RU211025U1 - Crane driver of a railway vehicle - Google Patents

Abstract

The utility model relates to the field of railway transport, namely to the arrangement of driver cranes designed to control automatic, pneumatic and electro-pneumatic brakes of freight, shunting and passenger trains.

The crane 1 of the driver of a railway vehicle consists of a control and executive parts 2 and 3. The control part 2 of the crane 1 of the driver contains, built into the control panel, an electronic remote-controlled controller 4 and a switch 5 of the control circuits with a pneumatic body 7 switching.

The executive part 3 of the crane 1 of the driver is made in the form of a block of electro-pneumatic devices installed in the engine room, mounted on a bearing bracket-plate 8 made of two plates glued together. valves 13, 14 for service braking, valve 15 for slow braking, acting as a blocking device, uncoupling devices 16, 17, valve 18 for stall, valve 19 for supply, valves 20, 21 for return valves, valve 22 for switching modes, reducer 23, stabilizer 24, pressure sensors 25 , 26, 27, pressure gauge 28, electronic unit 29 for controlling the crane of 1 driver. And on the other plate, for connecting the devices with compressed air, pneumatic channels are made, connected with supply and brake lines 30 and 31 connected to the executive unit 3, line 32 of the auxiliary brake valve 33, channels of the backup control valve 34, surge tank 35.

Pneumatic distributor 10 includes electro-pneumatic charging valve 36 and valve 37, pneumatic distributor 11 includes electro-pneumatic overcharging valve 38 and valve 39, pneumatic distributor 12 includes electro-pneumatic shut-off valve 40 and valve 41, disconnecting device 16 includes electro-pneumatic valve 42 and valve 43, disconnecting device 17 includes valve 44 electropneumatic switching on, valve 45 electropneumatic switching off, valves 46, 47, body 48 switching. Switch 5 control circuits is made with the fourth position of the key with self-return.

Block 3 executive is adapted to work with systems of automatic guidance of freight trains (ISAVP-RT), automated guidance of connected trains via the AV-RT radio channel, automatic control of SAU-OP.

The proposed utility model ensures the reliability of the driver's crane. 1 ill.

Description

The utility model relates to the field of railway transport, namely to the arrangement of driver cranes designed to control automatic, pneumatic and electro-pneumatic brakes of freight, shunting and passenger trains.

Known crane driver of a railway vehicle, containing mounted in the driver's cab control part, including built-in control panel brake controller, control circuit switch, backup braking valve and the executive part, including installed in the engine room block of pneumatic and electro-pneumatic devices, which consists of a carrier bracket-plate, glued from two plates, on one of them there are internal channels connected through fittings to the brake, impulse, supply pneumatic lines, as well as the atmosphere, for communicating with compressed air devices fixed on the other plate, including pressure switches, having cavities connected with a surge tank of the driver's crane, supply and brake lines, atmosphere, charge pressure reducer connected to the supply line, overcharge pressure stabilizer, electro-pneumatic braking and release valves connected to the control pressure switch cavity connected to the surge tank, electro-pneumatic shut-off valve connected to the brake line and through the check valve to the surge tank, supply valve connected to the supply line and the control cavity of the pressure switch, stall valve with an electro-pneumatic valve connected to the brake line and to the control cavity of the pressure switch, and in the emergency braking position communicated with the atmosphere, controlled by the switch of the control circuits, the device for blocking the brakes, connected pneumatically with the supply line, the brake line and the impulse line, the valve for switching modes for remote and backup control of the automatic brake, connected to the surge tank. /Patent of the Russian Federation No. 32738, 29.04.2003, IPC V60T 15/04/.

The disadvantages of the known technical solution, which reduce the reliability of the driver’s crane, include the absence of a throttle opening at the mode switching valve, which leads to changes in the value of the service braking time, the absence of a check valve in the channel between the electro-pneumatic release valve and the gearbox when the brake line is purged leads to the discharge of the control cavities of the pressure switch and surge tank, lack of pressure sensors on the channel of the control cavity of the pressure switch and the brake line, which reduces the control over the operation of devices, the fragility of the pressure switch due to design flaws in the diaphragm assembly, in which there is no limiter for its travel, the implementation of a backup control valve with unloaded valves, the control circuit switch has three key positions, which does not provide the "hot transfer" function, pressure reduction in the supply line during emergency braking, no remote control, including via radio, adapted to the IS-AVP-RT, AV-RT, SAU-OP systems, instability of thermodynamic processes in the surge tank, as well as large dimensions and weight.

