SU1583879A2 - Electric power plant - Google Patents

Abstract

The invention relates to electrical engineering, in particular, to the assessment of the insulation status of electrical installations containing direct current electrical networks. The purpose of the invention is to reduce the transition time of recharging network capacitances after changing the value of the insulation resistance and capacitance by optimizing the operation mode. The reduction in transient time is achieved by connecting capacitors to the buses and discharging them to resistors. The connection frequency control is carried out using a transient rate change control unit and a transient boost control unit, which perform the optimum mode of this process. The electrical installation contains a source of direct current energy 1, loads 2 and 3, connecting buses 4, switch 5, feeder 6, unit 7 for monitoring and measuring parameters, unit 7 forcing the transient process, unit 9 for controlling the transient process, unit 10 for fixing the presence of a transient process , block 11 controls the change in the rate of the transition process. 2 hp f-ly, 1 ill.

Description

The invention relates to electrical engineering, in particular to questions of assessing the state of insulation of electrical installations containing electrical direct current networks, and is an improvement of the invention by ed. St. No. 1499280.

The purpose of the invention is to reduce the time of the transient process of recharging the network capacitance after changing the value of the insulation resistance and capacitance by optimizing the operating mode.

The drawing shows a functional diagram of the electrical installation.

The circuit contains a source of DC energy 1, loads 2 and 3, connecting wires (bus) 4, p. switch 5, feeder 6, control unit 7 and measuring parameters, for example, insulation resistance and network capacitance, transient boost unit 8, transient boost control unit 9, 25 transient presence detection unit 10, transient rate change control unit 11.

The energy source 1 by connecting wires 4 is connected · to load 2 and through switch '5 and feeder 6 to load 3. The first input of the monitoring and measuring unit 7 is connected to one of the connecting wires 4, its second input is connected to ground. The first and second inputs of the transient boost unit 35 are connected respectively to the first and second buses 4 of the monitored network, the third input of this unit is connected to ground, the fourth and fifth (managed) inputs of the 8 unit are connected respectively to the first and second outputs of the transient boost control unit 9 and the first and second outputs of the transient boost block 8 are connected to the first and second inputs of block 11. monitoring changes in the speed of the transient, the first and second outputs of which are connected to the first and second 5θ inputs of the control unit 9, respectively. The third and fourth inputs of the control unit 9 through the block 10 for detecting the presence of a transient are connected to one of the buses 4, for example, 55 of the first controlled network. Block 8 forcing the transient contains on-off switches and 13, capacitors 14 and 15, low-resistance resistors 16 and 17 and current sensors 18 and 19. The first input of the boost unit 8 is connected to the first output of the switch 12, the second output of which through a low-impedance resistor 16 is connected to the third (earth) input of the entire boost unit 8. The first input of the switch 12 through the series-connected current sensor 18 and the capacitor 14 is also connected to the third (ground) input of the boost unit 8, which is connected through the low-resistance resistor 17 to the second output of the switch 13, and through the series-connected capacitor 15 and the current sensor 19 to the first the input of the switch 13. The second (controlled) inputs of the switches 12 and 13 are connected to the fourth and fifth inputs of the boost unit 8.

The transient boost control unit 9 contains memory elements, for example, static triggers 20 and 21, a single vibrator 22, delay elements 23 and 24, logic elements I 25 and 26, analog keys 27 and 28, a clock generator 29, an OR logic element 30.

The first input of the control unit 9 through the delay element 23 is connected to the first input of the storage element (static “trigger”) 20 and directly to the first input of the logic element OR 30, the second input of which is connected to the second input of the control unit 9 directly and through the delay element 24 with the first input memory element (static trigger) 21. The output of the logical element OR 30 through a single vibrator 22 is connected to the second (managed) inputs of the analog keys 27 and 28, the first inputs of which are connected to the outputs of the logical electronic elements And 25 and 26, respectively, outputs - with the second inputs of the storage elements 20 and 21, respectively. The first inputs of the logical elements And 25 and 26 are connected to the output of the generator 29 clock pulses, and the second inputs to the third and fourth inputs of the control unit 9,

Block 10 for detecting the presence of a transient process consists of a differentiating block 31 and bipolar threshold elements (signal conditioners) 32 and 33 connected to its output. The input of block 10 is connected to the input of the differentiating block 31, and the outputs of the threshold elements 32 $ and 33 are outputs of the entire block ₍ 10.

