RU2808777C1 - Maximum current protection on reed switches - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: relay protection method used as maximum current protection of electrical installations. Maximum current protection on reed switches contains an electrically insulating body made in the form of a hollow support insulator with a cap and body, a first strip, mounting angles, a replaceable element made in the form of a second rectangular strip on which three reed switches are fixed, a pulse counter and an output relay. According to the invention, three control windings are introduced, each of which is attached to one of the reed switches, an alternating voltage source, an intermediate relay, AND, OR elements, a timer and a button, and all these elements, except the control windings, are located in the relay compartment of the complete switchgear cell.

EFFECT: increasing the reliability of protection by identifying faults in the elements of the protection circuit.

1 cl, 2 dwg

Description

The invention relates to electrical engineering, namely to relay protection technology, and can be used as maximum current protection of electrical installations.

Maximum current protection is known, containing a current relay with an input connected to current transformers, and an output to a time relay, the output of which is connected to the output relay, the output of the output relay is connected to the trip circuit of the electrical installation switch [Chernobrovov N.V., Semenov V.A. Relay protection of energy systems. - M.: Energoatomizdat, 1998. - P. 346-359].

The disadvantage of this overcurrent protection is the use of metal-intensive current transformers.

Maximum current protection on reed switches is known, containing an electrically insulating body made in the form of a hollow support insulator with a cap and a housing, at the base of which there is an additional hole with a diameter equal to the internal diameter of the porcelain body of the hollow support insulator, the hollow support insulator is installed on the first strip, width and length which is equal to the dimensions of the base of the hollow support insulator, and with the help of nuts and bolts passed through the bolt holes in the base of the hollow support insulator and the hole in the first strip, is attached to the supporting structure, the mounting angles on one side are attached to the replacement element using a nut and bolt, passed through the holes in the mounting corners and the replacement element, the other side of the mounting corners is attached to the first strip with the help of nuts and bolts passed through the holes in the mounting corners and the strip, and the holes in the strip have extensions on the side of the supporting structure for placing nuts in them, with In this case, the replaceable element is made in the form of a second rectangular strip, the first, second and third reed switches, a pulse counter and an output relay are mounted on the replaceable element, the first contact of one of the reed switches is connected to the “plus” of the auxiliary power supply using a connecting wire, and the second contact is connected to the input of the pulse counter, the other inputs of which are connected using connecting wires to the “plus” and “minus” of the operating current source, and the output is to the input of the output relay, the other inputs of which are connected using connecting wires to the “plus” and “minus” of the source operative current, the connecting wires are laid in a groove made in the bar and brought out beyond the body of the hollow support insulator [KZ 35133 IPC H02H 7/22, publ. 07/09/2021].

The disadvantage of this maximum current protection is the possibility of failure to operate due to faults of its elements not detected in a timely manner.

The technical objective of the invention is to provide maximum current protection on reed switches using test diagnostics.

The problem is solved due to the fact that the maximum current protection on reed switches, as in the prototype, contains an electrically insulating body made in the form of a hollow support insulator with a cap and a body, at the base of which there is an additional hole with a diameter equal to the inner diameter of the porcelain body of the hollow support insulator , the hollow support insulator is mounted on a first strip, the width and length of which are equal to the dimensions of the base of the hollow support insulator, and is attached to the supporting structure by means of nuts and bolts passed through the bolt holes in the base of the hollow support insulator and the holes in the first strip. one side is attached to the replacement element using a nut and bolt passed through the holes in the mounting corners and the replacement element, with the other side the mounting angles are attached to the first strip using nuts and bolts passed through the holes in the mounting angles and the strip, and the holes in the strip have extensions from the side of the supporting structure to accommodate nuts in them, while the replaceable element is made in the form of a second rectangular strip, the first, second and third reed switches, the pulse counter and the output relay are fixed to the replaceable element, the first contact of one of the reed switches is connected using a connecting wire to the “plus” of the auxiliary power source, and the second contact is connected to the input of the pulse counter, the other inputs of which, using connecting wires, are connected to the “plus” and “minus” of the operative current source, and the output is connected to the input of the output relay, the other inputs of which are connected with using connecting wires to the “plus” and “minus” of the operating current source, the connecting wires are laid in a groove made in the strip and brought out beyond the body of the hollow support insulator.

According to the invention, first, second and third control windings are introduced, placed on the first, second and third reed switches, the terminals of which are connected to an alternating voltage source through normally open contacts of the intermediate relay, and the first contacts of the second and third reed switches are connected to the “plus” of the operating current source, the “AND” element is connected by inputs to the second contacts of the first, second and third reed switches, and by the output to the signaling circuit, the “OR” element is connected to the second contacts of the first, second and third reed switches, and by the output to the input of the timer, the output of which is connected to the signaling circuit, the intermediate relay is connected with one input through the normally closed contacts of the button to the “plus” of the operating current source, and with the other output - to the “minus” of the operating current source, the output relay is connected with its output to the alarm circuit and through the normally closed contacts of the intermediate relay to the trip circuit of the electrical installation switch, moreover, the button, elements “AND”, “OR”, timer, intermediate relay and alternating voltage source are located in the relay compartment of the switchgear cell.

