RU165635U1 - DEVICE FOR AUTOMATIC REPEATING OF A CABLE-AIR CABLE ELECTRIC TRANSMISSION - Google Patents

Abstract

A device for automatically reconnecting cable-overhead power lines (PTL), comprising a probe pulse generator, a probe pulse receiver, an information processing unit, the probe pulse output being connected to the first input of the information processing unit, characterized in that a switch, a high-frequency connection and a unit are introduced wave detection of damage to power lines, with high-frequency connection designed to connect to the end of the air section of power lines, input-output switch The ora is connected to a high-frequency connection, the first and second outputs of the switch are connected respectively to the inputs of the wave transmission line damage determination unit and the first input of the probe pulse receiver, the first output of the transmission line damage wave determination unit is connected to the second input of the information processing unit, the second output of the transmission line damage wave determination unit to the input of the probe pulse generator and the first input of the switch, the first and second outputs of the probe pulse generator are connected respectively To the second input of the switch and the second input of the probe pulse receiver, the first output of the information processing unit is the output of the re-enable signal, and its second output is the output of information about the location of the damage.

Description

The utility model relates to the field of electrical engineering and can be used for cable-overhead power lines.

According to the Electrical Installation Rules [Electrical Installation Rules (PUE), 7th edition (approved by Order of the Ministry of Energy of 08.07.2002. No. 204], clause 3.3.2. "... Automatic re-activation (AR) of air and mixed (cable- ") air lines of all types of voltages above 1 kV. Refusal to use automatic reclosure must be justified in each individual case."

However, in electrotechnical practice there are no typical technical solutions that provide ARs for high-voltage cable-air transmission lines (for example, 110 kV and higher).

To ensure economic efficiency, high-voltage cable-air power lines are used in the area of megacities. At the same time, from the point of view of safety and the prevention of personal injuries, it is advisable to implement the automatic reclosure of cable-overhead power lines in case of damage in the air sections and prohibit the reclosure in case of damage in the cable sections. Indeed, re-supplying high voltage to the high-voltage cable passing in the area of residential buildings can lead to significant damage, injury and even death. At the same time, transitions of cable sections into air ones, usually performed directly on power transmission towers, are of particular danger. It should be noted that on high-voltage cables, as a rule, there is no mechanism for self-repair of damage and for voltage re-supply they should be tested.

Therefore, for effective AR of high-voltage cable-air power transmission lines, it is necessary to determine with high accuracy on which of the areas (air or cable) the damage occurred and, when the damage is eliminated in the air section, to realize the AR of power transmission lines.

From the point of view of the above logic, the existing methods of AR-LEP [For example, Bogorad A.M., Nazarov Yu.G. Automatic reclosing in power systems. - M .: "Energy", 1969.] for cable lines are not directly applicable.

A known method of automatically re-enabling the power line [RF Patent No. 2365013 IPC Н02Н 3/06, publ. August 20, 2009], in which AR is performed in case of a positive result of the diagnosis of the status of power lines, the diagnosis of the state of power lines is carried out by receiving and analyzing at each phase continuous high-frequency signals containing at least one information sign of the performance of power lines or the presence of permanent damage, the reception and analysis of high-frequency signals is carried out at one end of the line, and informative signs are formed on the basis of the intrinsic and mutual resistances of the phases of the power lines at different frequencies.

However, the application of the known method and the corresponding AR devices is difficult on cable-air transmission lines because of the reflections of continuous high-frequency signals at the junction of cable and air sections, since each of the sections differs significantly in the values of wave impedances.

A known method of automatically re-enabling the power line [USSR Author's Certificate No. 943957, IPC Н02Н 3/06, publ. July 15, 1982], in which, in the case of a single-phase short circuit, the damaged phase is switched off and repeated switching on is carried out in case of self-repair of the damage.

However, this method is not intended for use on cable-overhead power lines, because the fact of serviceability of the cable is diagnosed according to the results of special tests.

