RU75620U1 - DEVICE FOR AUTOMATIC VOLTAGE REGULATION AT TRACTION SUBSTATION AND IN THE CONTACT NETWORK - Google Patents

Abstract

The utility model relates to electrical engineering, in particular, to voltage regulation and can be used in devices for automatic voltage regulation in a contact network in an electrified railway.

A useful model solves the problem of creating a device for automatically controlling the voltage at the traction substation and in the contact network, characterized by wide functionality due to the possibility of regulating the voltage not only in the contact network, but also at the traction substation.

To solve this problem, a device for automatically controlling the voltage at the traction substation and in the contact network, containing at least two blocks for extracting the voltage limit value in the contact network, the first of each of which is connected to the output of the corresponding voltage measuring unit in the contact network , while the output of at least one of the blocks for extracting the voltage limit value in the contact network is connected to at least one input of the OR element, the level calculation unit n voltage at the substation connected to the input of the transformer command generation unit, the second input of each voltage limit value allocation unit is connected to the output of the minimum voltage setpoint in the contact network, the current overload signal generation unit, the first input of which is connected to the substation current overload unit, its second input is connected to the output of the overcurrent generator, it is proposed, according to the present utility model, to introduce a block for generating a signal of a voltage stabilization level substations connected to a first input of a setpoint output voltage substation level stabilization and the second input - to the first output voltage measurement unit substation transformer, and the third input - to yield

the signal conditioning unit for increasing the voltage stabilization level, one input of which is connected to the output of the OR element, and the other input of which is connected to the output of the signal conditioning block for increasing the voltage stabilization, the input of which is connected to the first output of the overcurrent signal generating unit, the second output of which is connected with the input of the unit for generating the signal for lowering the voltage stabilization level of the substation, the output of which is connected to the first input of the substation for calculating the voltage level ii, the second input of which is connected to the output of the signal conditioning block of the substation voltage stabilization level, the third output of the current overload signal conditioning block is connected to one of the inputs of the And element, the other input of which is connected to the output of the control unit of the minimum stabilization voltage level, the input of which is connected to the second the output of the voltage transformer unit of the substation; the output of the And element is connected to the input of the signal conditioning unit of the voltage stabilization cancellation command and turning on the switching transformer conversion unit for a natural characteristic, the first output of which is connected to the second input of the transformer command generation unit, and the second output of the signal conditioning command of the transformer voltage cancellation unit and switching on the switching unit transfer the transformer to the natural characteristic to connect to the input of the time delay unit of the switching unit a, the output of which is connected to the switching unit.

Description

The utility model relates to electrical engineering, in particular, to voltage regulation and can be used in devices for automatic voltage regulation in a contact network in an electrified railway.

A device for automatically controlling the voltage in the contact network, containing two blocks of allocation of the maximum voltage in the contact network, the first of the inputs of each of which is connected to the output of the corresponding unit for measuring voltage in the contact network, while the outputs of both blocks of the voltage allocation in the contact network are connected respectively to the first and second inputs of the unit for calculating the voltage level at the substation, connected by the output to the input of the unit for forming the transformer commands, the second input of each about the voltage limit value highlighting unit is connected to the output of the voltage minimum contactor in the contact network, and the third input of the voltage level calculation unit of the substation is designed to connect the voltage substation voltage level adjuster of the traction substation, while one of the inputs of one of the voltage limit value highlighting blocks in the contact network is connected to the output of an additional voltage measuring unit in the contact network connected by the inputs to the contact network [L.1].

Described in [L. 1] a device for automatically controlling the voltage in the contact network is characterized by a relatively low operational reliability due to the relatively

low reliability of power supply due to the presence of equalizing currents and the inability to ensure stability during the operation of rolling stock in regenerative braking modes, as well as the inability to pass high-speed passenger and heavy freight trains.

