KR100485932B1 - Magnetic trip device - Google Patents

Abstract

The present invention relates to a magnetic trip device, which includes a permanent magnet and a moving core and converts an electrical signal of a trip relay into a mechanical output to drive a trip mechanism, and by the movement of the moving core due to the electrical signal. A hook lever lever for driving the slide held by the hook, a hook lever spring for rotating the hook lever so that the hook lever can hook the slide, and bringing the MTD reset lever back to its original position, and an MTD spring therein; A slide for driving the trip mechanism by advancing by the force of the MTD spring when the lever is rotated, a slide holder for fixing the MTD coil and the MTD spring and guiding the movement of the driven slide; Ratchet torsion spring to return slide, and forward when trip after MTD operation The ratchet lever which rotates the ratchet torsion spring to return the slide, and the MTD reset lever which is interlocked with the ratchet lever and reset the moving core of the MTD coil when the ratchet lever is rotated as the breaker trips, Characterized in that it comprises a supporting MTD case.

The present invention has the effect that the size of the output load can be made larger than the conventional method while simply configuring the MTD to smooth the operation and the capacity of the blocking capacity.

Description

Magnetic trip device {MAGNETIC TRIP DEVICE}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a magnetic trip device (MTD), and in particular, when an abnormal accident current such as overload, short circuit, or ground occurs in a line, the breaker is cut off in the shortest time by a signal detected by a trip relay mounted on the breaker body. It relates to an MTD which is intended to protect the lines and equipment on the power system by making it possible.

Conventionally, a method of detecting an accident caused by installing a trip relay on a line of a power system or a circuit breaker for the purpose of blocking an abnormal accident current has been used. At this time, in order to cut off the fault current and protect the line from the fault, it is required that the MTD mounted on the line or the breaker main body has no problem in operation even if any interruption current is generated.

However, when a huge fault current occurs in the breaker, magnetic force is generated in the main circuit of the breaker in proportion to the magnitude of the fault current, and the magnetic force generated in the main circuit immediately acts as a friction and load on each component of the breaker trip mechanism. It acts as a deterrent to make the driving force to drive the trip mechanism large.

Therefore, as the blocking current increases, the output of the MTD also becomes large.

In addition, the breaker technology of the recent breakdown technology is small, but the breaking capacity is relatively large capacity is a significant factor that can increase the efficiency of the configuration, combination, and mechanism of the parts.

Hereinafter, a conventional MTD will be described in more detail with reference to the accompanying drawings.

1 is a configuration diagram of an MTD coil of a general magnetic trip device, and FIG. 2 is a state diagram before operation of a conventional MTD.

As shown in FIG. 1 and FIG. 2, the conventional MTD includes a moving core 18 compressing the permanent magnet 14 and the coil spring 16 inside the coil 12 to mechanically output an electrical signal of the trip relay. The hook lever 20 for driving the slide 40 held by the hook by the movement of the moving core 18 generated by the operation of the MTD coil 10 and the trip relay signal, which converts the driving mechanism into a trip mechanism. The hook lever is rotated by the hook lever spring 30 and the hook lever 20 to rotate the hook lever 20 during the reset operation so that the hook lever 20 can hook the slide 40 while the MTD spring ( A slide holder 50 and a hook lever lever for advancing the slide lever 120 of the mechanism and the slide 40 to move forward and backward while advancing by the force of 60 and fixing the MTD coil 10. MTD spring (20) and slider (40) 60, the ratchet lever 80 advances the slide 40 when the ratchet lever 80 rotates, or returns the advanced slide 40 after the operation. The ratchet torsion spring 70, the hook lever 20, and the slide 40 ) Is released by the MTD spring 60 to rotate the ratchet torsion spring 70, or after ratcheting the ratchet torsion spring 70 to rotate the ratchet torsion spring 70 to return. 80) and the MTD spring 60 and the breaker trip the ratchet lever while rotating the ratchet lever 80 when the MTD coil 10 is operated while the load is kept in tension. When the 80 is rotated, the MTD reset lever 90 interlocked with the ratchet lever 80 and presses the moving core 18 of the MTD coil 10 to reset and the interruption of the MTD coil 10 when the breaker is closed. The reset spring 100 to return the MTD reset lever 90 to the home position so that It is composed of a combination MTD case 110 for supporting the.

