JP2018098993A - Protective relay - Google Patents

Abstract

A protective relay having an operation indicator that retains an operation display even when a magnetic pole of an iron core changes due to electromagnetic noise or the like is obtained. A bobbin 240 having a coil 260 and an iron core 250 around which the coil 260 is wound is housed in an outer frame 230 of an operation indicator 200A. Normally, the movable part 210 having the permanent magnet 216 is accommodated in the outer frame 230 by generating a first magnetic force attracting the iron core 250. When abnormality occurs in the power system, the coil 260 is energized, so that the movable part 210 is moved in the horizontal direction by the second magnetic force repelling the iron core 250 and exposed to the outside of the outer frame 230 to display an operation display. Do. [Selection] Figure 4

Description

  The present invention relates to a protective relay, and more particularly, to a protective relay including an operation indicator that displays an operation history of the protective relay.

  Protective relay protects the power system and various electrical devices by operating the circuit breaker, etc. by detecting an abnormality such as a power system accident from the amount of current input from the power system, etc., and disconnecting the abnormal section from the power system Equipment. Further, the protective relay includes an operation indicator for displaying that an operation signal for operating a circuit breaker or the like has been output (hereinafter referred to as an operation display). With this operation indicator, the maintenance / operator checks the operation status of the protective relay when an abnormality occurs or during maintenance inspection.

  By the way, some protective relays obtain the power of the control power supply for the protective relay from the power system. This type of protective relay loses the control power supply of the protective relay when the breaker or the like operates and is disconnected from the power system. For this reason, in this type of conventional protective relay, a magnetic reversal type operation indicator that does not require electric power for holding the operation display is used to hold the operation display even after the control power supply is lost. When an operation signal is output, the magnetic reversal type operation indicator performs an operation display by inverting the movable part having a permanent magnet by the magnetic force generated by supplying a current to the coil wound around the iron core. It was.

Japanese Utility Model Publication No. 62-57884

  Since the magnetic reversal type operation indicator described above retains the operation display by the residual magnetism of the iron core, when the magnetic pole of the iron core changes due to electromagnetic noise or the like, the movable part is reversed again, and the operation display is not retained. There is.

  The present invention has been made to solve the above-described problems, and provides a protective relay having an operation indicator that retains an operation display even when the magnetic pole of the iron core changes due to electromagnetic noise or the like.

  The protective relay according to the present invention includes a coil that is energized during operation, an iron core around which the coil is wound, an outer frame that houses the coil and the iron core, and a first magnetic force that attracts the iron core to generate an inner frame. And a movable part that moves in the horizontal direction and is exposed to the outside of the outer frame by a second magnetic force that repels the iron core when the coil is energized.

  The protective relay configured as described above has an electromagnetic noise because the movable part is exposed to the outside of the outer frame, the distance between the movable part and the iron core is increased, and the magnetic force between the movable part and the iron core is reduced. Even when the magnetic pole of the iron core changes due to, for example, the operation display can be maintained.

1 is a configuration diagram of a protective relay showing Embodiment 1. FIG. 1 is a perspective view of a protective relay showing a first embodiment. 1 is a cross-sectional view of a protective relay illustrating a first embodiment. FIG. 3 is an exploded view of the operation indicator showing the first embodiment. FIG. 3 is a cross-sectional view of the operation indicator at a normal time showing the first embodiment. FIG. 3 is a cross-sectional view of the operation indicator at the time of operation showing the first embodiment. FIG. 6 is a cross-sectional view of a protective relay that shows a first modification of the first embodiment. It is sectional drawing of the protection relay which shows the modification 2 of Embodiment 1. FIG. FIG. 6 is an exploded view of an operation indicator showing a second embodiment. FIG. 6 is a cross-sectional view of a protective relay in a steady state showing Embodiment 3. 6 is a cross-sectional view of a protective relay during operation showing Embodiment 3. FIG. FIG. 10 is a cross-sectional view of a protective relay in a steady state showing Embodiment 4. FIG. 6 is a cross-sectional view of a protective relay during operation showing Embodiment 4.

