RU2378731C1 - Tripping module and automatic switch having said module - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: tripping module has a housing with first and second lever cavities into which actuating arms, which are on a main shaft with different interphase distances on the main shaft, enter; an actuating mechanism placed inside the housing and having an output portion stretched outside or stretched inside when an overcurrent relay sends a trip signal; a plate for returnint to the initial position fitted inside the housing for interacting with the main shaft to as to exert initial action on the output portion of the actuating mechanism; as well as a tripping slide-block having such a configuration that, it allows the switching mechanism to carry out a tripping operation. An automatic switch with such a tripping module provides for placing the module between the overcurrent relay and the switching mechanism.

EFFECT: more compact configuration and operational reliability of the tripping module, as well as possibility of its wide use in devices with different interphase distances.

29 cl, 16 dwg

Description

BACKGROUND OF THE INVENTION

1. The technical field

The present invention relates to a trip module and a circuit breaker with such a module, namely a trip module, which is used in devices having different interphase intervals. Moreover, the present invention relates to a circuit breaker where such a trip module is used.

2. The prior art

The so-called circuit breaker refers to an electrical protection device that is installed between an electrical energy source and load equipment to ensure protection of this load equipment and the power supply line from damage current (short circuit, excess current due to a case short to ground, etc.), which may occur in an electrical circuit.

The circuit breaker contains a switching mechanism for activating a fixed contactor and a movable contactor, an overcurrent relay for detecting fault current and opening command to block the supply of excess current, as well as an opening module located between the switching mechanism and overcurrent relay to create a mechanical control force when this overcurrent relay commands to open, and transfers this mechanical control force to the switching mechanism.

This circuit breaker also contains other devices for performing additional functions, such as the opening alarm function, which serves to inform the external operation of the opening module, and the signal time delay function, which allows the overcurrent relay to perform the MCR operation (opening switching flows).

However, in the circuit breaker of the prior art, different distances between each phase (for example, the R, S, T or N phase) according to the breaking capacity of each device makes it impossible to widely use the opening module.

In addition, since other devices to perform additional functions, such as an alarm function and a time delay function, must be installed in the main body of the circuit breaker, this main body of the circuit breaker may have an increased size and assembly of such devices requires more effort and time. And, in addition, since in this case it is required to ensure the synchronization and interaction of each such device, the operational reliability of such a circuit breaker is difficult to achieve.

SUMMARY OF THE INVENTION

Thus, based on the aforementioned problems of the prior art, an object of the present invention is to provide an opening module that can be used in other devices having different interphase distances, and also to provide a circuit breaker with such a module.

Another objective of the present invention is to provide a trip module that is compact in size and provides better operational reliability, as well as provide a circuit breaker with the same module.

To achieve these and other advantages and in accordance with the purpose of the present invention, which is described in detail in this text, a disconnecting module is proposed that is placed between the overcurrent relay and the switching mechanism, which serves to turn on and off the contactors connected to this switching mechanism and which creates a mechanical control power when the overcurrent relay gives an open signal to allow this switching mechanism to perform an open operation, while this open The second module contains: a housing having first and second recesses for levers, so that they include drive levers located with different interfacial distances on the main shaft, an actuator located in this housing and having an output section, pulled out or pulled inward when the relay the maximum current gives a trip signal, the reset plate installed in this housing to interact with the main shaft to have an initial effect on the output section spolnitelnogo mechanism as well as break the slider having such a configuration as to allow the switching mechanism to perform a trip operation when the actuator performs the trip operation.

These drive levers may include a drive lever of the reset plate located so as to contact this reset plate, and the drive levers of the movable contactor attached to this movable contactor. In this case, the drive lever of the reset plate can enter the first lever recess, and the drive levers of the movable contactor can enter the second lever recess.

The drive levers can be attached to the movable contactor, as well as come into contact with the return plate and be located in the first lever recess.

The disconnecting module may further comprise a unit for providing the actuator to its initial position for interacting with the reset plate to its initial position in order to return the actuator to its original position.

The unit for providing the actuator to its initial position may contain a slider located on one side of the reset plate to move during a rotational rotation of the reset plate, when one side of the reset lever is in contact with the slider so that rotate rotationally, and the second side presses the actuator pusher to return this actuator to its original position.

This slider may include a casing and a return pin protruding from this casing to contact the reset lever.

The actuator resetting unit may further comprise a cushioning element located between the resetting plate and the actuator pusher and subjected to compression after the actuator pusher is returned to its original position.

The isolating module may further comprise a time delay signal supply device cooperating with the main shaft and serving to supply a signal with a predetermined time delay after the fixed contactor and the movable contactor come into contact with each other.

This time delay signal supply device may comprise a switch located on one side of the main shaft, a shutter mechanism located between this main shaft and the switch to rotate in cooperation with the rotary main shaft and serve to control the time delay switch after as a fixed contactor and a movable contactor in contact with each other, as well as the spring of the time delay mechanism, one end of which is connected to this mechanism the shutter speed so that it can apply its elastic force in such a direction that this shutter mechanism is forced to come into contact with this switch when the main shaft rotates in the closing direction, and also apply this elastic force in that direction so that the mechanism can be held shutter speeds at a certain distance from the switch when the main shaft rotates in the opening direction.

The disconnecting module may further comprise a disconnecting device for interacting with the overcurrent relay, which performs this interaction when the overcurrent relay is disconnected, in order to ensure the switching mechanism opens.