The closest technical solution to the proposed utility model is a device that implements a method for monitoring or emergency shutdown and failure to automatically turn on the head switch of the line supplying the transformer substation, determining the type of short circuit [RF Patent No. 2502178 IPC H02J 13/00, publ. December 20, 2013]. The device contains a head switch supplying a transformer substation, a power transformer, an input bus switch, power lines extending from the substation tires, a short-circuit current sensor, a NOT element, a voltage sensor, a MEMORY element, a DELAY element, a SINGLE-DISPLAY element, an AND element, a probe pulse generator , a probe pulse probe, an information processing unit, a recording device.

A distinctive feature of the device is that the state of the elements of the adjacent electrical network is determined by sensing and calculating the distances to the corresponding reflections.

The disadvantage of the prototype device is that it is designed for overhead power lines and it is impossible to use it for cable-air power lines.

The objective of the utility model is to create an automatic re-enable device for cable-overhead power lines, which provides a signal for re-inclusion if the damage occurred only in the air section and subsequently self-repaired.

The task is achieved by a device for automatically reconnecting a cable-overhead power line (transmission line), comprising a probe pulse generator, a probe pulse receiver, an information processing unit, wherein the output of the probe pulse receiver is connected to the first input of the information processing unit. According to the proposal, a commutator, a high-frequency connection and a wave detection unit for damage to power transmission lines were introduced; moreover, a high-frequency connection is intended to be connected to the end of the air section of the power transmission line, the input-output of the switch is connected to high-frequency connection, the first and second outputs of the switch are connected respectively to the inputs of the wave damage detection unit of the power transmission line and the first input of the probe sounding pulse receiver, the first output of the wave block for determining the damage to power lines is connected to the second input OK, the second output of the probe pulse generator and the first input of the switch, the first and second outputs of the probe pulse generator are connected respectively to the second input of the switch and the second input of the probe probe, the first output of the information processing block is the signal output repeated inclusion, and its second output is the output of information about the place of damage.

In FIG. 1 is a structural diagram of an automatic re-starting device interacting with a cable-air power line and equipment located at the opposite end of the power line.

The device (Fig. 1) contains: high-frequency connection 1 ₁ , switch 2; block 3 ₁ wave definition of damage to power lines; probe pulse generator 4; probe probe 5; information processing unit 6.

At the opposite end of the air section of the power transmission line 7 (Fig. 1), a high-frequency connection 1 _{2 is} installed, as well as a block 3 _{2 of the} wave definition of damage to the power lines.

The components of the device are connected as follows. The output of the receiver 5 of the probe pulses is connected to the first input of the information processing unit 6, the high-frequency connection 1 _{1 is} connected to the end of the air section of the power transmission line 7. The input-output of the switch 2 is connected to the high-frequency connection 1 ₁ . The first and second outputs of the switch 2 are connected respectively to the input of the block 3 ₁ wave definition of damage to power lines and the first input of the receiver 5 of the probe pulses. The first output of the power transmission line damage detection unit 3 _{1 is} connected to the second input of the information processing unit 6, the second output of the power transmission line damage detection unit 3 ₁ is connected to the input of the generator 4 of the probe pulses and the first input of the switch 2. The first and second outputs of the generator 4 of the probe pulses are connected to the second input of the switch 2 and the second input of the receiver 5 of the probe pulses. The first output of the information processing unit 6 is the output of the re-enable signal, and its second output is the output of information about the location of the damage.

To ensure the normal functioning of the device at the opposite end of the air section of the power transmission line, the high-frequency connection 1 _{2 is} connected to the power transmission line 7, and the input of the second block 3 _{2 of the} wave detection of damage to the power transmission line is connected to the output of the high-frequency connection 1 ₂ .

It should be noted that high-frequency connections can be made in accordance with circuit designs [For example, Mikutsky G.V., Skitaltsev B.C. High frequency power line communications. - M.: Energia, 1969.], and the blocks for wave-determining damage to power lines in accordance with circuit designs, for example, by the Canadian company Qualitrol [http://www.qualitrolcorp.ru].

The device operates as follows.

When damaged in the air section of the power transmission line 7, electromagnetic waves propagate from the point of damage to the ends of the air section. These waves pass through the high-frequency connections 1 ₁ , 1 ₂ located at the ends of the damaged air section of the power transmission line 7 and are registered by blocks 3 ₁ , 3 _{2 of the} wave definition of damage to the power transmission lines. Before entering block 3 _{1, an} electromagnetic wave passes through switch 2.

