RU225597U1 - Power supply device unified on DC bus - Google Patents

Abstract

The utility model relates to the field of electrical engineering. The technical result consists in providing uninterrupted power supply to consumers of direct and alternating current. The device contains at least one feeder input and protection device, a backup power plant feeder input and protection device, connected in parallel to an automatic transfer switch circuit, the output of which forms a guaranteed power bus, the first output of which provides power supply to guaranteed loads, the second output is connected through a transformer to at least one rectifier, the output of which forms a DC bus, to which at least one inverter, at least one converter and a battery cabinet are connected in parallel, while the output of at least one inverter is connected to the first input of the automatic and manual bypass circuit, the output of which is through a group of distribution transformers transformer panel and distribution panel is connected to the outputs for power supply of at least one group of backup loads and tone rail circuits, the second input of the automatic and manual bypass circuit is connected to the guaranteed power bus through a transformer, the output of at least one converter is connected to the low DC voltage output, additionally contains diagnostic module, the inputs of which are connected by an information cable to the outputs of at least one inverter, at least one converter, battery cabinet, automatic and manual bypass circuits, transformer switchboard, while the first output of the diagnostic module is connected to the technical diagnostics and monitoring system, the second output is connected to microprocessor centralization devices, the third output is connected to an integrated workstation for an electromechanical alarm, centralization and blocking. 1 ill.

Description

The utility model relates to the field of electrical engineering and can be used to power relay and microprocessor centralization devices and automatic interlocks of railway automation on the railway network.

A system of guaranteed DC power supply is known (RF Patent for utility model No. 62485, IPC H02J 9/06, published 04/10/2007, Bulletin No. 10), containing chargers connected to DC buses, to which they are connected via circuit breakers DC consumers, the battery, is additionally equipped with a battery monitoring and protection unit, the inputs of which are connected directly to the positive and negative terminals of the battery, and the first and second outputs of the battery monitoring and protection unit are connected to the control system of each charger, with the positive and negative outputs of the battery control and protection unit are connected, respectively, to DC buses.

The disadvantage of the presented analogue is the inability to continuously monitor the parameters of external power supplies and carry out preventive or repair work on rectifiers and/or inverters.

The closest in technical essence is an uninterruptible power supply device (RF Patent for utility model No. 222433, IPC H02J 9/06, published 12/25/2023, Bulletin No. 36), containing a rectifier connected to an AC supply network, DC buses, connecting the output of the rectifier to the input of the inverter, the output of which is connected to the first input of the load, the DC bus is connected to a charger-discharge device connected to the battery, the bypass diode is connected counter-parallel to the charger-discharge device, the anode to the battery, and the cathode to the bus DC, control unit, the outputs of which are connected to the DC bus and to the control inputs of the rectifier, charger-discharge device, inverter and the first switch, which forms the first bypass circuit between the AC supply network and the output of the inverter, thyristor voltage converter, one terminal of which connected to the input of the rectifier, and the second terminal is connected to the output of the inverter, an alternating voltage sensor, the input of which is connected to the first input of the load, and the output of the alternating voltage sensor is connected to the first input of the first signal comparison block, to the second input of which the first output of the voltage setting block is connected, the output of the first signal comparison block is connected to the control inputs of the thyristor voltage converter and the control unit, a constant voltage sensor, the input of which is connected to the second load input and to the output of the constant voltage converter, and the output of the constant voltage sensor is connected to the first input of the second signal comparison block, to the second the input of which is connected to the second output of the voltage setting block, the output of the second signal comparison block is connected to the control input of the DC voltage converter, the input of which is connected to the DC bus, a second switch is additionally introduced, which forms a second bypass circuit between the DC bus and the output of the DC voltage converter, the first terminal of the second key is connected to the input of the DC-DC converter, and its second terminal is connected to the second to the second load input, the output of the second signal comparison unit is connected to the input of the control unit, and the output of the control unit is connected to the control input of the second key.

The disadvantage of this technical solution is the limited scope of application and the inability to connect high and low voltage DC and AC loads.

The technical result of the claimed utility model is to provide uninterrupted power to consumers of direct and alternating current and expand the functionality of the device when carrying out preventive and/or repair work on the component parts of the device.

The technical result is achieved due to the fact that the power supply device unified on the DC bus contains at least one input and protection device for the feeder, an input and protection device for the feeder of the backup power plant, connected in parallel to the automatic transfer circuit, the output of which forms a guaranteed power bus, the first output which provides power supply to guaranteed loads, the second output is connected through a transformer to at least one rectifier, the output of which forms a DC bus, to which at least one inverter, at least one converter and a battery cabinet are connected in parallel, while the output of at least one inverter is connected to the first input of the automatic and manual bypass circuit, the output of which, through a group of transformers of the transformer distribution board and the distribution board, is connected to the outputs for power supply of at least one group of backup loads and tone rail circuits, the second input of the automatic and manual bypass circuit is connected to the guaranteed power bus through a transformer, the output of at least one converter is connected to the low DC voltage output, additionally contains a diagnostic module, the inputs of which are connected by an information cable to the outputs of at least one inverter, at least one converter, battery cabinet, automatic and manual bypass circuits, transformer distribution board, and the first The output of the diagnostic module is connected to the technical diagnostics and monitoring system, the second output is connected to microprocessor centralization devices, the third output is connected to the integrated workstation of the alarm, centralization and blocking electromechanic.

The presence of new distinctive essential features indicates compliance of the claimed utility model with the patentability criterion of “novelty”.

The claimed technical solution can be made from known materials using known means, which indicates that the claimed utility model meets the patentability criterion of “industrial applicability”.

A prototype of the device called “UEP-U-ShPT” was manufactured and tested at JSC “Atis”, St. Petersburg, and tested at the test site of the Moscow Railway.