The transient rate change control unit 11 comprises differentiating units 34-37 and shit elements 38 and 39. The first input of the control unit 11 is connected through series-connected differentiating units 34 and 36 and the threshold element 38 to the first output of the control unit J5 11. The second input of the control unit 11 through series-connected differentiating units 35 and 37 and the threshold element 39 is connected to the second output of the control unit 11. 20 In addition, the circuit contains insulation resistances of the poles (buses) of the monitored network R _{/ f} and R _xz , the capacitance of the poles (buses) of the network C _{/ (} and C _Xi , co.

the insulation resistance of the poles of the feeder R IFg and the capacitance of the poles of the feeder SF <And With φ -2 ·

Electrical installation works as follows.

After closing the switch 5 (connecting to the working DC network of the feeder 6 with the load 2), a transient process of recharging the network capacitors relative to the ground occurs in the network. At one of the outputs (depending on the increase or decrease in potential on the bus to which the block 10 is connected, with respect to the ground) of the block 10 for detecting the presence of a transient, a high level signal will appear Logical 1, for example, when the potential increases, the first output, as follows: the threshold element 32 responds to a signal of positive polarity: which will go to the third input of the transient boost control unit 9 (to the second input

(. logical element AND 25). Because ; the analog key 27 is normally closed, the incoming signal from the output of the generator 29, passing through the logical element And 25 and the analog key 27, is fed to the static trigger 20, moving it from position 1 to position 2. The signal from the output of this trigger 20 will come through the first output control unit 9 to the fourth input of re-forcing unit 8 _; . process (to the second input of the switch 12). This leads to the fact that the first input of the switch 12 is disconnected from its second output and connected to the first output of this switch. As a result, the capacitor 14 and the current sensor 18 will be connected in parallel with the total insulation resistance R _x , h PF, and the total network capacity C _X1 and C.

Thus, a low-impedance overpower channel is created for capacitance poles of the network. Information about the magnitude of the current of this overcharged charge from the output of the current sensor 18 begins to flow through the first output of block 8 to the first input of block I I monitoring the change in the speed of the transient process. The control of this parameter is due to the fact that during the forced recharging of the network capacitors, the boost capacitor 14 is also charged and the resistance value of the forced recharge channel begins to increase, i.e. its effectiveness begins to decline. To avoid this, with the help of block II, the acceleration (namely, deceleration) of the magnitude of the currents through the capacitor 14 is constantly monitored. At the moment when the specified acceleration (namely, deceleration) becomes larger than the specified allowable threshold, determined by the sensitivity threshold of the threshold element 38, at the output of the threshold element 38 in the IJ block, a signal will appear that will be transmitted to the first input of the control unit 9. This signal through the delay element 23 will go to the first input of the trigger 20, and through the logic element OR30 - to the input of the single-shot 22, translating it into an unstable state.

I

The translation of the single vibrator 22 into an unstable state will cause a disconnect. the analog key 27, which guarantees the absence of any signals at the second input of the trigger 20 by the time the signal arrives at the first input of this trigger 20 through the delay element 23 from the threshold element 38. Therefore, the trigger 20 is transferred by the indicated signal from position 2 to position I, which causes -– the disappearance of a high-level potential - Logical ”1 at its output and ensures the return of switch 12 in block 8 to its original position when the first input of this switch (and therefore the capacitor and current sensor) is disconnected from its first output and connects to its second output. Therefore, the capacitor 14 is (through the current sensor 18) closed to the low-resistance resistor 16, which provides an accelerated discharge of the capacitor 14 during the time the single-shot 22 is in an unstable state. After the return of the one-shot 22 to a stable (initial) state, the analog switch 27 closes, and if the transient process of recharging the network capacities continues, then the next pulse from the clock generator 29 passes through the logic element, And 25 (at the second input of which continues to be present - the signal from the first the output of the unit 10 for detecting the presence of a transient process) and the analog key 27 to the second input of the trigger 20, translating it again to the 2 ”position. The next step of forced recharging of network capacities begins. ’

The described steps are repeated until a high-level signal Logic 1 disappears at the first output of block 10 ‘for detecting the presence of the overwind process, which carries information about the completion of the transient process.

In this case, the clock pulses from the generator 29 clock pulses will cease to pass through the logical element And 25, and the steps (cycles) of creating channels of accelerated recharge will stop.

