence / absence of control pressure depending on the opening / closing of the switching valve, and a brake valve supplied through the pressure limiting valve. In an air brake system equipped with an actuator that operates with a pressure, the switching valve is a controller of a reservoir and a pressure limiting valve.
It is provided so as to open and close a passage communicating with the report.

[0003]

SUMMARY OF THE INVENTION This conventional air blower
In the system, the load capacity of the vehicle is small and the switching valve (2
When the way control valve) is switched to the closed position, the operation of the brake valve is started to apply the brake, and when the discharge pressure of the brake valve starts to increase from 0, the pressure limiting valve ( Since no control pressure is introduced into the limiting and quick release valve), the pressure supplied to the actuator is limited to a lower rate of rise than the discharge pressure in the brake valve by the depressurizing operation of the pressure limiting valve immediately. To be done. However, at the beginning of the braking effect, a sufficient braking force can be obtained by increasing the discharge pressure of the braking valve to the same level regardless of the loading load. There is a problem of lack of strength.

The present invention has been made to solve this problem, and it is an object of the present invention to provide an air brake system capable of eliminating the insufficient braking force at the beginning of the brake operation when the switching valve is closed. To aim.

[0005]

In order to achieve the above object, the air brake system of the present invention has a reservoir for storing compressed air and the compressed air from the reservoir in response to a driver's operation input. A brake valve that regulates and discharges pressure by means of a valve, and a switching valve that is opened and closed by a driver separately from the brake valve and that can deliver compressed air from the discharge side or the reservoir side of the brake valve by sending it. A pressure control valve which is provided so as to be able to reduce the pressure of the compressed air discharged from the brake valve, and the pressure reduction operation is invalidated by introducing the pressure of the compressed air as a control pressure in response to the opening operation of the switching valve; In an air brake system including an actuator that applies a brake to a wheel by supplying compressed air from the brake valve via a pressure control valve, closing the switching valve. When, characterized by being capable of supplying the valve opening predetermined pressure lower than the pressure supplied by the switch valve as a control pressure for said pressure control valve.

Further, the communication passage connecting the control port into which the control pressure of the pressure control valve is introduced to the discharge side or the reservoir side of the brake valve is provided at one end side thereof. The movable body has a movable body for receiving the pressure of the spring and the pressure of the spring and the pressure sent by the switching valve on the other end side, and the force acting on the one end side of the movable body is greater than the force acting on the other end side. Also, a valve device is provided for shutting off the communication passage in accordance with an increase in the size.

[0007]

In the air brake system of the present invention described above,
Even when the switching valve is operated to the closed position, a lower control pressure acts on the pressure limiting valve than when the switching valve is opened. Therefore, the discharge pressure of the brake valve starts to increase from 0 and reaches a predetermined pressure. Since the pressure reducing operation of the pressure limiting valve is invalidated, the discharge pressure from the brake valve is directly supplied to the actuator during this period.

[0008]

【Example】

 Example 1 Hereinafter, Example 1 of the present invention will be described with reference to FIG.

FIG. 1 is a piping system diagram showing the entire air brake system. The entire air brake system will be described below with reference to FIG.

In FIG. 1, an air reservoir 1 is supplied with compressed air from a compressor (not shown) through a pipe line. Compressed air from the air reservoir 1 is supplied to the brake valve 5 through the lines 3 and 4, respectively.
The compressed air supplied from the air reservoir 1 through the pipe 3 is depressed from the pipe 6 through one of the service ports of the brake valve 5 when the pedal 5a of the brake valve 5 is depressed. It is adapted to be supplied to the break chamber 7. Further, the compressed air supplied from the air reservoir 1 to the brake valve 5 via the pipe line 4 passes through the other service port of the brake valve 5 when the pedal 5a of the brake valve 5 is depressed. Is supplied from a conduit 8 to a pressure limiting valve 9 (also called limiting and quick release valve) shown in FIG. 3 and described later, and the output pressure of the pressure limiting valve 9 is supplied to the conduit 10. It is supplied to the rear brake chamber 11 via the. The front brake chamber 7 and the rear brake chamber to which compressed air is supplied are
The chamber 11 converts the compressed air into mechanical force to operate the front brake and the rear brake via an adjuster (not shown).

