SU1467648A1 - Device for protecting electric network against short currents - Google Patents

Abstract

The invention relates to the field of electrical engineering, in particular, to relay protection of the electrical network from short-circuit current. The purpose of the invention is to increase the selectivity of protection of electric power systems with powerful electric motors in metallic short circuits. In the case of a short circuit in the feeder, all three inputs of the AND 6 element contain signals — from the outputs of the HE element 5, OR 11 and the phase-sensitive block 17, the signal from the output of the And 6 element goes to block 14 off. In this case, the transition of an electric motor in a serviceable feeder to the mode of feeding a point of a short time after a damaged feeder is recognized by changing the direction of current (power) in a serviceable feeder. 1 il. "E cl

Description

The invention relates to electrical engineering, in particular to the field of protection of electrical networks from short circuit currents.

The aim of the invention is to increase the selectivity of protection of electric power systems with powerful motors for metal short circuits near switchboards.

The drawing shows a functional diagram of a device

The device contains a source 1 of operating current voltage, sensor ed 2 of operational current, differentiation unit 3, null-organ 4, element NOT 5, element And 6, industrial frequency current sensor 7 and 8, setting blocks 9 and 10, for example, threshold elements 20 you, element OR 11, block 12 * artificial zero point of the network, block 13 artificial zero point of the feeder, block 14 shutdown, filter plug 15 for the industrial frequency of the network, sensor 25 16 voltage of the industrial frequency, phase-sensitive block 17. In addition, shown generator 18 and electric motor 19. '

Depending on the distance of the point -30 of the short circuit in the faulty feeder from the switchboard, as well as the type of short circuit (metal or arc), the voltage at the point of connection of the adjacent current feeders (and the motors themselves connected by them) decreases compared to the nominal to a greater or lesser extent. As a rule, if the voltage at the terminals of an electric motor connected by a working feeder drops in this case to (0.8 0.9) U _HOM , then this electric motor enters the generator mode of feeding the short circuit point in the adjacent feeder.

The greatest probability of the transition of electric motors connected by serviceable feeders to the generator mode of feeding the short circuit point occurs if the short circuit is metallic and if the electric motor of the defective feeder is located very close to the switchboard. In this case, the voltage drop between the phases at the short circuit point is very small, which contributes to the transition of electric motors connected by serviceable feeders to the generator mode of feeding the short circuit point in the faulty feeder.

In this case, the least probability of the transition of electric motors to. adjacent serviceable feeders to the generator mode for a power system with electric motors of medium and low power, since in this case the cross-sectional area of the feeders (including the defective at the moment) is less than that of feeders connecting high-power motors, and therefore the resistance the feeder from the point of short circuit to the switchboard is much greater than the resistance of the interfacial metal short circuit at the point of short circuit.

Thus, the voltage landing (dip) on the distribution board is less than, for example, for high-power electric motors, under the same conditions, the distance of the short circuit point from the distribution board is equal, and even less if the short circuit point in the defective feeder is more distant from the distribution board . Therefore, the probability of the transition of electric motors of neighboring serviceable Leaders to the generator mode of feeding the short-circuit point is much less.

For electric systems with electric motors of high power, in view of the comparison with the previous low resistance of the supply feeders, the probability of the transition of electric motors of serviceable Leaders to the generator mode of feeding the short-circuit point of the short Leader is much 45 higher.

When the motors in serviceable feeders go into the generator mode of feeding the short circuit point in the faulty feeder, the elimination of the faults jq depends on the number and power of the motors that are connected to the generator of the given power, and can provide two ways. Since when the defective feeder is switched off, the electric motors that have switched to the generator feeding mode of the short stuttering point must automatically (through the transient process) again switch to the motor mode, the mains generator must provide the possibility of simultaneous starting (starting) of all motors (through high starting currents), which with a large number of electric motors and a small margin of power the generator is difficult to provide. Therefore, a number of protection systems include j disabling both the faulty feeder and the serviceable feeder (with subsequent restart), in which the engine goes into the generator mode of feeding the short-circuit point,

Such a system then provides a sequential (or group) start-up of electric motors, which does not require multiple 2 power reserves from the generator in comparison with normal operation.

Thus, the indicated technical solutions are convenient when, under operating conditions, it is necessary to power 2 a large amount of motor load., The total power of which is not much less than the power of the supplying generator, from a given generator or in cases where the power system consists of medium and small electric motors power with long feeders.

If the power of the supply generator is many times greater than the total power of the motors connected to it and is capable of simultaneously starting all the motors ^, .. and also in power systems with electric motors of high power, strategy 4 for protecting the power system may be different. In this case, it is advisable to exclude the repeated switching start of electric motors, ensuring that only one - defective - 4 feeder is turned off, without disconnecting serviceable feeders, in which the motors switched to generator mode.

The device operates as follows on 4. The signal from the output of zero-orgap 4 through the element 5 is fed to the first input of the element And 6. The signals from the output of the sensors 7 and 8 of the industrial frequency current are fed to the inputs of the blocks 9 and 10 of the settings, in case of exceeding one from signals c. the outputs of these sensors 7 and 8 of the current level specified by the setting in blocks 9 or 10, at the output of one (or two) threshold element in these blocks, a signal appears that is fed to one of the inputs of the element OR II. From the output of the element OR 11, the signal goes to the second input of the element And 6.

When the electric motor 19 is connected to the mains in the starting current mode, signals appear at the outputs of the current sensors 7 and 8, which can exceed the settings in blocks 9 and 10. At the same time, the signal at the output of the current sensor 2 changes, which causes the appearance of the signal at the output differentiation unit 3 and, therefore, at the output of nullorgan 4 (the role of which in this case is to convert the analog signal from the output of differentiation unit 3 into a discrete signal, the amplitude of which is sufficient for supplying to the logic elements Devices). The signal from the output of nullorgan 4 is fed to the input of the element NOT 5, which causes the disappearance of the signal from its output.