Here, the MTD coil 10 is composed of a moving core in which a permanent magnet and a coil spring are compressed therein to convert an electrical signal of the trip relay into a mechanical output to drive a trip mechanism. When the trip mechanism is driven to move the moving core, the hook lever 20 drives the slide 40 held by the hook.

The hook lever spring 30 causes the black lever 20 to rotate during the reset operation so that the hook lever 20 can hook the slide 40. At this time, the slide 40 is rotated by the hook lever 20. As the hook is released, it advances by the force of the MTD spring 60 and rotates the trip lever 120 of the mechanism. When the slide 40 moves forward or backward, the slide holder 50 serves to guide the forward and backward movement thereof and to fix the MTD coil 10 at the same time.

Meanwhile, when the hook lever 20 drives the slide 40, the ratchet lever 80 is rotated by the MTD spring 60 to rotate the ratchet torsion spring 70, or the slide 40 advanced after the operation. Rotate the ratchet torsion spring 70 to return.

When the ratchet lever 80 is rotated by the MTD spring 60, the ratchet torsion spring 70 advances the slide 40 or returns the advanced slide 40 after the operation.

 The MTD reset lever 90 is interlocked with the ratchet lever 80 when the breaker trips and the ratchet lever 80 is rotated to reset the moving core of the MTD coil 10 by pressing the reset spring and the reset spring 100 is a breaker. The MTD reset lever 90 is returned to its original position so that the MTD coil 10 does not interfere with the closing. Finally, the MTD case 110 serves to support them in combination.

As shown in FIG. 2, on the MTD before operation, the hook of the hook lever 20 is caught in the first groove 42 of the slide 40 and the ratchet torsion spring 80 is the second groove of the slide 40. The ratchet lever 80 is interlocked with the ratchet lever 80 and is fitted to the same center 72 of the ratchet torsion spring 80 by the MTD spring 60 by using the groove 82 of the ratchet lever 80. (80) It is fitted to rotate the ratchet torsion spring 70 during rotation, and the MTD spring 60 is tensioned between the fixed point 112 of the MTD case 110 and the working point 74 of the ratchet lever 80. The ratchet lever 80 is waiting for rotation.

3 is a state diagram after the operation of the conventional MTD.

As shown in FIG. 3, when the moving core is released from the MTD coil 10 to push the rotation action point 26 of the hook lever 20, the hook lever 20 slides while rotating the rotation center 22 as a starting point. The hook of the hook lever 20 that has been caught in the first groove 42 of the 40 is released. At this time, the ratchet lever 80 is rotated by the force of the MTD spring 60, which is caught in the first rotational action point 86 of the ratchet lever 80 in the tensioned state, and the groove 84 of the ratchet lever 80 is rotated. Ratchet torsion spring 70 is linked to the rotation center is rotated from the center (72).

At this time, the slide 40 interlocked with the second groove 44 of the slide 40 is guided by the slide holder 50 while the first groove 42 is released from the hook of the hook lever 20. .

At this time, the protrusion 46 of the advanced slide 40 collides with the rotation action point 124 of the trip lever 120 of the trip mechanism, and the trip lever 120 rotates around the center of rotation 122 as a breaker. Trips and cuts off the fault current.

4 is a circuit breaker opening state diagram of a conventional magnetic trip device.

As shown in FIG. 4, when the breaker trips, the main shaft 130 of the breaker is rotated. When the main shaft 130 rotates from the center 132 of the main shaft, the reset roll 134 of the main shaft is ratchet lever ( The second rotary action point 82 of 80 is pushed, and at this time, the ratchet lever 80 retracts the MTD spring 60 hanging on the first rotation action point 86 while rotating in the opposite direction during the trip operation. The ratchet torsion spring 70 is reversed by the second rotation action point 82. When the ratchet torsion spring 70 rotates, the slide 40 linked to the second groove 44 of the slide 40 returns to its original position.