Further, in this air-brake system, the compressed air from the air reservoir 1 is further supplied to the conduit 1
Is supplied to the switching valve 13 (2-way control valve) via 2 and is supplied to the pressure reducing valve 15 shown in FIG. 4 and described later in detail by the conduit 14 branched from the middle of the conduit 12. To be done. This switching valve 13 itself has a publicly known configuration, and by the switching operation of the driver's operation lever 13a, the side of the conduit 16 is shut off from the atmosphere and communicated with the conduit 12, or the conduit 16 is opened. It is placed in a closed position where it is cut off from the conduit 12 and communicates with the atmosphere, and compressed air from the air reservoir 1 is supplied to the conduit 16 side, or the conduit 16 side is communicated with the atmosphere by an exhaust conduit not shown. It is like this. The pipe 16 is connected to the pressure reducing valve 15, and the pressure reducing valve 15 is connected to the pressure limiting valve 9 via the pipe 17.

Next, details of the pressure limiting valve 9 and the pressure reducing valve 15 in FIG. 1 will be described with reference to FIGS.

In FIG. 3, the pressure limiting valve 9 has a main body 20 in which two members are fitted and connected, and inside the main body 20, a medium diameter hole portion 21A, a large diameter hole portion 21B, from the upper side of FIG. A cylinder hole 21 is formed in which the small diameter hole portion 21C is continuous. An input port 22 communicating with the medium diameter hole 21A is formed at one end of the main body 20, and the service port of the brake valve 5 is provided to the input port 22 through the conduit 8 in FIG. And a control port 23 that opens to this peripheral wall and communicates with the large-diameter hole portion 21B is formed, and the pressure reducing valve 15 is connected to this via a conduit 17 in FIG. An exhaust port 24 communicating with the small diameter hole portion 21C is formed at the other end of the main body 20, and is communicated with the atmosphere through an exhaust pipe (not shown). An output port 25 communicating with the portion 21C is formed, and the rear brake chamber 11 is connected to the output port 25 via the conduit 10 in FIG.

The cylinder hole 21 has a small diameter portion 27A and a large diameter portion 27 which extend to the medium diameter hole portion 21A and the large diameter hole portion 21B.
The stepped piston 27 having B has a seal ring 26A,
26B is interposed so as to be slidably fitted between the end wall 21a of the medium diameter hole portion 21A and the step portion 20a on the small diameter hole portion 21C side. The stepped piston 27 is urged toward the input port 22 by a spring 29 received by a spring receiving plate 28 fitted in the small diameter hole portion 21C of the cylinder hole 21, and normally, as shown in the figure. The control chamber A is in contact with the end wall 21a, and the shoulder portion 27a faces the step portion 21b of the large diameter hole portion 21B and the medium diameter hole portion 21A of the cylinder hole 21.
Is defined. The spring receiving plate 28 has a cup shape having a peripheral wall, and a plurality of small holes 30a are formed in the plate portion 30. By fitting the peripheral wall into the small diameter hole portion 21C, the small diameter hole portion is formed. An output chamber B is defined on the output port 25 side of 21C.