This disconnecting device for interacting with the overcurrent relay may include a section of the rotary shaft rotationally mounted in this disconnecting module, a working arm extending radially from one area of this section of the rotary shaft to come into contact with the overcurrent relay, as well as a drive lever, extending from another region of this rotary shaft to rotate simultaneously with a given portion of the rotary shaft and thereby press the release module to release neniya opening operation, and an elastic member for applying an elastic force in such a direction that the resulting force operating lever enter into contact with the overcurrent relay.

The opening slider may be equipped with a drive protrusion protruding to contact the drive lever.

To direct the movement of the overcurrent relay in this housing, a guide portion can be made.

The opening module may further comprise an opening signal supply device cooperating with an actuator to provide an opening signal to the outside when the actuator performs the opening operation.

The opening signal supply device may include a switch for supplying a signal upon contact with it, and an intermediate interaction element interacting with the opening slide to come into contact with this switch when this opening slide is in the opening position.

The trip signal supply device may further comprise a contact element located between the intermediate interaction element and this switch.

The opening module may further comprise a resetting unit for returning the opening signal supply device to its initial position.

The release module may further comprise a push slide located on one side of the release slide so as to slide the release slide towards the release position when sliding, and also a release spring designed to create and apply elastic force to advance this push slide to the release position, then how the resetting unit may comprise a resetting lever located on one side of the pressure slide to have the ability to rotate between the opening position and the closing position, as well as move the pressure slider to the closing position.

The release module may further comprise a latch that rotates between the locking position in which it locks the pressure slider in the closing position and the released position in which the locked pressure slider is released, as well as a latch spring designed to apply elastic force to rotate the latch to the locking the position where the opening slider can be returned to the closing position with this latch when the pressure slider is in the opening position.

The resetting unit may further comprise a resetting pin protruding from one side of the overcurrent relay to the outside, and interacting with the resetting lever to the outgoing position and, when pressed, returning this returning lever to the closing position.

The resetting unit may further comprise a spring of the resetting pin intended to create an elastic force by which this resetting pin moves to the resetting lever.

The resetting unit may further comprise a resetting button set in such a way that one portion thereof is outside and the other portion is attached to the resetting pin.

The disconnecting module may further comprise a time delay signal supply device interacting with the main shaft to supply a signal with a predetermined time delay after the fixed contactor makes contact with the movable contactor, as well as a trip device for interacting with the overcurrent relay that implements this interaction when disconnecting this overcurrent relay to open the switching mechanism, and the device for supplying the opening signal, interaction operating with an actuator, for supplying an open signal when the actuator performs an open operation.

The circuit breaker, where such an isolating module is used, has a main body comprising a fixed contactor and a movable contactor, a main shaft, a switching mechanism interacting with this main shaft and a movable contactor to turn these fixed and movable contactors on or off, an overcurrent relay connected to the main body of this circuit breaker to detect a fault current, and wherein the aforementioned trip module is located between the overcurrent relay and The mechanisms of switching.

The circuit breaker may further comprise a unit for providing a return of the actuator to its initial position, which cooperates with the return plate to return the actuator to its original position .

The circuit breaker may further comprise a time delay signal supply device cooperating with the main shaft to supply a signal with a predetermined time delay after the fixed contactor makes contact with the movable contactor.

The circuit breaker may further comprise a disconnecting device for interacting with the overcurrent relay, which performs this interaction when the overcurrent relay is disconnected in order to open the switching mechanism.

The circuit breaker may further comprise an opening signal supply device cooperating with an actuator for supplying an opening signal to the outside when the actuator performs an opening operation.

The circuit breaker may further comprise a time delay signal supply device cooperating with the main shaft for supplying a signal with a predetermined time delay after the fixed contactor comes into contact with the movable contactor, as well as a trip device for interacting with the overcurrent relay that implements this interaction when disconnecting this overcurrent relay to open the switching mechanism, and the device for supplying the opening signal, inter operating with an actuator for supplying an opening signal to the outside when the actuator performs an opening operation.

The above and other objectives, features and advantages of the present invention will become more apparent from the following detailed description, followed by the corresponding drawings.

Brief Description of the Drawings

The accompanying drawings, which are included in this text for a better understanding of the present invention and form part of the present description, illustrate embodiments of the present invention and together with the description serve to explain the principles of the present invention.

In particular, these drawings show:

Figure 1 is an external perspective view of a circuit breaker having an opening module in accordance with one embodiment of the present invention;

2 is - inside view in perspective of the circuit breaker of Figure 1;

FIG. 3 is a side view of the circuit breaker of FIG. 1 with a trip module installed;

FIG. 4 is a perspective view of a trip module of FIG. 1;

FIG. 5 is a detail perspective view of a trip module of FIG. 1 ;

6 and 7 are perspective views, respectively, showing a certain stage of operation of the trip module of FIG. 3;

Fig. 8 is a perspective view showing a portion of the actuator of Fig. 3;

Fig.9 is a side view of the actuator of Fig.8;

Figure 10 is a schematic view serving to describe the operation of the actuator of Figure 8;

11 is a side view showing a time delay signal supply device related to the trip module of FIG. 5;

Fig. 12 is a perspective view showing the time delay signal supply device of Fig. 11 in an attached state;

FIG. 13 is a front view showing a trip device for interacting with a maximum current relay related to the trip unit of FIG. 3;

Fig. 14 is a side view showing the opening position in which the opening signal supply device of Fig. 3 is located;

Fig. 15 is a side view used to demonstrate the operation of the opening device for interacting with the overcurrent relay of Fig. 13;

FIG. 16 is a front view showing an in-state trip signal supply device related to the trip unit of FIG. 2.