(Embodiment 1)
Below, schematic structure of 100 A of protection relays which are one Embodiment is demonstrated using FIG.

(Schematic configuration of the protective relay 100A)
The protective relay 100A detects an abnormality such as an accident in the power system by performing arithmetic processing based on voltage and current information collected from the power system, and an operation signal for operating the circuit breaker and the like Is output. Thereby, the abnormal section is separated from the power system, and the power system and various electric devices are protected. When only one of the current and the voltage is used for the calculation process, the protective relay 100A may be configured to collect either the current or the voltage necessary for the calculation.

  Specifically, the protective relay 100A includes an input circuit 102, an arithmetic circuit 104, an output circuit 106, and an operation indicator 108. The input circuit 102 converts voltage and current analog signals in the power system input from a transformer (not shown) into digital signals. The arithmetic circuit 104 performs various arithmetic processes using the digital signal from the input circuit 102, detects that an abnormality such as an accident has occurred in the power system, and determines whether or not to operate a circuit breaker (not shown). (Hereinafter referred to as operation determination). The output circuit 106 outputs an operation signal for operating the circuit breaker and the like and outputs a display signal to the operation indicator 108 based on the result of the operation determination of the arithmetic circuit 104. The operation indicator 108 receives the display signal and displays the operation. Details of the operation display will be described later.

  The protective relay 100A obtains the power of the control power supply for the protective relay 100A from the secondary side of the transformer (not shown). That is, the protective relay 100A obtains the power of the control power source from the power system. Therefore, in a state where the circuit breaker or the like is operated and the protective relay 100A is disconnected from the power system, the protective relay 100A loses the control power supply.

  FIG. 2 is a perspective view showing the appearance of the protective relay 100A. The protective relay 100A includes a housing 110 and an operation panel 120.

  The casing 110 is a cylindrical container, and stores a front substrate 130 and a flat substrate 132, which will be described later, on which a circuit (an arithmetic circuit or the like) necessary for operating the protective relay 100A is mounted.

  The operation panel 120 has a rectangular parallelepiped shape and is attached to the housing 110. On the surface of the operation panel 120, a numerical display confirmation window 122, an operation unit window 124, and an operation display confirmation window 126 are provided. The numerical value display confirmation window 122 is an opening provided for confirming a numerical value display part 134 described later. The operation unit window 124 is an opening provided for operating an operation unit 136 described later. The operation display confirmation window 126 is an opening provided for confirming the display of an operation indicator 200A described later.

  FIG. 3 is a cross-sectional view showing the internal structure of the protective relay 100A. A front substrate 130 and a planar substrate 132 are accommodated in the housing 110. The front substrate 130 and the flat substrate 132 are fixed in the housing 110, and a circuit (an arithmetic circuit or the like) necessary for operating the protective relay 100A is mounted. In addition, a numerical value display unit 134 is mounted on the front substrate 130. The numerical value display part 134 is comprised by 7 segment LED etc., for example, and displays various numerical values, such as a measured value. An operation unit 136 is also mounted on the front substrate 130. The operation unit 136 includes knobs and buttons, and performs selection of numerical values to be displayed and various settings. The operation unit 136 is provided in a number necessary for the operation, and for example, two operation units 136 are provided. An operation indicator 200A is mounted on the flat substrate 132. The number of operation indicators 200A required for operation display is provided, for example, three.

  The operation indicator 200 </ b> A includes a movable part 210 and a fixed part 220. The movable part 210 is housed in the fixed part 220 when it is normal (hereinafter, referred to as steady state) when no abnormality occurs in the power system. When an abnormality occurs in the power system and the operation indicator 200A receives a display signal (hereinafter referred to as operation), the movable unit 210 moves in the horizontal direction and is exposed to the outside of the fixed unit 220. 3 shows a state where the movable unit 210 is exposed to the outside of the fixed unit 220. The operation indicator 200A is provided at a position where at least the movable part 210 is exposed to the outside of the protective relay 100A from the operation display confirmation window 126 when the movable part 210 is exposed to the outside of the fixed part 220.

