RU203930U1 - Distance protection device - Google Patents

Abstract

The utility model relates to the field of electrical engineering and electric power engineering, in particular to the means of relay protection of electrical networks. The purpose of the proposed utility model is to create a device that implements the distance protection principle more fully and more accurately. The distance protection device contains current and voltage sensors, a circuit breaker control unit, the first and second blocks for short circuit simulation, a comparison block, the first input of which is connected to the output of the first short circuit model, the second input of the comparison block is connected to the output of the second short circuit model, and is additionally equipped with a block registration unit, a remote body, a time delay counting unit, an indication unit, the first input of the recording unit is connected to the output of the current sensor, the second input of the recording unit is connected to the output of the voltage sensor, the output of the recording unit is connected to the inputs of the first and second short circuit simulation units, the input of the remote organ is connected to the output of the comparison unit, the first output of the remote organ is connected to the input of the time delay counting unit, the second output is connected to the input of the display unit, the output of the time delay counting unit is connected to the input of the switch control unit. 2 ill.

Description

The utility model relates to the field of electrical engineering and electric power engineering, in particular to the means of relay protection of electrical networks.

A distance protection device is widely known [1], in which the distance to the fault location is determined using a resistance relay according to an indirect principle - a change in the resistance of a short circuit, calculated from the signals of current transformers and voltage transformers. The protection device generates a command to disconnect the line when the resistance vector enters a certain zone (area of the response characteristic) on the complex plane.

This approach assumes the stationarity of the controlled mode, and therefore, under conditions of transient processes, the error in determining the distance of the closure increases significantly.

In addition, the measured resistance vector may fall into the distance protection operation zone under certain load modes (for example, when starting a large asynchronous electric motor) and in the presence of some types of transient resistance at the point of damage. These factors reduce the accuracy of measuring the distance of the short-circuit point and, therefore, reduce the degree of selectivity of protection.

The closest in technical essence to the claimed device is the solution chosen as a prototype [2]. The prototype device contains current and voltage sensors, a circuit breaker control unit, the first and second short circuit simulation units, a comparison unit, the first input of which is connected to the output of the first short circuit model, the second input of the comparison unit is connected to the output of the second short circuit model.

The currents and voltages corresponding to the emergency and normal (pre-emergency) modes are used to calculate the emergency components, which, according to the superposition principle [3], are determined mainly by the type and location of damage. Their use makes it possible to tune out the influence of the load mode on the calculation of the place of damage.

On the basis of the emergency components, using two models of the protected power transmission line, the reactive powers of the prospective (calculated) short-circuit circuits are determined in case of damage at the beginning and at the end of the protected line, respectively. Assuming that the resistance at the fault site has an active (resistive) character, the damage is considered internal (on the protected line) when the signs of the two reactive power values obtained are different.

The disadvantage of the known solution lies in the fact that it allows to reveal only the fact of damage to the protected power line, but does not ensure the dependence of the response time of the distance protection on the remoteness of the short circuit.

The purpose of the proposed utility model is to create a device that implements the distance protection principle more fully and more accurately.

This goal is achieved by the fact that a distance protection device containing current and voltage sensors, a circuit breaker control unit, the first and second short circuit simulation units, a comparison unit, the first input of which is connected to the output of the first short circuit model, the second input of the comparison unit is connected to the output of the second short circuit model, additionally equipped with a recording unit, a remote control, a time delay counting unit and an indicator, the first input of the recording unit is connected to the output of the current sensor, the second input of the recording unit is connected to the output of the voltage sensor, the output of the recording unit is connected to the inputs of the first and second simulation units short circuit, the input of the remote organ is connected to the output of the comparison unit, the first output of the remote organ is connected to the input of the timing unit, the second output is connected to the input of the display unit, the output of the timing unit is connected to the input of the circuit breaker control unit.

Comparative analysis of the claimed device with the prototype shows that the claimed technical solution has novelty in terms of registration units, timing and indication, as well as connections between them. This allows you to establish its compliance with the "novelty" criterion.

Comparison of the proposed solution with other technical solutions in this field of technology shows that the claimed solution uses a direct measurement of the distance of the damage site, and not an indirect sign - the resistance vector hits a pre-formed zone (area of response characteristics). This allows us to conclude that the proposed device meets the criterion of "significant differences".

