RU2168826C1 - Arc-protection device for disconnecting metalclad switchgear cubicle - Google Patents

Abstract

FIELD: open-arc short-circuit protection of metal clad switchgear cubicles . SUBSTANCE: device has two light conductors of different attenuation factors assembled into common cable , two photoelectric converters, electronic signal-processing unit, and n final elements, where n is number of cubicles under protection. Each light conductor is optically coupled on one end with input of its respective photoelectric converter; outputs of photoelectric converters are connected to respective inputs of electronic signal-processing unit. Each of its n outputs is connected to respective final element; attenuation factors of light conductors differ by Δα ≈ 2/L, where L is light conductor length. Electronic signal-processing unit is designed for implementing mathematical function x = 1/Δα•InI₁/I₂, where x is distance from arcing metal clad switchgear cubicle to photoelectric converters along light-conductor cables; I₁,I₂ are photoelectric output currents of photoelectric converters. EFFECT: enlarged length of metal clad switchgear internal section handled by protective device. 2 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 a short circuit occurs in it.

 When developing emergency protection systems for electrical distribution equipment, in particular switchgear, when an electric arc occurs in a separate switchgear cell, the task is to turn off this damaged cell without disconnecting the switchgear as a whole. The arc protection device must cover all the switchgear cells, register the damaged cell and signal to turn it off. Also, it should have high speed, not respond to electromagnetic interference and allow multiple operation.

 A device for arc protection [1] is known, which contains a sensing element in the form of a fiber — a fiber optic bundle with a translucent sheath, which is optically connected to the input of the photoelectronic converter, the output of which through a threshold device is connected to the actuator, which disconnects the switchgear as a whole. The light guide is laid in places of the possible occurrence of an arc in the switchgear cells. The device operates as follows. When an open electric arc arises in the switchgear cell, the light from it, incident on the side surface of the fiber, passes through its translucent sheath and is captured by the light-conducting channel of the fiber, through which it is transmitted to the photoelectronic converter, where it is converted into an electrical analog - a voltage jump at the output of the photoelectronic converter. The amplitude of this jump on the threshold device is compared with the response level of this device. When this level is exceeded, the threshold device generates a signal that triggers the actuation of the executive body, which disables the switchgear as a whole. This device allows you to cover several switchgear cells by laying the fiber in these cells, has sufficient speed, does not respond to electromagnetic interference due to the use of a dielectric fiber. In addition, it allows multiple operation, since the fiber is not destroyed when exposed to an arc. However, it does not allow to determine the damaged cell for its selective shutdown, and therefore shuts down the switchgear as a whole.

где x - расстояние от ячейки, где возникла электрическая дуга, до первого фотоэлектронного преобразователя вдоль световода;
L - длина световода;
α - коэффициент затухания световода;
I₁, I₂ - фототоки с первого и второго фотоэлектронных преобразователей соответственно.The closest technical solution to the proposed one is a device for disconnecting a cell of a complete switchgear [2], consisting of a fiber with a light-transmitting sheath, two photoelectronic converters, an electronic signal processing unit and n actuators, where n is equal to the number of monitored switchgear cells. The optical fiber at its ends is connected through photoelectronic converters to the inputs of the electronic signal processing unit, the outputs of which are connected to the executive bodies. As in the previous device, the light guide extends through the switchgear cells near the places of the possible occurrence of an open electric arc. The device operates as follows. When an open electric arc occurs, its light falls on the lateral surface of the fiber, is captured in its light guide channel and transmitted through it to both ends of the fiber to photoelectric converters, which convert the light coming to them into electrical signals proportional to its power - photocurrents. These photocurrents go to the inputs of the electronic signal processing unit, where they are mathematically processed according to the formula:

where x is the distance from the cell where the electric arc occurred to the first photoelectronic converter along the fiber;
L is the length of the fiber;
α is the fiber attenuation coefficient;
I ₁ , I ₂ - photocurrents from the first and second photoelectronic converters, respectively.