A crane of a railway vehicle driver is known, containing a control part installed in the driver's cab, including a brake control controller and a control circuit switch built into the control panel, an executive part that includes a block of pneumatic and electro-pneumatic devices installed in the engine room, which consists of a carrier plate glued from two plates, on one of them there are internal channels connected through fittings to the brake, impulse, supply pneumatic lines, as well as the atmosphere, for communicating with compressed air devices fixed on the other plate, including pressure switches, having cavities connected with the surge tank, supply and brake lines, and atmosphere, charging pressure reducer, overcharge pressure elimination stabilizer connected to the supply line, electro-pneumatic valves for charging, overcharging, shutting off, service and slow braking associated with control pressure switch cavity connected to the surge tank, while the electro-pneumatic shut-off valve is connected to the brake line and through the check valve to the surge tank, the supply valve connected to the supply line and the control cavity of the pressure switch, the stall valve with the electro-pneumatic valve connected to the brake line and control cavity of the pressure switch, and in the emergency braking position communicated with the atmosphere, controlled by a control circuit breaker, a brake blocking device connected pneumatically to the supply line, brake line and impulse line, a mode switching valve with two positions of the handle for remote and backup control of the automatic brake, connected to the surge tank, and made with a throttle hole to limit the discharge of the surge tank by the rate of service braking, pressure sensors installed on the channel of the control cavity of the pressure switch and on the brake line, a check valve mounted on the channel between the release valve and the gearbox, an electronic unit, as well as a backup control valve installed in the driver's cab and pneumatically connected to the unit of electro-pneumatic devices / RF Patent No. 2635732, 06/28/2016, IPC V60T 15/04/.

The disadvantages of the known technical solution, which reduce the reliability of the driver’s crane, are a decrease in pressure in the supply line during emergency braking, an electrical control is present in the control circuit switch, there is no “hot transfer” function when moving from cab to cab, service braking is unsafe, unnecessary electrical intermediate and external connections, instability of thermodynamic processes in the surge tank, and there is also no remote control of the executive unit, including via a radio channel adapted for automatic guidance systems for freight trains (ISAVP-RT), automated guidance of connected trains via the AV-RT radio channel, automatic control of ACS- OP.

The technical objective of the invention is to improve the operation of the driver's crane by eliminating the decrease in pressure in the supply line during emergency braking, the implementation of safe service braking, replacing the cabin change algorithm in the electric control circuit switch with pneumatic control, eliminating intermediate electrical connections, reducing the number of external electrical connectors by 80%, increasing the degree of protection of the electronic unit and electrical connectors, implementing a new “hot transfer” function by the control circuit switch when moving from cabin to cabin, systemic stabilization of thermodynamic processes in the surge tank, the use of pneumatic and electro-pneumatic components on a new element base, the implementation of remote control, including via a radio channel, adapted to the ISAVP-RT, AV-RT, SAU-OP systems, as well as reducing the mass of the executive unit and the area of the bracket plate, increasing service life up to 20 years and overhaul interval up to 5 years.

The technical result that will be obtained in the implementation of the invention is to increase reliability.

The specified technical result is achieved by the fact that the railway vehicle driver's crane contains a control part mounted in the driver's cab, including a brake control controller and a control circuit switch built into the control panel, an executive part installed in the engine room and made in the form of a block of pneumatic and electro-pneumatic devices, which consists of a carrier plate glued from two plates, on one of them there are internal channels connected through fittings to the brake, impulse, supply pneumatic lines, as well as the atmosphere, for communicating with compressed air the block devices fixed on the other plate, including pressure switches having cavities connected with the equalization tank of the driver’s crane, the feed and brake lines, and the atmosphere, the charging pressure reducer, the overcharge pressure elimination stabilizer connected to the feed line, the charging solenoid valves, overcharging and, overlapping, service and delayed braking, associated with the control cavity of the pressure switch, communicated with the surge tank, while the shutoff solenoid valve is connected to the brake line and through the check valve with the surge tank, the supply valve connected to the supply line and the control cavity of the relay pressure, a stall valve with a solenoid valve connected to the brake line and to the control cavity of the pressure switch, and in the emergency braking position communicated with the atmosphere, a brake blocking device controlled by a control circuit switch, connected pneumatically to the supply line, brake line and impulse line, mode switching valve for remote and backup control of the automatic brake, connected to the surge tank, and made with a throttle hole to limit the discharge of the surge tank by the rate of service braking, pressure sensors installed on the channel in the control cavity of the pressure switch and on the brake line, a check valve mounted on the channel between the release valve and the gearbox, to prevent discharge of the control cavity of the pressure switch when purging the brake line, an electronic unit installed in the driver's cab and pneumatically connected to the block of electro-pneumatic devices, a backup valve braking, as well as an additional backup electro-pneumatic service braking valve connected to the control cavity of the pressure switch, a pressure gauge for measuring pressure in the surge tank, fixed on the channel of the control cavity of the pressure switch, while the blocking device is made in the form of two uncoupling devices connected to the supply line, one of which includes electro-pneumatic valves on and off, two valves and a switching element, mounted with the possibility of manual control, and the other uncoupling device, includes an electro-pneumatic valve with a valve anom connected to the electrical circuit with the possibility of switching on during emergency braking, and a sensor installed at its output, moreover, the control circuit switch is made with an additional position of the key with self-return and has a pneumatic control, the pressure switch is made of a piston type.

