RU2120167C1 - Metalclad switchgear cubicle disconnecting device - Google Patents

Abstract

FIELD: relay protection of electrical equipment. SUBSTANCE: device has light conductor, photoelectronic converter, AND circuit, gate pulse shaping circuit, current- ratio log taking unit, signal divider of n- amplitude pulse selectors, and n final elements, where n is number of cubicles under check. Each end of light conductor is connected to input of its respective photoelectronic converter whose outputs are connected to first and second inputs of AND circuit and to first and second inputs of current-ratio log taking unit. Output of AND circuit is connected through gate pulse shaping unit to third input of current-ratio log taking unit whose output is connected to signal divider. Each of n-outputs of signal divider is connected through respective pulse amplitude selector to input of respective final element. EFFECT: reduced probability of false operation. 1 dwg

Description

 The invention relates to systems of relay protection of electrical equipment and can be used to send a signal for emergency shutdown of the switchgear cubicle when an electric arc short circuit occurs in it.

 When developing emergency protection systems for electrical distribution equipment, in particular switchgear, the task arises of disconnecting a separate switchgear cell without disconnecting the switchgear as a whole when an electric arc occurs in this cell. The device for switching off the switchgear must cover all its cells, have high speed and not respond to electromagnetic interference.

 A device for arc protection UDZ-1 [1], consisting of a fiber, a photodetector, a comparator and an executive body. The optical fiber is laid in places of the possible occurrence of an electric arc and is connected to a photodetector connected to a non-inverting input of the comparator, the load of which is the actuator that disconnects the switchgear. The device operates as follows. When an electric arc occurs at the fiber, the insulation layer burns or burns out. Through the light-conducting channel, light enters the photodetector, where it is converted into an electrical analog, which is compared on a comparator with a given voltage level, the excess of which indicates the appearance of an electric arc. In this case, the signal from the comparator triggers the actuator, which disables the switchgear as a whole. This device allows you to cover multiple cells by laying the fiber in these cells. However, this device does not allow to determine the location of the arc and therefore disables the switchgear as a whole.

 The closest technical solution to the proposed one is a device [2] for disconnecting a switchgear cell containing a fiber, the first and second photoelectronic converters (photoelectric converters), the inputs of which are connected by the fiber at their ends, and the outputs of which are connected respectively to the first and second inputs of the current ratio logarithm unit (BLOT), and in parallel to the first and second inputs of the OR circuit. The outputs of the BLOT and OR circuits are respectively connected to the first input of the ADC and to the second input of the microprocessor. The first output of the microprocessor is connected to the second input of the ADC. The remaining outputs of the microprocessor are connected to the corresponding inputs of the actuators (IO). The principle of operation of the device is that light signals from two ends of the fiber are recorded in the device, the distance from the place of the electric arc to the first PEC along the fiber is determined by logarithm of the ratio of the currents from the PEC outputs, and knowing the location of the fiber in the switchgear cells, determine the cell in which there was an electric arc, and they turn it off without disconnecting the switchgear as a whole. When an electric arc occurs simultaneously in two or more cells, all the switchgear is switched off.

The disadvantage of the prototype is the increased likelihood of a false positive device. The main source of false positives in the device are solar cell noises. Since the first and second photomultipliers are included in the device according to the OR scheme, the probability of false operation of the device P will be equal to the sum of the probabilities of the following events:
- the first FEP falsely works, the second FEP falsely does not work;
- the first FEP falsely does not work, the second FEP falsely works;
- the first PEC will falsely work, the second PEC will falsely work.

Assuming that the first and second FEZ are the same, the probability of the first event is determined by the formula for determining the probabilities of independent events
P1 = p • (1-p),
where p is the probability of the event when the first PEC falsely triggers;
(1-p) - the probability of the event when the second solar cell falsely does not work.

Exactly the same formula will be for the second event, which follows from the above assumption that the first and second solar cells are identical
P2 = (1-p) • p
The probability of a third event using the same formula for the probability of two independent events
P3 = p • p = p ²
Then the sum of the probabilities of these three events can be written as
P = P1 + P2 + P3 = 2 • p + p ² (1)
The probability of false triggering of any of the two PECs is p = 10 ^-9 [3].

Then the probability of a false response of the device is P = 2 • 10 ^-9 .

 The technical result provided by the claimed invention is to reduce the likelihood of a false response of the device.

 The technical result is achieved by the fact that a device for disconnecting a cell of a complex switchgear containing a fiber, first and second photoelectric converters, the inputs of which are connected by the fiber at their ends, and the outputs of which are connected respectively to the first and second inputs of the unit of the logarithm of the ratio of currents, and n Executive bodies , where n is the number of monitored cells, additionally contains an And circuit, a block for generating strobe pulses, a signal divider, and n amplitude impulse selectors Ls, and the first and second inputs of the And circuit are connected respectively to the outputs of the first and second photoelectronic converters, and the output through the gate pulse generating unit is connected to the third input of the current ratio logarithm unit, the output of which is connected to the input of the signal divider, each of n outputs of which is connected through the corresponding amplitude pulse selector to the input of the corresponding actuator.

 The block diagram of the device shown in the drawing.

 A device for disconnecting a switchgear cell contains a fiber 1, two photoelectronic converters (PEC) 2 and 3, circuit I 4, a block for generating strobe pulses (BFSI) 5, a block for the logarithm of the ratio of currents (BLOT) 6, a signal divider (DS) 7, n amplitude pulse selectors (ASI) 8, and n executive bodies (IO) 9, where n is the number of monitored cells. Each end of the optical fiber 1 is connected to the input of its photomultiplier, the outputs of which are connected respectively to the first and second inputs of the AND 4 and BLOT 6 circuit. The output of the And 4 circuit through BFSI 5 is connected to the third BLOT 6 input, and the BLOT 6 output is connected to the DS 7 input, having n outputs, each output of the DS 7 through the corresponding ASI 8 is connected to the input of the corresponding IO 9.

