KR100854387B1 - Trip device module and circuit breaker having thereof - Google Patents

Abstract

A trip device module and a circuit breaker having the same are provided to prevent a malfunction caused by a vibration of a mass body due to an electronic repulsive power by using a spring and excluding the mass body. A trip device module includes a case, an actuator(161), a reset plate(171), and a trip slider(181). The case has a different distance. First and Second arm receiving units are formed on the case to receive a driving arm formed on a main shaft. The actuator is received in the case, and generates an operation force when a trip signal of an over-current meter is outputted. The reset plate is installed to be coupled with the main shaft inside the case, and initializes an output unit of the actuator. The trip slider is slid on the case, and is installed to be coupled with a switch device. The trip slider enables the switch device to perform a trip operation when the actuator performs the trip operation.

Description

Trip mechanism module and circuit breaker with same {TRIP DEVICE MODULE AND CIRCUIT BREAKER HAVING THEREOF}

The present invention relates to a trip mechanism module and a circuit breaker having the same, and more particularly, to a trip mechanism module and a circuit breaker having the same, which can be used in devices having different phase distances.

As is well known, a circuit breaker is an electrical protection device installed between a power supply and a load device so as to protect the load device and the line from possible accident currents (large current due to short circuit, ground fault, etc.) in the electric circuit.

Such a circuit breaker includes an opening and closing mechanism for opening and closing the fixed contact portion and the movable contact portion, an overcurrent relay for detecting an accident current and outputting a trip command to block the energization of a large current, and the overcurrent relay disposed between the switching mechanism and the overcurrent relay. It is provided with a trip mechanism module for generating a mechanical operating force when transmitting the trip command output of the relay to the opening and closing mechanism.

In addition, the breaker is an additional function to perform a trip alarm function for notifying the outside of the trip mechanism module when the trip operation, and a delay time output function for the overcurrent relay to perform the MAKING CURRENT RELEASE function. Separate devices are provided for.

However, in such a conventional circuit breaker, since the separation distance between each phase (for example, R phase, S phase, T phase or N phase) differs according to the breaking capacity of the apparatus, it is said that the trip mechanism module cannot be used in common. There is a problem.

In addition, the size of the circuit breaker body is increased because separate devices must be installed in the circuit breaker body in order to perform the above-described additional functions, that is, the trip alarm function and the delay time output function, and the assembly takes much time and effort. In addition, there is a problem that it is difficult to ensure the reliability of the operation during synchronization or interworking between the devices.

Accordingly, an object of the present invention is to provide a tripping mechanism module and a circuit breaker having the same, which can be used in a device having a different phase distance from each other.

In addition, another object of the present invention is to provide a tripping mechanism module and a circuit breaker having the same, which can be compactly constructed and ensure the reliability of operation.

The present invention is connected to the opening and closing mechanism between the overcurrent relay for detecting the fault current and outputting a trip signal to achieve the object described above, and the opening and closing mechanism connected to the main shaft to open and close the fixed contact portion and the movable contact portion The trip mechanism module is arranged so as to generate an operating force when outputting the trip signal of the overcurrent relay so that the opening and closing mechanism performs a trip operation. The trip mechanism module may accommodate driving arms formed on the main shaft at different phase distances. A case in which the first and second arm accommodation portions are formed; An actuator accommodated inside the case to generate an operation force when outputting the trip signal of the overcurrent relay; A reset plate installed in the case and interlocked with the main shaft to initialize an output of the actuator; A trip mechanism module including a trip slider which is slidable in the case and is connected to the opening / closing mechanism so that the opening / closing mechanism performs a tripping operation when the actuator is tripping.

The driving arm may include a reset plate driving arm in contact with the reset plate and a movable contact drive arm connected to the movable contact part, wherein the reset plate driving arm is accommodated in the first arm receiving part. Preferably, the movable contact drive arm is accommodated in the second arm receiving portion.

The drive arm is in contact with the reset plate and is connected to the movable contact portion, and the drive arm is effectively accommodated in the first arm receiving portion.

Preferably it further comprises an actuator set device for returning the actuator to the initial position in conjunction with the reset plate.

The actuator set device may include a slider disposed on one side of the reset plate and pressed and moved when the reset plate rotates, and one side rotates in contact with the slider, and the other side presses the actuator of the actuator to initialize the actuator. It is effective to include a return arm that returns to position.

The slider preferably includes a housing and a reset pin protruding from the housing and contacting the return arm.

It is effective to further include a delay time output device for outputting a signal having a set delay time after contacting the fixed contact portion and the movable contact portion in conjunction with the main shaft.

The delay time output device is arranged to be rotated in synchronization with the rotation of the main shaft between the switch and the switch disposed on one side of the main shaft, after contact with the fixed contact portion and the movable contact portion A delay member for operating the switch with a set delay time, one side of which is connected to the delay member to apply an elastic force in a direction in which the delay member is in contact with the switch when the main shaft rotates in the feeding direction; Preferably, the retardation member includes a retardation member spring for applying an elastic force to maintain the state spaced apart from the switch when the blocking direction rotates.