Knowing the geometry of the fiber optics, it is not difficult to identify a damaged cell arc. By the value of x, the electronic signal processing unit determines the number n _{k of the} cell where the arc occurred, and generates a signal at its n _k output, which is supplied to the n _k executive body, which turns off this cell. In the case when the value x does not correspond to any cell, the electronic signal processing unit generates signals to all the switchgear cells and turns it off as a whole. This device covers several switchgear cells, does not respond to electromagnetic interference, disables A only of the damaged cell without disconnecting the switchgear as a whole, allows multiple operation.

The determination of the distance x from the cell in which the arc appeared to photoelectronic converters is determined with an error. For a given maximum error | Δx | _max length of the section controlled inside the switchgear is limited, which is confirmed by the following.

где ΔI_1, ΔI₂ - среднеквадратичные значения флуктуации фототоков фотоэлектронных преобразователей. С учетом того, что относительные флуктуации фототоков ε₁ = ΔI₁/I₁, ε₂ = ΔI₂/I₂, выражение (2) можно переписать в виде:

где ε_max = max{|ε₁|,|ε₂|}.
Относительная флуктуация ε фототока, связанная только с флуктуацией светового потока, определяется по формуле (4):

где ν - энергия фотона, принимаемого фотоэлектронным преобразователем; η - квантовая эффективность фотоэлектронного преобразователя: W - шум фактор; Δ f - полоса частот, в которой регистрируется сигнал; P - световая мощность сигнала, принимаемого фотоэлектронным преобразователем, и определяемая выражением:
P=P₀exp(- α •x), (5)
где P₀ - световая мощность, захваченная световодом от световой вспышки дуги и направленная на один из фотоэлектронных преобразователей, x - расстояние от дуги до этого преобразователя вдоль световода.The absolute error Δx of determining the location of occurrence of the arc by this device can be written in the form:

where ΔI _1, ΔI ₂ are the rms fluctuations of the photocurrents of photoelectric converters. Considering that the relative fluctuations of the photocurrents ε ₁ = ΔI ₁ / I ₁ , ε ₂ = ΔI ₂ / I ₂ , expression (2) can be rewritten in the form:

where ε _max = max {| ε ₁ |, | ε ₂ |}.
The relative fluctuation ε of the photocurrent, associated only with the fluctuation of the light flux, is determined by the formula (4):

where ν is the energy of the photon received by the photoelectronic converter; η is the quantum efficiency of the photoelectronic converter: W is the noise factor; Δ f is the frequency band in which the signal is recorded; P is the light power of the signal received by the photoelectronic converter, and is determined by the expression:
P = P ₀ exp (- α • x), (5)
where P ₀ is the light power captured by the light guide from the light flash of the arc and directed to one of the photoelectronic converters, x is the distance from the arc to this converter along the light guide.

Так как фотоэлектронные преобразователи находятся рядом, оба конца световода должны быть расположены вблизи друг от друга. Поэтому длина L световода должна быть примерно в 2 раза больше длины L_конт контролируемого участка:
L=2L_конт
С учетом вышесказанного максимальная длина контролируемого участка будет равна:

Так, при α =0,07 1/м, P₀ = 1 мкВт, |Δx|_max = 0,5 м; К = 2,2587•10^-5 мкВт максимальная длина контролируемого участка будет 28,5 м, при длине световода ~57 м.The relative fluctuation ε will be maximum when the light power P of the received signal is minimal, which corresponds to a light flash acting on the far end of the fiber from the photoelectronic converter, when x = L, therefore, the maximum error | Δx | _max can be written as:

Since photoelectric converters are close by, both ends of the fiber must be located close to each other. Therefore, the length L of the fiber should be approximately 2 times greater than the length L _cont controllable area:
L = 2L _cont
Based on the foregoing, the maximum length of the controlled area will be equal to:

So, at α = 0.07 1 / m, P ₀ = 1 μW, | Δx | _max = 0.5 m; K = 2.2587 • 10 ^-5 μW, the maximum length of the controlled section will be 28.5 m, with a fiber length of ~ 57 m.

 The disadvantage of the prototype is the small length of the controlled area inside the switchgear with a significant length of the fiber.

 The technical result provided by the claimed invention is to increase the length of the controlled area inside the switchgear.

