JPH0379922B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Application of the Invention] The present invention relates to a brake system for a railway vehicle, and particularly to a brake system for a railway vehicle suitable for a train set in which a power vehicle and an auxiliary vehicle are connected.

[Background of the invention]

The brake equipment of trains that make up a general train is
In the case of a powered vehicle that has a motor for driving the vehicle, the motor is used as a generator to generate electricity when braking is required, and the electric power is dissipated as heat by a resistor or returned to the overhead wires by electric brakes and compression. It is also used with an air brake that performs control using compressed air obtained by the machine. On the other hand, in the case of an accompanying vehicle that does not have a driving motor, only the air brake described above is provided, and this air brake is used.

Normally, in a vehicle train consisting of a motive vehicle and a companion vehicle, when braking is applied from a high speed range during running, an electric brake is applied on the motive vehicle and an air brake is applied on the companion vehicle. Under such brake operation conditions, the air brakes of the accompanying vehicle are used more frequently than those of the motorized vehicle, and there is a drawback that the brake shoes and the like in the brake equipment of the accompanying vehicle are highly worn out.

[Purpose of the invention]

In view of the above points, the present invention minimizes the frequency of use of the air brake, which requires parts replacement and inspection, by giving priority to the electric brake of the motor vehicle.
The purpose is to simplify maintenance and inspection and save labor.

[Summary of the invention]

The present invention is a brake control device for a railway vehicle having a shutoff valve 6 and a control circuit A traveling drive motor installed in the Y is used as an electric brake, and both brakes are controlled by a brake valve 5 operated by the driving vehicle to effect braking. Air piping 2,
4 installed in the middle and controlled by the control circuit X, connecting the air pipes 2 and 4 by a communication operation,
The control circuit X has relays R ₁ and R ₂ and is controlled by a brake valve 5 to open the other side of the air pipes 2 and 4 to the atmosphere. When the degree of opening of the brake valve 5 is small, it outputs a control signal that closes the shutoff valve 6, and when the degree of opening of the brake valve 5 is large (N or more), it outputs a control signal that causes the shutoff valve 6 to open. It is something.

[Embodiments of the invention]

Next, an embodiment of a brake device according to the present invention will be described with reference to FIGS. 1 to 5. FIG. 1 is a circuit diagram showing a pneumatic circuit for an air brake in a companion vehicle. In the figure, reference numeral 1 denotes a brake controller, which controls and supplies compressed air compressed by an air compressor with a brake valve operated by a driver. A brake cylinder 3 is supplied with the compressed air and converts the pressure of the compressed air into braking force. Pipes 2 and 3 connect the brake controller 1 and the brake cylinder 3 so as to be able to supply compressed air. The brake controller 1, piping 2, piping 4, and brake cylinder 3 constitute an air brake Y. A shutoff valve 6 is provided between the piping 2 and the piping 4 of this brake cylinder Y. The shutoff valve 6 can open and close its air circuit, that is, the communication between the pipes 2 and 4, according to an electric command, and when the electric command is OFF, the shutoff valve 6 can open and close communication between the air circuit and the pipes 2 and 4.
and 4 are open, and when the electrical command is ON, the pipe 2 side is closed and the compressed air from the pipe 4 side is exhausted.

Next, FIG. 2 is an electric circuit diagram for controlling the shutoff valve 6. As shown in FIG. In the figure, 103 is a power line;
Reference numeral 105 denotes a command line, each of which is arranged to lead through the train. A brake valve 5 is connected to the power line 103 and the command line 105, and controls the amount of compressed air supplied to the brake cylinder 3 and the electric brake force in the brake controller 1 described above. The brake force is increased by moving the handle (not shown) of the brake valve 5 from 0 to the M direction, that is, by increasing the opening degree of the brake valve 5. The 0 point is the loosened position, and an electrical contact is provided between the movement N and M of the handle. R ₁ is the command line 105
The relay is connected to the command line 105 and controlled by power supplied to the command line 105, and its contacts are provided in a circuit connected to the power line 103. _R2 is a relay that opens and closes in conjunction with the activation of the electric brake of the motor vehicle, and when the electric brake is not activated, the contacts of the relay _R2 are in an open state. Contacts and relays of said relay _R1
The contact point of _R2 is connected in series to the power supply line 103, and the circuit further includes the coil 6 of the shutoff valve 6.
a are connected in series. A control circuit X is constituted by the relay R ₁ , relay R ₂ and the coil 6a of the shutoff valve 6. In addition, A in Figure 2
indicates a vehicle in the vehicle formation, and B indicates another vehicle. That is, as shown in FIG. 5, the vehicle formation consists of cars A, ie, accompanying cars without a motor for driving the vehicle, and cars B and C, ie, a powered vehicle having a motor for driving the vehicle. In such a configuration, the brake control state will be explained with reference to FIGS. 3 and 4. Figure 3 shows the movement of the brake valve handle on the horizontal axis and the air brake force on the vertical axis, and Figure 4 shows the movement of the brake valve handle on the horizontal axis and the electric brake force on the vertical axis. , shows the braking force of each vehicle in the vehicle formation shown in FIG. 5. first,
Compressed air is supplied to a pipe 2 from a vertical brake controller 1 in response to movement of a handle of a brake valve 5 when the train is running. At this time, if the electric brake of power vehicle B or C is operating, the contacts of relay R ₂ are closed, and if the handle of brake valve 5 is below N, the contacts of relay R ₁ are closed. Therefore, the coil of the shutoff valve 6 is excited and the air circuit 2 is closed off. Therefore, compressed air is not supplied from the air pipe 2 to the air pipe 4, and compressed air is not supplied to the brake cylinder 3 either. Therefore, in the above-mentioned state, the air brake Y of car A does not work. Next, if a greater braking force than in the above-mentioned state is required, the handle of the brake valve 5 is moved to the N position or higher. As the handle is operated, the contacts of the relay _R1 are opened, whereby the coil of the shutoff valve 6 is placed in a non-magnetic state. Therefore, the shutoff valve 6 opens,
Air pipes 2 and 4 communicate with each other, and compressed air from the brake controller 1 is supplied to the brake cylinder 3. Therefore, in this state, the air brake Y of car A, which is the accompanying car, is activated.