In FIG. 1 shows the brake driver's crane of a railway vehicle, pneumatic diagram.

The crane 1 of the railway vehicle driver consists of a control part 2 and an executive part 3.

The control part 2 of the driver's crane 1 contains mounted in the driver's cab and built into the control panel the controller 4 of the driver's crane 1 and the switch 5 of the control circuits.

The controller 4 of the crane 1 driver is made electronic with remote control and has seven positions of the handle: I - overcharging; II - train; III and IV - overlapping without food and with food; Va - slow braking; V and VI - service and emergency braking.

The control circuit switch 5 contains, installed in the housing and controlled by a removable key 6, a pneumatic switch 7 communicated with the brake line and the brake cylinder (not shown). Key 6 has three fixed positions and one additional position with self-return - respectively on, off, changing cabs and informing the locomotive control system about setting a command for a "hot transition" from cab to cab.

The executive part 3 of the crane 1 of the driver is made in the form of a block installed in the engine room, on the supporting bracket-plate 8 of which, consisting of two two plates glued together (not shown), pneumatic and electro-pneumatic devices are fixed. On one of the plates, pressure relay 9, pneumatic distributors 10, 11, 12, valve 13 and reserve valve 14 for service braking, valve 15 for delayed braking, a brake blocking device implemented in the form of two uncoupling devices 16, 17, valve 18 stall, valve 19 supply valve, 20, 21 return valves, mode switching valve 22, reducer 23, stabilizer 24, pressure sensors 25, 26, 27, pressure gauge 28, electronic control unit 29 for the driver's crane is connected to the controller 4 through electrical connectors.

These pneumatic and electro-pneumatic devices are connected by pneumatic channels made on another plate of the carrier bracket-plate 8, with supply and brake lines 30 and 31 connected to the executive unit 3, line 32 of the auxiliary brake valve 33, channels of the valve 34 of the backup control, reservoir 35 surge.

The pressure switch 9 is made of a piston type, designed to fill and discharge compressed air in the brake line 31, depending on the pressure in the control cavity of the relay 9 and the surge tank 35.

The pneumatic distributor 10 includes an electro-pneumatic charging valve 36 and a valve 37, a pneumatic distributor 11 - an electro-pneumatic overcharging valve 38 and a valve 39, a pneumatic distributor 12 - an electro-pneumatic shut-off valve 40 and a valve 41.

Uncoupling device 16 contains electropneumatic valve 42 and valve 43, uncoupling device 17 - electropneumatic valve 44 on, electropneumatic valve 45 off, valves 46, 47, switching body 48.

The stall valve 18 includes an electro-pneumatic emergency braking valve 49 and a valve 50 designed to quickly discharge the brake line 31 in the emergency braking position through the control cavity of the pressure switch 9 communicated with the atmosphere.

The supply valve 19 is connected to the line 30 of the supply and control cavity of the pressure switch 9, designed to power the pressure switch 9 through a channel with a large flow area, to charge and release the brake line 31, and also to maintain pressure in the brake line 31 in case of leakage from it.

The valve 22 for switching modes is a three-way ball valve and is designed to turn off the electro-pneumatic valves when switching to standby control. The handle of the crane 22 switching modes has two positions corresponding to the normal and standby modes. In the normal "W" mode, the driver's crane 1 is controlled from the controller 4, and in the standby mode "P" - from the backup control crane 34.

Reducer 23 is designed to maintain a predetermined pressure in surge tank 35. Compressed air pressure is adjusted by rotating the adjusting stop acting on a spring (not shown). A check valve 20 is installed at the inlet to the gearbox 23.

The stabilizer 24 provides a transition from increased to normal charging pressure without causing the brakes to operate.

The pressure sensors 25, 26, 27 are respectively installed on the channels communicating the pressure relay 9 with the surge tank 35, on the brake line 31, on the channel at the outlet of the valve 43 of the uncoupling device 16.

The pressure gauge 28 provides pressure measurement in the surge tank 35.