It is effective to further include an overcurrent relay interlock trip device for tripping the opening and closing mechanism in conjunction with the detachment of the overcurrent relay.

The overcurrent relay interlocking trip device includes a rotation shaft part rotatably installed in the trip mechanism module, an actuating arm projecting along a radial direction in one region of the rotation shaft part and contacting the overcurrent relay, and the other rotation shaft part. A driving arm which protrudes along the radial direction to the area and is rotated at the same time as the rotation shaft rotates to press the trip mechanism module to perform a tripping operation, and an elastic member for applying an elastic force in a direction in which the working arm contacts the overcurrent relay; It is preferable to configure including.

It is effective to further comprise a trip signal output device for outputting a trip signal to the outside when the trip operation of the actuator in conjunction with the actuator.

The trip signal output device may include a switch for outputting a signal upon contact, and an interlocking member contacting the switch at the trip position of the trip slider in conjunction with the trip slider.

The apparatus may further include a reset device for returning the trip signal output device to an initial position.

And a pressurized slider arranged to slide on one side of the trip slider in the case to press the trip slider to the trip position, and a pressurized slider spring to apply an elastic force to move the press slider to the trip position. The device is effectively configured to include a reset arm on one side of the pressure slider to be rotatable between the trip position and the closing position to move the pressure slider to the closing position.

Preferably, the reset device further includes a reset rod protruding to be exposed to the outside from one side of the overcurrent relay in conjunction with the reset arm and returning the reset arm to the input position when pressurized.

A delay time output device for outputting a signal having a set delay time after contact with the fixed contact part and the movable contact part in association with the main shaft, and an overcurrent relay interlocking with the detachment of the overcurrent relay to trip the switching mechanism It is effective to further include a trip device and a trip signal output device for outputting a trip signal to the outside when the trip operation of the actuator in conjunction with the actuator.

On the other hand, according to another field of the present invention, there is provided a fixed contact portion and the movable contact portion, the main shaft, the opening and closing mechanism for opening and closing the fixed contact portion and the movable contact in conjunction with the main shaft and the movable contact portion therein. Blocking primitives; An overcurrent relay coupled to the blocking body to detect an accident current; A circuit breaker having a trip mechanism module including a trip mechanism module of any one of claims 1 to 3 interposed between the overcurrent relay and the switching mechanism is provided.

Preferably it further comprises an actuator set device for returning the actuator to the initial position in conjunction with the reset plate.

It is effective to further include a delay time output device for outputting a signal having a set delay time after contacting the fixed contact portion and the movable contact portion in conjunction with the main shaft.

It is preferable to further include an overcurrent relay interlock trip device for tripping the opening and closing mechanism in conjunction with the detachment of the overcurrent relay.

It is effective to further include a trip signal output device for outputting a trip signal to the outside when the trip operation of the actuator in conjunction with the actuator.

A delay time output device for outputting a signal having a set delay time after contact with the fixed contact part and the movable contact part in association with the main shaft, and an overcurrent relay interlocking with the detachment of the overcurrent relay to trip the switching mechanism The apparatus may further include a trip signal output device for outputting a trip signal to the outside when the trip operation of the actuator is performed in conjunction with the trip device and the actuator.

As described above, according to the present invention, there is provided a tripping mechanism module and a circuit breaker having the same, which can be used in common in a device having a different phase distance from each other.

In addition, according to the present invention, by arranging devices interlocked with the operation of the actuator and the main shaft in one case so as to be interlocked with each other in outputting the trip command, each device must be manufactured separately, thereby increasing the number and size of parts and mutually. Unlike the conventional method in which the configuration of the device for interlocking is additionally required and the reliability of the operation is not only deteriorated, but also a relatively large installation space is required and the overall size of the device is increased, a compact configuration is possible and the reliability of the operation is improved. There is provided a tripping mechanism module and a circuit breaker having the same.

In addition, according to the present invention, a tripping mechanism module capable of preventing electric shock, component damage, etc. due to a non-trip operation by carrying out a trip operation is carried out uniformly without depending on the judgment of the operator when the overcurrent relay is separated, Breakers are provided.

Further, according to the present invention, by using a spring and eliminating the use of a mass body, there is provided a tripping mechanism module and a circuit breaker having the same, which can prevent malfunction due to vibration of the mass due to electromagnetic repulsive force and improve reliability. .

In addition, according to the present invention, there is provided a tripping mechanism module and a circuit breaker having the same to prevent damage to the components by allowing the actuator to be reset so that a large force of the main shaft is not directly transmitted to the actuator.

In addition, according to the present invention, since the trip signal can be continuously output in conjunction with the trip mechanism module, there is provided a trip mechanism module and a circuit breaker having the same, which can eliminate the use of a separate circuit for sustaining the trip signal.