DETAILED DESCRIPTION OF THE INVENTION

Hereinafter, a detailed description will be given of a trip module and a circuit breaker containing this module according to the present invention and with reference to the accompanying drawings.

As shown in FIGS. 1-3, a circuit breaker having a given opening module may comprise a main body 110 with fixed and movable contactors located inside it, a main shaft 111 and a switching mechanism 117 located between the movable contactor and the main shaft 111 to turn on or turn off these fixed and movable contactors, as well as the front surface panel 120 connected to the front surface of the main body 110, the overcurrent relay 131 connected to the front surface panel 120 so The reason is that its front surface is visible from the outside, and which serves to detect the fault current and give the trip signal (command), as well as the trip module 140, which has an actuator 161 that generates mechanical control force when the overcurrent relay 131 gives a signal opening to be able to join the main shaft 111 with different interfacial distances.

An opening 122 is made on the front surface panel 120, which serves for the external placement of the overcurrent relay 131. On the same front surface panel 120, an opening button 125 and a closing button 126 are also respectively located to manually turn the switching mechanism 117 on or off.

The isolating module 140 is installed at the rear side of the overcurrent relay 131. The switching mechanism 117 is located on one side of the isolating module 140 so as to perform the opening operation of the fixed contactor and the movable contactor in accordance with the opened command when an overcurrent relay fault current 131 is detected. .

As shown in FIGS. 4 and 5, the trip module 140 may include a housing 141 having first and second recesses 148 and 149 (see FIGS. 6 and 7), while these recesses are sized to receive the drive arms located on the main shaft 111 with different interfacial distances, as well as an actuator 161 located in the housing 141 to create a control force when the overcurrent relay 131 gives an open signal, and the reset plate 171 installed in the housing 141 to interact with the main shaft 111 with CE pour initiating action on the output section of the actuator 161, and the opening slider 181, which, being attached to the switching mechanism 117, slides along the housing 141 and serves to provide the operation of opening this switching mechanism 117 when the actuator 161 performs the opening operation.

The isolating module 140 may further comprise a time delay signal supply device 250 cooperating with the main shaft 111 to provide a time delay signal after the fixed contactor makes contact with the movable contactor, as well as a trip device 280 for interacting with the overcurrent relay, which carries out this interaction when disconnecting the overcurrent relay 131 to ensure that the switching mechanism 117 is opened, and the opening signal supply device 290, operating with an actuator 161 for supplying an opening signal to the outside when the actuator 161 performs an opening operation.

The housing 141 may comprise a main body part 142a having an open cavity and openings on its front side, and a housing cover 142b attached to the main body part 142a by a plurality of screws 143 to close the opening on the front side of this main body part 142a.

This main body part 142a may be equipped with guide sections 150 to slide overcurrent relay 131 when this overcurrent relay 131 is disconnected. On both side surfaces of the overcurrent relay 131, respectively, guide rails 133 (see FIG. 14) are arranged so as to slide into the guide sections 150.

The main shaft 111 may comprise a plurality of drive levers of the movable contactor for moving the movable contactor of each phase, separated by a distance from the other phase, to have different interphase distances, as well as a drive lever of the switching mechanism connected to the switching mechanism 117. As shown in FIG. 6, along a first main shaft 112a having a relatively small permissible current load (e.g., 2000 A) is spaced apart by a plurality of drive arms 113 of a movable contactor with a relatively short m zhfaznym distance L1. As shown in FIG. 7, along the second main shaft 112a having a relatively large permissible current load (for example, 4000 A), a plurality of actuating arms 113 of the movable contactor with a relatively long interfacial distance L2 are spaced.

In addition, the second main shaft 112b is configured such that the drive lever 114 of the reset plate is spaced apart from the drive levers 113 of the movable contactor due to its relatively long interphase spacing. The first main shaft 112a may not have any separate reset lever of the reset plate, since the drive levers 113 of the existing movable contactor control this movable contactor and the reset plate 171. Thus, the second recess 149 for receiving the lever is an unallocated space. A description will be given below as an example of a first main shaft 112a (hereinafter referred to as a main shaft 111) in which the drive lever of the reset plate and the drive arms of the movable contactor are combined with each other.

In the housing 141 are installed: an actuator 161, which creates a mechanical control force when the overcurrent relay 131 gives an open command, as well as a reset plate 171, rotated by rotation when interacting with the main shaft 111, to return to the initial position the operating section of the actuator mechanism 161.

As shown in FIGS. 8-10, the actuator 161 may include a stator 162 that produces magnetic force when it is under an energy load, a pusher 165 pushed by the magnetic force of the stator 162, and a spring 169 that creates an elastic force acting in that direction so that the pusher 165 inevitably extends. The stator 162 may include a casing 163 and a coil 164 located inside this casing 163. At one end of the actuator 161, an operation section 167 is installed that cooperates with the plunger 165. This operation section 167 consists of two parts, both of which protrude towards the return plate 171 in the initial position when the pusher 165 is in the extended position.

One end portion of the reset plate 171 is pivotally mounted on the pivot shaft 173, and a curved end portion 174 is formed on the other end portion of the reset plate 171, which drives the time delay signal supply device 250. Locking rings 176 are attached to both ends of the rotary shaft 173. On the lateral portion of the reset plate 171, at the end of the rotary shaft 173, there is a curved portion 175 of the reset lever that can press one of the working sections 167 of the actuator 161 to returning this actuator 161 to its original position.