It is also known a device for automatically controlling the voltage in the contact network, containing two units for allocating the maximum voltage in the contact network, the first of the inputs of each of which is connected to the output of the corresponding unit for measuring voltage in the contact network, while the output of at least one of the allocation units the voltage limit value in the contact network is connected to the first input of the voltage level calculation unit at the substation, connected by the output to the input of the transformer command generation unit , the second input of each unit for extracting the limit voltage is connected to the output of the setpoint of the minimum voltage value in the contact network, and the second input of the unit for calculating the voltage level at the substation is designed to connect to the output of the setter of the voltage level at the substation; current overload unit, the first input of which is connected to the substation over current unit, its second input is connected to the output of the overcurrent master, and the output of the current overload unit is connected to an additional input of the substation voltage level calculation unit, the outputs of both voltage limit value allocation units in the contact network are connected to the first input of the unit for calculating the voltage level at the substation by means of the OR element [L. 2].

The device for regulating the voltage in the contact network according to [L.2] is characterized in comparison with a similar device according to [L.1] higher operational reliability due to

high reliability of power supply due to the exclusion of equalizing currents, and, therefore, the ability to ensure stability during operation of rolling stock in regenerative braking modes, as well as the ability to skip high-speed and heavy trains.

However, in this case, the device for automatically controlling the voltage in the contact network according to [L.2] is characterized by limited functionality due to the impossibility of regulating the voltage at the traction substation using this device.

A useful model solves the problem of creating a device for automatically controlling the voltage at the traction substation and in the contact network, characterized by wide functionality due to the possibility of regulating the voltage not only in the contact network, but also at the traction substation.

To solve this problem, a device for automatically controlling the voltage at the traction substation and in the contact network, containing at least two blocks for extracting the voltage limit value in the contact network, the first of each of which is connected to the output of the corresponding voltage measuring unit in the contact network , while the output of at least one of the blocks for extracting the voltage limit value in the contact network is connected to at least one input of the OR element, the level calculation unit n voltage at the substation connected to the input of the transformer command generation unit, the second input of each voltage limit value allocation unit is connected to the output of the minimum voltage setpoint in the contact network, the current overload signal generation unit, the first input of which

connected to the substation overcurrent block, its second input is connected to the output of the overcurrent master, it is proposed, according to this utility model, to introduce a substation voltage signal conditioning unit connected to the first input with the output of the substation voltage stabilizer, and the second input to the first output of the substation transformer voltage measuring unit, and the third input - with the output of the signal conditioning unit for increasing the voltage stabilization level, one input of which is connected go to the output of the OR element, and the other input of which is connected to the output of the block for generating the signal for prohibiting the increase of the voltage stabilization level, the input of which is connected to the first output of the block for generating the current overload signal, the second output of which is connected to the input of the block for generating the signal for reducing the voltage stabilization level of the substation the output of which is connected to the first input of the unit for calculating the voltage level of the substation, the second input of which is connected to the output of the unit for generating the signal of the stabilization level at substation voltage, connect the third output of the overcurrent signal generating unit to one of the inputs of the And element, the other input of which is connected to the output of the control unit for the minimum stabilization voltage level, the input of which is connected to the second output of the substation transformer voltage measurement unit; the output of the And element is connected to the input of the signal conditioning unit of the voltage stabilization cancellation command and turning on the switching transformer conversion unit for a natural characteristic, the first output of which is connected to the second input of the transformer command generation unit, and the second output of the signal conditioning command of the transformer voltage cancellation unit and switching on the switching unit translation

connect the transformer for a natural characteristic to the input of the time delay block of the switching block, the output of which is connected to the switching block.

The utility model is illustrated by drawings, in which respectively are presented: Fig. 1 is an electrical schematic diagram of the inventive device for automatically controlling voltage at a substation and in a contact network; figure 2 - the dependence of voltage on current at various modes of voltage stabilization.

 A device for automatically controlling the voltage at the traction substation and in the contact network contains two blocks 1 and 2 for allocating the voltage limit value in the contact network, as well as two blocks 3 and 4 for measuring voltage in the contact network. The first input of the voltage limit value allocation unit 1 in the contact network is connected to the output of the voltage measurement unit 3 in the contact network, and the first input of the voltage limit value allocation unit 2 in the contact network is connected to the output of the voltage value measurement unit 4 of the contact network. The outputs of blocks 1 and 2 of the allocation of the voltage limit value in the contact network are connected to the first input of the signal generating unit 5 to increase the voltage stabilization level at the substation by means of an OR element 6.