The use of control windings placed on each of the reed switches, an alternating voltage source, a button, an intermediate relay, elements “AND”, “OR”, a timer, and their appropriate connection allows you to perform test diagnostics of overcurrent protection on the reed switches, identifying faults in the elements.

In fig. Figure 1 shows the maximum current protection when it is attached to the internal structural elements of the switchgear cell.

In fig. Figure 2 shows a diagram of the connection of overcurrent protection elements.

Maximum current protection on reed switches contains (Fig. 1 and 2) an electrically insulating body made in the form of a hollow support insulator with a base 1, a cap 2 and a body 3. The base 1 is installed on the bar 4 and using bolts 5, 6 and nuts 7, 8 , passed through the holes in the base 1 and the strip 4, is attached to the internal structural element 9 of the switchgear cell. The replaceable element 10 is fixed to the bar 4 using mounting angles 11, bolts 12, 13 and nuts 14. Reed switches 15, 16, 17, with control windings 18, 19, 20, pulse counter 21 (SI) and output relay 22 (VR) attached to the replaceable element 10. The first contact of the reed switches 15, 16, 17, one input of the pulse counter 21 (SI) and the output relay 22 (BP) are connected to the “plus” of the operating current source using connecting wires 23. Other outputs of the pulse counter 21 (SI) and the output relay 22 (VR) are connected to the negative side of the operating current source using connecting wires 23. The second contact, for example, of the reed switch 15 is connected via connecting wire 23 to the input of the pulse counter 21 (SI), the output of which is connected via connecting wire 23 to the input of the output relay 22 (BP). The output of the output relay 22 (BP), using a connecting wire 23, is connected to the trip circuit of the electrical installation switch through the normally closed contacts 24 of the intermediate relay 25 (PR) and to the alarm circuit. One output of the control windings 18, 19, 20 using a connecting wire 23 is connected through a normally open contact 26 of the intermediate relay 25 (PR) to one of the outputs of the source 27 (IN) of alternating voltage, and the other output is connected to another input of the source 27 (IN) alternating voltage. Intermediate relay 25 (PR) is connected with one input through the normally open contacts of button 28 to the “plus” of the operating current source, and with the other input - to the “minus” of the operating current source. Element “I” 29 (I) is connected by inputs to the second contacts of reed switches 15, 16, 17, and by output to the signaling circuit. Element “OR” 30 (OR) is connected to the second contacts of reed switches 15, 16, 17, and its output is connected to the input of timer 31 (T), the output of which is connected to the alarm circuit. Intermediate relay 25 (PR), alternating voltage source 27 (IN), button 28, elements “AND” 29 (I), “OR” 30 (OR) and timer 31 (T) are located in the relay compartment of the switchgear cell.

An OA-6 type insulator can be used as a hollow support insulator 1 with a cap 2 and a housing 3. The strip 4 and the replaceable element 10 can be made of textolite. Bolts and nuts of type M5 can be used as bolts 5, 6, 12, 13 and nuts 7, 8, 14, and mounting angles 11 can be used as mounting angles BILAR KUM-25x25. As reed switches 15, 16, 17 with control windings 18, 19, 20, for example, reed switch relays of the RGK-54 type can be used. Amplifiers of the K14UD6 type can be used as amplifiers 9 (U1) and 10 (U2). Pulse counter 21 (SI), as well as elements “AND” 29 (I), “OR” 30 (OR), timer 31 (T), can be implemented on a microcontroller series 51 manufactured by atmel AT89S53. An intermediate relay of type RT424024 can be used as output relay 22 (BP) and intermediate relay 25 (PR). As a connecting wire 23, an alternating voltage source 27 (IN), a button 28, a UTP 5e cable, a laboratory autotransformer LATR-2M, a PKE-212 1 U3 button can be used, respectively.

The claimed maximum current protection works as follows. Suppose it is necessary to protect a cable line with a maximum operating current I _r.max = 500 A, connected to the supply busbars through the cell of a complete switchgear (KRU). The current I _sz in the bus at which the protection should operate is calculated using the well-known formula, I _sz = 1500 A. Then, from the reed switches 15, 16, 17, the one for which the condition is met is selected $$F_{cp}=I_{\mathrm{With}h}/2\pi h$$ , where h is the distance from the tire to the reed switch. Let the reed switch 15 correspond to this condition. Then the contacts of the reed switch 15 are connected to the input of the pulse counter 21 (SI). Then the hollow support insulator is installed with base 1 on the bar 4 and attached using bolts 5, 6 and nuts 7, 8 to the internal structural elements 9 of the cell Switchgear (Fig. 1).