Between the main shaft 111 and the actuator 161, a unit 230 is provided for providing a return of the actuator 161 to its initial position. The actuator resetting unit 230 may include a resetting plate 171 cooperating with the main shaft 111, a slider 231 located on one side of the plate 171 that is pressed to move when the resetting plate 171 is rotated, as well as a lever 238 return to its original position, in contact for rotary rotation at one end with a slider 231, while the other side presses the actuator pusher 165 mechanism 161 in order to bring this actuator 161 to its original position. The reset lever 238 can be provided with a return spring 239, which exerts its elastic force on the reset lever 238 to return it to its original position.

As shown in FIG. 9, the slider 231 may include a casing 233, a return pin 235 attached thereto to extend from or slide into this casing 233, and expanding or contracting the cushioning element 237 arranged in the casing 233 in the form of a compressible twisted springs for pressing the return pin 235 to push it out of the casing 233. The casing 233 is pressed when the reset plate 171 is rotated and guided by a guide portion made in the housing 141 com (not shown) so as to linearly move to the lever 238 return to its original position.

As shown in FIGS. 4 and 5, a lateral slider 181 is arranged in a longitudinal direction on the side portion of the housing 141 so as to slide between the locking position and the opening position. On one section of this opening slider 181, a receiving section 183 is made, which serves to enter some part of the switching mechanism 117 into it. Thus, being in the standby position, the switching mechanism 117 is protected from performing the opening operation. When the opening slider 181 is moved to the opening position, that part of the switching mechanism 117 that is in contact with the receiving portion 183 is pressed to move it and thus is released from the limiting obstacle. And accordingly, the switching mechanism 117 can immediately perform the opening operation. In the opening slider 181, an elongated guide slit 185 is formed, which includes guide pins 146 protruding from the side portion of the housing 141. One end portion of this opening slider 181 is in contact with the working portion 167. A pressure slider is located adjacent to one end of this opening slider 181. 191, which serves to push the movement of this opening slider 181 to the opening position.

An elongated guide slit 195 is formed in the pressure slide 191, which includes guide pins 146 protruding from the housing 141. A pressure slide spring 197 is attached to one end of this pressure slide 191, which creates an elastic force causing this pressure slide 191 to move towards the opening position. On this pressure slider 191, there is a contact portion 196, which is in contact with the opening slide 181 when pressed.

On one side of the push slide 191 is a latch 211, which serves to fix this push slide 191 in the closing position. This latch 211 is installed so that it can rotate between the position when it locks the given pressure slider 191 and the position when it releases the locked pressure slider 191. The latch 211 is rotated by rotation around the pivot shaft 213 passing through its central portion. On this rotary shaft 213 there is a washer 217 and retaining rings 218 that serve to fix the latch 211. At one end of this latch 211, a locking protrusion 215 is made, it enters and engages in the locking groove 193 made in the pressure slide 191. The other end of the latch 211 is in contact with the working portion 167 of the actuator 161. The latch 211 is equipped with a spring 219 , which serves to return this latch 211 to its original position. The latch 211 is pressed by the working part 167 to rotate to take the released position when the actuator 161 performs an opening operation. Accordingly, the pressure slider 191 can be moved to the opening position. And also, when the actuator 161 is returned using its corresponding control unit 230 to its initial position, the latch 211 moves the opening slider 181 to the opening position by the force generated by the spring 219 of this latch.

As shown in FIGS. 11 and 12, the time delay signal supply device 250 is used to perform the so-called MCR function (opening switching currents) in such a way that the overcurrent relay 131 sets a certain value of the current value to prevent a strong current from entering the load side, and determines the incoming current, so that in connection with the appearance of a strong current having a larger magnitude than a predetermined one, instantly open the circuit breaker. That is, in order for the overcurrent relay 131 to perform the MCR function, this relay must recognize two situations, namely the situation when the fault current is blocked (that is, the fixed contactor and the movable contactor are separated from each other) when the circuit breaker is closed, and the situation when the current faults are opened when the circuit breaker is closed (i.e. the fixed contactor and the movable contactor are in contact) on the line (or circuit) where the circuit breaker was opened due to the previous okopovrezhdeniya. In order to recognize these two situations, the time delay signal supply device 250 provides a constant time contact signal after the fixed contactor and the movable contactor come into contact with each other.

As shown in FIG. 11, the time delay signal supply device 250 may include a switch 251 located on one side of the main shaft 111 to turn the fixed contactor and the movable contactor on and off, as well as a time delay mechanism 261 located between the main shaft 111 and the switch 251 to rotate in conjunction with the rotation of the main shaft 111 and control the switch 251 with a predetermined time delay after the fixed contactor and the movable contactor come into contact with each other, and the same spring 270 of the time delay mechanism, one end of which is connected to the time delay mechanism 261 in such a way that it can direct its elastic force in such a direction that, as a result of its action, the exposure mechanism 261 is forced to come into contact with the switch 251 when the main shaft 111 rotates in the closing direction, and also use this elastic force to hold the holding mechanism 261 at a certain distance from the switch 251, when the main shaft 111 rotates in the opening direction.

Figure 5 shows the switch 251, which is installed in the housing 141, and the time delay mechanism 261, pivotally mounted on one side of this circuit breaker 251. A contactor 253 is located on one side of this switch 251 (see Figure 11). At the upper portion of the switch 251, a locking device 255 is made, which restricts the rotation of the shutter mechanism 261. The spring 270 of the shutter speed mechanism is attached to one side of this shutter mechanism 261.

