SU666610A1 - Starting device for automatic cutting-in of standby power supply of consumers - Google Patents

Description

(54) STARTING BODY FOR AUTOMOBILE INPUT OF BACKUP POWER CONSUMERS

one

The invention relates to emergency control of power systems and, in particular, can be applied at substations of consumers with a motor load and redundant power sources.

Devices are known for starting an automatic input reserve body containing operating and reserve voltage control bodies and actuators, for example, a relay with a response delay}. These devices are simple in design, however, they have a significant slowdown in the operation at substations with a motor load, when during a loss of power from a working source

inertia rotating engines. they generate long-lasting voltage.

The closest solution to the technical problem is a trigger body for automatic input of backup power, containing a block of control of the angle of divergence of the voltage vectors, triggered by the flow of active power from the consumer tires to the source, a coincidence circuit and execution units 2.

This triggering organ is complicated due to the presence of several phase-sensitive blocks and current sensors in the control unit, especially in schemes with two-sided operation of automatic input reserve, it allows for power failure when the active power is not transmitted to the line and is spent on its own load

0 substations, as well as in the presence of other consumers on the supply line with a more powerful motor load, which feeds at a joint run of the engines controlled

5 substation These drawbacks are determined by the use of an active power direction control unit.

The purpose of the present invention

0 is a simplification and enhancement of reliability.

The goal is achieved by the fact that the trigger body for automatic input of backup power

5 consumers with motor load, containing a block of control of the angle of divergence of the voltage vector, the inputs of which are intended to be connected to the voltage of two

power supply units, and executive units, are supplemented with two units with a given output signal duration, and the vector divergence control unit is equipped with an element of simultaneous fixation of the phase sequence, the output of each block with a given output signal duration is connected to the inhibitory input of another unit with a given output sirnal duration and the corresponding block, and the developing inputs of the blocks with a given output signal duration are connected to the outputs of the block of control of the angle of divergence of the vectors for example zheny.

Also, by the fact that the starting angle control unit of the vector with the element of simultaneous fixation of the phase order contains two synchronization control relays for connecting two power sources to the voltage, the closing contacts of one synchronization control relay and the opening contacts of the other relay are connected in series and connected to the resolution inputs of the blocks with a given duration of the output signal.

Also by the fact that the unit for controlling the divergence of the vectors with the element of simultaneous fixation of the phase sequence contains two thyristors, and the control circuit of the ceycristor is designed to switch on the voltage of one of the sources, the power circuit of each thyristor is intended to be connected to an antiphase other source of nutrition.

Figure 1 shows the structural block diagram of the starting body; in fig. 2 shows an example of the implementation of a unit for monitoring the angle of divergence of a vector with an element of simultaneous fixing of the phase order, performed on two synchronization control relays; FIG. 3 shows an example of the implementation of a unit for monitoring the angle between the vectors and an element of simultaneous fixation of the order of the following phases, performed on thyristors.

A motor-loaded consumer has two sections fed separately from two sources through input switches 1 and 2. The sections are connected by a switch 3. The inputs of the block of control of the angle of divergence of the voltage vector 4 provide an element of simultaneous fixation of the phase sequence 5 and are connected to voltage transformers 6 and 7 of the first second sections, and the outputs are connected to the permissive inputs of the blocks with a given duration of the output signal 8 and 9, and the output of each block with a given duration of the output signal is connected with the prohibition conductive

the input of another block with a given duration of the output signal and with executive blocks 10 and 11.

When the power supply of the first section is lost, the motors run out, the phase difference of the voltage A and B of the sections reaches the value specified within 0-180 and has a corresponding sign. Unit 4 supplies power to unit 8, which acts to disconnect input 1 and at the same time prohibits operation of unit 9. When the further overrun of the motors, the phase ordering of the voltages varies. The device is in such a state until the end of the after-run of the engines (the disappearance of the voltage on the first section) or switching to the reserve source, after which it returns to the initial state.