In addition, according to the present invention, when the reset button or the reset rod protrudes forward, the user can immediately recognize that the trip state that the actuator has performed a trip operation, so that the trip mechanism module and the breaker having the same as soon as possible for an accident Is provided.

Hereinafter, with reference to the accompanying drawings will be described in detail the present invention.

1 is a perspective view of a circuit breaker having a trip mechanism module according to an embodiment of the present invention, FIG. 2 is a view illustrating an interior of the circuit breaker of FIG. 1, and FIG. 3 is a view illustrating an installation state of the trip mechanism module of FIG. 2. Side view. As shown in these figures, the circuit breaker including the tripping mechanism module is interposed between the fixed contact portion and the movable contact portion, the main shaft 111, and the movable contact portion and the main shaft 111 therein. A main body 110 having an opening / closing mechanism 117 for opening and closing the fixed contact portion and the movable contact portion, a front cover 120 coupled to the front surface of the main body 110, and a front surface of the front cover 120. The phase difference between each other is provided with an overcurrent relay 131 coupled to be exposed to detect an accident current and outputting a trip signal (command), and an actuator 161 for generating a manipulation force when outputting the trip signal of the overcurrent relay 131. It comprises a trip mechanism module 140 that can be coupled to the main shaft 111 having a.

An opening 122 is formed in the front cover 120 to expose the overcurrent relay 131 to the outside, and the front cover 120 is operated to open and close the opening and closing mechanism 117 manually. The trip button 125 and the closing button 126 are respectively provided.

The tripping mechanism module 140 is installed behind the overcurrent relay 131, as shown in FIG. 3. One side of the trip mechanism module 140 is provided with the opening and closing mechanism 117 to perform the trip operation of the fixed contact portion and the movable contact portion according to a trip command when the accident current of the overcurrent relay 131 is detected.

4 is a perspective view of the trip mechanism module of FIG. 3, FIG. 5 is an exploded perspective view of the trip mechanism module of FIG. 4, and FIGS. 6 and 7 are views illustrating a state of use of the trip mechanism module of FIG. 3, respectively. 8 is a perspective view of the area of the actuator of FIG. 3. As shown in these figures, the trip mechanism module 140 has first and second arm receiving portions 148 and 149 to accommodate driving arms formed on the main shaft 111 at different phase distances. The case 141 is formed; An actuator 161 accommodated in the case 141 to generate an operation force when outputting a trip signal of the overcurrent relay 131; A reset plate 171 installed in cooperation with the main shaft 111 in the case 141 to initialize an output of the actuator 161; It includes a trip slider 181 that is slidable to the case 141 and is connected to the opening and closing mechanism 117 so that the opening and closing mechanism 117 performs a tripping operation when the actuator 161 is tripped. Consists of.

The trip mechanism module 140 includes a delay time output device 250 for outputting a signal having a set delay time after contact with the fixed contact unit and the movable contact unit in conjunction with the main shaft 111, and the overcurrent relay ( An overcurrent relay interlocking trip device 280 for interlocking with the desorption mechanism 117 and the actuator 161 and a trip signal externally during a trip operation of the actuator 161 in conjunction with the actuator 161. Each trip signal output device 290 is provided.

On the other hand, the case 141, the case body with a plurality of screws 143 to block the front opening of the case main body 142a and the front surface of the opening to form a receiving space therein and the case body 142a A case cover 142b is integrally coupled to the 142a.

The main shaft 111 has a plurality of movable contact drive arm and the opening and closing mechanism drive arm connected to the opening and closing mechanism 117 to drive the movable contact portion of each phase spaced apart to have a different phase distance according to the capacity These are formed, respectively. As shown in FIG. 6, the main shaft 111 is shown in FIG. 7 as compared with the driving arm 113 of each movable contact portion 113 of the first main shaft 112a having a relatively small capacity (for example, 2000A). As shown, it is formed to have a small phase distance compared to each movable contact drive arm 113 of the second main shaft 112b having a relatively large capacity (for example, 4000A). In addition, the reset plate driving arm 114 and the movable contact drive arm 113 are formed on the second main shaft 112b to be spaced apart from each other due to a relatively large phase distance. Since the movable contact drive arm 113 drives the movable contact part and drives the reset plate 171 on the first main shaft 112a, the reset plate drive arm is not formed separately. Accordingly, the second arm accommodating part 149 is present as an empty space. Hereinafter, the first main shaft 112a (hereinafter, referred to as the main shaft 111) in which the reset plate driving arm and the movable contact drive arm are integrally described will be described.

On the other hand, the case 141, the actuator 161 for generating a manipulation force when outputting the trip command of the overcurrent relay 131, and in conjunction with the main shaft 111 to reset the operating portion of the actuator 161 The reset plate 171 is rotatably provided.

As illustrated in FIG. 8, the actuator 161 may include a stator 163 generating magnetic force when power is applied, a mover 165 protruding by the magnetic force of the stator 163, and the mover ( 165 is provided with a spring 169 that exerts an elastic force in the direction in which it protrudes. One side of the actuator 161 is provided with an operating unit 167 to interlock with the mover 165. The operation unit 167 is composed of two parts and both protrude toward the reset plate 171 when the mover 165 protrudes.

