RU94919U1 - DEVICE FOR AUTOMATIC VOLTAGE CONTROL IN THE CONTACT NETWORK - Google Patents

Abstract

 A device for automatically controlling the voltage in the contact network, containing two units for allocating 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 unit for measuring voltage in the contact network, while the output of at least one of the limit allocation units the voltage values in the contact network are connected to the first input of the voltage level calculation unit at the substation, connected by the output to the first input of the transformer command generation unit a, the second input of each voltage limit value allocation unit is connected to the output of the minimum voltage value setter in the contact network, and the second input of the voltage level calculation unit of the substation is used to connect the substation voltage level setter output, a current overload unit, the first input of which is connected to substation overcurrent unit, its second input is connected to the output of the overcurrent master, and the output of the overcurrent input unit is connected to the third input of the calculation unit I is the voltage level at the substation, the outputs of both voltage limit value isolation units in the contact network are connected to the first input of the voltage level calculation unit at the substation by means of an OR element, characterized in that it contains at least two blocks for controlling the speed of a moving object, the output of each of which is connected to the first input of the corresponding unit for allocating speed of a moving object, the second input of each of the units for allocating speed of a moving object is connected to the output of the limiter

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 automatic voltage regulation in the contact network (SU 1444185, IPC B60M 3/02. - B.A. Arzhannikov, L.A. Frolov, V.I.Sipkin. Device for automatic voltage regulation in the contact network. - Publ. 12/15/1988 Bull. No. 46), containing two limit voltage allocation units in the contact network, the first of each of which is connected to the output of the corresponding voltage measurement unit in the contact network, while the outputs of both voltage allocation units in the contact network are connected respectively to the first and WTO to the second inputs of the voltage level calculation unit at the substation connected to the output of the transformer command generation unit, the second input of each voltage limit value allocation unit is connected to the output of the undervoltage regulator in the contact network, and the third input of the voltage level calculation unit of the substation is designed to connect to the output of the setter voltage level of the traction substation, while one of the inputs of one of the blocks for extracting the voltage limit value in the contact network is connected to the output For more voltage measuring unit in a contact network connected with the inputs of the contact network.

The disadvantage of this device is the relatively low operational reliability due to the presence of equalizing currents and the inability to ensure stability during operation of the rolling stock in regenerative braking modes.

A device is also known for automatic voltage regulation in a contact network (RU 50933, IPC V60M 3/02, Н02М 5/257. A.B. Arzhnikov, L. A. Frolov, V. A. Verbitsky, I. O. Naboychenko. Device for automatic voltage regulation in the contact network. - Published on January 27, 2006 Bull No. 03), which contains two limit voltage isolation blocks in the contact network, the first of the inputs of each of which is connected to the output of the corresponding voltage measurement block in the contact network, the output being at least one of the limit value allocation blocks voltages in the contact network are 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 voltage limit value allocation unit is connected to the output of the minimum voltage setpoint in the contact network, and the second input of the voltage level calculation unit at the substation it is intended for connection to the output of the voltage level substation of the substation, a current overload unit, the first input of which is connected to the overload unit the substation is narrow in current, its second input is connected to the output of the overcurrent master, and the output of the introduced overcurrent block is connected to the third input of the substation voltage level calculation unit, the outputs of both voltage limit value allocation blocks in the contact network are connected to the first input of the level calculation unit voltage at substations by means of the OR element.

The disadvantage of this device is that it does not provide a prompt for a minimum time voltage increase due to an increase in the speed of trains, and, therefore, is characterized by insufficiently high operational reliability.

The objective of the utility model is to create a device with high operational reliability, due to a rapid increase in voltage during a minimum time with increasing train speed.

The essence of the utility model is that it contains at least two blocks for controlling the speed of a moving object, the output of each of which is connected to the first input of the corresponding block for selecting the speed of a moving object, the second input of each of the blocks for selecting the speed of a moving object is connected to the output of the limiter values of the speed of a moving object, the output of each block allocating the limit value of the speed of a moving object is connected to the input of the block forming the maximum level of stabilization voltage substation by means of OR, the output of unit forming the maximum level of voltage stabilization at the substation is connected to a second input unit for generating commands transformer.

Figure 1 presents the electrical schematic diagram of the inventive device for automatic voltage regulation in the contact network.

A device for automatically controlling the voltage in the contact network contains two blocks 1 and 2 highlighting the limit value of voltage in the contact network, as well as two blocks 3 and 4 of 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 selection of the voltage limit value in the contact network are connected to the first input of the block 5 for calculating the voltage level at the substation through the first element 6 OR.

The output of the voltage level calculating unit 5 at the substation is connected to the first input of the transformer command generation unit 7.

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 master 8 and 9 of the minimum voltage value in the contact network. In this case, the second input of the voltage level calculation unit 5 at the substation is intended to be connected to the output of the voltage level setter 10 at the substation.

The device also comprises a current overload unit 11. The first input of the overcurrent block 11 is connected to the substation overcurrent block 12, the second input of the overcurrent block 11 is connected to the overcurrent master 13. The output of the current overload unit 11 is connected to the third input of the voltage level calculation unit 5 at the substation.