The stepped piston 27 is a taper which penetrates in the axial direction of the stepped piston 27 and connects the medium diameter hole portion 21A to the large diameter hole portion 21B.
A stepped hole 31 with a step is formed, and the taper of the stepped hole 31 is formed.
A valve seat 32 is formed in the reduced diameter portion, and a spherical air supply covered with rubber provided at the end of the valve rod 34 of the valve body 33 on the input port 22 side with respect to the valve seat 32. The valve member 35 can be seated and detached. Then, the air supply valve member 35
The input chamber C is defined on the side of the input port 22 of. The valve rod 34 extends toward the output chamber B side by being inserted in the order of the small-diameter communication hole 32a that opens to the end surface on the large-diameter portion 27B side of the stepped piston 27, the spring 29, and the tubular portion 28A of the spring receiving plate 28. A rubber-covered spherical exhaust valve member 36 provided at the end of the output chamber B is formed between the small-diameter hole portion 21C of the cylinder hole 21 and the exhaust port 24.
It opposes the par-shaped valve seat 37 so that it can be seated on and off. In addition,
The valve rod 34 of the valve body 32 has a cylindrical portion 28A of the spring receiving plate 28.
It is slidably fitted inside.

Next, the structure of the pressure reducing valve 15 will be described with reference to FIG.

In FIG. 4, reference numeral 45 denotes a valve main body of the pressure reducing valve 15, which has a cylinder hole 46 penetrating in the axial direction, and the exhaust port 4 connected to the cylinder hole 46 on the peripheral surface thereof.
7 and the outlet 48 are open. Cylinder hole 46
Is a large diameter hole portion 46A and a medium diameter hole portion 46 in order from the upper side of FIG.
B, the small diameter hole portion 46C and the valve hole portion 46D are continuous, and the lid members 49 and 50 are attached to the large diameter hole portion 46A opening and the valve hole portion 46D opening, respectively. Lid member 49
Is fitted into the large-diameter hole portion 46A with the seal ring 51 interposed, and communicates with the medium-diameter hole portion 46B so as to communicate with the control port 52.
1 is formed in the control port 52, and the conduit 1 in FIG.
The outlet of the switching valve 13 is connected via 6. Also,
The lid member 50 is fitted into the valve hole portion 46D with the seal ring 53 interposed, and an inlet 54 is formed in communication with the valve hole portion 46D. The inlet 54 is provided with the conduit 14 in FIG. The air reservoir 1 is connected through the air reservoir 1. Exit 4
8 is opened to the small diameter hole portion 46C through the lateral hole 48a and is communicated with the control port 23 of the pressure limiting valve 9 through the conduit 17 in FIG. 1, and the exhaust port 47 is constantly communicated with the atmosphere. Has been done.

Inside the cylinder hole 46, a piston 55 is slidably accommodated so as to extend to the medium diameter hole portion 46B and the small diameter hole portion 46C. The piston 55 is integrally formed with a large-diameter portion 55A, a medium-diameter portion 55B, a small-diameter portion 55C, and a shaft portion 55D that gradually decrease in diameter from the control opening 52 side. Has a recess 56 that opens,
A cylinder ring 46 is slidably fitted to an inner peripheral surface of a medium diameter hole portion 46B with a seal ring 57 interposed therebetween. The large diameter portion 55A defines a pressure chamber D in the large diameter hole portion 46A. Is made. Further, the piston 55 is biased toward the inlet 54 side by a preload spring 58 interposed between the bottom of the recess 56 and the lid member 49, and the middle diameter portion 55B is located inside the cylinder hole 46. It is adapted to engage with the end surface 46b of the radial hole portion 46B. The small-diameter portion 55C and the shaft portion 55D of the piston 55 are inserted into the small-diameter hole portion 46C of the cylinder hole 46. The small-diameter portion 55C has a seal ring 59 on the inner peripheral surface of the small-diameter hole portion 46C. It is slidably fitted, and the end of the shaft 55D projects into the valve hole 46D. An exhaust valve seat 60 is formed at the end of the shaft portion 55D so as to project radially outward. The exhaust valve seat 60 extends radially inward toward the medium diameter portion 55B of the piston 55 and extends toward the valve hole portion. An inverted L-shaped passage 61 is formed which communicates 46D with the exhaust port 32.