When power is lost, the total emf of run-out motors continuously changes in phase with respect to the backup voltage, and at the initial moment of overrun, within the range of the phase difference 0-180, it lags behind the voltage of the backup source; Further, the order of alternation of voltage phases changes periodically. The applied control unit determines the power loss by the magnitude of the phase difference and the de-energized section by the sign of the phase difference (phase lag), forms a signal at the corresponding output and includes one block with a given output pulse duration ensuring reliable operation of the actuator and switching of switching devices. A signal from the output of the included time element to prohibit the switching on of another element is necessary, since the switching on signal appears alternately at each of the outputs of the control unit before the end of coasting or switching to the backup source.

Figure 2 shows an example of the implementation of a block of control of the angle of divergence of vectors. It contains a synchronism control relay 12 of the PH-55/160 type, the winding 100 V of which is connected to the voltage of the first section of busbars, and the winding 60 V connected to the voltage of the second section, and the synchronization control relay 13, the winding of 100 V of which is connected to the voltage the second section of busbars, and the 60 V winding is connected to the voltage of the first section. Output relays 14 and 15 of magnitude as follows: relay 14 - through the closing contacts of relay 12, opening the discon- the cycles of the relay 13 and the disconnecting contacts of the relay 15; relay 15 — through the closing contacts of the relay 13, dissolving the contacts of the relay 12 and disconnecting the contacts of relay 14. As relays 14 and 15, intermediate relays were used with a delay to drop. Relay 14 acts to disconnect input first

section, relay 15 acts to disable the input of the second section. Relay 12 and 13 set to 40 (0.68 radians). The initial phase shift between the monitored voltages is 30 (0.52 radians), with the voltage vector of the first section being ahead of the relay 12 the second section voltage vector, and vice versa 13. In the normal voltage mode, both sections are synchronous, the relay setting is greater than the initial phase shift, the relays 12,13 and 14 are in an unworked state.

When the first section is extinguished and the engines run out on it, the vector of stresses of this section rotate with a lower angular velocity and lag behind the stress vectors of the healthy section. Then, when the angle between the vectors of the compared voltages increases by 10 (0.17 radians), relay 12 is triggered, and if the angle increases by 70 (1.19 radians), relay 13 will work, that is, given the initial phase shift and the settings, relay 13 will work later relay 12 to 60 (1.04 radians), relay 12 will energize relay 14 and open its contact in the power supply circuit of relay 15. Relay 14 will impulse to disconnect the input of the first section and at the same time block the activation of output relay 15, therefore, although when the vectors diverge by the angle of 290 ° (5.04 radian) there comes a moment when, when triggered m relay 13 disappears relay 12, the relay 15 is not included. Relay 12 energizes relay 14 several times, the number of actuations is determined by the number of voltage beats, due to which the device is in the activated state for the entire run-up time of the motors and returns to its initial state when the voltage on the quenched section completely disappears (relay 12 and 13 are attracted), or when power is restored to both sections (relays 12 and 13 in a dropped position). The device operates at the same time as the second section is canceled. To increase reliability, a blocking organ can be introduced into the device when voltage circuits malfunction, for example, type КРБ-13 with a single-phase ground fault action. Instead of intermediate relays with a slowdown in the fallout can be used on-off relays.

If a capacitor 5.0 µf and an additional resistance of 500 ohms are connected in series with the winding 60 in the synchronism control relay and applied to the relay of the same linear voltage of the reserved sections, an angle of about 30 (0.52 radians) forms between the voltages on the relay windings. The operation of the device is similar to that described above, but the reliability increases because the magnitude and phase of the linear voltage are not affected by single-phase short-circuits in the high-voltage network, and if one linear voltage fails, both synchronization control relays operate simultaneously and with their opening contacts .

Fig. 3 shows an example of a unit controlling the angle of divergence of the vectors with an element of simultaneous fixation of the order of the following phases, performed on the thyristors.