Other outputs of blocks 3 and 4 of measuring voltage in the contact network are connected to the inputs of similar blocks 2 and 1 of the allocation of the maximum voltage in the contact network of neighboring substations (not shown).

In addition, the device contains two blocks 14 and 15 for controlling the speed of a moving object, two blocks 16 and 17 for highlighting the speed limit value of a moving object, two adjusters 18 and 19 of the speed limit value for a moving object, a second OR element 20, and also a maximum level formation unit 21 voltage stabilization at the substation.

The device operates as follows.

In the initial position, the voltage substation 10 at the substation is supplied with the substation voltage, indicated in the drawing U _p , then supplied to the substation voltage level calculating unit 5 and the transformer command generation unit 7, where the intermediate value of the substation voltage is set within the maximum and minimum voltage stabilization or open circuit voltage with step voltage regulation. Blocks 3 and 4 measuring voltage in the contact network measure voltage in the contact network, for example, at sectioning posts or in parallel connection points located to the left or right of a particular substation.

By reducing the tension in the catenary lower U _of predetermined setting elements 8 and 9, the minimum value of voltage in the catenary, the blocks 1 or 2 discharge limit voltage value in the contact system, both separately and jointly, emits a signal through the element 6 or in the unit 5 calculating the level voltage at the substation, forming a signal transmitted to block 7 to increase the voltage of the substation.

When the voltage in the contact network rises above U _{s of the} minimum value, the signals from the output of blocks 1 and 2 are removed, and the voltage at the substation assumes the original, initial, value determined by U _p .

If at the initial value of the voltage of the substation or at its increase according to the signals of blocks 1 or 2, the current of the substation I _p , controlled by the overcurrent unit 12, exceeds the maximum value I _{p max} determined by the overcurrent setter 13, then a signal is generated by the overload unit 11, entering the voltage level calculation unit 5 at the substation, to lower the voltage of the substation, which, in turn, leads to a decrease in the current of a particular substation and an increase in the current of neighboring substations.

With the simultaneous action of signals about a decrease in voltage in the contact network and an excess of current above the maximum value of the substation load current, preference is given to the current channel, i.e. substation voltage is reduced. Signals of undervoltage from blocks 3 and 4 of voltage measurement in the contact network are transmitted to similar blocks, respectively 2 and 1 highlighting the voltage limit of neighboring substations, the voltage on which increases.

In the initial position, a reference voltage is indicated on the speed limiters of the moving object, indicated on the drawing U _back , then supplied to the blocks 16 and 17 for allocating the speed limit value of the moving object. Each of the blocks 14 and 15 control the speed of movement is set in such a way that it can measure the speed of a moving object (train). In addition, to the blocks 16 and 17 of the allocation of the limiting value of the speed of a moving object, a signal is sent from the corresponding block 14 and 15 to control the speed of movement.

When increasing the speed of the object above the limit value of the speed of the moving object, the blocks 14 and 15 control the speed of trains give a signal through blocks 16 and 17 highlighting the limit value of the speed of the moving object and the element 20 OR and block 21 forming the maximum level of stabilization at the substation in block 7 for increasing voltage at the substation.

The described situation occurs when passing high-speed passenger trains.

The implementation of the proposed technical solution will provide:

- improving the efficiency of railway transport;

- increase in throughput and freight capacity;

- reduction of electricity losses in the contact network;

- improving the safety of train traffic due to more reliable regenerative braking;

- improving the operational reliability of the device for automatic voltage control in the contact network due to operational for a minimum time voltage increase with increasing speed of trains.

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. Currently, work is underway on the manufacture of an industrial design of a device for automatically controlling the voltage in a contact network.

Claims (1)

A device for automatically controlling the voltage in the contact network, containing two blocks for allocating 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, while the output of at least one of the limit the voltage values in the contact network are connected to the first input of the voltage level calculating unit at the substation, connected by the output to the first input of the transformer command unit a, the second input of each voltage limit value allocation unit is connected to the output of the minimum voltage value setter in the contact network, and the second input of the voltage level calculation unit of the substation is used to connect the substation voltage level setter output, a current overload unit, the first input of which is connected to substation overcurrent unit, its second input is connected to the output of the overcurrent master, and the output of the overcurrent input unit is connected to the third input of the calculation unit voltage level at the substation, the outputs of both voltage limit value isolation blocks in the contact network are connected to the first input of the voltage level calculation unit at the substation by means of an OR element, characterized in that it contains at least two blocks for controlling the speed of a moving object, the output of each of which is connected to the first input of the corresponding unit for allocating speed of a moving object, the second input of each of the units for allocating speed of a moving object is connected to the output of the master the value of the speed of a moving object, the output of each block for allocating a limit value of the speed of a moving object is connected to the input of the unit for generating the maximum level of voltage stabilization at the substation by means of an OR element, the output of the unit for generating the maximum level of voltage stabilization at the substation is connected to the second input of the unit for generating the transformer commands.