A valve member 62 is arranged in the valve hole portion 46D of the cylinder hole 46. The valve member 62 has a disk shape, and four protrusions 63 extending radially outward are formed at a peripheral portion of the valve member 62 at predetermined intervals in the circumferential direction. Supported cup-shaped spring support plate 64
Is urged toward the piston 55 side by a valve spring 65 interposed between the valve member 62 and the exhaust valve seat 60 of the piston 55, and the valve member 62 is a small-diameter hole portion 46 of the cylinder hole 46.
It faces the air supply valve seat 66 formed in the opening of the valve hole portion 46D of C so that it can be seated and detached. In the illustrated state, the valve hole portion 46
D communicates with the outlet 48, compressed air flows into the valve hole portion 46D from the air reservoir 1 through the pipe lines 12 and 14, and from the outlet 48 through the pipe line 17 to the control chamber A of the pressure limiting valve 9. To form a flow path to be supplied to.

The air brake system according to the first embodiment of the present invention is constructed as described above. Next, the operation of the air brake system will be described.

(1) When the vehicle has a small load: In FIG. 1, the driver operates the operation lever 13a of the switching valve 13 to switch the switching valve 13 to the pressure chamber D of the pressure reducing valve 15 to the air reservoir. Cut off from 1 and switch to the closed position to communicate with the atmosphere. As a result, in the pressure reducing valve 15 in FIG. 4, the pressure chamber D is not supplied with the compressed air and is in the atmospheric pressure state, but the compressed air from the air reservoir 1 passes through the pipe lines 12 and 14 to reduce the pressure reducing valve 15. Is supplied to the valve hole portion 46D. Therefore,
Compressed air flows from the valve hole portion 46D of the pressure reducing valve 15 to the small diameter hole portion 4
6C, through the lateral hole 48a and the line 17, the pressure limiting valve 9
Is supplied to the control room A of the pressure reducing valve 1 at this time.
The piston 55 of No. 5 receives the pressure of the compressed air flowing into the valve hole portion 46D in an area equal to the cross-sectional area of the small diameter portion 55C.
When the acting force corresponding to the pressure acting on the small diameter portion 55C overcomes the spring force of the preload spring 58, the piston 55 moves from the position shown to the control port 52 side, and the valve member 62 causes the valve spring 6 to move.
The urging force of 5 follows the movement of the piston 55 and approaches the air supply valve seat 66. And finally, the valve member 6
2 seats on the intake valve seat 66, blocking the outlet 48 from the inlet 54. Due to this cutoff, the compressed air is not supplied to the control chamber A of the pressure limiting valve 9 via the pipe line 17, and the pressure of the compressed air in the control chamber A of the pressure limiting valve 9 is the compressed air of the air reservoir 1. Pressure (eg 7-8Kg / C
It is kept at a predetermined pressure (for example, 1.5 Kg / Cm ² ) lower than m ² ).

The stepped piston 27 of the pressure limiting valve 9
Controls the pressure of the compressed air supplied to the control chamber A to the shoulder 2
When it is received by 7a, it moves to the output chamber B side together with the valve body 33, and the exhaust valve member 36 of this valve body 33 is seated on the valve seat 37 to shut off the output chamber B from the exhaust port 24. Thereafter, the air supply valve member 35 of the valve element 33 separates from the valve seat 32 formed on the stepped piston 27 while the stepped piston 27 moves until it comes into contact with the stepped portion 20a of the main body 20, The input chamber C communicates with the output chamber B through the communication hole 32a and the small hole 30a of the spring receiving plate 28. And the stepped piston 27
Remains at the position where it comes into contact with the stepped portion 20a of the main body 20.

In this state, when the driver depresses the pedal 5a to activate the brake, the compressed air from the air reservoir 1 passes through the brake valve 5 and the conduit 6 in response to the depression. Is supplied to the front brake chamber 7 and is also supplied to the input chamber C of the pressure limiting valve 9 via the conduit 8. At this time, in the pressure limiting valve 9, as described above, the air supply valve member 3 of the valve body 33 is already formed.
Since 5 is separated from the valve seat 32 and the input chamber C and the output chamber B are communicated with each other, the compressed air supplied to the input chamber C is rear-blown as it is via the output port 25 and the conduit 10. It is supplied to the chamber 11. That is, the pressure supplied to the rear brake chamber 11 is equal to that of the front brake chamber 7.
As the discharge pressure of the brake valve 5 rises with the pressure supplied to the brake valve 5, the brake begins to work.

