RU58271U1 - CONTACT NETWORK - Google Patents

Abstract

The utility model relates to electrical engineering, in particular to the power supply of electrified railways, and can be used in contact networks having devices for protection against short circuits in case of insulation failure on the supports of the contact network.

A useful model solves the problem of creating a contact network, characterized by high reliability due to the exclusion of the possibility of artificial short circuit of the contact network with the rail, disconnecting high-speed machines in the protected area without short-circuit currents, indicating a damaged insulator and without damaging the support.

To solve the problem in a contact network containing a supporting cable, strings, contact wire, console, traction, clamp rods located on each support, the supporting cable, strings, and contact wire are separated from the metal fastening elements on the support of these elements by means of insulators, it is proposed , according to this utility model, between the metal fasteners and the support, install interconnected radio transmitters and a voltage sensor, which fix the occurrence of voltage on the support When the breakdown of an insulator and a broadcast radio signal to turn off the power supply contact.

Description

The utility model relates to electrical engineering, in particular to the power supply of electrified railways, and can be used in contact networks having devices for protection against short circuits in case of insulation failure on the supports of the contact network.

Known contact network containing placed on each support bearing cable, strings, contact wire, console, traction, retainer rods, metal fasteners on the support, while the bearing cable, strings, contact wire, console, traction and clamp rods are separated from metal elements fastenings on a support by means of insulators [L.1].

A contact network is also known comprising a supporting cable, strings, a contact wire, a console, a rod, a latch rod, metal fasteners on a support located on each support, while the supporting cable, strings, a contact wire are separated from the metal fastening elements on the support by means of insulators [ L.2].

The contact network described in [L.1] and [L.2] is characterized by relatively low reliability, since it does not protect the supports from short-circuit current, which leads to the combustion and destruction of the support, during the breakdown of insulators and the high voltage of the contact wire and the carrier cable to the support, while the short circuit current flows from the power source installed on the traction substation through the contact wire and the supporting cable, through the support, ground, rail and returns to the power source.

A contact network is known that contains a supporting cable, strings, a contact wire, a console, a rod, latch rods, metal fasteners on a support, as well as a ground conductor connecting metal fasteners on a support with a rail and providing a short circuit current breakdown of insulators and protection of the support [L.3].

However, a protective grounding conductor that protects the contact network support from short circuit current during the breakdown of insulators creates a leakage current circuit with serviceable insulators: rail - protective grounding conductor - fastening elements on the support - support - ground, which leads to electrical corrosion of the foundation anchor bolts metal supports and reinforcement of reinforced concrete supports, contributing to the damage of the support due to the loss of its mechanical strength [L.4].

To prevent this phenomenon, devices are used that provide grounding to the rail through protective devices that prevent the leakage of current from the rails through the circuit of the leakage currents flowing to the ground. Such protective devices include diode or thyristor grounding conductors with a spark gap, which provide individual protection of each support or several supports using an additional group grounding wire [L.5]

Protective grounding devices described in [L.5] are “an acceptable solution to the problem of protecting contact network supports in DC sections from corrosion”.

The disadvantages of the contact network of the described design include “the presence of an expensive group grounding cable with a significant cross-sectional area, the lack of control of its integrity, as well as the presence of expensive diode grounding conductors and the need

their verification under linear conditions. In addition, the presence in the short circuit of the resistance of the group grounding cable during short circuits causes a decrease in the short circuit current ... ”, which can lead to non-disconnection of the damaged insulator supports and to the development of the consequences of the dangerous situation. Unreliable operation of spark gaps consists in welding (melting) copper contact washers (electrodes), the need for periodic checks of spark gaps, etc., which, in turn, will reduce the reliability of the entire contact network as a whole [L.6].

A contact network is also known, comprising a supporting cable, strings, a contact wire, a console, a rod, a clamp rod located on each support, while the supporting cable, strings, a contact wire are separated from the metal fastening elements on the support of these elements by means of insulators, and an additional wire, connected through spark gaps with supports on the protected area of the contact network, at the ends and in the middle of which protection blocks are installed, consisting of an input device and a short circuit, installed between contact network and rail [L.7].

When the insulator breaks down on any support, the spark gap located on it breaks through, and the additional wire at this point is energized by the contact network, which is fed to short-circuit through the input device, they are triggered and the contact network is closed to the rail. Short-circuit current trips high-speed circuit breakers and relieves voltage from the contact network of the protected area.

The contact network in accordance with [L.7], having the protection of supports isolated from the rail (ZOIR), has the disadvantages inherent in the contact network with protection of group grounding with a diode ground electrode

- during breakdown of the insulator of one support, the voltage of the contact network through the additional wire enters all the supports of the protected zone, which can cause breakdown of spark gaps at different ends of the protected zone, which, in turn, will inevitably lead to the appearance of flowing currents in the additional wire. The current flowing from the rails to the additional wire (or vice versa - from the additional wire to the rail) can reach several amperes depending on the train situation. A current of this magnitude, flowing from an additional wire to the underground part of the supports and foundations, causes intense electrical corrosion of the underground part, since it exceeds the maximum permissible current (0.04 A) by tens, and in some cases, hundreds of times.