The time delay mechanism 261 may include a rotary shaft 263 located close to the main shaft 111, a first contact portion 265 extending to one end from the rotary shaft 263 to come into contact with the switch 251, and a second contact portion 268 extending to the other end thereof a pivot shaft 263 and pivotable together with the first contact portion 265. This second contact portion 268 may include a rounded portion 266 to smoothly come into contact with the curved end portion 174 of the return plate 171 th position when the main shaft 111 is rotated in the rotation direction of the interrupter. In this example, when the holding mechanism 261, passing through the dead center of the spring by an external or other similar force, is rotated in a direction closer to the switch 251, the curved end portion 174 comes into contact with the rounded portion 266 so as to limit the rotary rotation of this shutter mechanism 261. In addition, this curved end portion 174 is made relative to this inclined time delay mechanism 261. It has such a configuration to always provide a constant time delay. To this end, when the main shaft 111 is rotated by rotation from the opening position to the closing position, the reset plate 171 is rotated by an elastic force emanating from the spring 178 of this return plate, which then contacts its curved end portion 174 with the rounded portion 266, which leads to the rotation of the shutter mechanism 261 in such a direction as to be at a certain distance from the switch 251.

The spring 270 of the time delay mechanism, which uses elastic force to rotate the exposure mechanism 261, is attached to one portion of this exposure mechanism 261, namely, the first contact portion 265. The spring 270 of the time delay mechanism exerts its elastic force in such a direction that this mechanism 261 the shutter enters into forced contact with the switch 251 when the main shaft 111 is in the closing position, while when applying this elastic force in the direction when as a result this holding mechanism 261 is held is located at a certain distance from the switch 251, because the holding mechanism 261 is rotated by passing through the dead center of the holding mechanism spring 270, the main shaft 111 is in the opening position.

FIG. 3 shows an opening device 280 for interacting with an overcurrent relay that is mounted on a rear side of an overcurrent relay 131 to provide an opening operation in which a fixed contactor and a movable contactor are separated from each other when interacting with the disconnection of the overcurrent relay 131.

As shown in FIGS. 13-15, the trip device 280 for interacting with the overcurrent relay may comprise a rotatable shaft portion 283 rotatably mounted in the trip unit 140, an operating arm 285 extending along a radial direction from one area of the rotary shaft portion 283 to contact overcurrent relay 131, a drive lever 287 extending from another region of the rotary shaft portion 283 to simultaneously rotate when the rotary shaft portion 283 is rotated so that, in accordance with by this action, press on the drive protrusion 188 of the opening slide 181, with which the pressing on the opening module 140 is performed to perform the opening operation, as well as the elastic element 289 to ensure that the elastic force acts in such a direction that the operating lever 285 is forced to come into contact with the maximum relay current 131.

Section 283 of the rotary shaft is rotary mounted on the front surface of the housing 141 of the trip module 140 and in the transverse direction relative to this housing 141. The operating lever 285, which protrudes in the radial direction from section 283 of the rotary shaft and is designed to provide contact with the overcurrent relay 131, is rotationally mounted in one area of section 283 of this rotary shaft. In another area of the pivot shaft portion 283, a drive lever 287 is formed. This drive lever 287 contacts the opening slide 181 to allow this opening slide 181 to move to the opening position.

To ensure contact with the drive protrusion 188 of the release slide 181, a drive lever 287 is provided so as to press on the release slide 181. An elastic element 289 is disposed on the rotary shaft portion 283 to apply elastic force in a direction such that the rotary shaft portion 283 comes into contact with the maximum current relay 131. This elastic element 289 accumulates elastic force when the overcurrent relay 131 is connected to it, and with the help of this accumulated elastic force, it rotates this actuating lever 287 when the overcurrent relay 131 is disconnected. Accordingly, the opening slider 181 is moved to the opening position, in which the movement of the switching mechanism 117 is activated to perform the opening operation.

On the other hand, to the lower region of the housing 141, screws 147 are screwed onto a PCB (printed circuit board) 144 connected to the overcurrent relay 131.

This printed circuit board 144 is equipped with a connector 145 (see FIG. 5) for connecting to the overcurrent relay 131. As shown in FIGS. 12 and 16, the trip signal input device 290 interacts with an actuator 161 used when the overcurrent relay 131 provides an open signal to an external display to indicate that the actuator 161 has performed an open operation.

The opening signal input device 290 of the isolating module 140 may include a switch 293 for supplying a signal upon reaching a contact, wherein the interaction element 313 is in contact with the switch 293 when the opening slider 181 is in the opening position.

The switch 293 is installed so that it enters on one side the actuator 161 in the housing 141, and the contacting contactors 295 are located on one side of the switch 293. The interaction element 313 may include a rotary shaft 315 and two lever sections 317 at its center extending into in different directions from the rotary shaft 315. These two lever sections 317 extend respectively to the switch 293 and to the opening slider 181. Between the contactors 295 and the interaction element 313 there is a contact element 319, which INH for the same pressure on the contactor 295. By disconnecting slider 181 moves pressure finger 187, which serves to provide clicking on the lever portion 317 interaction element 313 to provide rotation when disconnecting slider 181 is moved to the trip position.

On the other hand, as shown in FIGS. 14-15, on one side of the housing 141, a reset unit 320 is provided that serves to return to the initial position of the trip signal supply device 290. The resetting unit 320 relating to the trip signal supply device 290 may include a resetting lever 321, which is located on one side of the push slide 191 and which rotates between the open position and the closing position to be able to move this push the slider 191 to the closing position, as well as the pin 331 return to the initial position, protruding when interacting with the lever 321 return to the original position, while moving away from one Torons overcurrent relay 131 and by clicking the return lever 321 returning to the closing position.