In addition, the third rotary action point (not shown) is to link the first rotary action point 94 of the MTD reset lever 90, wherein the MTD reset lever 90 is rotated from the rotation center 92 starting point The moving core of the MTD coil 10 released by the second rotation action point 96 is returned to its original position, and when the breaker is closed again, the operation of the MTD coil 10 is interrupted as shown in FIG. MTD reset lever 90 is rotated to its original position by the reset spring 100 so that there is no.

When the moving core of the MTD coil 10 returns to its original position and the slide 40 returns, the hook lever 20 is returned to its original position by the hook lever spring 30 mounted on the rotation center 22 of the hook lever 20. At this time, the hook 24 of the hook lever 20 is engaged with the first groove 42 of the slide 40 so that the MTD returns to the state before operation.

As described above, in the case of the prior art configuration, each component including the coil is limited in a limited space so that there is not enough space to increase the output, and the MTD spring is a driving force for driving the trip mechanism. Even if the load of (60) is increased, the friction force between the hook 24 of the hook lever 20 and the first groove 42 of the slide 40 increases when the load of the MTD spring 60 becomes large, thereby increasing the hook lever. The coil spring load of the MTD coil 10 for rotation must also be greater.

In this case, the magnetic flux strength of the permanent magnets that are limited cannot withstand the coil spring load, and the breaker may malfunction due to the impact drop during the breaker operation.

In addition, in the structure of the prior art, the load of the MTD spring 60 is interlocked by the ratchet lever 80 and the ratchet torsion spring 70, and the like. In particular, the ratchet torsion spring 70 allows the slide 40 to be moved. There is a drawback that the efficiency is considerably reduced by resistance such as friction of each part interlocked while driving.

Therefore, the conventional magnetic trip device (MTD) has a problem that the ability to drive the trip mechanism is limited even if the breaker of the breaker is increased.

An object of the present invention is to solve the above problems, the magnetic trip is mounted on the circuit breaker to protect the line and equipment of the power system by cutting off the fault current in case of abnormal fault current such as overload, short circuit, ground fault in the line of the power system The present invention provides a magnetic trip device capable of maximizing the efficiency of a device in a limited space by simplifying the configuration of a device than a conventional driving method.

In addition, another object of the present invention is to increase the driving force for driving the trip mechanism to safely cut off a large amount of current as quickly as possible, to protect the lines and equipment to facilitate smooth operation of the power system and the user safety. The present invention provides a magnetic trip device.

Magnetic trip device (MTD) according to the present invention for achieving the above object is

In a magnetic trip device (MTD), a permanent magnet, a coil spring, and a moving core inside a coil, and an MTD coil for converting an electrical signal of a trip relay into a mechanical output to drive a trip mechanism, and a signal to the trip lily. The hook lever for driving the slide held by the hook by the movement of the moving core generated by the hook, the hook lever rotates the hook lever during the reset operation to hook the slide and the MTD reset lever so as not to interfere with the operation of the MTD coil. Hook lever spring to return to the original position, the hook is released by the rotation of the hook lever, the slide advances by the force of the MTD spring to drive the trip mechanism, the MTD coil and MTD spring is fixed and the forward and backward movement of the slide A slide holder for guiding, and fixed inside the slide holder MTD spring, which is inserted into the slide and moves the slide forward when the hook lever is rotated when the MTD coil is operated, and a ratchet torsion spring which returns the slide advanced by the trip after the MTD is operated. The ratchet lever for rotating the ratchet torsion spring to return the slide advanced by the trip after the operation of the MTD, and when the ratchet lever is rotated by the tripping operation of the breaker, interlocks with the ratchet lever to move the moving core of the MTD coil. MTD reset lever to be reset by pressing, it characterized in that it comprises a magnetic trip device (MTD) characterized in that it comprises a MTD case for supporting a combination thereof.