Next, if the electric brakes of the B and C motor vehicles fail for some reason, the relay
Since the contact _R2 is opened, the coil of the shutoff valve 6 is de-energized. Therefore, regardless of the position of the handle of the brake valve 5, the cutoff valve 6 is always open, so compressed air from the brake controller 1 is supplied to the brake cylinder 3, and the air brake Y can be operated. .

In such a configuration, the braking force in the train set is as shown in Figure 4 when the electric brakes of cars B and C of the motive cars are effective, and when the electric brakes are inoperable. is set to have a braking force as shown in FIG. That is, in cars B and C, the maximum value of the air brake force is set so that it can be achieved when the handle of the brake valve 5 is located at point M. Also,
The maximum value of the electric brake force is set so that it can be achieved when the handle of the brake valve 5 is located at the N point. The reason why these maximum values are set as values B' and C' in the figure is to prevent the wheels from slipping by applying extreme braking force to the same vehicle.

According to such a configuration, when a brake is applied from a high speed range while the train is running, the electric brake of the motive vehicle is activated first, and when the handle of the brake valve 5 is below the N point, the air brake of the accompanying vehicle is activated. Since it does not operate, the air brake can be used less frequently than conventional brakes. Therefore, it is possible to minimize wear and tear on the parts that wear out, such as the brake shoe of the accompanying vehicle. Further, when a regenerative brake is used as the electric brake of the motor vehicle, the kinetic energy of the accompanying vehicle can also be recovered, which is effective from the viewpoint of energy saving. By the way, in the above-described configuration, if the electric brake of the motive vehicle stops working, the electric brake of the motive vehicle is automatically switched to the air brake as described above, and the air brake of the accompanying vehicle is automatically switched. Since the structure also operates the brakes, there is no need to reduce the braking force or put strain on the brake shoe of the motor vehicle. In addition, in the above configuration, if a low pressure (for example, 0.3 to 0.5 Kgf/cm ² ) discharge valve is provided at the exhaust port of the shutoff valve 6, once the air brake is activated, the piping 4 and the brake cylinder The set pressure remains in the brake cylinder 3, and the brake cylinder 3 is held in a semi-relaxed state. Therefore, when the air brake is operated again after the air brake has been operated, the set pressure remains in the brake cylinder 3 as described above, so that the operating speed can be increased and responsiveness can be improved.

〔Effect of the invention〕

As explained above, according to the present invention, when braking is performed while the vehicle is running, first the electric brake is activated, thereby reducing the frequency of use of the air brake and minimizing wear and tear on the air brake components. This makes it possible to simplify maintenance and inspection work and save labor.

[Brief explanation of drawings]

FIG. 1 is a circuit diagram showing an air circuit of an air brake in an accompanying vehicle of an embodiment of the brake system according to the present invention, FIG. 2 is a circuit diagram showing an electric circuit for controlling the shutoff valve of FIG. 1, and FIG. 4 and 4 are graphs showing the relationship between the operating status of the brake valve and the electric brake and pneumatic brake forces, and FIG. 5 is a plan view showing the train formation. 1... Brake controller, 2, 4... Piping, 3...
...Brake cylinder, 5...Brake valve, 6...
Shutoff valve, R ₁ , R ₂ ... Relay, X ... Control circuit,
Y...Air brake.

Claims (1)

[Claims] 1. A brake control device for a railway vehicle having a shutoff valve 6 and a control circuit A running drive motor installed in the power vehicle is used as an electric brake, and both brakes are controlled by a brake valve 5 operated by the driver for braking operation. Brake Y air pipe 2,
4 installed in the middle and controlled by the control circuit X, connecting the air pipes 2 and 4 by a communication operation,
The control circuit X has relays R ₁ and R ₂ and is controlled by a brake valve 5 to open the other side of the air pipes 2 and 4 to the atmosphere. When the opening degree of the brake valve 5 is small, it outputs a control signal to close the shutoff valve 6, and when the opening degree of the brake valve 5 is large (N or more), it outputs a control signal to operate the shutoff valve 6. .