The reset lever 321 may comprise a pivot shaft 323 and two lever sections 325 extending respectively in different directions from each other in its central portion. To attach this return lever 321 to the pivot shaft 323, retaining rings 327 and a washer 328 are used. The front end portion of the return pin 331 extends forward from the main circuit breaker housing 110. The return pin 331 is equipped with a spring 337, providing an impact on this return pin 331 by elastic force to move it to the reset lever 321. As shown in FIG. 1, at the front end portion of the return pin 331 there is a reset button 335 that acts on this return pin 331 when pressed. The reset lever 321 may be designed to be controlled by the engine. As well as the front end portion of the lever 331 return to its original position can be designed so as to have a direct exit to the outside.

With this configuration, when the overcurrent relay 131 gives an open command, the actuator 161 produces magnetic force when energy is supplied to the stator 162, and the pusher 165 extends under the influence of this magnetic force. When the plunger 165 is in the extended position, the working portion 167 interacts with it to move to the opening position. At this point, the latch 211 under the influence of the working section 167 is pressed to rotate to the released position.

When the latch 211 is rotated, the pressure slide 191 is moved to the opening position by the elastic force of the spring 197 of the pressure slide. Accordingly, the opening slider 181 is pressed to move to the opening position. This movement of the opening slide 181 to the opening position releases the switching mechanism 117 from its locked position by contacting the opening slide 181. Then, the switching mechanism 117 performs an opening operation, as a result of which the main shaft 111 is rotated to the opening position. Accordingly, the fixed contactor and the movable contactor are separated from each other. At the same time, when the release slide 181 is moved to the release position, the engagement member 313 in contact with the pressure pin 187 is pressed to rotate around the rotary shaft 315. The rotated engagement member 313 pushes the contact member 319. This pressed contact member 319 enters contact with the contactors 295 of the switch 293. And then the switch 293 provides an open signal.

When the main shaft 111 is rotated to the opening position, the reset plate 171 is rotated to the opening position by the drive lever 114 of the reset plate. According to the rotation of the reset plate 171, the slider 231 slides under the pressure of this plate 171. Then, the reset lever 238 is rotated by pressing the return pin 235 of the slider 231. This rotated reset lever 238 pushes the plunger 165 to return the actuator 161 to its original position. And when this pusher 165 is returned to its original position, the reset lever 238 stops turning, whereby the return pin 235 of the slider 231 also stops. In this state, if the casing 233 is pressed to move forward, the shock-absorbing element 237 is compressed to fulfill its depreciation function.

When the reset plate 171 is rotated to the opening position, this plate 171 contacts the operating portion 167 of the actuator 161, and accordingly, the operating portion 167 returns to its initial position.

In this case, since the opening slider 181 is locked by the pressure slide 191, this opening slider 181 is in the opening position in order to be able to prevent the closing of the opening slider. After the user has verified the cause of the opening, he presses the reset button 335 to rotate the reset lever 321 to the locking position using the reset pin 331. When the reset lever 321 is rotated to the locking position, the pressure slide 191 in contact with lever 321 return, extends up to move to the locking position. In accordance with the movement of the pressure slide 191 to the locking position, the latch 211 is rotated to the locking position by the elastic force of the spring 219 of this latch. When the latch 211 is rotated to the locking position, the pressure slider 191 is locked in the locking position and the opening slide 181 in contact with the latch 211 is pressed by the latch 211 to move to the locking position, thereby being in a state where it can be open.

While the reset plate 171 is rotated to the opening position, the curved end portion 174 presses on a mechanism 261 related to the time delay signal supply device 250. Then, this holding mechanism 261 is rotated in such a direction as to move a certain distance from the switch 293. In this case, the spring 270 of this holding mechanism passes through a dead center. Accordingly, the holding mechanism 261 applies its elastic force in such a direction as to move a certain distance from the switch 251. On the other hand, when the reset plate 171 is rotated to the locking position due to rotation to the locking position of the main shaft 111, this plate 171 is rotated rotation to the closing position using the elastic force of the spring 178 of the reset plate.

The curved end portion 174 of the reset plate 171 presses the first contactor 265 so that the holding mechanism 261 contacts the contactor 253 of the switch 251 with a predetermined time delay after the fixed contactor makes contact with the movable contactor to allow the switch 251 to be energized outward read signal. When the first contactor 265 comes into contact with the switch 251, this switch 251 gives a signal. Meanwhile, when the shutter mechanism 261 is rotated by an external or other similar force in such a direction as to move closer to the switch 251, the shutter mechanism 261 is blocked from rotational rotation due to contact between the rounded portion 266 and the curved end portion 174.

When the main shaft 111 is rotated to the locking position, the reset plate 171 rotates clockwise (in the drawing) under the influence of the elastic force of the spring 178 of the reset plate. Then, the curved end portion 174 of this plate 171 upwards raises the rounded portion 266 of the second contact portion 268 (in the drawing) to rotate the holding mechanism 261 in a direction further away from the switch 251. Then due to the interaction between the curved end portion 174 and the rounded by section 266, the holding mechanism 261 is rotated so that the spring 270 of this holding mechanism passes through a dead center, and thus, the elastic force of the holding mechanism spring 270 is applied to om direction that the shutter mechanism 261 moves a certain distance from the switch 251.