где x - расстояние от ячейки КРУ, в которой возникла дуга до фотоэлектронных преобразователей вдоль кабеля световодов: I₁, I₂ - фототоки с выходов фотоэлектронных преобразователей.The technical result is achieved by the fact that the arc protection device for disconnecting the cells of the complete switchgear containing a light guide with a light-transmitting sheath, two photoelectronic converters, an electronic signal processing unit and n actuators, where n is the number of monitored cells, the outputs of the photoelectric converters are connected to the corresponding inputs of the electronic a signal processing unit, each of the n outputs of which is connected to the corresponding executive body, additionally with contains a second fiber with a translucent sheath and a attenuation coefficient different from the attenuation coefficient of the first fiber by Δα≈2 / L, where L is the length of the optical fibers, the optical fibers are combined into a cable, each fiber is optically connected to the input of its photoelectric converter at one end, and an electronic processing unit signals made with the possibility of implementing a mathematical function:

where x is the distance from the switchgear cell in which the arc appeared to the photoelectronic converters along the optical fiber cable: I ₁ , I ₂ are the photocurrents from the outputs of the photoelectronic converters.

 In FIG. 1 shows a diagram of the device, in FIG. 2 is a diagram of an example embodiment of an electronic signal processing unit.

The arc protection device for disconnecting the switchgear cell contains optical fibers 1, 2, combined into one cable, photoelectronic converters 3, 4, an electronic signal processing unit 5 and n of the actuating organs 6, where n is the number of monitored cells. The optical fibers 1 and 2 are optically connected at one of their ends to the inputs of the photoelectric converters 3, 4, respectively. The outputs of the photoelectronic converters 3, 4 are connected respectively to the first and second inputs of the electronic signal processing unit 5, and each of the n outputs of this unit is connected to the corresponding actuator 6 _{1 ... n} .

The device operates as follows. When an open electric arc occurs in one of the switchgear cells, the light from it falls on the side surface of the cable of optical fibers having different attenuation coefficients, passes through their translucent sheath and is captured in their light guide channels. Through the optical fibers 1, 2, the light signals from the arc propagate with varying degrees of attenuation of their power and are transmitted to photoelectric converters 3, 4, where their powers are converted into photocurrent signals proportional to these powers. The photocurrents are fed to the inputs of the electronic signal processing unit 5, where the number of the damaged cell is determined by their ratios, after which a signal to turn it off is generated at the output of the electronic signal processing unit corresponding to this cell, which is supplied to the 6 _m actuator corresponding to the mth cell. The executive body 6 _m disables the m-th damaged cell.

 The principle of operation of the proposed device is based on a linear dependence of the logarithm of the ratio of the power of the light signals recorded at the ends of the fibers, on the length of these fibers between the flash of light and their ends. Knowing this length with the known geometry of the cable laying of the optical fibers, it is possible to determine the cell where the arc appeared. The ability to determine the cable length of the optical fibers between the flash of light and its end is confirmed by the following.

The power of the light signals P ₁ and P ₂ induced in the fibers by a flash of light, for example from an open electric arc, and recorded at their ends, are determined by the formulas:
P ₁ = q • F • l • exp (-α ₁ x) (9)
P ₂ = q • F • l • exp (-α ₂ x) (10)
where q is the coefficient of conversion of light into light power captured by the light guide and directed to the end connected to the photoelectric converter;
F is the illumination created by the recorded light flash at the location of the optical fibers;
l is the irradiated length of the optical fibers;
α _1, α _{2 /} - attenuation coefficients of the light power of the optical fibers 1, 2, respectively;
x is the length of the optical fibers from the place of the light flash to their ends, connected to photoelectric converters.

Вводя обозначение Δα = α₂-α₁ и учитывая, что световые мощности P₁ и P₂ пропорциональны фототокам I₁ и I₂ на фотоэлектронных преобразователях 3, 4, уравнение (11) можно переписать в виде формулы:

Таким образом положение световой вспышки вдоль кабеля из двух световодов будет определено.Dividing equations (9) by (10) and taking the logarithm from the resulting expression, it is easy to obtain the following formula:

Introducing the notation Δα = α ₂ -α ₁ and taking into account that the light powers P ₁ and P _{2 are} proportional to the photocurrents I ₁ and I ₂ on photoelectric converters 3, 4, equation (11) can be rewritten in the form of the formula:

Thus, the position of the light flash along the cable of two optical fibers will be determined.