A rotation shaft 173 is provided at one end of the reset plate 171, and a bent end 174 for driving the delay time output device 250 is formed at the other end. The stop rings 176 are coupled to both ends of the rotation shaft 173. The reset section 175 is bent in the end region of the rotation plate 173 side of the reset plate 171 to press one of the operating sections 167 of the actuator 161 to return to the initial position. .

An actuator set device 230 is provided between the reset plate 171 and the actuator 161 to reset (return) the actuator 161 to an initial position. The actuator set device 230 is disposed on one side of the reset plate 171 and the reset plate 171 that interlocks with the main shaft 111, and is pressed and moved when the reset plate 171 rotates. Slider 231, one side is in contact with the slider 231 is rotated and the other side presses the mover 165 of the actuator 161 to return the actuator 161 to the initial position 238 Equipped with. The return arm 238 is provided with a return spring 239 for applying an elastic force to return the return arm 238 to the initial position.

The slider 231 may include a housing 233, a reset pin 235 protrudingly and retracted with respect to the housing 233, and a flexible pin disposed inside the housing 233 so as to be retractable. 235 is provided with a cushioning member 237 implemented by a compression coil spring for pressing the protruding against the housing 233. Here, the housing 233 is pressed during the rotation of the reset plate 171 and guided by a guide part (not shown) formed in the case 141 to be linearly moved toward the return arm 238.

The side of the case 141 is provided with a trip slider 181 to be slidably moved between the input position and the trip position along the longitudinal direction. In one region of the trip slider 181, an accommodation part 183 is formed to accommodate a portion of the opening / closing mechanism 117. Here, the opening and closing mechanism 117 is constrained in a state capable of performing a trip operation, and when the trip slider 181 moves to a trip position, a portion that is in contact with the inside of the receiving portion 183 is pressed. As a result, the restrained state is released and thus the trip operation is performed immediately. The trip slider 181 is formed with a guide slot 185 in the long hole to accommodate the guide pin 146 protruding to the side of the case 141. One end of the trip slider 181 is in contact with the operation unit 167, and one side of the trip slider 181 is disposed in parallel with the trip slider 181 to trip the trip slider 181. The pressure slider 191 for pressurizing is arranged.

The pressure slider 191 is formed with a long guide slot 195 to accommodate the guide pin protruding from the case 141. One side of the pressure slider 191 is connected to the pressure slider spring 197 for applying an elastic force to move the pressure slider 191 to the trip position. The pressure slider 191 has a contact portion 196 formed in contact with the trip slider 181 to press the trip slide.

One side of the pressure slider 191 is provided with a latch member 211 to fix the pressure slider 191 in the input position. The latch member 211 is rotatably installed between a fixed position for fixing the pressure slider 191 and a release position for releasing. The latch member 211 is rotated about a pivot shaft 213 formed at the center thereof, and a washer 217 and a stop ring 218 are fixed to the pivot shaft 213 to fix the latch member 211. It is provided. On one side of the latch member 211 is formed a locking jaw 215 is inserted into the fixing groove 193 formed in the pressure slider 191, the other side of the latch member 211 is the actuator 161 In contact with the operating part 167). The latch member 211 is provided with a latch member spring 219 for returning the latch member 211 to an initial position. The latch member 211 is pressurized by the operating unit 167 when the trip operation of the actuator 161 is rotated to the release position so that the pressure slider 191 can be moved to the trip position, the actuator ( When the 161 returns to the initial position by the actuator set device 230, the trip slider 181 is moved to the input position by the elastic force of the latch member spring 219.

9 is a side view of the delay time output device of the tripping mechanism module of FIG. 5, and FIG. 10 is a perspective view of a coupled state of the delay time output device of FIG. 9. As shown in these figures, the present delay time output device 250 sets a current value and detects an inflow current so that the overcurrent relay 131 can prevent a large current from flowing into the load side. It is a device that is used to perform the so-called MCR (making current release) function, which allows the instantaneous blocking of the inflow. That is, in order to perform the MS function, the overcurrent relay 131 cuts the fault current while the breaker is turned on (open: the fixed contact point and the movable contact point are separated), and the breaker is blocked because an accident has already occurred. When the breaker is closed on the line (close: the fixed contact point and the movable contact point), it is necessary to distinguish the case where the accidental current is interrupted, and the delay time output device 250 has a fixed contact point to distinguish the two cases. After contact part and movable contact part contact each other, it outputs contact signal with constant delay time.