After that, the pressure of the compressed air supplied from the brake valve 5 to the input port 22 of the pressure limiting valve 9 increases, and the pressure is kept constant by the pressure reducing valve 15. When the pressure exceeds the pressure in the output chamber B, the stepped piston 27 in the pressure limiting valve 9 (= the input chamber C).
Force exerted on the large diameter portion 27B by the pressure of
Since the pressure becomes larger than the force acting on the small diameter portion 27A, it moves from the position in contact with the stepped portion 20a to the input port 22 side. And according to this movement,
The output chamber B is cut off from the input chamber C by the air supply valve member 35 of the valve body 33 seated on the valve seat 32. After that, when the pressure supplied to the input chamber C rises and the force acting on the small diameter portion 27A of the stepped piston 27 becomes larger than the force acting on the large diameter portion 27B thereof, the stepped piston 27 is exhausted again. The air supply valve member 35 of the valve element 33 moves away from the valve seat 34, and the output chamber B and the input chamber C communicate with each other.
In this way, when the pressure of the compressed air supplied to the input port 22 exceeds the pressure in the control chamber A, the pressure limiting valve 9 reciprocates the stepped piston 27 so that the air supply valve member 35 operates as a valve. The seat 32 is repeatedly attached to and detached from the seat 32, and the rate of increase in the pressure sent to the rear brake chamber 11 via the output port 25 is limited to be smaller than the rate of increase in the pressure supplied from the brake valve 5 to the input chamber C. Yes, that is, a proportional decompression action is performed.

When the driver stops depressing the pedal 5a in order to release the operation of the brake, the compressed air supplied to the front brake chamber 7 is supplied to the brake valve 5 via the pipe 6. It is discharged from the exhaust port not shown,
The compressed air supplied to the rear brake chamber 11 is supplied even if the exhaust valve member 36 of the valve element 33 is seated on the valve seat 37 by the compressed air continuously supplied to the control chamber A of the pressure limiting valve 9. Since the air valve member 35 is separated from the valve seat 32, the air valve member 35 is discharged from the exhaust port of the brake valve 5 through the output chamber B, the input chamber C, and the pipe line 8 to be stored in the brake chambers 7 and 11. The pressure is released and the brake is released.

(2) When the vehicle has a large load: The pressures in the brake chambers 7 and 11 are released,
1, the driver operates the operating lever 13a of the switching valve 13 to release the pressure chamber D from the closed position where the switching valve 13 communicates the pressure chamber D of the pressure reducing valve 15 with the atmosphere in FIG. It is assumed that the air reservoir 1 has been switched to the open position where it communicates with the air reservoir 1. Due to the operation of (1), the pressure reducing valve 1 in FIG.
5, the piston 55 has already moved to the control port 52 side and the valve member 62 is seated on the intake valve seat 66.
When the acting force obtained by adding the spring force of the preload spring 58 to the force acting on the large diameter portion 55A of 5 becomes larger than the force acting on the small diameter portion 55C, the piston 55
Moves toward the inlet 54 side, the valve member 62 separates from the air supply valve seat 66 against the biasing force of the valve spring 64, and the valve hole portion 46D and the outlet 48 communicate with each other. After that, the pressure reducing valve 15 is connected to the large diameter portion 5
Since there is a pressure receiving area difference between 5C and the small diameter portion 55C, the inlet 5
4 and the outlet 48 are held in communication with each other. Due to this communication, the compressed air of the air reservoir 1 is transferred to the valve hole portion 46.
The pressure of the compressed air in the control chamber A is maintained at the same pressure as the compressed air pressure of the air reservoir 1 by being supplied from the outlet 48 to the control chamber A of the pressure limiting valve 9 through the pipe line 17.