The second input of each of the blocks 1 and 2 of the selection of the voltage limit value is connected respectively to the output of the setter 7 and 8 of the minimum voltage value in the contact network.

The second input of the signal generating unit 5 for increasing the voltage stabilization level is designed to be connected to the output of the signal generating unit 9 for inhibiting the increase in the voltage stabilization level. The output of the block 5 forming a signal level increase

voltage stabilization is connected to the first input of the block 10 of the formation of the signal level stabilization voltage of the substation.

The first output of the overcurrent signal generating unit 11 is connected to the input of the generating unit 9 of the prohibition signal for increasing the voltage stabilization level.

The second output of the overcurrent signal generating unit 11 is connected to the input of the generating unit 12 for lowering the voltage stabilization level of the substation.

The third output of the block 11 generating an overcurrent signal is connected to the first input of the element 13 I.

The first input of the overcurrent signal generating unit 11 is connected to the input of the overcurrent transformer 14 of the substation transformer.

The second input of the current overload signal generating unit 11 is connected to the output of the current overload unit 15 of the substation transformer.

The output of the unit 12 for generating the signal for lowering the voltage stabilization level of the substation is connected to the first input of the unit 16 for calculating the voltage level of the substation.

The second input of the substation voltage level calculation unit 16 is connected to the output of the substation voltage stabilization level signal generating unit 10.

The output of the substation voltage level calculating unit 16 is connected to the first input of the transformer command generation unit 17.

 The second input of the signal generating unit 10 of the voltage stabilization level of the substation is connected to the output of the master 18 of the voltage stabilization level of the substation.

The third input of the signal conditioning level block 10 of the substation voltage stabilization level is connected to the first output of the substation transformer voltage measurement block 19.

The second output of the substation transformer voltage measuring unit 19 is connected to the input of the minimum stabilization voltage control unit 20.

The output of block 20 for monitoring the minimum voltage level of stabilization is connected to the second input of element 13 I.

The output of the element 13 And is connected to the input of the signal generation block 21 of the command for canceling the voltage stabilization of the transformer and turning on the switching unit for converting the transformer to a natural characteristic.

The first output of the block 21 of the formation of the signal command cancel the stabilization of the voltage of the transformer and the inclusion of the switching unit for converting the transformer to the natural characteristic is connected to the input of the block 17 of the formation of the transformer commands.

The second output of the block 21 of the formation of the signal command cancel the stabilization of the voltage of the transformer and the inclusion of the switching unit for transferring the transformer to the natural characteristic is connected to the input of the unit 22 of the time delay for switching on the switching unit.

The output of block 22 of the time delay for switching on the switching block is connected to the input of the switching block 23.

A device for automatically controlling the voltage at the traction substation and in the contact network works as follows.

In the starting position, i.e. in the absence of current overload I _d when the voltage in the contact network is higher than the minimum value U _{ks min} with the help of the regulator 18 of the stabilization voltage level at the substation

one of the intermediate values of the stabilized voltage (FIG. 2) is set between the maximum U _{d cm max} (characteristic 5, FIG. 2) and the minimum U _{d cm min} (characteristic 1, FIG. 2) voltage values.

The substation voltage stabilization level signal generating unit 10 generates a substation voltage level signal and, through the substation voltage level calculating unit 16, generates a command for the transformer control device (not shown in Fig. 1) using the transformer command generation unit 17 in order to maintain the voltage at a given stabilization level at the change in the load current I _d ( _figure 2) from zero to a maximum I _dmax .

When the voltage in the contact network drops below a predetermined minimum voltage level in the contact network U _{ks min} , and in the absence of current overload I _d through block 6 OR, in block 5 of the formation of the signal for increasing the voltage stabilization level, a signal for increasing the voltage stabilization level is generated, which is generated in the block 10 of generating a signal of a voltage stabilization level of a substation with a given stabilization level and is summed in block 16 for calculating the voltage level of the substation and through the transform command generation block 17 at the level of voltage stabilization increases up to the maximum stabilization level U _{d cm max} (figure 2).