The curved end portion 174 of the initial position plate 171, rotated by the rounded portion 266, is continuously rotated to apply pressure to the first contact portion 265, thus turning the holding mechanism 261 to pass the blind spot. Accordingly, the switch 251 always has the ability to signal with a constant delay after the fixed contactor comes into contact with the movable contactor. The holding mechanism 261 continues to rotate due to the elastic force of the spring 270 of the holding mechanism, and accordingly, the first contact portion 265 comes into contact with the contactor 253 of the switch 251. And when this first contact portion 265 comes into contact with the contactor 253, the switch 251 sends a signal to the outside.

Meanwhile, after checking or replacing the overcurrent relay 131, when the overcurrent relay 131 is disconnected from the trip unit 140, the operating arm 285, the rotary shaft 283, and the drive arm 287 simultaneously rotate under the action of the accumulated elastic force of the elastic member 289. When the drive arm 287 it rotates, pressing is carried out on the drive protrusion 188, so that the opening slide 181 moves down along the housing 141. That part of the switching mechanism 117 that is in contact with the opening slide 181 is also exposed aetsya pressing to release the locked switching mechanism 117. Accordingly, the switching mechanism 117 performs the trip operation.

As described above, the present invention provides an isolating module that can be widely used for devices with different interphase distances, as well as a circuit breaker with such a module.

And also according to the present invention, those nodes that interact with the operation of the actuator and the main shaft after giving the opening command are located in one housing, so that they work in interaction with each other. Thus, a more compact configuration is achieved and greater reliability is achieved in the operation of the opening module and the circuit breaker having the same nodes, if we compare them with similar equipment of the previous level of technology, where the separate manufacture of each node leads to an increase in the number and size of these components, as well as to the need special device for ensuring the interaction in the work of these individual nodes, which reduces operational reliability and increases the overall size of this device a unit that requires more space to install.

In addition, the present invention proposes a trip module that is able to prevent electric shock and damage to nodes resulting from failure to open, and which allows you to perform the opening operation unifiedly, regardless of the intentions of the operator when disconnecting the overcurrent relay, which applies to the circuit breaker having the same nodes.

The present invention provides an isolating module that is able to prevent equipment malfunctioning due to mass vibration due to electric repulsive force or other similar force, and to increase equipment reliability by opposing the spring mass; the same applies to a circuit breaker having similar nodes.

The present invention also provides a trip module that is able to prevent component breakdown by providing the actuator with a return to its original position so that the great force possessed by the main shaft cannot be directly directed to the actuator; the same applies to a circuit breaker having the same components.

The present invention also provides an opening module that is capable of functioning without a separate circuit to support an opening signal, since it can provide a constant opening signal when the nodes of this module interact, the same applies to a circuit breaker having the same nodes.

In addition, the present invention also provides an opening module that provides a quick response in the event of a malfunction, enabling the user to instantly detect an open state of the device in which the actuator has already performed the opening operation if the button or reset pin protrudes forward.

The above embodiments and advantages of the present invention are exemplary herein and are not intended to limit the present description. The provisions of the present description can be easily applied to other types of devices and equipment. This description is intended to illustrate and not to limit the scope of the claims. One skilled in the art will recognize that the present invention may have many modifications and variations. Features, structural elements, methods and other characteristics of the embodiments illustrated herein may be combined in various ways to achieve additional and / or alternative illustrative embodiments.

Since the features of this invention can be embodied in various forms, without departing from the above characteristics, it should also be understood that the above embodiments are not limited to any particulars of the above description, unless otherwise indicated, but rather should be understood in their entirety the completeness of its scope limited by this claims, therefore, all changes and modifications falling within the limitations of this formula, or equivalents of such restrictions are considered covered and this claims.

Claims (29)

