RU2539963C1 - Fibre-optical arc blowout device with identification of electric arc location - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention is related to electric engineering and intended for short-circuit arcing protection in electric equipment, in particular, in switchgear and control gear (SWCG) of 0.4-40 kV. Technical result is attained by the fact that the fibre-optical arc blowout device with identification of electric arc location comprises fibre guides, and each of them is connected by its one end through the emitting source to the respective output of the microcontroller and by its other end through a photoelectronic transducer to the respective input of the microcontroller; all fibre guides pass through the same light-isolating sections; each fibre guide is divided along the whole its length into alternating sections passing or non-passing lights through its lateral surface so that in one section each fibre guide has only a passing or a non-passing section, and passing or non-passing sections of different fibre guides in the same section form a binary code corresponding to the section number, at that quantity of fibre guides N for sections Q control is selected on the following condition: N≥log₂(Q+1).

EFFECT: simplifying structure of arc blowout device due to reducing number of fibre guides controlling the light-isolating sections of SWCG.

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Description

The invention relates to electrical engineering and is intended to protect against an electric arc short circuit in electrical equipment, in particular in switchgear (switchgear) 0.4-40 kV.

The arc protection device must monitor several light-insulated compartments of switchgear cabinets for the occurrence of an arc, determine the number of the compartment where the electric arc occurred, and in accordance with this number, provide information to the relay protection and automation system for timely disconnection of the emergency compartment from the high-voltage power circuit. Also, the device should have a self-monitoring function and high speed, not have galvanic communication with high-voltage circuits of the protected switchgear, not respond to electromagnetic interference, allow multiple tripping.

A device for arc protection [1], containing a fiber waveguide, one end of which is connected through a radiation source to the output of the microcontroller, and the second through a photoelectric converter to the input of the microcontroller, the fiber has a transparent sheath of the side surface. The light guide is laid in the places of the most effective registration of possible arc discharges inside the light-insulated compartments of switchgear cabinets. An optical fiber through the lateral surface perceives the optical radiation of the arc and transmits it to a photoelectronic converter, which converts it into a similar electrical signal. This signal enters the microcontroller. When the amplitude of the signal exceeds a predetermined level, the microcontroller gives a signal to the relay protection and automation system information about the occurrence of an arc in the controlled compartments of the switchgear.

For the purposes of self-monitoring (checking the integrity of the optical fiber and the operability of the photoelectronic converter), the microcontroller periodically sends a signal to the radiation source through a given time interval, through which the radiation source transmits the fiber. At the photoelectronic converter, translucent radiation is converted into an electrical analog, the amplitude of which is compared with a given level in the microcontroller. If this level is exceeded, the device is considered serviceable, otherwise the device is considered faulty, and the microcontroller transmits information about the failure to the relay protection and automation system.

The use of a fiber light guide allows one device to control several light-insulated compartments of switchgear cabinets. Due to the periodic transmission of the fiber, the device implements the function of self-monitoring. The use of the optical registration method makes it possible to ensure high performance. Since a fiber made of dielectric materials is used as a sensitive element, it is not affected by electromagnetic interference, and it allows galvanic isolation of the electronic part of the arc protection device from the high-voltage circuits of the switchgear compartments through which it is laid. The light guide can be located at a considerable distance from the arc origin, which eliminates its destruction. This provides the possibility of multiple operation of the device without replacing its components.

The disadvantage of this device is the inability to determine the emergency compartment switchgear, in which there was an electric arc.

Closest to the claimed (prototype) is an arc protection device [2], containing fiber optical fibers, one end of each of which is connected through its radiation source to the output of the microcontroller, and the second through its photoelectronic converter - to the corresponding input of the microcontroller, and each fiber has a gap dividing him into two knees. At the rupture site, both knees are optically connected to a wide-aperture lens. The lens is installed in the light-insulated compartment of the switchgear cabinet in such a way that light from the electric arc gets into it in case of its occurrence. This light along one of the fibers of the fiber enters the photoelectric converter, where it is converted into an electrical analog, the amplitude of which is compared with a given level in the microcontroller. When the threshold level is exceeded, the microcontroller generates a signal about the occurrence of an arc in the monitored switchgear compartments for the relay protection and automation system, indicating the compartment number where the arc occurred.