FIG. 1 shows a block diagram of the proposed distance protection device.

The diagram contains: an image of the monitored power line, current sensor 1 and voltage sensor 2, registration block 3, short circuit simulation blocks 4 and 5, comparison block 6, remote body 7, timing block 8, indication block 9, circuit breaker control block 10.

FIG. 2 shows a diagram of reactive power Q (x), determined by the emergency components in case of faults at the beginning and at the end of the protected line.

The points H and K are marked on the diagram, which correspond to the results of the transformations performed in blocks 4 and 5 of the short circuit simulation, and the point of intersection of the segment [H, K] with the abscissa, corresponding to the coordinate of the damage site.

Distance protection device (Fig. 1) works as follows. The signals from the current sensor 1 and the voltage sensor 2 enter the registration unit 3, which continuously records and stores the measured values. When a short circuit occurs at an arbitrary point K of the power line, the registration unit 3 detects the onset of the transient process and, based on the available information about the measured values, generates two sets of currents and voltages that correspond to normal and emergency operation modes of the network. The third set is calculated - the emergency components of currents and voltages. Also, the registration block 3 determines the type of damage.

The resulting sets of currents and voltages are fed to the inputs of blocks 4 and 5 for modeling a short circuit. The model embedded in them is formed on the basis of solving differential equations describing the protected line. These blocks perform the mathematical conversion observables damage branches to the current (I _ƒ) and the voltage at the point of damage (U _ƒ), on the assumption that short-circuit type that corresponds to what has been defined unit 3 registration occurred in the beginning (point K _n ) and the end (point K _to , remote at a distance l from the installation site of the device) of the power line, respectively. They are used to calculate the reactive power of the damage branches at the beginning (Q _n ) and end (Q _k ) of the line. In this case, each type of short circuit has its own design expression, which in the case of a three-phase short circuit will have the following form:

The signs of the obtained reactive power values are compared in the comparison unit 6, and if they differ, the values of Q _n and Q _{k are} converted, according to FIG. 2, in the distance to the short circuit (x _ƒ ) according to the following expression:

The obtained coordinate by the display unit 9 is displayed on the screen of the device, and is also fed to the input of the remote organ 7, where it is compared with the length of the protected zone l _s.z. The result of the comparison is transmitted to the input of the block 8 counting the time delay. Depending on the remoteness of the damage from the installation site of the device, the time delay unit 8 introduces a corresponding delay for issuing the trip command to the circuit breaker control unit 10.

Experimental studies of the inventive distance protection device have shown that, in comparison with the prototype, the inventive device calculates the distance to the damage site and provides the dependence of the protection response time on the damage distance.

The use of a direct assessment of the distance of the damage site allows increasing the accuracy of distance protection, and the implementation of dependent time delay - the degree of its selectivity.

Information sources:

1. Chernobrovov N.V. Relay protection. Moscow: Energiya, 1974 .-- 680 p.

2. Lamets Yu.Ya., Antonov V.I., Nudelman GS, Akhmetzyanov S.Kh. Patent for invention No. 1775787 of the Russian Federation, Н02Н 3/40. Method of distance protection of power transmission lines. Publ. 15.11.1992, Bul. No. 42 (prototype).

3. Fundamentals of circuit theory: Textbook. for universities / Zeveke G.V., Ionkin P.A., Netushil A.V., Strakhov S.V. - 5th ed., Rev. - M .: Energoatomizdat, 1989.

Claims (1)

A distance protection device containing current and voltage sensors, a circuit breaker control unit, the first and second blocks for short circuit simulation, a comparison unit, the first input of which is connected to the output of the first short circuit model, the second input of the comparison unit is connected to the output of the second short circuit model, characterized in that that it is additionally equipped with a recording unit, a remote organ, a time delay counting unit and an indication unit, the first input of the recording unit is connected to the output of the current sensor, the second input of the recording unit is connected to the output of the voltage sensor, the output of the recording unit is connected to the inputs of the first and second simulation units short circuit, the input of the remote organ is connected to the output of the comparison unit, the first output of the remote organ is connected to the input of the timing unit, the second output is connected to the input of the display unit, the output of the timing unit is connected to the input of the switch control unit.

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