1. An isolating module placed between the overcurrent relay and the switching mechanism, used to turn on or off the contactors using this switching mechanism and to create a mechanical control force when the overcurrent relay gives an opening signal to allow the switching mechanism to perform an opening operation, while disconnect module contains:
a housing having first and second lever recesses made therein so that drive arms located on the main shaft with different interphase distances enter there;
an actuator located in this housing and having an output portion pulled out or pulled back when the overcurrent relay provides an open signal;
a return plate installed in this housing for interacting with the main shaft to have an initial effect on the output section of the actuator; and
an opening slider configured to allow the switching mechanism to perform an opening operation when the actuator performs an opening operation. 2. The module according to claim 1, in which the drive levers contain a drive lever of the reset plate in contact with this reset plate, and the drive levers of the movable contactor attached to this movable contactor, while the drive lever of the reset plate enters the first lever recess, and the drive levers of the movable contactor are included in the second lever recess. 3. The module according to claim 1, in which the drive levers are connected to the movable contactor, as well as in contact with the return plate to the initial position, and enter the first lever recess. 4. The module according to claim 1, additionally containing a block return to the initial position of the actuator, interacting with the return plate to return this actuator to its original position. 5. The module according to claim 4, in which the block return to the initial position of the actuator contains:
a slider located on one side of the return plate, and moved when pressed, when the return plate is rotated; and
a return lever in contact with one end with a given slider for making a turn, while the other side presses the actuator pusher to return the actuator to its original position. 6. The module according to claim 5, in which the slider includes a casing and a reset pin protruding from this casing to contact the reset lever. 7. The module according to claim 5, in which the return unit to the initial position of the actuator comprises a cushioning element that is located between the return plate and the actuator pusher and is compressed after the actuator pusher is returned to its original position. 8. The module according to claim 4, further comprising a time delay signal supply device cooperating with the main shaft for supplying a signal with a predetermined time delay after the fixed contactor and the movable contactor come into contact with each other. 9. The module of claim 8, in which the time delay signal supply device comprises:
a switch located on one side of the main shaft;
a time delay mechanism located between the main shaft and the circuit breaker to rotate in cooperation with the rotary main shaft and serve to control the circuit breaker with a predetermined time delay after the fixed contactor and the movable contactor come into contact with each other; and
the spring of the time delay mechanism, one end of which is connected to this exposure mechanism in order to be able to apply its elastic force in such a direction that this time delay mechanism contacts the switch when the main shaft rotates in the closing direction, and also apply this elastic force direction so that the holding mechanism can be held at a certain distance from the switch when the main shaft rotates in the opening direction. 10. The module according to claim 1, additionally containing a disconnecting device for interacting with the overcurrent relay, performing this interaction when disconnecting this overcurrent relay to ensure that the switching mechanism opens. 11. The module of claim 10, in which the disconnecting device for interaction with the overcurrent relay contains:
a section of the rotary shaft rotationally mounted in this disconnect module;
a working lever extending radially from one area of this section of the rotary shaft to come into contact with the overcurrent relay;
a drive lever extending from another region of this portion of the rotary shaft to rotate simultaneously with this portion of the rotary shaft, thereby pressing the release module to perform the opening operation; and
an elastic element designed to exert an elastic force in such a direction as to result in forcing the operating arm to come into contact with the overcurrent relay. 12. The module according to claim 11, in which the opening slider is provided with a drive protrusion, which protrudes for contact with the drive lever. 13. The module according to claim 10, according to which in the main body there is a guide portion serving to guide the overcurrent relay. 14. The module according to claim 1, further comprising an opening signal supply device cooperating with an actuator to provide an opening signal to the outside when the actuator performs an opening operation. 15. The module of claim 14, wherein the opening signal supply device comprises:
a switch designed to provide a signal upon contact with it; and
an interaction element interacting with the opening slider to come into contact with the switch when this opening slider is in the opening position. 16. The module of claim 15, wherein the opening signal supply device further comprises a contact element located between the interaction element and the switch. 17. The module according to clause 15, further comprising a resetting unit for returning the opening signal supply device to its initial position. 18. The module according to 17, further comprising:
a pressure slider located on one side of the opening slider, so that when sliding with the pressure to direct this opening slider to the opening position;
the spring of the opening slider, designed to apply elastic force to move this pressure slide to the opening position;
wherein the resetting unit comprises a resetting lever located on one side of the pressure slide so as to be able to pivot between the opening position and the closing position, and also be able to move the pressure slide to the locking position. 19. The module of claim 18, further comprising:
a latch that rotates between the locking position in which it locks the pressure slider in the closing position and the released position in which the locked pressure slider is released; and
a latch spring designed to apply elastic force to rotate the latch to a locking position;
wherein the opening slide returns to the closing position with this latch when the pressure slide is in the opening position. 20. The module of claim 18, wherein the resetting unit further comprises a resetting pin that projects when interacting with the resetting lever from one side of the overcurrent relay to the outside and, when pressed, returns this returning lever to the closing position . 21. The module according to claim 20, in which the resetting unit further comprises a spring of the resetting pin intended for applying elastic force by which this resetting pin moves to the returning lever. 22. The module according to claim 20, in which the unit for returning to the initial position further comprises a button for returning to the initial position, set in such a way that one of its sections is located outside and the other section is attached to the reset pin. 23. The module according to claim 1, additionally containing:
a time delay signal supply device cooperating with the main shaft to supply a signal with a predetermined time delay after the fixed contactor makes contact with the movable contactor;
a disconnecting device for interacting with the overcurrent relay, which interacts when this overcurrent relay is disconnected to open the switching mechanism;
an opening signal supply device cooperating with an actuator for supplying an opening signal to the outside when the actuator performs an opening operation. 24. A circuit breaker having an isolating module, comprising:
a main circuit breaker housing comprising a fixed contactor and a movable contactor, a main shaft, a switching mechanism cooperating with this main shaft and a movable contactor to turn these fixed and movable contactors on or off;
overcurrent relay connected to the main body of the circuit breaker to detect fault current;
wherein the disconnecting module according to any one of claims 1 to 3 is located between the overcurrent relay and the switching mechanism. 25. The circuit breaker according to paragraph 24, further comprising a unit for providing a return of the actuator to its initial position, which interacts with the return plate to return the actuator of the trip module to its original position. 26. The circuit breaker of claim 25, further comprising a time delay signal supply device cooperating with the main shaft to provide a signal with a predetermined time delay after the fixed contactor makes contact with the movable contactor. 27. The circuit breaker according to claim 25, further comprising a disconnecting device for interacting with the overcurrent relay, which performs this interaction when the overcurrent relay is disconnected to open the switching mechanism. 28. The circuit breaker of claim 25, further comprising an opening signal supply device cooperating with an actuator for supplying an opening signal to the outside when the actuator performs an opening operation. 29. The circuit breaker of claim 25, further comprising:
a time delay signal supply device cooperating with the main shaft for supplying a signal with a predetermined time delay after the fixed contactor comes into contact with the movable contactor;
a disconnecting device for interacting with the overcurrent relay, which performs this interaction when the overcurrent relay is disconnected in order to open the switching mechanism; and
an opening signal supply device cooperating with an actuator for supplying an opening signal when the actuator performs an opening operation.

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