In load mode, when the currents in the busbars of the switchgear cell do not exceed the current I _сз , the reed switch 15 does not operate. Therefore, there are no signals at the outputs of pulse counter 21 (SI) and output relay 22 (BP). The protection doesn't work.

When a short circuit occurs, the currents in the busbars of the switchgear cell become greater than the current I _сз =1500 A. Therefore, the reed switch 15 is triggered and outputs a signal (pulse) to the input of the pulse counter 21 (SI). Pulse counter 21 (SI) begins to count the specified number of pulses arriving at its input. The specified number of pulses depends on the amount of time delay that must be provided. Let the protection operate with a time delay of 0.5 s, then taking into account that the contacts of the reed switch 15 close and fall off every half-wave of alternating current, i.e. in each half-wave of alternating current, a signal is received at the input of the pulse counter, the specified number of pulses is 50. After the fiftieth signal is received at the input of the pulse counter 21 (SI), the pulse counter 21 (SI) outputs a signal to the input of the output relay 22 (BP) , which is triggered and sends a signal to the alarm and trip circuits of the electrical installation circuit breaker. In this case, the “AND” element 29 (I) does not produce a signal, since the reed switches 16 and 17 did not work, and the “OR” element 30 (OR) and the timer 31 (T) - since the contacts of the reed switch 15 are not stuck. If the contacts of the reed switch 15 are stuck, then the timer 31 (T) after a time delay, for example 0.02 s, signals this.

To identify faults in the overcurrent protection device, it is equipped with test diagnostics. When button 28 is pressed, the intermediate relay 25 (PR) is activated, which breaks the trip circuit of the electrical installation switch and connects the control windings 18, 19, 20 to the alternating voltage source 27 (IN). Under the influence of magnetic fields created by currents in the control windings 18, 19, 20, the reed switches 15, 16, 17 are activated and fall off, if in good condition, every half-wave of alternating current. Therefore, elements “AND” 29 (AND), “OR” 30 (OR) produce signals, but timer 31 (T) does not. After the reed switch 15 produces the 50th pulse, the pulse counter 21 (SI) will operate, and then the output relay 22 (BP), giving a signal about the serviceability of the protection. If at least one reed switch 15, 16 or 17 does not operate, then element “I” 29 (I) does not produce a signal. If the contacts of any of the reed switches 15, 16, 17 are stuck, timer 31 (T) will give a signal. If pulse counter 21 (SI) or output relay 22 (BP) is faulty, then there is no signal from the output of the latter.

The technical result is the identification of faults in the elements of the protection circuit.

Claims (1)

Maximum current protection on reed switches, containing an electrically insulating body made in the form of a hollow support insulator with a cap and a housing, in the base of which there is an additional hole with a diameter equal to the inner diameter of the porcelain body of the hollow support insulator, the hollow support insulator is installed on the first strip, the width and length of which equal to the dimensions of the base of the hollow support insulator, and by means of nuts and bolts passed through the bolt holes in the base of the hollow support insulator and the hole in the first strip, attached to the supporting structure, the mounting angles on one side are attached to the replacement element by means of a nut and bolt passed through the holes in the mounting corners and the replacement element, the other side of the mounting corners is attached to the first strip using nuts and bolts passed through the holes in the mounting corners and the strip, and the holes in the strip have extensions on the side of the supporting structure for placing nuts in them, while the replaceable element is made in the form of a second rectangular strip, the first, second and third reed switches, the pulse counter and the output relay are fixed on the replaceable element, the first contact of one of the reed switches is connected to the “plus” of the auxiliary power supply using a connecting wire, and the second contact is connected to input of the pulse counter, the other inputs of which are connected using connecting wires to the “plus” and “minus” of the operational current source, and the output is to the input of the output relay, the other inputs of which are connected using connecting wires to the “plus” and “minus” of the operational current source current, the connecting wires are laid in a groove made in the strip and brought out beyond the body of the hollow support insulator, characterized in that the first, second and third control windings are inserted, put on the first, second and third reed switches, the terminals of which are connected to an alternating voltage source through normally open contacts of the intermediate relay, and the first contacts of the second and third reed switches are connected to the “plus” of the operating current source, the “AND” element is connected by inputs to the second contacts of the first, second and third reed switches, and the output to the signaling circuit, the “OR” element is connected to the second contacts of the first, second and third reed switches, and the output to the input of the timer, the output of which is connected to the signaling circuit, the intermediate relay is connected with one input through the normally closed contacts of the button to the “plus” of the operating current source, and the other output - to the “minus” of the operating current source current, the output relay is connected to the alarm circuit and through the normally closed contacts of the intermediate relay to the trip circuit of the electrical installation switch, and the button, elements “AND”, “OR”, timer, intermediate relay and an alternating voltage source are located in the relay compartment of the complete switchgear cell (KRU).