The stepped piston 27 of the pressure limiting valve 9
When the shoulder 27a receives a pressure equal to the compressed air pressure of the air reservoir 1, the shoulder 27a is pressed toward the exhaust port 24 with a larger biasing force than in the case of (1), and the output chamber B is cut off from the exhaust port 26 and the input chamber C
The position where it is communicated with, in other words, the position where it abuts the step portion 20a.

In this state, when the driver depresses the pedal 5a to activate the brake, the compressed air from the air reservoir 1 passes through the brake valve 5 and the conduit 6 in response to the depression. It is supplied to the front brake chamber 7 and also supplied to the input chamber C of the pressure limiting valve 9 via the pipe 8. At this time, in the pressure limiting valve 9,
As described above, since the air supply valve member 35 of the valve element 33 has already been separated from the valve seat 34 and the input chamber C and the output chamber B are in communication with each other, the compressed air supplied to the input chamber C is It is directly supplied to the rear brake chamber 11 via the output port 25 and the conduit 10. That is, the rear brake chamber 1
The pressure supplied to No. 1 increases with the pressure supplied to the front brake chamber 7 at the same rate of increase as the discharge pressure of the brake valve 5, and the brake begins to work.

Thereafter, the pressure of the compressed air supplied from the brake valve 5 to the input port 22 of the pressure limiting valve 9 rises, and the pressure is kept at the pressure of the air reservoir 1. Even if the pressure becomes equal to the pressure of A, the stepped piston 27 in the pressure limiting valve 9 causes the force acting on the large diameter portion 27B by the pressure of the output chamber B (= the pressure of the input chamber C) to be larger than that of the input chamber C. Since the force exerted on the small diameter portion 27A by the pressure does not become larger than the force exerted on the shoulder portion 27a by the pressure of the control chamber A, the air supply valve member 35 of the valve body 33 is The output chamber B remains separated from the seat 32.
Are maintained in communication with the input chamber C. Therefore, the pressure sent to the rear brake chamber 11 via the output port 25 rises to the same level as the pressure supplied from the brake valve 5 via the input port 22 without limiting the rising rate. It will cause a break.

Incidentally, the release of the brake operation is the same as in the case of the above-mentioned (1), so the explanation thereof will be omitted. However, when the brake is released, the switching valve 13 is switched from the open position to the closed position again. In that case, the compressed air supplied to the pressure chamber D of the pressure reducing valve 15 is released to the atmosphere via the pipe 16, and the pressure chamber D is brought to the atmospheric pressure state. At that time, the piston 5 of the pressure reducing valve 15
The small-diameter portion 55C of No. 5 receives the pressure of the compressed air supplied to the control chamber A, moves toward the control port 52 side against the spring force of the preload spring 58 in the pressure chamber D, and the valve member 62 is supplied. Air valve seat 66
The exhaust valve seat 60 is separated from the valve member 62. As a result, the inlet 54 and the outlet 48 are disconnected from each other, and the small diameter hole portion 46C and the exhaust port 47 communicate with each other through the passage 61,
The compressed air in the control chamber A of the pressure limiting valve 9 is discharged to the atmosphere. Then, when the compressed air in the restriction chamber A is discharged to the atmosphere, the acting force of the compressed air in the control chamber A of the pressure restriction valve 9 decreases to the spring force of the preload spring 58 of the pressure reducing valve 15, and again, The piston 55 is moved to the inlet 54 side by the preload spring 58, and the exhaust valve seat 60 is moved to the valve member 6
Sit on 2. As a result, the pressure in the control chamber A of the pressure limiting valve 9 is set to a predetermined pressure lower than the discharge pressure of the air reservoir 1, so that the operation (1) described above can be performed.