As shown in FIG. 9, the delay time output device 250 includes a switch 251 disposed on one side of the main shaft 111 for opening and closing the fixed contact portion and the movable contact portion, and the main shaft 111. A delay member disposed between the switch 251 and the switch 251 in rotation with the rotation of the main shaft 111 to operate the switch 251 with a delay time set after contacting the fixed contact portion and the movable contact portion ( 261 and one side is connected to the delay member 261 to apply an elastic force in a direction in which the delay member 261 is in contact with the switch 251 when the main shaft 111 is rotated in the input direction. When the shaft 111 rotates in the blocking direction, the delay member 261 includes a delay member spring 270 that applies an elastic force to maintain the state spaced apart from the switch 251.

As illustrated in FIG. 5, the switch 251 is installed inside the case 141, and the delay member 261 is rotatably installed at one side thereof. A contact portion 253 is provided at one side of the switch 251, and a stopper 255 is formed in the upper region of the switch 251 to suppress the rotation of the delay member 261. The delay member spring 270 is connected to one side of the delay member 261.

The delay member 261 may include a rotation shaft 263 disposed in parallel with the main shaft 111, and a first contact portion 265 extending from one side of the rotation shaft 263 to one side and contacting the switch 251. ) And a second contact portion 268 extending from the rotation shaft 263 to the other side and rotating simultaneously with the first contact portion 265. The second contact part 268 is provided with a rounding part 266 for smooth contact with the bent end 174 of the reset plate 171 when the main shaft 111 is blocked. Here, the bending end 174 is in contact with the rounding part 266 when the delay member 261 is rotated past the dead point of the spring in a direction approaching the switch 251 by an external force or the like. As a result, the rotation is suppressed and is inclined with respect to the delay member 261. This is because when the main shaft 111 rotates from the blocking position to the closing position, the reset plate 171 is rotated by the elastic force of the reset plate spring 178 and the bent end 174 is the rounding part 266. It is to ensure that the delay time is always ensured by rotating the delay member 261 in the direction away from the switch 251 while being in contact with the.

A delay member spring 270 is applied to one region of the delay member 261, that is, the first contact portion 265, to apply an elastic force to rotate the delay member 261. The retardation member spring 270 exerts an elastic force in a direction in which the retardation member 261 is in contact with the switch 251 at the closing position of the main shaft 111, but the main shaft 111. The delay member 261 is rotated past the dead point of the delay member spring 270 at the blocking position of the delay member 261 so that the delay member 261 is spaced apart from the switch 251. The elastic force is applied in the direction.

FIG. 11 is a front view of the overcurrent relay interlocking trip device of the trip mechanism module of FIG. 3, and FIG. 12 is a side view for explaining the operation of the overcurrent relay interlocking trip device of FIG. 11. As illustrated in FIG. 3, the overcurrent relay interlocking trip may be connected to the rear of the overcurrent relay 131 so that a trip operation in which the fixed contact portion and the movable contact portion are separated in conjunction with the separation of the overcurrent relay 131 may be involved. The device 280 is installed.

The overcurrent relay interlocking trip device 280 is rotatably installed in the tripping mechanism module 140 and protrudes along one radial direction of the rotation shaft portion 283 along the radial direction to the overcurrent relay. The working arm 285 in contact with 131 and the other area of the pivot shaft 283 protrude along the radial direction and are rotated at the same time as the pivot shaft 283 rotates, so that the trip mechanism module 140 trips. The driving arm 287 pressurizes to perform an operation, and the actuating arm 285 includes an elastic member 289 for applying an elastic force in a direction in which the actuating arm 285 is in contact with the overcurrent relay 131.

A rotating shaft portion 283 is rotatably installed in the longitudinal direction on the front surface of the case 141 of the trip mechanism module 140, and the overcurrent relay 131 and the overcurrent relay 131 are formed in one region of the rotating shaft portion 283. A working arm 285 projecting radially in contact with each other is rotatably formed. A driving arm 287 is formed in the other area of the pivot shaft 283 to contact the trip slider 181 and to press the trip slider 181 to move to the trip position. The driving arm 287 extends in contact with the protrusion 188 of the trip slider 181 so as to press the trip slider 181. The rotating shaft portion 283 is provided with an elastic member 289 for applying an elastic force in a direction in which the rotating shaft portion 283 is in contact with the overcurrent relay 131. The elastic member 289 accumulates an elastic force when the overcurrent relay 131 is coupled, and rotates the driving arm 287 with the accumulated elastic force when the overcurrent relay 131 is separated from the trip slider 181. By moving to the trip position, the opening and closing mechanism 117 is operated to perform the trip operation.

Meanwhile, a PCB 144 connected to the overcurrent relay 131 is fixed to the inner region of the case 141 by a screw 147, and the overcurrent relay 131 is connected to the PCB 144. Is provided with a connector 145 connected thereto.

FIG. 13 is a front view illustrating an installation state of a trip signal output device of the trip mechanism module of FIG. 2. As shown in FIGS. 10 and 13, the trip signal output device 290 of the trip mechanism module is interlocked with the actuator 161 which is operated when the trip command of the overcurrent relay 131 is output. ) Indicates to the outside that the trip operation has been performed.