(Configuration of operation indicator 200A)
FIG. 4 is an exploded view showing the configuration of the operation indicator 200A. As described above, the operation indicator 200 </ b> A includes the movable portion 210 and the fixed portion 220.

  The movable part 210 has a rectangular parallelepiped first portion 212 and a flat plate-like second portion 214 forming a square shape. The first portion 212 is joined to the main surface of the second portion 214. And when the movable part 210 is seen from the direction orthogonal to the main surface of the 2nd part 214, the 2nd part 214 is larger than the 1st part. A permanent magnet 216 is fixed inside the movable portion 210.

  The fixed part is composed of an outer frame 230, a bobbin 240, an iron core 250 and a coil 260. The outer frame 230 is a rectangular parallelepiped cylinder, and a first opening 232 and a second opening 234 are provided on a pair of opposed surfaces. That is, the outer frame 230 is formed with a hole extending from the first opening 232 to the second opening 234. A rib portion 236 protruding inward is formed on the surface provided with the first opening portion 232, and the first opening portion 232 is provided at an inner end portion of the rib portion 236. The bobbin 240 includes a pair of a first plate 242 and a second plate 244 and a hollow shaft 246 fixed therebetween. An iron core 250 is fixed inside the hollow shaft 246, and a coil 260 is wound around the outside of the hollow shaft 246. The second plate 244 is formed with a first terminal 247 that is electrically connected to one end of the coil 260 and a second terminal 248 that is electrically connected to the other end of the coil 260. And is electrically connected to a planar substrate of a protective relay (not shown).

  The bobbin 240, the iron core 250, and the coil 260 are housed and fixed in the outer frame 230. Specifically, the second plate 244 of the bobbin 240 is accommodated so as to close the second opening 2334 of the outer frame 230, and the first terminal 247 and the second terminal 248 are located outside the outer frame 230. It protrudes. The movable part 210 is accommodated in the outer frame 230, and the inner diameter of the first opening 232 of the outer frame 230 is smaller than the outer diameter of the second part 214 of the movable part 210, and the outer part of the first part 212 is outside. It is larger than the diameter. Therefore, the movable unit 210 can move in the horizontal direction, and at least a part of the first portion 212 of the movable unit 210 can be exposed to the outside of the outer frame 230.

(Operation of the operation indicator 200A)
5 and 6 are cross-sectional views showing the operation indicator 200A during normal operation and during operation. FIG. 5 shows a steady state and FIG. 6 shows an operating state.

  In FIG. 5, in a steady state, the movable portion 210 of the motion indicator 200 </ b> A is accommodated in the outer frame 230 by the first magnetic force attracting the iron core 250 generated by the permanent magnet 216 and is in contact with the first plate 242.

  During operation, that is, when the operation indicator 200A receives a display signal, the coil 260 is supplied with a current necessary for the movable unit 210 to move in the horizontal direction by the second magnetic force repelling the movable unit 210 and the iron core 250. To supply. Thereby, as shown in FIG. 6, the movable portion 210 moves in the horizontal direction from the state in contact with the first plate 242, and the second portion 214 of the movable portion 210 is in contact with the rib portion 236 of the outer frame 230. It becomes. That is, a part of the first portion 212 of the movable part 210 is exposed to the outside of the outer frame 230. As a result, the exposed movable part 210 can be confirmed when viewed from the outside of the protective relay. That is, the operation display can be confirmed. The current supplied to the coil 260 is generated based on the voltage on the secondary side of a transformer (not shown).

  When the circuit breaker or the like operates and the protective relay is disconnected from the power system, the protective relay loses the control power supply. Therefore, no current is supplied to the coil 260 after the control power supply is lost. In this state, the movable portion 210 exposed to the outside of the outer frame 230 has a greater frictional force generated between the outer frame 230 and the movable portion 210 than the third magnetic force attracting the iron core 250. Therefore, the movable part 210 holds the state exposed to the outside of the outer frame 230, that is, the operation display.