In addition, the magnetic trip device is characterized in that the tripping portion of the slide when the advance of the slide by the collision of the tripping point of the trip lever by the collision of the trip lever rotates the breaker while tripping the breaker to cut off the accident current Can be.

Hereinafter, preferred embodiments of the present invention as described above will be described in more detail with reference to the accompanying drawings.

In the drawings of the present invention, the same reference numerals will be used for the same configurations as the conventional configurations.

5 is a state diagram before operation of the magnetic trip device according to the present invention.

1 and 5, the MTD of the present invention is composed of a moving core 18 in which a permanent magnet 14 and a coil spring 16 are compressed inside a coil 12, so that an electrical signal of a trip relay is mechanically processed. The hook lever 20 for driving the slide 40 held by the hook by the movement of the moving core 18 generated by the operation of the MTD coil 10 and the trip relay signal, which is converted to the output and drives the trip mechanism. ) And the hook lever 20 are hooked by the hook lever lever 30 and the hook lever 20 to rotate the hook lever 20 during the reset operation so that the hook is released and the MTD spring The slide 40 and the slide 40 for rotating the trip lever 120 of the mechanism while moving forward by the force of the 60 and the guide role and the MTD coil 10 fixed and the MTD spring 60 to move back and forth Fixed slide holder 50 and slide holder 50 inside When the hook lever lever 20 is rotated during the operation of the MTD coil 10, the MTD spring 60 moves forward when the hook 40 is rotated, and the slide 40 is returned during the trip after the MTD operation. Ratchet lever 80 and the circuit breaker trip the ratchet torsion spring (70) to rotate the ratchet torsion spring (70) so that the advanced slide (40) returns when the ratchet torsion spring (70) and the MTD operation are tripped. The MTD reset lever 90 interlocks with the ratchet lever 80 and presses and resets the moving core 18 of the MTD coil 10, and the MTD case 110 supports the combination thereof. .

 In general, the MTD coil 10 has a greater strength in the magnetic flux direction of the permanent magnet 14 than the compressive force of the coil spring 16 so that the moving core 18 contacts the permanent magnet with the coil spring 16 compressed. It is fixed.

When the trip relay detects this by the above-described accident in a closed state of the circuit breaker and gives a small voltage signal to the MTD coil 10, power is applied to the coil 12 as shown in FIG. The reverse magnetic flux is generated in the magnetic flux direction of the permanent magnet 14 by the law.

At this time, the magnetic flux intensity of the permanent magnet 14, which is greater than the compressive force of the coil spring 16, is caused by the reverse magnetic flux acting on the coil 12. It becomes smaller than the sum so that the moving core 18 is separated from the permanent magnet 14 and released.

As a result, the MTD coil 10 converts the electrical signal of the trip relay into a mechanical output to drive the trip mechanism.

6 is a state diagram after the operation of the magnetic trip device according to the present invention.

Looking at the configuration of the present invention with reference to Figure 6 the present invention is the slide 40 that was held in the hook by the movement of the moving core 18 generated by the operation of the trip relay signal, in addition to the above-described MTD coil (10) In order to hook the hook lever 20 and the hook lever 20 to drive the slide 40, the hook lever 20 is rotated during the reset operation, and the MTD coil 10 does not interfere with the operation of the MTD coil 10. It comprises a hook lever spring 30 for bringing the reset lever 90 to its original position.

In addition, while the hook is released by the rotation of the hook lever 20, the slide 40 and the slide 40 for rotating the trip lever 120 of the mechanism while moving forward by the force of the MTD spring 60 can be moved back and forth. When the hook lever 20 is rotated during the operation of the MTD coil 10 is fixed inside the slide holder 50 and the slide holder 50 to fix the guide role and the MTD coil 10 and the MTD spring 60. And an MTD spring 60 for advancing the slide 40 to cause a trip operation.