The composition of the electronic control unit 29 includes a decoder, a processor and a cross-board (not shown). The control unit decoder generates control signals for valves 13, 14, 15, 36, 38, 40, 42, 44, 45, 49 of the electro-pneumatic unit 3 of the executive unit. Formation of control signals is possible from one of three sources - controller 4 crane 1 driver, automatic brake control system, upper control level.

For external electrical connections, plug connectors are installed on the panel. All wires providing internal connections between plug connectors, electronic unit 29, pressure sensors 25, 26, 27 and valves 13, 14, 15, 36, 38, 40, 42, 44, 45, 49 are connected in bundles and laid in cable channels.

The operation of the crane driver of a railway vehicle is carried out as follows.

The crane 1 of the driver is turned on from the control panel by setting the key 6 of the switch 5 of the control circuits to the first position. In this case, voltage is applied to the valve 44 of the electro-pneumatic switching on of the uncoupling device 17, compressed air from the supply line 30 is supplied to the switching body 48 and then to the valves 46, 47 and through the normally open electro-pneumatic valve 42 of the electro-pneumatic disconnecting device 16 to the valve 43. Next, the compressed air enters to the pneumatic distributors 10, 11, 12, respectively, the electro-pneumatic charging valve 38 and valve 39, the electro-pneumatic overcharging valve 40 and valve 41, the electro-pneumatic shut-off valve 36 and valve 37, through the supply valve 19 to the pressure switch 9, and also through the valve 20 return to the gearbox 23, the stabilizer 24, the auxiliary brake valve 33 communicates with the line 32, while the pressure switch 9 and the stall valve 18 are connected to the brake line 31.

The order of turning on the electro-pneumatic valves when controlling the switch 5 of the control circuits is shown in Table 1.

The first position (on) of the key 6 of the switch 5 of the control circuit is carried out by turning the key to the stop clockwise, then the second position (off), turning the key from the first position 90 degrees counterclockwise, the third position (changing cabins) - the key is turned more 90 degrees counter-clockwise with the possibility of removal from the socket and an additional fourth position (cabin change - "hot transfer") the key turns 30 degrees with self-return to the third position. In the first two positions, the key is blocked. It is possible to transfer the key to the third and fourth positions only after the pressure in the TM drops below 0.1 MPa (1.0 kgf / cm ² ) and the pressure in the TC increases above 0.3 MPa (3.0 kgf / cm ² ). The pneumatic control of unlocking the key 6 is realized thanks to the logic element AND, integrated into the housing of the switch 5 of the control circuits, communicated with the highway 31 by the brake and brake cylinder.

When the key 6 is moved from position II to position III and the key 6 is removed, a new function is activated - "hot transition". At the same time, the control system of the electric locomotive is turned on and the pantographs are raised, which allows you not to wait for a complete overload of the control system when moving to another cabin of the electric locomotive. When the key 6 is moved from position III to position IV and held in it for 5 seconds, key 6 returns (self-return) to position III. After that, the control system of the electric locomotive is turned off and the pantographs are lowered, after which it is possible to remove the key 6 from position III.

The main pneumatic control of the compressed air pressure in the line 31 of the brake locomotive or train is carried out by the driver by means of a seven-position remote electronic controller 4 of the crane 1 of the driver, by transmitting controlled signals to the electronic unit 29 and then to the valves 13, 14, 15, 36, 38, 40, 42 , 44, 45, 49 electro-pneumatic. Sector seven-position controller 4 crane 1 driver has the following positions of the handle: I - overcharging; II - train; III and IV - overlapping without food and with food; Va - slow braking; V and VI - service and emergency braking. All controller positions 4 are fixed except position I.

Each position of the controller knob 4 corresponds to a certain state of the electro-pneumatic valves. The algorithm for switching on the electro-pneumatic valves of the executive unit 3 is shown in Table 2.

In the proposed design of the driver's crane 1, unlike the prototype, service braking is implemented by using two electro-pneumatic valves 13, 14, which discharge the surge tank 35 into the atmosphere at the rate of service braking. These valves have a parallel electrical connection and in case of failure of the mechanical part of one of the valves, the second one, which acts as a backup, will provide a safe rate of service braking.

All electropneumatic valves are of the switching type. Valves 13 and 14 are electro-pneumatic in all positions, except for the brake ones, are energized, providing service braking when the voltage is removed.

Uncoupling devices 16 and 17 perform the function of a device for blocking the brakes of the crane 1 driver. In this case, the electro-pneumatic valves 44, 45, when voltage is applied to them, provide control of the disconnecting device 17, and the electro-pneumatic valve 42 provides control of the disconnecting device 16.