  When an abnormality such as an accident in the power system is recovered and the operation display of the operation indicator 200A is restored (reset), the maintenance / operator exposes the movable unit 210 exposed outside the outer frame 230 to the first direction in the horizontal direction. By pushing until it comes into contact with the plate 242, the distance between the movable portion 210 and the outer frame 230 is reduced, and the state in which the movable portion 210 is housed in the outer frame 230 again by the first magnetic force is maintained.

(effect)
As described above, in the protective relay 100A including the operation indicator 200A shown in the present embodiment, the operation display can be maintained even when the magnetic pole of the iron core 250 changes due to electromagnetic noise or the like. Since the magnetic reversal type operation indicator used in the conventional protective relay performs the operation display by inverting the movable portion, the distance between the movable portion and the iron core does not change even after the operation display. On the other hand, since the motion indicator 200A of this embodiment performs motion display by moving the movable portion 210 in the horizontal direction, the distance between the movable portion 210 and the iron core 250 increases after the motion display. As the distance between the movable part 210 and the iron core 250 increases, the magnetic force generated between the movable part 210 and the iron core 250 becomes smaller. Therefore, even when the magnetic pole of the iron core 250 changes due to electromagnetic noise or the like, the operation display can be maintained. it can.

  Further, according to the operation indicator 200A of the protective relay 100A of the present embodiment, it can be determined by touching whether or not the movable portion 210 is exposed from the outer frame 230. For this reason, even a maintenance / operator with visual impairment can easily determine whether or not an operation is displayed.

  In addition, the movable part 210 may be colored with a different color (for example, red) from the outer frame 230, the operation panel 120 of the protective relay 100A, or the like. By coloring the movable part 210, the visibility of the operation display can be further improved.

(First modification)
In the protective relay 100B of the first modification of the present embodiment, the operation indicator 200B is mounted on the front substrate 130 as shown in FIG.

  Thus, even if the operation indicator 200B is provided on the front substrate 130, the same effect as that of the protective relay 100A of the first embodiment is obtained. Further, by providing the operation indicator 200B on the front substrate 130, a flat substrate can be eliminated, and the effect of reducing the number of components is also achieved.

  Other configurations of the protective relay 100B of the present example are the same as those of the protective relay 100A of the first embodiment. Therefore, in the protective relay 100B, the description other than the matter relating to the operation indicator 200B provided on the front substrate 130 is as described in the protective relay 100A of the first embodiment.

(Second modification)
In the protective relay 100C of the second modification of the present embodiment, the operation indicator 200C is detachably fixed to the housing 110 as shown in FIG.

  One end and the other end of a coil (not shown) provided in the fixed portion 220 of the operation indicator 200C are electrically connected to the two lead wires 202, respectively. The two lead wires 202 are connected to the connector 300, and the connector 300 is mounted on the flat substrate 132. Further, the two lead wires 202 and the connector 300 are detachably provided.

  Thus, even if the operation indicator 200C is provided in the housing 110, the same effect as that of the protective relay 100A of the first embodiment is obtained. Further, since the operation indicator 200C is detachably fixed to the housing 110, only the operation indicator 200C can be easily replaced when the operation indicator 200C breaks down. Furthermore, the mounting area of the flat substrate 132 can be reduced as compared with the case where the operation indicator 200C is directly mounted on the flat substrate 132.

  Other configurations of the protective relay 200C of the present example are the same as those of the protective relay 100A of the first embodiment. Therefore, in the protective relay 100C, the description other than the matter relating to the operation indicator 200C provided in the housing 110 is as described in the protective relay 100A of the first embodiment.

(Embodiment 2)
The configuration of the operation indicator 200D of the protective relay according to the second embodiment will be described with reference to FIG. The operation indicator 200D used in the protective relay of this example is obtained by further providing a spring 270 as an elastic body with respect to the operation indicator 200A of the protective relay 100A according to the first embodiment.

  The spring 270 is, for example, a coil spring, is provided between the bobbin 240 and the movable part 210, and is housed in the outer frame 230. An annular groove 249 is formed in the first plate 242, and one end of the spring 270 is inserted and fixed in the groove 249. The other end of the spring 270 is provided so that the movable part 210 can be pressed. That is, the spring 270 is provided so as to push the movable portion 210 in the horizontal direction.