Self-monitoring of the device is carried out periodically at a given time interval. The microcontroller provides a signal to the radiation source, through which the radiation source sends an optical signal to one of the bends of the fiber. This signal reaches the point where the fiber is broken, where it is reflected from the lens and fed to the photoelectronic converter via the other knee, where it is converted into an electrical analog, the amplitude of which is compared with a given level in the microcontroller. If this level is exceeded, the device is considered serviceable, otherwise the device is considered to be faulty, and the microcontroller transmits information about the failure to the relay protection and automation system.

The disadvantage of this device is the use of a large number of optical fibers due to the need to stretch their own optical fiber in each controlled compartment of the switchgear.

The technical result is to simplify the design of the arc protection device by reducing the number of optical fibers that control the light-insulated compartments of the switchgear.

The technical result is achieved in that the fiber-optic arc protection device with determining the location of the electric arc, containing fiber optical fibers, each of which is connected at one end through a radiation source to the corresponding output of the microcontroller, and the other end through a photoelectric converter - to the corresponding input of the microcontroller, all the optical fibers pass through the same light-insulated compartments, each light guide is divided along its length into alternating sections, passing or transmitting light through its lateral surface in such a way that each fiber in one compartment has only a transmitting or only non-transmitting section, and transmitting or non-transmitting sections of different optical fibers in one compartment form a binary code corresponding to the compartment number, while the number of optical fibers N to control Q compartments is selected from the condition: N≥log ₂ (Q + 1).

Figure 1 shows the functional diagram of the device arc protection.

Accepted designations:

1 ₁ , ..., 1 _N - fiber optical fibers with open and closed sections;

2 ₁ , ..., 2 _N - radiation sources;

3 ₁ , ..., 3 _N - photoelectronic converters;

4 - microcontroller.

Figure 2 shows an example of the location of open and closed sections for three optical fibers 1 ₁ , 1 ₂ , 1 ₃ (N = 3), controlling seven compartments, Q = 7.

The arc protection device consists of fiber optic fibers 1 ₁ , ..., 1 _N , with alternating sections transmitting and not passing light through the side surface, each section corresponds to its light-insulated switchgear compartment, as shown in FIG. 2. Transmitting and non-transmitting sections form a binary code, in which the unit “1” corresponds to the open section of the fiber, and zero “0” - to the closed one. Each fiber 1 ₁ , ..., 1 _{N is} connected at one end to a radiation source 2 ₁ , ..., 2 _N , and the other end is connected to a photoelectric converter 3 ₁ , ..., 3 _N. The inputs of the radiation sources 2 ₁ , ..., 2 _{N are} connected, each, to their output of the microcontroller 4. The outputs of the photoelectronic converters 3 ₁ , ..., 3 _{N are} connected, each, to their input of the microcontroller 4.

Fiber optic fibers 1 ₁ , ..., 1 _{N are} laid through Q lightproof compartments of switchgear cabinets in such a way that light from a possible arc can get on their side surface.

The number of optical fibers N is chosen equal to the number of bits of the binary code that these optical fibers form, so that the minimum value of this code is unity, and the maximum value is no less than the number of monitored compartments Q. This condition can be written in the form of the formula: $$N\ge {\log }_2\left(Q+\mathrm{one}\right).\left(\mathrm{one}\right)$$

For example, in order to protect Q = 7 switchgear compartments, it is necessary to use N = 3 optical fibers in accordance with formula (1). Alternating sections of the lateral surface of the optical fibers, transmitting and not transmitting light, can be configured as shown in FIG. Let the transmitting section correspond to logical 1, and the non-transmitting section to logical 0. Then if the arc occurs in 1 compartment, the binary code from the outputs of the optical fibers will be 001, which is equal to compartment number 1, if the arc occurs in 2 compartment, then 010, which corresponds to the compartment number 2, if the arc occurs in 3 compartments, then -011, which corresponds to compartment number 3, if the arc occurs in 4 compartments, then 100, which corresponds to compartment number 4, if the arc occurs in 5 compartment, then - 101, which corresponds to the number compartment 5, if the arc occurs in compartment 6, then - 110, which corresponds to ru of compartment 6, if the arc occurs in compartment 7, then 111, which corresponds to compartment number 7.