The trip signal output device 290 of the trip mechanism module 140 includes a switch 293 that outputs a signal upon contact, and a switch at the trip position of the trip slider 181 in conjunction with the trip slider 181. It comprises a linking member 313 in contact with (293).

The switch 293 is accommodated and installed on one side of the actuator 161 in the case 141, and a contact portion 295 is formed on one side of the switch 293 in contact with the pusher. The interlocking member 313 has a central pivot 315 and two arm portions 317 extending in different directions from the pivot 315. The two arm portions 317 extend to the switch 293 side and the trip slider 181 side, respectively. A contact piece 319 is provided between the contact portion 295 and the interlocking member 313 to uniformly press the contact portion 295. In the trip slider 181, a pressure rod 187 is extended to move the arm part 317 of the interlocking member 313 by rotating when moving to the trip position.

On the other hand, one side of the case 141 is provided with a reset device 320 to return the trip signal output device 290 to the initial position. The reset device 320 of the trip signal output device 290 is disposed on one side of the pressure slider 191 so as to be rotatable between the trip position and the closing position to move the pressure slider 191 to the closing position. The reset arm 321 and the reset rod 321 protrude outwardly from one side of the overcurrent relay 131 in conjunction with the reset arm 321 and return the reset arm 321 to the closing position when pressed. 331 is provided. The reset arm 321 includes a central rotation shaft 323 and two arm portions 325 extending from the rotation shaft 323 toward the pressure slider 191 and the reset arm 321, respectively. . A stop ring 327 and a washer 328 for coupling the reset arm 321 are coupled to the pivot shaft 323. The front end of the reset rod 331 extends in front of the breaker body 110, the reset rod 331 is a reset rod for applying an elastic force to move the reset rod 331 to the reset arm 321 side A spring 337 is provided. As shown in FIG. 1, a reset button 335 is provided at the front end of the reset rod 331 to press the reset rod 331. Here, the reset arm 321 may be configured to be driven by an electric motor. In addition, the front end of the reset rod 331 may be configured to be directly exposed to the outside.

By such a configuration, when the overcurrent relay 131 outputs a trip command, the actuator 161 is supplied with power to the stator 163 to generate a magnetic force, and the movable member 165 protrudes by the magnetic force. When the mover 165 protrudes, the operation unit 167 is moved to the trip position by interlocking. At this time, the latch member 211 is pressed by the operation unit 167 to be rotated to the release position.

When the latch member 211 is rotated, the pressure slider 191 is moved to the trip position by the elastic force of the pressure slider spring 197, and at this time, the trip slider 181 is pressed to move to the trip position. When the trip slider 181 is moved to the trip position, the main shaft 111 is rotated to the trip position by performing a trip operation while the restraint of the opening / closing mechanism 117 in contact with the trip slider 181 is released. As a result, the fixed contact portion and the movable contact portion are separated from each other. On the other hand, when the trip slider 181 is moved to the input position, the interlocking member 313 in contact with the pressing rod 187 is pressed while being rotated about the rotation shaft 315. The pivoted interlocking member 313 presses the contact piece 319, and the pressed contact piece 319 is brought into contact with the progressive portion 295 of the switch 293 so that the switch 293 outputs a trip signal.

When the main shaft 111 rotates to the trip position, the reset plate drive arm 114 rotates the reset plate 171 to the trip position. When the reset plate 171 is rotated, the slider 231 is pressed by the reset plate 171 and slidably moved, and is pressed by the reset pin 235 of the slider 231 to return the arm 238. Is rotated. The pivoting return arm 238 pressurizes the mover 165 to return the actuator 161 to an initial position. At this time, the slider 231 is reset when the movable arm 165 is returned to the initial position because the return arm 238 is no longer rotated, the reset pin 235 is stopped, in this state the housing 233 When the pressure is advanced, the buffer member 237 is compressed to perform a buffer function.

On the other hand, when the reset plate 171 is rotated to the trip position, the operation of the reset plate 171 and the actuator 161 of the actuator 161 is in contact with the operating unit 167 is returned to the initial position.

At this time, since the trip slider 181 is constrained by the pressure slider 191, the trip slider 181 exists in the trip position to prevent re-entry. When the cause of the trip is checked by the user, the user presses the reset button 335 to rotate the reset arm 321 to the closing position by the reset rod 331. When the reset arm 321 is rotated to the closing position, the pressure slider 191 in contact with the reset arm 321 is pulled to move to the closing position. When the pressure slider 191 is moved to the input position, the latch member 211 is rotated to the input position by the elastic force of the latch member spring 219. When the latch member 211 is rotated to the input position, the pressure slider 191 is fixed to the input position, the trip slider 181 in contact with the latch member 211 is by the latch member 211 It is pressurized and moved to the feeding position so that a trip is possible.