The triggering organ contains thyristors 16,17. The power circuit of the thyristor 16 through the relay with a delay for the drop-off 18 and the protective diode 19 is turned on for the voltage of the first section, and the control circuit through the protective diode 20 and the isolation transformer 21

0 is turned on for the voltage of the second section. The power circuit of the thyristor 17 is connected through a relay with a delay to the drop-off 22 and the protective diode 23 to the voltage of the second section, and the control circuit through the protective diode 24 and the isolation transformer 25 is connected to the voltage of the first section. Reserved voltages are taken in antiphase, primary and secondary windings

0 isolation transformers are switched in phase. The closing contact of the relay 18-1 is connected to the input section disconnecting unit of the second section 26, the opening contact of the relay 18-2 is inserted into

5 the thyristor control circuit 17. The closing contact of the relay 22-1 is connected to the input section disconnecting unit of the first section 27, the trip contact of the relay 22-2 is inserted into the control circuit of the transmitter 16 (blocking circuit). In the normal mode, the positive half waves entering the power and control circuits of the thyristors do not coincide in time, the thyristors are turned off.

With the disappearance of power first

The 5 sections of the electric motors connected to it run out, generating a voltage with decreasing frequency, as a result of which the thyristors 16, 17 begin to flow

 time positive half-wave voltage. Let the thyristor turn on at approximately equal in percentage terms to the nominal value of the power voltages

5 and the control circuit. After switching on the power voltage of the thyristor. 17 increases, despite the decrease in the control voltage, which causes its actuator 22 to operate, and

the voltage of the thyristor 16 decreases until it is turned off, despite the increase in control voltage, while the executive body 18

Claims (2)

5 does not work. In the process of further deceleration of the motors of the first section, conditions are created for the actuator 18 to operate, however, since the contact of the relay 22-2 is opened in the control circuit of the thyristor 16, this does not occur. The closure of contact 22-1, which excites the input section of the first section 27, disconnects the consumer to a backup source. If one voltage disappears, the false operation of the device is automatically excluded according to the principle of operation of the thyristors. Upon the termination of the engines overrun on the sections or after a successful switch to the backup source, the device returns to its initial state. In order for the device to work properly, the following conditions must be met: the thyristor switch-on voltage is greater than the voltage of its holding in the on state at a given load resistance, but less than the actuator actuation voltage. As a rule, these conditions are easily provided with. Locking chains can be performed in many ways. With comparative simplicity, the start-up body has a much greater speed in comparison with the existing start-up bodies of automatic input reserve with control elements of redundant voltages and allows the regreg to divide the loss of operating power without reducing the magnitude of the voltage on the section, while changing the phase difference of the voltages l rad. The device can be made on relay-contactor, semi-conductor or magnetic logic elements and does not require significant expenses for its manufacture. Claim 1. Starting body for automatic input of backup power supply to customers with a motor load containing a block of control of the angle of divergence of voltage vectors, the input of which is intended to be connected to either the voltage of two power sources 8, and actuating blocks in order to simplify and increase reliability, two blocks with a given output signal duration are additionally introduced into it, and the vector divergence control block is equipped with an element of simultaneous fixation of the sequence phases, the output of each block of a predetermined duration of the output signal is connected to the inhibit input of another block with the task duration of the output signal and a corresponding actuating unit, and razrv11ayu | que inputs of blocks with a predetermined duration of the output signal are connected to the outputs of the angle of divergence control vectors stresses. 2. Starting body according to claim 1. characterized in that the unit of control of the angle of divergence of the vectors with the element of simultaneous fixation of the phase sequence contains two synchronization control relays designed to connect two power sources to the voltage, the closing contacts of one synchronization control relay and the opening contacts of the other relay are connected in series and connected to allowing inputs of blocks with a given duration of the output signal. 3. A triggering device for PL, which is characterized in that the unit controlling the angle of divergence of the vectors with the element of simultaneous fixation of the order of the following phases contains two thyristors, and the control circuit and circuit of each thyristor is intended for switching on the voltage (one of the sources, The circuit of each thyristor is intended to be connected to the out-of-phase voltage of a different power source.Information sources taken into account during the examination 1. M. Levchenko, M. Khomkov. Automatic switch-on, M., Energie, 1971, p.11. 2. USSR author's certificate No. 493858, cl. H 02 D 9/06. 1973. l I ev iPut. one l let FIG. I