The device operates as follows.

In the absence of an electric arc, periodically with a predetermined time interval, the microcontroller 4 generates at its outputs signals that enter the inputs of radiation sources 2 ₁ , ..., 2 _N. These radiation sources generate optical signals at their outputs, which, through their respective optical fibers, enter the input of photoelectronic converters 3 ₁ , ..., 3 _N , where they are converted into electrical analogues. These analogs are supplied to the corresponding inputs of the microcontroller 4, where they are compared with a given level. If the signal level is exceeded, the microcontroller provides information on the health of the device to the relay protection and automation system. If the signal amplitude is below the threshold level, then the microcontroller provides information on the device malfunction to the relay protection and automation system.

When an electric arc occurs in one of the controlled compartments of the switchgear cabinets, the light from the arc enters the sections of the optical fibers 1 ₁ , ..., 1 _N. In those optical fibers whose portions are open to light, an optical signal is generated that arrives through the same optical fiber to the corresponding photoelectric converter. In other optical fibers with closed sections, an optical signal is not formed. Photoelectric converters 3 ₁ , ..., 3 _N convert the optical signals into electrical analogs, which are fed to the microcontroller 4, where they are compared with a given level. When the level is exceeded, microcontroller 4 generates an information signal about the occurrence of an arc with an indication of the compartment where the arc occurred, and issues it to the relay protection and automation system to turn off emergency high-voltage circuits.

As optical fibers 1 ₁ , ..., 1 _N, you can use a polymer optical fiber with a protective sheath made of transparent polyvinyl chloride. Closed areas can be made of black PVC tubes worn on a fiber.

As a radiation source 2 ₁ , ..., 2 _N , LEDs L10762, manufactured by HAMAMATSU, can be used.

As photoelectric converters 3 ₁ , ..., 3 _N, you can use photodiodes S1223 company "HAMAMATSU".

As microprocessor unit 4, you can use the microcontroller ADUC812 company "ANALOG DEVICE".

The maximum number of compartments Q _max in switchgear cabinets, which can be controlled by N optical fibers of the claimed device, can be found by the formula: Q = 2 ^N -l.

To control 31 compartments of switchgear cabinets (the usual number of compartments in one section of switchgear cabinets at a substation) in the prototype, it is necessary to use 31 optical fibers, and in the inventive device only 5 optical fibers, which is 6 times less.

Thus, the proposed device can significantly reduce the number of optical fibers required to control switchgear cabinets, and thereby simplify the design of the arc protection device.

Information sources

1. Jan Kulchinsky. ABB introduces REA Modular Arc Protection // Electrical News, No. 4, 2005.

2. Grigoriev V.A., Milokhin V.E., Paley E.L. Fiber-optic arc protection of switchgear cells 6-10 kV // Energetik. - 2002. - No. 2. - S.23-24 (prototype).

Claims (1)

Fiber-optic arc protection device with determining the location of the electric arc, containing fiber optical fibers, each of which is connected through one radiation source to the corresponding output of the microcontroller, and the other end through a photoelectric converter - to the corresponding input of the microcontroller, the information output of the microcontroller is connected to the input of the relay system protection and automation, made with the possibility of disconnecting the compartment in which an electric arc occurred, which differs so that all the fibers pass through the same light-insulated compartments, each fiber is divided along its length into alternating sections that let light through or pass through its side surface so that in one compartment each fiber has only a transmission section or only a transmission section, and transmission or non-transmitting sections of different optical fibers in one compartment form a binary code corresponding to the number of the compartment, and the number of optical fibers N for monitoring the Q compartments is selected from the condition: N≥log ₂ (Q + 1).

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