  Normally, the movable portion 210 of the operation indicator 200D is accommodated in the outer frame 230 by the first magnetic force attracting the iron core 250 generated by the permanent magnet 216, and is in contact with the first plate 242. During operation, that is, when the operation indicator 200D receives a display signal, a current necessary for moving the movable unit 210 in the horizontal direction by the second magnetic force repelling the movable unit 210 and the iron core 250 is supplied to the coil 260. To supply. As a result, the movable portion 210 moves in the horizontal direction from the state in contact with the first plate 242, and a part of the first portion 212 of the movable portion 210 is exposed to the outside of the outer frame 230. In a state where the protective relay is disconnected from the power system and no current is supplied to the coil 260, the movable part 210 exposed to the outside of the outer frame 230 is repelled from the iron core 250 by the spring 270 rather than the third magnetic force attracting the iron core 250. The elastic force is greater. Therefore, the movable part 210 keeps the state exposed to the outside of the outer frame 230.

  Even in the protective relay shown in this embodiment configured as described above, the operation display can be maintained even when the magnetic pole of the iron core 250 is changed due to electromagnetic noise or the like. Further, the operation indicator 200D of the protective relay according to the present embodiment can further reduce the force required when the movable unit 210 moves in the horizontal direction by further providing the spring 270. That is, the amount of current supplied to the coil 260 in order to generate the second magnetic force that repels the iron core 250 can be reduced.

  Further, in the operation indicator 200D of the protective relay according to the present embodiment, the movable part 210 exposed to the outside of the outer frame 230 acts on the exposed movable part 210 because the elastic force repelling the iron core 260 by the spring 270 acts. When touching or vibration is applied to the operation indicator 220 </ b> D, it is possible to prevent the movable unit 210 from being accidentally placed in the outer frame 230.

  Other configurations of the protective relay of the present embodiment are the same as those of the protective relay 100A of the first embodiment. Therefore, in the operation indicator 200D of the protective relay, the description other than the matters relating to the provision of the spring 270 is as described in the protective relay 100A of the first embodiment.

(Embodiment 3)
The configuration of the operation indicator 200E of the protective relay 100E according to the third embodiment will be described with reference to FIGS. FIG. 10 shows a steady state and FIG. 11 shows an operating state. The operation indicator 200E used for the protective relay 100E of the present embodiment is obtained by further providing a cover 280 on the fixed portion 220 of the operation indicator 200A of the protective relay 100A according to the first embodiment.

  As shown in FIG. 10, the fixing unit 220 of the operation indicator 200E is mounted on the planar substrate 132 inside the housing 110 of the protective relay 100E. The cover 280 has a plate shape and is fixed to the hinge 282. The hinge 282 is fixed to the upper surface of an outer frame (not shown) of the fixing part 220. That is, the cover 280 is rotatably provided on the fixed portion 220. At regular time, the cover 280 covers a first opening (not shown) formed in the outer frame by its own weight. In operation, as shown in FIG. 11, the cover 280 is rotated about 90 degrees by the movement of the movable portion 210 in the horizontal direction, and the first opening is opened. The movable part 210 exposed to the outside of the fixed part 220 serves as a stopper for the cover 280 and supports the cover 280 from below.

  When an abnormality such as an accident in the power system is recovered and the operation display of the operation indicator 200E is restored (reset), the maintenance / operator pushes the movable unit 210 in the horizontal direction and stores it in the fixed unit 220. The cover 280 covers the first opening by its own weight, and the operation display is restored.

  Even in the protective relay 100E shown in this example configured as described above, the operation display can be maintained even when the magnetic pole of the iron core changes due to electromagnetic noise or the like, as in the first embodiment. Furthermore, the operation indicator 200E of the protective relay 100E shown in the present embodiment is further provided with a cover 280, so that the visibility of the operation display when viewed from the front of the protective relay 100E, that is, from the direction in which the movable part 210 moves, is provided. Can be increased. When the operation indicator 200E is viewed from the front of the protective relay 100E at a constant time, the movable portion 210 is covered with the cover 280 and cannot be confirmed as shown in FIG. On the other hand, when the operation indicator 200E is viewed from the front of the protective relay 100E during operation, the cover 280 rotates to open the first opening as shown in FIG. be able to. Therefore, the visibility of the operation display when viewed from the front of the protective relay 100E can be enhanced. Further, the cover 280 and the movable portion 210 may be formed of different colors and materials. Thereby, the visibility of the operation display when viewed from the front of the protective relay 100E can be further increased.