Thus, at the second input of the And 6 element, a signal is present, while at its first input there is no signal. Therefore, the signal at the output of the And 6 element does not appear,. L switching off the feeder with the electric motor 19 does not occur.

There is no signal at the output of the And 6 element even if the signals at the outputs of the current sensors 7 and 8 do not exceed the level of the settings in blocks 9 and 10, since there is no signal at the second input of the And 6 element.

at once.

Using signals 2, 7 and 8 of the current, they continuously emit signals proportional to the value of the operating current and the industrial frequency currents in the phases of the network, respectively. The signal from the output of the sensor 2 operational current continuously. differentiate and compare with a given level (in this case with zero) using zero-org · ^

In the event of a short circuit in the feeder, the signal appears not only at the second input of the And 6 element, but is also present at its first input, since there is no change in the value of the operating current in the measuring circuit. There is no signal at the output of the differentiation unit 3 (and nullorgan 4), which leads to the preservation of the signal at the output of element * NOT 5.

At the same time, a signal (logical unit) is present at the third input of the And 6 element, since with a short shutdown in the feeder with an electric motor 19, the direction of the current (power) does not occur, and the polarity of the signal at the output of the phase-sensitive circuit in the phase-sensitive block 17 ensures its presence. the output of a logical unit, This leads to the fact that at the output of the element And 6 there is a signal that 15 is fed to the controlled input of the shutdown unit 14, as a result of which the feeder with the motor 19 is turned off.

Disabling other feeders does not occur. This is explained as follows. If, in the event of a short circuit in the feeder with the electric motor 19, the fifth motor connected to some other (neighboring) feeder 25 goes into the generator mode (the mode of feeding the short-circuit point in the feeder with the electric one).

^: motor · · 19), due to the fact that the device for protecting the ηth feeder 30 is absolutely identical to the device for protecting the feeder with the electric motor 19, the signal polarity changes at the output of the phase-sensitive block 17-p, which ensures the translation of a logical unit at the output of the phase-sensitive block 17-p to logical ^ zero, which goes to the third input of the And 6-p element. Therefore, at the output of the And 6-p element, no signal to turn off the shut-off block 14-p appears.

_t The trip signal does not appear on the output of the AND element 6-p and if the nth motor does not go into the generator mode in this case, 'i.e. works fine. In this case, a logical zero is present at the second input of the AND 6-p element (from the output of the 5θ OR 11-p element).

The current sensors 7 and 8 and the industrial frequency voltage sensor 16 are located at the beginning of the feeder, i.e. in the switchboard in the immediate vicinity of the shutdown unit 14.

When implementing a protection device to avoid skipping a short circuit in the absence of a pre-determined blocking of the possibility of switching on a feeder with an interphase short circuit, an additional time delay unit 20 and an element can be introduced into the device. OR 21, wherein block 20 includes serially connected time delay element 22 and threshold element 23.

The input of the time delay unit 20 is connected in this case to the output of the setting unit 9 of one of the industrial frequency current sensors, for example, sensor 8, and the output is connected to the first input of the OR gate 21, the second input of which is connected to the output of AND gate 6. The output of the logic element OR 21 is connected to the control input of the shutdown unit 14.

If the feeder is turned on with a short circuit (phase-to-phase) already occurring, the signal from the output of the specified set-point block 9 (threshold element) is input to the time delay block 20, but appears at its output only if the current exceeds the level set by the set point, will exceed the set inrush current flow time. In this case, the signal from the output of the time delay unit 20 is supplied through the OR gate 21 to the controlled input of the shutdown unit 14 (for disconnecting the feeder).

In the absence of an interphase circuit in the switchable feeder (at the moment of switching on), the indicated blocks 20 and 21 .. do not affect the operation of the protection device.

The device allows with high selectivity and speed to distinguish between short circuit modes and inrush currents, regardless of any ratio of the values of these currents, including for cases where the values of these currents are the same. .

Claims (1)

Claim A device for protecting the electric network from short circuit current, comprising a block of artificial zero point of the network and a block of artificial zero point of the feeder, the first conclusions Ί of which are intended to be connected to the three phases of the network and the feeder, respectively, the second common terminal of the artificial zero point block of the network $ is connected in series with an operating current voltage source, an operational current sensor, a differentiation unit, a zero-organ, the second input of which is connected to terminal u for connection to ground, a logical element NOT, the output of which is connected to the first input of the And element, the first and second industrial frequency current sensors, the first conclusions of each of which are designed to connect connected to the corresponding phase of the network in the immediate vicinity of the shutdown unit, and the first and 20 second setting blocks are connected to the output of the industrial frequency current sensors, respectively, the outputs of the latter are connected to the inputs of the OR element. ', a filter plug on the industrial frequency of the network, one output of which is connected to the second common terminal of the feeder artificial zero point block, and the other terminal to the second terminal of the operational current sensor, an industrial frequency voltage sensor, two inputs of which are designed to connect to two phases a feeder with industrial frequency current sensors, and the output is to the first input of a phase-sensitive block, the second input of which is connected to the output of one of the industrial frequency current sensors, characterized in that, in order to increase the selectivity of protection of power systems with powerful electric motors with metal short circuits near distribution boards, the second input of the AND element is connected to the output of the OR element, and the third input is to the output of the phase-sensitive block, the output of the And element is connected to the -controlled input of the open unit so me.