As described above, according to the first embodiment, when the load on the vehicle is small and the switching valve 13 is switched from the air reservoir 1 to the closed position for communicating with the atmosphere, the pressure reducing valve 13 limits the pressure. The compressed air pressure supplied to the control chamber A of the valve 9 is maintained at a predetermined pressure state lower than the compressed air pressure of the air reservoir 1, and this stepped pressure causes the stepped piston 27 of the pressure limiting valve 9 to exhaust the exhaust port. The valve body 33 is moved to the side of 24 and the valve body 33 receives the input chamber C and the output chamber B of the pressure limiting valve 9 regardless of whether the brake pedal 5a of the brake valve 5 is depressed.
Therefore, at the beginning of the effect of the brake, the pressure of the compressed air from the brake valve 5 supplied to the input chamber C of the pressure limiting valve 9 via the pipe 8 is started. Similarly to the above, the pressure of the rear brake chamber 11 can be increased, and thereafter, the pressure supplied to the rear brake chamber 11 is lower than the pressure of the compressed air from the brake valve 5 by the pressure reducing operation of the pressure limiting valve 9. Can also limit the rate of increase to a low level.

Second Embodiment A second embodiment of the present invention will be described below with reference to FIG.

In FIG. 2, the pipe line 12 is connected to the pipe line 8, and the compressed air from the air reservoir 1 is intervened by the brake valve 5 and the switching valve 13 and the pipe line branched from the pipe line 12. A pipe line 14 supplies the pressure reducing valve 15. Other configurations are the same as the configurations shown in the first embodiment.

The operation of the air-brake system according to the second embodiment having such a structure will be described below. In this configuration, when the brake valve 5 is not operated, the pressure reducing valve 15 and the pressure limiting valve 9 are irrespective of the switching position (open or closed) of the switching valve 13 shown in FIGS.
It is in the state of.

(1 ') When the vehicle load is small: Fig. 2
At this time, when the driver operates the operation lever 13a of the switching valve 13 to switch the switching valve 13 to the closed position and depresses the pedal 5a to operate the brake, the brake valve 5 causes pressure limitation. Due to the compressed air pressure supplied to the control chamber A of the valve 9 and the compressed air force supplied to the input chamber C to the pressure limiting valve 9 via the conduit 8, the stepped piston 27 of the pressure limiting valve 9 is moved to the valve body. It moves to the exhaust port 24 side together with 33 to make the input chamber C and the output chamber B communicate with each other. At the beginning of the effect of the brake, the pressure chamber is connected to the input chamber C of the pressure limiting valve 9 via the pipe 8. When the pressure of the rear brake chamber 11 is raised to the same level as the pressure of the compressed air supplied from the brake valve 5, and then the discharge pressure of the brake valve 5 exceeds the closing pressure of the pressure reducing valve 15, the control chamber Since the pressure of A is kept at a predetermined pressure and does not rise, By vacuum actuation of Kiriben 9, Riabure - pressure supplied to Kichanba 11 blur - is limited to a low rate of rise than the pressure of the compressed air from the Kibarubu 5.

When the driver stops depressing the pedal 5a to release the brake, the brake valve 5 moves to the front brake chamber 7, the control chamber A of the pressure limiting valve 9 and the input chamber C. Since the supplied pressure becomes 0, the compressed air supplied to the front brake chamber 7 is discharged into the atmosphere from the exhaust port (not shown) of the brake valve 5 via the pipe 6, and the pressure limiting valve Since the stepped piston 27 of 9 returns to the position shown in FIG. 4 together with the valve element 33 to connect the output chamber B and the exhaust port 24,
The compressed air supplied to the rear brake chamber 11 is exhausted to the atmosphere at the exhaust port 24, the pressure in each of the brake chambers 7 and 11 is released, and the brake is released.