According to the recorded times of arrival of electromagnetic waves in blocks 3 ₁ , 3 ₂ , the distance to the place of damage is calculated [For example, G. Shalyt Determination of places of damage in electrical networks. - M.: Energoatomizdat, 1982. p. 19.]

where L is the length of the damaged air section of the transmission line; v is the propagation velocity of electromagnetic waves through the air section of the power transmission line; t ₁ and t ₂ - respectively, the time of arrival of electromagnetic waves in blocks 3 ₁ and 3 ₂ .

To provide calculations for the specified expression, information about the registered time t ₂ from block 3 ₂ is transmitted (for example, over the air) to block 3 ₁ for performing calculations. From the first output of block 3 _{1 of the} wave definition of damage to power lines, information about the location of the damage enters the information processing unit 6.

Additionally, when an electromagnetic wave arrives from the place of damage to block 3 _{1, a} signal is sent from the second output of block 3 ₁ to start the generator 4 of the probe pulses and to switch 2 for connecting the generator 4 through switch 2 and the high-frequency connection 1 ₁ to the air section of the power transmission line 7.

The probe pulse generator 4 probes the power line 7. From the second output of the generator 4, control signals are supplied to the second input of the receiver 5 to block the receiver when each of the probe pulses is emitted in the power line 7. These control signals are additionally used in the receiver 5 to fix the delay time between the radiation in power lines and reception of sounding pulses reflected from damage.

The receiver 5 implements the reception of the reflected probe pulses and provides the calculation of the distance to the place of reflection. If the probe pulses are reflected from the opposite end of the installation of the receiver 5 of the end of the air section of the power transmission line (the delay time is t ₃ = L / v), then it is decided that there is no damage to the analyzed air section of the power line. Otherwise, the reflection from the damage is recorded in the receiver, the delay time t _{zp is recorded,} and the distance to the damage is calculated accordingly by the expression

The signal about the presence of damage in the air section of the power transmission line 7 and the place of damage, obtained by sensing, from the output of the receiver 5 enters the information processing unit 6.

The information processing unit 6 clarifies the location of the damage, for example, by averaging the distance obtained as a result of calculations according to expressions (1) and (2). Thus, the exact location of the damage in the air section of the power transmission line 7 is made, first implemented by the passive wave method, and then refined by the results of active sensing.

The fact of self-repair of damage in the air section of the power transmission line 7 is recorded according to the results of sounding (case t ₃ = L / v). In this case, the information processing unit 6 receives a signal from the receiver 5 about the absence of damage.

In the reclosure cycle (during the interval allotted for re-inclusion) when self-repairing damage from the first output of the information processing unit 6, a re-activation signal (reclosure resolution) is issued. In the presence of damage detected by continuous active sensing of the air section of the power transmission line 7, the AR signal is not issued.

Additionally, if there is damage from the second output of the information processing unit 6, an updated value of the distance to the place of damage of the air section of the power transmission line 7 is issued.

Thus, the proposed proposed utility model provides a re-enable signal in case of damage only in the air section of the cable-air power line and the damage has self-repaired.

Claims (1)

A device for automatically reconnecting cable-overhead power lines (power lines), comprising a probe pulse generator, a probe pulse receiver, an information processing unit, wherein the probe pulse receiver output is connected to the first input of the information processing unit, characterized in that a switch, a high-frequency connection and a unit are introduced wave detection of damage to power lines, with high-frequency connection designed to connect to the end of the air section of power lines, input-output switch The ora is connected to a high-frequency connection, the first and second outputs of the switch are connected respectively to the inputs of the wave transmission line damage determination unit and the first input of the probe pulse receiver, the first output of the transmission line damage wave determination unit is connected to the second input of the information processing unit, the second output of the transmission line damage wave determination unit to the input of the probe pulse generator and the first input of the switch, the first and second outputs of the probe pulse generator are connected respectively To the second input of the switch and the second input of the probe pulse receiver, the first output of the information processing unit is the output of the re-enable signal, and its second output is the output of information about the location of the damage.

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