During emergency braking, voltage is applied to the electro-pneumatic valves 42 and 49, the valve 50 of the stall valve 18 will ensure that the supply line 30 is turned off. Also, when voltage is applied to the electro-pneumatic valve 42 during emergency braking, the air pressure supply to the supply valve 19 and the pressure switch 9 will be blocked, which will prevent the air pressure drop in the supply line 30 of the locomotive.

The valve 36 of the electropneumatic pneumatic valve 10 provides compressed air to the control cavity of the pressure switch 9 and the surge tank 35, and the valve 40 of the electropneumatic valve 12 provides communication of the surge tank 35 and the brake line 31 through the check valve 21.

When voltage is applied to the electro-pneumatic valve 15, the equalizing reservoir 35 is discharged, thus providing a function of stabilizing thermodynamic processes in the equalizing reservoir 35, which is guaranteed to exclude a spontaneous increase in pressure in the equalizing reservoir 35 during braking steps.

Reserve pneumatic control of the pressure of compressed air in the brake line 31 of the locomotive or train is carried out by the driver by means of a remote valve 34 of the backup control, which has three fixed positions - vacation, overlap with power, service braking.

To switch to a backup pneumatic control, it is necessary to de-energize the electronic unit 29 and turn off the controller 4. Next, move the handle of the valve 22 for switching modes on the block 8 of electro-pneumatic devices to the vertical position and, when disconnecting the disconnecting device 17, turn it on manually.

Block 3 executive is adapted to work with systems of automatic guidance of freight trains (ISAVP-RT), automated guidance of connected trains via the AV-RT radio channel, automatic control of SAU-OP.

Provides predictive diagnostics of the state of the driver's crane 1 as a whole, as well as an extended list of diagnostic messages to the locomotive control system.

The proposed utility model ensures the reliability of the driver’s crane by eliminating the pressure drop in the supply line during emergency braking, the implementation of safe service braking, the replacement of the cabin change algorithm in the switch of the electric control circuits with pneumatic control, the increase in the degree of protection of the electronic unit and electrical connectors, the implementation of the circuit breaker control of the new "hot transfer" function during the transition from cabin to cabin, systemic stabilization of thermodynamic processes in the surge tank, remote control, including via radio, adapted to the ISAVP-RT, AV-RT, SAU-OP systems.

Claims (1)

Crane of the driver of a railway vehicle, containing a control part mounted in the driver's cab, including a brake control controller and a control circuit switch built into the control panel, an executive part installed in the engine room and made in the form of a block of pneumatic and electro-pneumatic devices, which consists of a bearing bracket - plate, glued from two plates, on one of them there are internal channels connected through fittings with brake, impulse, supply pneumatic lines, as well as the atmosphere, for communicating with compressed air devices fixed on the other plate, including pressure switches, having cavities associated with the tank equalization, supply and brake lines, and atmosphere, charge pressure reducer, overcharge pressure elimination stabilizer connected to the supply line, electro-pneumatic valves for charging, overcharging, shutting off, service and delayed braking, communication data with the control cavity of the pressure switch, communicated with the surge tank, while the electro-pneumatic shut-off valve is connected to the brake line and through the check valve - to the surge tank, the supply valve connected to the supply line and the control cavity of the pressure switch, the stall valve with the electro-pneumatic valve, connected with a brake line and with a control cavity of the pressure switch, and in the emergency braking position communicated with the atmosphere, controlled by a control circuit breaker, a brake blocking device connected pneumatically to the supply line, brake line and impulse line, a mode switching valve with two positions of the handle for remote and backup control automatic brake, connected to the surge tank, and made with a throttle hole to limit the discharge of the surge tank by the rate of service braking, pressure sensors installed on the channel of the control pressure switch and on the brake line, a check valve mounted on the channel between the electro-pneumatic release valve and the gearbox, an electronic unit, as well as a backup control valve installed in the driver's cab and pneumatically connected to the electro-pneumatic devices unit, characterized in that it is equipped with an additional electro-pneumatic backup valve service braking connected to the control chamber of the pressure switch, a pressure gauge for measuring the pressure in the surge tank, fixed on the channel of the control chamber of the pressure switch, while the blocking device is made in the form of two uncoupling devices connected to the supply line, one of which includes electro-pneumatic valves on and off , two valves and a switching body, mounted with the possibility of manual control, and another disconnecting device includes an electro-pneumatic valve with a valve connected to the electrical circuit with the possibility of switching on emergency braking, and a sensor installed at its output, moreover, the control circuit switch is made with an additional key position and has pneumatic control in the cab change algorithm, the pressure switch is made of a piston type.

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