 In the claimed device, the light guide 1 is an irregular fiber optic bundle, made according to the drawing 5AC503582 JSC "Lytkarinsky Optical Glass Plant". As photomultiplier tubes 1 and 2, photodiodes FD263 are used. Scheme I 4 is implemented on the basis of the K521CA3 chip. BFSI 5 is implemented on the basis of the K564TM2 chip. BLOT 6 is implemented on the basis of K140UD7, K140UD17, K140UK20 microcircuits. DS 7 is implemented on the basis of K301MP7, K308MP12 chips. ASI 8 is implemented on the basis of the K521CA3 chip. As IO 9, the REN-33 relay is used.

 The proposed device operates as follows.

 The occurrence and burning of an electric arc in a switchgear cell is accompanied by intense emission of light that enters the lateral surface of fiber 1 and excites a light signal in it that passes through the fiber to PECs 2 and 3, where it is converted into electrical analogues. Electrical signals are fed to the first and second inputs of circuit I 4 and BLOT 6. When the electrical signals coincide at the inputs of circuit I 4, a signal is generated at its output, which is fed to BFSI 5. Based on this signal, BFSI 5 generates a strobe pulse of a given amplitude at its output and duration, which is supplied to the third input of BLOT 6. By this gating pulse at the output of BLOT 6, a pulse signal is formed with an amplitude linearly dependent on the logarithm of the ratio of the instantaneous values of the signals at the outputs of the solar cells 2 and 3, and the duration is th duration of the gating pulse, which is uniquely associated with the position of the cell. Note that before the arrival of the gating pulse at the output of BLOT 6, a predetermined constant level is maintained that exceeds the largest possible amplitude of the signal generated as a result of the electric arc. The pulse signal from the output of BLOT 6 is fed to the input of DS 7, where it is divided into n signals (n is the number of monitored cells), each of which is fed to the input of the corresponding ASI 8. In ASI 8, the signal amplitude is compared with the specified upper and lower levels, which are determined the location of the switchgear cells. If the amplitude of the signal lies between these levels, ASI 8 gives a signal to the input of the corresponding IO 9, by which it disconnects this cell.

 The principle of operation of the proposed device is based on the dependence of the amplitude of the signal at the output of BLOT 6 on the distances between the flash of light and the photomultiplier 3. Knowing this distance with a known fiber path, you can determine the cell where the arc occurred. This can be confirmed by the following.

The currents i1 and i2 arising in the solar cells 2 and 3 are determined by the formulas
i1 = e • S • F • l • 9 ^{-0.1a (Lx)} (2)
i2 = e • S • f • l • 9 ^0.1ax (3)
where e is the conversion coefficient of the light of an electric arc into the light power induced in the fiber;
S is the steepness of the conversion of light power to current in the photomultiplier;
F is the illumination of the fiber created by light from an electric arc;
l is the fiber length per cell;
a is the attenuation coefficient of the light power in the fiber;
L is the length of the fiber;
X is the distance from the photomultiplier 3 to the cell where the electric arc occurred.

BLOT 6 results in a mathematical operation of logarithm of the ratio of currents i1 and i2 from the outputs of the photocell 2 and 3
U _O = R • lg (i2 / i1 ) + U _QS
where U _o - voltage at the output of block 4;
U _smo - constants determined by the specific execution of BLOT 6.

Representing (2) and (3) in (4) and carrying out the necessary mathematical transformations, we obtain the function U _o = f (x), depending on the coordinate x
U _out = 0.1 • a • R • (L-2x) + U _cm . (4)
The lower E1 and upper E2 levels in ASI 8 can be set for the k-th cell in the form
E1 = 0.1 • a • R • (L-2 • x1) + U _cmo (5)
E2 = 0.1 • a • R • (L-2 • x2) + U _cmo (6)
where the fiber segment [x2, x1] lies in the kth cell.

False triggering of the proposed device will occur when PECs 2, 3 are falsely triggered, which follows the logic of operation of circuit I 4. Therefore, the probability of a false triggering of the device can be determined by the formula for the probability of two independent events - false triggering of PEC 2 and false triggering of PEC 4:
P '= p ² (7)
When p = 10 ^-9 as in the prototype, the probability of false positives is P '= 10 ^-18 , which is approximately 0.5 • 10 ⁹ times less than that of the prototype.

Thus, the technical result of using the inventive device to disconnect the switchgear cell in comparison with the prototype is to reduce the likelihood of false alarms by 0.5 • 10 ⁹ times.

Claims (1)

 A device for disconnecting a cell of a complete switchgear containing a fiber, the first and second photoelectronic converters, to the inputs of which the fiber is connected at its ends, and the outputs of which are connected respectively to the first and second inputs of the current ratio logarithm unit, and n actuators, where n is the number of monitored cells, characterized in that it further comprises an AND circuit, a gate pulse generation unit, a signal divider and n amplitude pulse selectors, the first the second and second inputs of the And circuit are connected respectively to the outputs of the first and second photoconverters, and the output through the gate pulse generation unit is connected to the third input of the current ratio logarithm unit, the output of which is connected to the input of the signal divider, each of n outputs of which is connected through the corresponding amplitude pulse selector to the entrance of the relevant executive body.