In addition, the ratchet torsion spring 70 for returning the advanced slide 40 at the time of trip after MTD operation and the ratchet torsion spring 70 for rotating the ratchet torsion spring 70 at the time of tripping after MTD operation ( 80) and the MTD reset lever 90 which interlocks with the ratchet lever 80 and presses the moving core 18 of the MTD coil 10 when the ratchet lever 80 is rotated as the trip operation is performed. , Combination of these MTD case 110 is composed of.

When abnormal current such as overload, short circuit, ground fault occurs on the power line, trip relay installed in the circuit breaker detects the above-mentioned type of accident and outputs a signal of less voltage within 24V and sends it to MTD. The MTD coil is configured to receive the trip relay signal.

Before normal operation, the MTD coil is operated to be larger than the compressive force of the coil spring 16 by the strength of the magnetic flux direction of the permanent magnet 14, and the moving core 18 contacts the permanent magnet with the coil spring 16 compressed. It is fixed. If the trip relay detects this by the above-mentioned accident and the like while the circuit breaker is closed and supplies a small voltage signal to the MTD coil 10, power is applied to the coil 12 as shown in FIG. As a result, the reverse magnetic flux is generated in the magnetic flux direction of the permanent magnet 14.

At this time, the magnetic flux intensity of the permanent magnet 14, which has been greater than the compressive force of the coil spring 16, is the sum of the strength of the compressive force of the coil spring 16 and the reverse magnetic flux of the coil 12 by the reverse magnetic flux acting on the coil 12. The smaller the moving core 18 is released from the permanent magnet 14 is released.

In addition, as shown in FIG. 5, the MTD spring 60 has a load greater than that of the conventional MTD spring 60 and is mounted in the slide holder 50 while being fitted to the slide 40 and the slide holder 50 is mounted. The conventional MTD spring 60 is mounted on the lower portion as much as the space where the conventional MTD spring 60 was located. The rotation radius L2 between the rotation center 122 and the rotation action point 124 of the trip lever 120 of the trip mechanism is a conventional rotation radius L1. Becomes greater than).

The present invention is sufficient for the problems caused by increasing the breaking force of the circuit breaker by increasing the driving force of the trip mechanism by increasing the load and the rotation radius to determine the amount of torque required for the rotation of the trip lever 120 compared to the conventional device. You can get the effect that you can cope with.

In addition, the radius of rotation between the rotation center 22 of the hook lever 20 and the rotation operating point 26 of the hook lever 20 by the slide 40 mounted on the lower portion as much as the space where the conventional MTD spring 60 was located ( SL2) is configured to be larger than the same rotation radius SL1 of the conventional method so that the load of the MTD spring 60 when the hook 24 of the hook lever 20 and the first groove 42 of the slider 40 is caught. Even if the size is increased, by increasing the radius of the rotation action point 26 of the hook lever lever 20 can increase the size of the rotation torque of the hook lever lever 20, so that the coil spring 16 of the same size can be used to operate the breaker It is possible to eliminate the malfunction caused by the impact drop.

In addition, the ratchet torsion spring 70 is interlocked with the second groove 44 of the slider 40, and the ratchet torch 80 is fitted to the same center 22 of the ratchet torsion spring 70.

Referring to FIG. 6, when the moving core 18 is released from the MTD coil 10 to push the rotation action point 26 of the hook lever 20, the hook lever 20 rotates about the rotation center 22 as a starting point. The hook 24 of the hook lever 20 caught in the first groove 42 of the slide 40 is released. At this time, the slide 40 is guided by the slide holder 50 to move forward while the MTD spring 60 is inserted into the slide 40 in a compressed state.

At this time, the protrusion 46 of the advanced slide 40 collides with the rotation action point 122 of the trip lever 120 of the trip mechanism, and the trip lever 120 rotates around the center of rotation, and the breaker trips. It will cut off the fault current.

7 is a state diagram illustrating a circuit breaker opening of the magnetic trip device according to the present invention.