(Embodiment 4)
The configuration of the operation indicator 200F of the protective relay 100F according to the fourth embodiment will be described with reference to FIGS. FIG. 12 shows a steady state and FIG. 13 shows an operating state. The operation indicator 200F used in the protective relay 100F of the present embodiment is obtained by further providing a reflector 400 in the housing 110 with respect to the operation indicator 200A of the protective relay 100A according to the first embodiment.

  As shown in FIG. 12, the fixing part 220 of the operation indicator 200F is mounted on the flat substrate 132 inside the housing 110 of the protective relay 100F. The operation panel 120 according to the fourth embodiment is formed with a support portion 128 in which the lower side of the operation display confirmation window 126 protrudes into the housing 110. The reflector 400 is a mirror, for example, and is fixed to the support unit 128. As shown in FIG. 13, the reflector 400 is fixed at an angle at which the lower surface of the exposed movable part 210 can be seen when viewed from the front of the protective relay 100F, that is, from the direction in which the movable part 210 moves.

  Even in the protective relay 100F shown in the present example configured as described above, the operation display can be maintained even when the magnetic pole of the iron core changes due to electromagnetic noise or the like, as in the first embodiment. Furthermore, the operation indicator 200F of the protective relay 100F shown in the present embodiment can improve the visibility of the operation display when viewed from the front of the protective relay 100F by providing the reflector 400 in the housing 110. it can. When the operation indicator 200F is viewed from the front side of the protective relay 100F at a constant time, as shown in FIG. 12, since the movable part 210 is accommodated in the fixed part 220, the lower surface of the movable part 210 is passed through the reflector 400. I can't see. On the other hand, when the operation indicator 200F is viewed from the front of the protective relay 100F during operation, the reflector 400 projects the movable part 210 exposed outside the fixed part 220 as shown in FIG. Can be confirmed. Therefore, the visibility of the operation display when viewed from the front of the protective relay 100E can be enhanced.

(Other embodiments)
The protective relay according to the present invention is not limited to the above embodiment, and can be changed within the scope of the gist thereof. For example, although the motion indicator shown in the above-described embodiment has been described as a rectangular parallelepiped, it is not limited thereto, and may be a cylinder. Moreover, you may combine the structure of said each embodiment suitably.

200A-200F operation indicator, 210 movable part, 230 outer frame, 250 iron core,
260 coil, 270 spring, 280 cover, 400 reflector.

Claims (5)

A coil that is energized when the power system is abnormal,
An iron core around which the coil is wound;
An outer frame that houses the coil and the iron core;
A first magnetic force that attracts the iron core is generated to fit within the outer frame, and when the coil is energized, the second magnetic force that repels the iron core moves in the horizontal direction and is exposed to the outside of the outer frame. And
A protective relay with an operation indicator. The protective relay according to claim 1, wherein the movable part exposed to the outside of the outer frame has a larger frictional force between the outer frame and the third magnetic force attracting the iron core. Further comprising an elastic body between the iron core and the movable part,
The protective relay according to claim 1, wherein the movable portion exposed to the outside of the outer frame has a larger elastic force that repels the iron core due to the elastic body than a third magnetic force attracting the iron core. The cover further includes a cover that is rotatably provided on the outer frame and that opens and closes the outer frame by rotating the movable portion in a horizontal direction.
The protective relay according to any one of claims 1 to 3. The operation indicator is provided in a housing of the protective relay,
A reflective plate that is provided in the housing and reflects the movable part exposed to the outside of the outer frame in a direction in which the movable part moves;
The protective relay according to any one of claims 1 to 3.

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