Other disadvantages of the ZOIR include:

- the presence of interference or a low signal level of the input device that can cause a false operation or failure of the short circuit;

- the operation of the short circuit near the traction substation due to the low resistance of the electrical circuit of the short circuit, leading to the occurrence of large short circuit currents, and, consequently, to a decrease in the reliability, durability and the probability of failure-free operation of high-speed switches and power equipment of the traction substation;

- the difficulty of finding faulty insulators in the protected area due to the fact that the current flowing through the damaged insulators is limited by the resistance of the input device and is only a few hundred amperes; a current of this magnitude in most cases does not lead to visible damage to the insulators; destruction occurs after repeated supply of voltage, in which case the consequences

destruction of insulators leads to more serious damage to the contact network.

A useful model solves the problem of creating a contact network, characterized by high reliability due to the exclusion of the possibility of artificial short circuit of the contact network with the rail, disconnecting high-speed machines in the protected area without short-circuit currents, indicating a damaged insulator and without damaging the support.

To solve this problem, in a contact network containing a supporting cable, strings, contact wire, console, traction, clamp rods placed on each support, the supporting cable, strings, and contact wire are separated from the metal fastening elements on the support of these elements by means of insulators, It is proposed, according to this utility model, to install interconnected radio transmitters and voltage sensors between the metal fasteners and the support, which fix the occurrence of voltage on the support during the breakdown of the insulator and the transmission of a radio signal to turn off the power supply of the contact network.

The utility model is illustrated by the example of the drawings:

figure 1 and 2, which show: figure 1 is a functional diagram of the inventive contact network, and figure 2 is a connection diagram of a voltage sensor.

The contact network 1 contains a support cable 3, strings 4, a contact wire 5, a console 6, a rod 7, a retainer rod 8. The support 2 is installed near the rail 9. The fastening elements 10 on the support 2 are separated from the elements placed on the support 2 : support cable 3, strings 4, contact wire 5, console 6, rod 7, retainer rods 8 by means of an insulator 11.

Between the metal fastening elements 10 and the support 2, a voltage sensor 12 is installed, the output of which is connected to the input of the radio transmitter 13, equipped with a radio transmitting antenna 14.

The first output of the radio 15, equipped with a radio antenna 16, is connected to the input of the disconnect block 17 of the contact network from the power source 18, and the second output of the radio 15 is connected to the display unit 19.

In the event of an emergency (overvoltage and, consequently, breakdown of the insulator 11), the voltage sensor 12 detects the excess voltage and, being connected to the radio transmitter 13, transmits this information to the radio transmitter 13.

The information received in the form of a radio signal through a radio transmitting antenna 14 of the radio transmitter 13 is fed to the radio receiving antenna 16 of the radio receiver 15, located, for example, at a traction substation. Further, this signal enters the display unit 19 and signals that the insulator is damaged on the support with a specific number. The same information from the radio 15 enters the shutdown unit 17 of the contact network and disconnects it from the power source 18.

The implementation of the contact network in accordance with the proposed solution will increase its reliability by relatively simple means, eliminating the false operation or malfunctioning of generally disconnecting equipment (short circuit), while significantly simplifying the process of finding faulty insulators in the contact network, since all information about the failure the corresponding insulator is present on the display unit.

In accordance with the claimed decision, OOO NPP Elektromash developed the technical documentation of the protection unit containing

radio transmitter and voltage sensor; its prototype is made.

Tests of the prototype confirmed its efficiency and wide possibilities for its practical application in the future.

Literature:

1. NL Sokolov \\ Contact network \\ Educational illustrated textbook for students of technical schools, colleges and students of educational institutions of railway transport providing initial vocational training, M., “Route”, 2003, p.3, Fig. 1a.

2. The same, p. 33, fig. 1b.

3. The same with. 35, Fig. 2.

4. P.M. Shichkin, A.A. Porselan, A.V. Kotelnikov. Protection of the DC contact network with various methods of grounding supports, M., "Transport", 1977, p.13-14.

5. The same, p.15.

6. The same p. 17, 23-27.

7. Certificate for utility model No. 16146, IPC N 02 N 7/26, 2001

Claims (1)

A contact network containing a supporting cable, strings, contact wire, console, traction, clamp rods located on each support, while the supporting cable, strings, contact wire are separated from the metal fastening elements on the support of these elements by means of insulators, characterized in that between the metal fastening elements and a support are installed interconnected radio transmitter and voltage sensor, providing a fixation of the appearance of voltage on the support during the breakdown of the insulator and the transmission of the radio signal to shutdown lektropitaniya contact network.