In addition, while the reset plate 171 is rotated to the trip position, the bent end 174 presses the delay member 261 of the delay time output device 250 so that the delay member 261 is spaced apart from the switch 293. Rotate in the direction. At this time, the delay member spring 270 passes through the dead point to apply an elastic force in the direction in which the delay member 261 is spaced apart from the switch 251. On the other hand, when the main shaft 111 is rotated to the input position and the reset plate 171 is rotated to the input position, the reset plate 171 is rotated to the input position by the elastic force of the reset plate spring 178. The reset plate 171 has the set delay time after the fixed contact portion and the movable contact portion contact, and the delay member 261 contacts the contact portion 253 of the switch 251 so that the switch 251 The bent end 174 presses the first contact part 265 to output the detection signal to the outside. When the first contact portion 265 is in contact with the switch 251, the switch 251 outputs a signal. On the other hand, when the delay member 261 is rotated in the direction approaching the switch 251 by the action of an external force, as shown in Figure 6, the delay member 261 is the rounding member 266 Rotation is suppressed by contacting the bent end 174.

When the main shaft 111 is rotated to the input position, the reset plate 171 is rotated along the clockwise direction in the drawing by the elastic force of the reset plate spring 178. Then, the bent end 174 of the reset plate 171 rotates the rounding part 266 of the second contact part 268 upward in the drawing to rotate the delay member 261 in a direction away from the switch 251. Let's do it. At this time, due to the interaction between the bent end portion 174 and the rounding portion 266, the retardation member 261 has a resilient force of the retardation member spring 270 after passing through the dead point of the retardation member spring 270. 261 is rotated to act in a direction away from the switch 251. The bent end portion 174 of the reset plate 171 rotated past the rounding portion 266 continues to rotate to press the first contact portion 265 to rotate the delay member 261 to pass through the dead point. After the switch 251 is in contact with the fixed contact portion and the movable contact portion, the switch 251 may output a signal with a constant delay time. The delay member 261 is continuously rotated by the elastic force of the delay member spring 270 so that the first contact portion 265 contacts the contact portion 253 of the switch 251. The switch 251 outputs a signal to the outside when the first contact portion 265 contacts the contact portion 253.

On the other hand, when checking or replacing the overcurrent relay 131, if the overcurrent relay 131 is separated from the trip mechanism module 140, the working arm (285), the rotating shaft part by the accumulated elastic force of the elastic member 283 and the driving arm 287 are rotated at the same time. When the driving arm 287 is rotated, the driving protrusion is pressed to move the trip slider 181 below the case 141, and the opening and closing mechanism 117 of the opening and closing mechanism 117 is in contact with the trip slider 181. As a part is pressed, the restraint of the opening / closing mechanism 117 is released and the opening / closing mechanism 117 performs a trip operation.

1 is a perspective view of a circuit breaker having a tripping mechanism module according to an embodiment of the present invention;

2 is a view showing the inside of the circuit breaker of FIG.

Figure 3 is a side view of the installation state of the trip mechanism module of FIG.

4 is a perspective view of the tripping mechanism module of FIG.

5 is an exploded perspective view of the trip mechanism module of FIG. 4;

6 and 7 are views showing a state of use of the trip mechanism module of FIG.

8 is a perspective view of an area of the actuator of FIG. 3, FIG.

9 is a side view of the delay time output device of the tripping mechanism module of FIG. 5;

10 is a perspective view of a coupled state of the delay time output device of FIG. 9;

11 is a front view of the overcurrent relay interlocking trip device of the tripping mechanism module of FIG. 3;

12 is a side view for explaining the operation of the overcurrent relay interlocking trip device of FIG.

FIG. 13 is a front view illustrating an installation state of a trip signal output device of the trip mechanism module of FIG. 2.

Explanation of symbols on the main parts of the drawings

110: main body 111: main shaft

117: opening and closing mechanism 120: front cover

131: overcurrent relay 140: trip mechanism module

141 case 148: the first arm receiving portion

149: second arm accommodation portion 161: actuator

165: mover 167: operating part

171: reset plate 174: bending end

175: reset unit 178: reset plate spring

181: Trip Slider 187: Pressurized Rod

191: pressure slider 197: pressure slider spring

211: latch member 215: locking jaw

230: actuator set device 231: slider

237: buffer member 238: return arm

239: return spring 250: delay time output device

251 switch 261 delay member

270: delay member spring 280: overcurrent relay interlock trip device

283: rotating shaft 285: working arm

287 driving arm 289 elastic member

290: trip signal output device 293: switch

313: linkage member 319: contact piece

320: reset device 321: reset arm

331: reset load 335: reset button

337: reset rod spring

Claims (22)