When overcurrent, the signal from the overcurrent signal generating unit 11 is fed to the block 9 for generating a voltage stabilization inhibiting signal, which prohibits generating a signal for increasing the voltage stabilization level, and in the block 12 for generating a voltage stabilization reduction signal

substation, a signal is generated to lower the voltage stabilization level of the substation, and as a result, the voltage stabilization level decreases to the minimum stabilization level U _{d cm min} (Fig. 2).

If at the same time the current overload is preserved, then from the overcurrent signal generating unit 11 the signal is supplied to element 13 And and at the minimum voltage stabilization level U _{d cm min} this signal, controlled by the minimum stabilization voltage control unit 20, is fed to the forming unit 21 the signal of the command to cancel the stabilization of the voltage of the transformer and turn on the switching unit for transferring the transformer to the natural characteristic and from its second output, through the block 22 of the time delay, turn on the current unit enters the switching unit 23, bypassing the voltage regulation device (not shown in Fig. 1), which leads to the transfer of the transformer to the natural characteristic 0 (Fig. 2) without interrupting the operation of the transformer.

Implementation of the proposed technical solutions provide expansion capability apparatus for automatically controlling the voltage at the substation and the catenary substation by increasing the voltage change range when the maximum current I _{d max} from a stabilized voltage characteristics of 5 to the natural characteristic 0 (2) voltage.

In accordance with the claimed decision, technical documentation has been developed. A prototype of a device for automatic voltage regulation in a contact network was manufactured and tested. The test results confirmed the operability of the device and the wide possibilities of its practical application in the future. At present

time, work is underway on the manufacture of an industrial design of a device for automatically regulating voltage at substations and in a contact network.

Literature:

1. Auth. testimonial. USSR No. 1444185, IPC V60M 3/02, 1988

2. RF patent No. 50933 for utility model, IPC B60M 3/02, Н02М 5/257, 2006

Claims (1)

A device for automatically controlling the voltage at the traction substation and in the contact network, containing at least two blocks for extracting the voltage limit value in the contact network, the first of the inputs of each of which is connected to the output of the corresponding voltage measuring unit in the contact network, at least one of the voltage limit value isolation blocks in the contact network is connected to at least one input of the OR element, the voltage level calculation unit at the substation is connected output by the input of the transformer command generation unit, the second input of each voltage limit value allocation unit is connected to the output of the minimum voltage setpoint in the contact network, the current overload signal generation unit, the first input of which is connected to the substation current overload unit, its second input is connected to the output of the overcurrent master, characterized in that it contains a signal conditioning unit of the voltage stabilization level of the substation connected to the output by the first input the voltage stabilization level of the substation, and the second input with the first output of the substation transformer voltage measuring unit, and the third input with the output of the voltage stabilization raising signal generating unit, one input of which is connected to the output of the OR element, and the other input of which is connected to the output of the unit the formation of a ban signal to increase the level of voltage stabilization, the input of which is connected to the first output of the block for generating an overcurrent signal, the second output of which is connected to the input of the block generating a signal for lowering the voltage stabilization level of the substation, the output of which is connected to the first input of the substation voltage level calculation unit, the second input of which is connected to the output of the substation voltage stabilization level generating unit, the third output of the overcurrent signal generating unit is connected to one of the inputs of the And element, the other input of which is connected to the output of the control unit of the minimum stabilization voltage level, the input of which is connected to the second output of the voltage measurement unit transformer substation; the output of the And element is connected to the input of the signal conditioning unit for canceling the voltage stabilization and turning on the switching unit for transferring the transformer to a natural characteristic, the first output of which is connected to the second input of the unit for generating the transformer commands, and the second output of the signal conditioning unit for the canceling the voltage transformer and switching on the switching unit transfer of the transformer to the natural characteristic is connected to the input of the time delay unit of the switching unit, in the output of which is connected to the switching unit.