In the event that after switching in the network, the potential on the bus to which the transient fixation block 10 is connected starts to decrease, a high-level signal Logic 1 will appear at the output of the threshold element 33 that responds to a signal of negative polarity, i.e. at the second output of unit 10. This signal will be transmitted to the fourth input of control unit 9 (to the second input of AND gate 26), as a result of which a clock pulse from generator 29 will arrive at the first input of analog key 28 and from its output to the second input of static trigger

21, translating it to position 2. The signal from the output of the trigger 21 will come through the second output of the control unit 9 to the fifth input of the transient forcing unit 8 (to the second input of the switch 13). This will cause the resistance R _x2 and R to be parallelized by the boost capacitor 15th sensor 19 current. The boost current through the capacitor 15 is measured by a current sensor 19, the nature of the output voltage change (proportional to the measured current) is controlled using differentiating blocks 35 and 37 located in block 11 and the threshold element 39. When the slowdown of the boost current through the capacitor 15 becomes greater than the specified allowable threshold determined by the sensitivity threshold of the threshold element 39, a signal will appear at its output, which will be fed to the second input of the control unit 9. This signal through the delay element 24 will go to the first input of the trigger 21, and through the logic element OR 30 to the input of the single-shot

22, translating it into an unstable state.

The translation of the one-shot 22 into an unstable state will cause the analog switch 28 to open, which ensures that there are no signals at the second input of the trigger 21 by the time the signal arrives at the first input of the trigger through the delay element 24 from the threshold element 39. Therefore, the trigger 21 is transferred by the indicated signal from position 2 to position 1, which causes the disappearance at its output of a high level potential of Logic 1 and ensures the return of the switch 13 in block 8 to its original position (the first input of this switch is turned off m and its first output connected to its second output). Therefore, the capacitor 15 is through the current sensor 19 closed to a low resistance resistor

17, which provides an accelerated discharge of the capacitor 15 during the stay of the single vibrator 22 in an unstable state.

After the return of the one-shot to a stable state, the analog switch 28 closes, and if the transient process of recharging the network capacities continues, then the next

1583879 'the pulse from the generator 29 clock pulses passes through the logical element And 26 (at the second input of which the signal continues to be present.' Signal from the second output of the transient fixation block 10) and the analog key 28 to the second input of the trigger 21, translating it again to the position '' 2 ''. The next | Step of forced recharging of network capacities begins.

The described steps are repeated until a high-level signal Logic 1 disappears at the second output of the central heating unit of the presence of the transient process, which carries information about the completion of the transient process. In this case, the clock pulses from the generator 29 will no longer pass through the AND 26 logic element, steps (cycles) the creation of accelerated recharge channels will stop.

Claims (3)

Claim 1. Electrical installation by auto No. 1499280, characterized in that, with. the purpose of reducing the time of the transient recharge process _; capacities of the network after changing the value of insulation resistance and capacitance, a transient speed change control unit, a transient boost control unit and first and second current sensors are additionally introduced into it, the first input of the first current sensor connected to the first input of the first on / off switch, the second input the first current sensor is connected to the first output of the first capacitor, and the output of the first current sensor is connected to the first input of the transient rate change control unit, per the second input of the second current sensor is connected to the first input of the second on-off switch, the second input of the second current sensor is connected to the first output of the second capacitor, and the output of the second, current sensor is connected to the second input of the transient rate control unit, the first and second outputs which are connected with the first and second inputs of the control unit forcing the transient process. 2. The electrical installation according to claim 1, characterized in that the control unit for changing the speed of the transition process is made of four differentiating units and two threshold elements, the first input of the entire control unit through series-connected first and second differentiating units and the first threshold element connected to the first by the output of this block, the second input of the entire block through the third and fourth differentiating blocks and the second threshold element connected in series is connected to the second output of the entire control block. 3. The electrical installation according to claim 1, characterized in that the transient boost control unit 'is made of two storage elements, for example, static triggers, a single-shot, two delay elements, two AND logic elements, a clock generator, two analog keys and an OR logic element, the first input of the control unit through the first delay element connected to the first input of the first storage element, for example, the first static trigger, the second input of which is connected to the output of the first of the analog key, the first input of the second storage element, for example, a static trigger, is connected through the second delay element to the second input of the entire block and the second input of the OR logical element, the first input of which is connected to the first input of the entire block, and the output through the one-shot is connected to the second (controlled) the inputs of the first and second analog keys, the first input of the second analog key is connected to the output of the second logical element And, the first inputs of the logical elements And are connected to the output of the clock pulse generator hs, and their second inputs are connected to the third and fourth inputs of the entire control unit, the outputs of the first and second storage elements, for example, static triggers, are connected respectively to the first and second outputs of the entire control unit.