It is arranged to be connected to the switchgear between an overcurrent relay for detecting an accidental current and outputting a trip signal, and an opening / closing mechanism connected to the main shaft to open and close the fixed contact portion and the movable contact portion, so as to provide a manipulation force when the trip signal is output. A tripping mechanism module which generates the tripping mechanism to perform a tripping operation; A case in which first and second arm accommodation portions are formed to accommodate the driving arms formed on the main shaft at different phase distances; An actuator accommodated inside the case to generate an operation force when outputting the trip signal of the overcurrent relay; A reset plate installed in the case and interlocked with the main shaft to initialize an output of the actuator; A trip mechanism module slidable in the case and connected to the opening and closing mechanism, the trip mechanism module including a trip slider for performing the trip operation during the trip operation of the actuator. The method of claim 1, The drive arm includes a reset plate drive arm in contact with the reset plate and a movable contact part drive arm connected to the movable contact part, wherein the reset plate drive arm is accommodated in the first arm receiving part and is movable contacted. The sub-drive arm is a tripping mechanism module characterized in that it is accommodated in the second arm receiving portion. The method of claim 1, And the driving arm is in contact with the reset plate and connected to the movable contact portion, wherein the driving arm is accommodated in the first arm receiving portion. The method according to any one of claims 1 to 3, And an actuator set device for returning the actuator to an initial position in association with the reset plate. The method of claim 4, wherein The actuator set device may include a slider disposed on one side of the reset plate and pressed and moved when the reset plate rotates, and one side rotates in contact with the slider, and the other side presses the actuator of the actuator to initialize the actuator. And a return arm for returning to the position. The method of claim 5, And the slider comprises a housing and a reset pin protruding with respect to the housing to contact the return arm. The method of claim 4, wherein And a delay time output device for outputting a signal having a set delay time after contacting the fixed contact part and the movable contact part in conjunction with the main shaft. The method of claim 7, wherein The delay time output device is arranged to be rotated in synchronization with the rotation of the main shaft between the switch and the switch disposed on one side of the main shaft, after contact with the fixed contact portion and the movable contact portion A delay member for operating the switch with a set delay time, one side of which is connected to the delay member to apply an elastic force in a direction in which the delay member is in contact with the switch when the main shaft rotates in the feeding direction; And a delay member spring for applying an elastic force to maintain the state of the delay member spaced apart from the switch when the blocking direction rotates. The method of claim 4, wherein And an overcurrent relay interlocking trip device for tripping the open / close mechanism in association with the detachment of the overcurrent relay. The method of claim 9, The overcurrent relay interlocking trip device includes a rotation shaft part rotatably installed in the trip mechanism module, an actuating arm projecting along a radial direction in one region of the rotation shaft part and contacting the overcurrent relay, and the other rotation shaft part. A driving arm which protrudes along the radial direction to the area and is rotated at the same time as the rotation shaft rotates to press the trip mechanism module to perform a tripping operation; Trip mechanism module comprising a. The method of claim 4, wherein And a trip signal output device for outputting a trip signal to the outside when the trip operation of the actuator is performed in conjunction with the actuator. The method of claim 11, The trip signal output device includes a switch for outputting a signal upon contact, and an interlocking member contacting the switch at a trip position of the trip slider in conjunction with the trip slider. The method of claim 12, And a reset device for returning the trip signal output device to an initial position. The method of claim 13, The reset device further includes a pressure slider configured to slide on one side of the trip slider in the case to press the trip slider to the trip position, and a pressurized slider spring to apply an elastic force to move the pressure slider to the trip position. And a reset arm disposed on one side of the pressure slider so as to be rotatable between a trip position and an input position to move the pressure slider to the input position. The method of claim 14, And the reset device further includes a reset rod protruding to be exposed to the outside from one side of the overcurrent relay in conjunction with the reset arm and returning the reset arm to the input position when pressurized. The method of claim 4, wherein A delay time output device for outputting a signal having a set delay time after contact with the fixed contact part and the movable contact part in conjunction with the main shaft, and an overcurrent relay for tripping the switching mechanism in conjunction with the detachment of the overcurrent relay; And a trip signal output device for outputting a trip signal to the outside when the trip operation of the actuator is performed in conjunction with the interlock trip device and the actuator. A blocking base body having a fixed contact portion and a movable contact portion, a main shaft, and an opening and closing mechanism for opening and closing the fixed contact portion and the movable contact portion in association with the main shaft and the movable contact portion therein; An overcurrent relay coupled to the blocking body to detect an accident current; A circuit breaker having a trip mechanism module comprising a trip mechanism module of any one of claims 1 to 3 interposed between the overcurrent relay and the switching mechanism. The method of claim 17, And an actuator set device for returning the actuator to an initial position in linkage with the reset plate. The method of claim 18, And a delay time output device for outputting a signal having a set delay time after contact with the fixed contact portion and the movable contact portion in association with the main shaft. The method of claim 18, And an overcurrent relay interlocking trip device for tripping the open / close mechanism in conjunction with the detachment of the overcurrent relay. The method of claim 18, And a trip signal output device for outputting a trip signal to the outside when the trip operation of the actuator is performed in conjunction with the actuator. The method of claim 18, A delay time output device for outputting a signal having a set delay time after contact with the fixed contact part and the movable contact part in association with the main shaft, and an overcurrent relay interlocking with the detachment of the overcurrent relay to trip the switching mechanism And a trip signal output device for outputting a trip signal to the outside when the trip device performs the trip operation of the actuator in conjunction with the trip device.

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