где ε_max1,ε_max2 - максимальные относительные флуктуации фототоков I₁, I₂ соответственно.The value of Δα is chosen so as to provide a minimum error in determining the position of the light flash along the cable. The maximum absolute error Δx is determined by the formula:

where ε _max1, ε _max2 are the maximum relative fluctuations of the photocurrents I ₁ , I _2, respectively.

можно записать в виде:

Можно показать, что |Δx|_max имеет минимум, когда Δα ≈ 2/L.
Отметим, что в данной схеме длина контролируемого участка равна длине световодов L_конт=L. Если пренебречь затуханием в световоде l, то длина L_конт контролируемого участка может быть оценена по формуле:

При тех же параметрах, что и в прототипе, а именно: при α = 0,07 1/м, P₀ = 1 мкВт, |Δx|_max = 0-5 м; К= 2,2587•10^-5 мкВт, длина контролируемого участка составит L_конт ≈ 53 м, что в 1,85 раз больше, чем в прототипе.As in the prototype, it is obvious that the relative fluctuation ε will be maximum when the light flash occurs at the ends of the optical fibers far from the photoelectric converters. Therefore, the maximum error

can be written as:

It can be shown that | Δx | _max has a minimum when Δα ≈ 2 / L.
Note that in this scheme, the length of the monitored section is equal to the length of the optical fibers L _cont = L. If we neglect the attenuation in the optical fiber l, then the length L _cont controllable section can be estimated by the formula:

With the same parameters as in the prototype, namely: at α = 0.07 1 / m, P ₀ = 1 μW, | Δx | _max = 0-5 m; K = 2.2587 • 10 ^-5 μW, the length of the controlled area will be L _cont ≈ 53 m, which is 1.85 times more than in the prototype.

 In the claimed device, as optical fibers 1, 2, for example, irregular fiber optic bundles manufactured by Lytkarinsky Optical Glass Plant JSC can be used.

 Photodetectors made on the basis of LFD-2 photodiodes can be used as photoelectronic converters.

 As an electronic signal processing unit, a block made according to the circuit shown in FIG. 2, which consists of a block of the logarithm of the ratio of currents 7, made on the basis of the circuit shown in [4], and a linear-point indicator based on a microcircuit of the LM3914 type described in [5].

 A block based on the REN-33 relay can be used as an executive body.

 Thus, the technical result of using the inventive arc protection device to disconnect the cells of the complete switchgear in comparison with the prototype is to increase the length of the controlled area.

Sources of information
1. Arc protection device, MKI ⁷ H 02 H 7/26, Utility Model Certificate N 5893, 09.26.1996.

2. Device for disconnecting complete switchgear, Patent for the invention, MKI ⁷ H 02 H 7/26, N 2096887, 04.08.1993.

 3. P.A. Demyanenko, Radio engineering, 1988, N 2, p. 88.

 4. Shilo V.L. Linear Integrated Circuits, Moscow: Soviet Radio, 1979, p. 179.

 5. C. Shoemaker "Amateur control and signaling schemes for IP", M .: Mir, 1989, p.111.

Claims (1)

An arc protection device for disconnecting a switchgear switchgear cubicle containing a light guide with a light-transmitting sheath, two photoelectronic converters, an electronic signal processing unit and n actuators, where n is the number of monitored cells, the outputs of the photoelectric converters are connected to the corresponding inputs of the electronic signal processing unit , each of the n outputs of which is connected to the corresponding executive body, characterized in that it further comprises a second with translucent light guide sheath and the attenuation coefficient different from the damping coefficient of the first optical fiber by an amount

where L is the length of the optical fibers, the optical fibers are combined into a cable, one end of each optical fiber is optically connected to the input of its photoelectronic converter, the electronic signal processing unit is configured to implement a mathematical function

where x is the distance from the switchgear cell in which the arc appeared to photoelectronic converters along the fiber cable;
I ₁ , I ₂ - photocurrents from the outputs of photoelectronic converters.

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