As shown in FIG. 7, when the breaker trips, the main shaft 130 of the breaker rotates. When the main shaft 130 rotates about the center 132 of the main shaft, the reset roll 134 of the main shaft is ratchet lever. The second rotary action point 82 of 80 is pushed, and at this time, the ratchet traveler 80 is tripped at the same rotation center 72 of the ratchet torsion spring 70 and the ratchet traveler 80. While rotating in the opposite direction to rotate the ratchet torsion spring 70 linked to the second rotary action point (82). When the ratchet torsion spring 70 rotates, the slide 40 linked to the second groove 44 of the slide 40 returns to its original position.

In addition, the third rotary action point (not shown in the drawing) is linked to the first rotary action point 92 of the MTD reset lever 90 to rotate the same center of rotation 22 of the hook lever 20 and the MTD reset lever 90. By rotating to the starting point, the moving core 18 of the MTD coil 10 released by the second rotary action point 94 is returned to its original position.

When the moving core 18 of the MTD coil 10 returns to its original position and the slide 40 returns, the hook lever 20 is returned to its original position by the hook lever spring 30 mounted at the rotation center of the hook lever 20. It rotates and meshes with the first groove 42 of the slide 40 so that the MTD returns to the state before operation.

Then, after the breaker is closed again, the MTD reset lever 90 also rotates to its original position by the hook lever spring 30 so that there is no interference in the operation of the MTD coil 10.

As described above, the magnetic trip device according to the present invention relates to the magnitude of the fault current in a circuit breaker that protects the line and the device by blocking the fault current when an abnormal fault current such as overload, short circuit, or ground occurs in the power line. The device configuration of the magnetic trip device (MTD) is designed to maximize the efficiency in a limited space so that the smooth trip mechanism can be driven without any problem. The effect of increasing the size of the can be obtained.

1 is a configuration diagram of an MTD coil of a general magnetic trip device

Figure 2 is a state diagram before operation of the conventional magnetic trip device

3 is a state diagram after the operation of the conventional magnetic trip device

Figure 4 is a state diagram when the breaker opening of the conventional magnetic trip device

5 is a state diagram before operation of the magnetic trip device according to the present invention;

6 is a state diagram after the operation of the magnetic trip device according to the present invention;

Figure 7 is a circuit breaker open state diagram of the magnetic trip device according to the present invention

<Explanation of symbols for the main parts of the drawings>

10: MTD coil 12: coil

14: permanent magnet 16: coil spring

18: Moving core 20: Hook lever

22: center of rotation 24: hook

26: operating point 30: hook lever spring

40: slide 50: slide holder

60: MTD spring 70: Ratchet torsion spring

80: ratchet lever 90: MTD reset lever

100: reset spring 110: MTD case

120: trip lever

Claims (2)

A magnetic trip device (MTD), comprising: a permanent magnet, a coil spring, and a moving core inside a coil, the MTD coil converting an electrical signal of a trip relay into a mechanical output to drive a trip mechanism; A hook lever for driving the slide held by the hook by the movement of the moving core generated by the trip lily signal; A hook lever spring for rotating the hook lever in a reset operation so that the hook lever hooks the slide and bringing the MTD reset lever to its original position so as not to interfere with the operation of the MTD coil; A slide for driving the trip mechanism by advancing by the force of the MTD spring while the hook is released by the rotation of the hook lever; A slide holder for fixing the MTD coil and the MTD spring and guiding forward and backward movement of the slide; An MTD spring fixed inside the slide holder and inserted into the slide to move the slide forward when the hook lever is rotated when the MTD coil is operated; A ratchet torsion spring for returning the slide advanced by the trip after the operation of the MTD; A ratchet lever for rotating the ratchet torsion spring to return the slide advanced by the trip after the operation of the MTD; An MTD reset lever which is interlocked with the ratchet lever and resets the moving core of the MTD coil when the ratchet lever is rotated by a tripping operation of the breaker; Magnetic trip device characterized in that it comprises a magnetic trip device (MTD) characterized in that it comprises a MTD case for supporting a combination thereof The method of claim 1, wherein the magnetic trip device, Magnetic trip device, characterized in that the tripping portion of the slide when the advance of the slide by the collision of the tripping point of the trip lever by the trip lever rotates around the center of rotation to trip the breaker to cut off the accident current.