The claimed technical solution is illustrated by the drawing:

fig. 1 - block diagram of a power supply device unified on a DC bus.

Used in FIGS. 1 legend:

1 - feeder input and protection device;

2 - device for input and protection of the backup power plant feeder;

3 - diagram of automatic switching on of the reserve;

4 - transformer;

5 - rectifier;

6 - inverter;

7 - converter;

8 - battery cabinet;

9 - diagram of automatic and manual bypass;

10 - transformer distribution board;

11 - distribution board;

12 - diagnostic module;

13 - integrated electromechanical workstation for alarm, centralization and blocking.

The claimed technical solution is described as follows.

Alternating three-phase or single-phase voltage from an external source is supplied to the input of at least one feeder input and protection device (1) and a backup power plant feeder input and protection device (2).

Feeder input and protection devices (backup power station) are designed for cable input from an external alternating current source (input or power input of a diesel generator unit, protection against atmospheric and switching overvoltages, commercial and/or technical metering of electrical energy parameters, overcurrent protection .

Feeders from the outputs of devices (1) and (2) are connected to the terminals of automatic switches of the automatic transfer circuit (3).

The output of the automatic transfer switch circuit forms a guaranteed power bus, to the first output of which guaranteed loads are connected, and to the second - through a transformer (4) the input of at least one rectifier (5).

Guaranteed loads, for example, include:

electrical heating of the contact system of the electric drive through a three-phase isolating transformer. If there is a single-phase external power supply feeder, the connection is made through two single-phase isolating transformers;

guaranteed lighting;

power supply of air conditioning systems;

guaranteed power load;

wired communication devices (in the absence of independent power supply devices);

power supply to the life support system of a diesel generator unit, etc.

The rectifier(s) (5) converts the input three-phase or single-phase AC voltage of 220 V 50 Hz into a voltage of 48 V DC and supplies the DC bus to which the input of at least one inverter (6), at least one converter (7) is connected. and battery cabinet (8).

The inverter(s) (6) converts the DC voltage to three-phase AC voltage. The inverter output (6) is connected via an uninterruptible power supply bus to a transformer distribution board (10), designed for placement inside three-phase and single-phase isolating transformers.

The voltage from the output of the transformer distribution board (10) through the distribution board (11) provides power supply to the redundant loads of groups 1 (with microprocessor centralization and automatic blocking) and (2) (with relay centralization) and tone track circuits.

The converter (7) converts the DC voltage supplied from the DC bus into a DC voltage of the required rating and supplies it to the low DC voltage output.

The battery cabinet (8) contains batteries of the required capacity to power railway automation loads of the required power for a given battery life. The input of the battery cabinet (8) receives voltage from the DC bus for normal and accelerated charging of batteries.

In emergency mode, for repair work or maintenance, the claimed technical solution provides an automatic and manual bypass circuit (9), the input of which is connected to the output of the transformer (4), and the output through manual or automatic switches with an uninterruptible power supply bus.

In addition, the claimed device additionally contains a diagnostic module (12), the inputs of which are connected by an information cable to the outputs of at least one inverter (6), at least one converter (7), battery cabinet (8), automatic and manual bypass circuits (9) , transformer distribution board (10). In this case, the first output of the diagnostic module (12) is connected to the technical diagnostics and monitoring system, the second output is connected to microprocessor centralization devices, the third output is connected to the integrated workstation of the alarm, centralization and blocking electromechanic (13).

The diagnostic module (12) monitors:

operating status and electrical parameters from external power sources;

operating status and electrical parameters of the device (1) and (2);

operating status of the automatic transfer switch circuit (3);

electrical energy parameters at guaranteed loads

operating status of the automatic and manual bypass circuit (9);

operating status of rectifiers (5) and inverters (6);

parameters of electrical energy at the output of direct current sources;

state of circuit breakers and main elements;

operating status and electrical parameters of the transformer switchboard (10);

state of circuit breakers and battery cabinet elements (8);

controls electrical parameters at the output of the distribution board.

At the integrated electromechanical workstation for signaling, centralization and blocking (13), for example, the following is carried out:

displaying information on the LCD display with a block diagram of the operation;

displaying information about the measurement of electrical parameters;

displaying messages in the event and accident log, etc.

Thus, due to the presence of guaranteed and uninterruptible power supply buses and a diagnostic module, the claimed device guarantees uninterrupted power supply to DC and AC consumers and significantly expands the functionality of the device, thereby ensuring the achievement of a technical result.

Claims (1)

A power supply device unified on a DC bus, containing at least one input and protection device for the feeder, an input and protection device for the feeder of the backup power plant, connected in parallel to the automatic transfer circuit, the output of which forms a guaranteed power bus, the first output of which provides power supply to the guaranteed loads, the second the output is connected through a transformer to at least one rectifier, the output of which forms a DC bus, to which at least one inverter, at least one converter and a battery cabinet are connected in parallel, while the output of at least one inverter is connected to the first input of the automatic and manual bypass circuit , the output of which, through a group of transformers of the transformer distribution board and the distribution board, is connected to the outputs for power supply of at least one group of backup loads and tone rail circuits, the second input of the automatic and manual bypass circuit is connected to the guaranteed power bus through a transformer, the output of at least one converter is connected to low direct voltage output, additionally contains a diagnostic module, the inputs of which are connected by an information cable to the outputs of at least one inverter, at least one converter, battery cabinet, automatic and manual bypass circuit, transformer distribution board, while the first output of the diagnostic module is connected to the technical system diagnostics and monitoring, the second output is connected to microprocessor centralization devices, the third output is connected to the integrated workstation of the electromechanic of alarm, centralization and blocking.