(2 ') When the vehicle has a large load: The driver operates the operation lever 13a of the switching valve 13 to switch the switching valve 13 to the open position and activate the brake.
When the pedal 5a is depressed, as shown in (1 '), the input chamber C and the output chamber B of the pressure limiting valve 9 are made to communicate with each other, and at the beginning of the effect of the brake, the input chamber C of the pressure limiting valve is started. The pressure in the rear brake chamber 11 can be increased to the same level as the compressed air from the brake valve 5 supplied to the brake valve 5, and then the discharge pressure of the brake valve 5 is reduced.
Input chamber C and output chamber B without exceeding the valve opening pressure of No. 5
Since the communication state of the rear brake chamber 11 is maintained,
The pressure supplied to the valve rises to the same level as the pressure of the compressed air from the brake valve 5 without limiting the rate of increase.

Regarding the release of the brake operation,
Since it is similar to the case of (1 '), the description thereof is omitted.

As described above, according to the second embodiment, the switching valve 1
When the pedal 3 is operated to the closed position and the pedal 5a is depressed, the same operational effect as that of the first embodiment, that is, at the beginning of the effect of the brake, the discharge pressure of the brake valve 5 is equivalent to the rear brake chamber. The pressure of valve 11 can be increased, and thereafter, by the depressurizing operation of pressure limiting valve 9, the rate of increase of the pressure supplied to rear brake chamber 11 is restricted to be lower than the pressure of the compressed air from brake valve 5. be able to.

Incidentally, instead of the pressure limiting valve 9 (limiting and quick release valve) shown in the second embodiment, as in the pressure limiting valve 9, the inside of the cylinder hole is controlled by the piston as a control chamber, an input chamber, And the relay divided into the output chamber
A valve or the like may be used.

Further, the brake chambers 7 and 11 for operating the brakes in the first and second embodiments are replaced with AOH boosters for operating the brakes. Good.

[0042]

As described above in detail, according to the air brake system of the present invention, even when the switching valve is operated to the closed position, the control pressure lower than that when the switching valve is opened acts on the pressure control valve. Therefore, the depressurizing operation of the pressure control valve is disabled until the discharge pressure of the brake valve rises from 0 and reaches a predetermined pressure. Instead, the pressure of the actuator can be raised to the same level as the discharge pressure of the brake valve, so that the problem of insufficient brake force during the operation of the brake can be solved as in the conventional case.

[Brief description of drawings]

FIG. 1 is a piping system diagram showing an entire air-brake system as a first embodiment of the present invention.

FIG. 2 is a piping system diagram showing an entire air-brake system as a second embodiment of the present invention.

FIG. 3 is a vertical cross-sectional view showing details of the pressure limiting valve in FIGS. 1 and 2.

FIG. 4 is a vertical cross-sectional view showing details of the pressure reducing valve in FIGS. 1 and 2.

[Explanation of symbols]

 1 Air Reservoir 5 Break Valve 9 Pressure Limiting Valve 11 Rear Break Chamber 13 Switching Valve 15 Pressure Reduction Valve

Claims (2)

[Claims] 1. A reservoir for storing compressed air, and this reservoir.
A brake valve that regulates and discharges compressed air from a compressor according to a driver's operation input, and a brake valve that is opened / closed by a driver separately from the brake valve from the discharge side or the reservoir side of the brake valve. By providing a switching valve capable of guiding and delivering compressed air and a device capable of reducing the pressure of the compressed air discharged from the brake valve, the pressure of the compressed air is introduced as a control pressure according to the opening operation of the switching valve. An air brake system including a pressure control valve for deactivating the pressure reducing operation, and an actuator for applying a brake air to the wheel by supplying compressed air from the brake valve via the pressure control valve. At the time of closing the switching valve, an air brake capable of supplying a predetermined pressure lower than the pressure supplied by opening the switching valve as a control pressure for the pressure control valve. Stem. 2. A communication passage for connecting a control port, into which the control pressure of the pressure control valve is introduced, to the discharge side or the reservoir side of the brake valve, at one end side thereof. The movable body has a movable body for receiving the pressure of the spring and the pressure of the spring and the pressure sent by the switching valve on the other end side, and the force acting on the one end side of the movable body is greater than the force acting on the other end side. 2. An air blower according to claim 1, further comprising a valve device for shutting off the communication passage in response to an increase in size.
The system.