KR20180076833A - Isolation mechanism of controller for circuit breaker - Google Patents

Abstract

The present invention provides an isolation device of a controller for a circuit breaker, which is simple in structure and capable of quickly manipulating connection/isolation of a power source. The isolation device of a controller for a circuit breaker according to the present invention includes: a fixed contact electrically connected to a terminal of the circuit breaker; a movable contact movable between a first position in contact with the fixed contact and a second position separated from the fixed contact and electrically connected to a control unit; an insulating operating member for transmitting operational force from a user and having an electrical insulation property; a first link linearly movable in accordance with the motion of the insulating operation member; a lever mechanism rotatable in accordance with the linear movement of the first link; and a second link which is connected to the movable contact, receives power from the lever mechanism to vertically move, and converts the rotational power of the lever mechanism into a linear movement to transfer the force of the linear movement to the movable contact.

Description

[0001] ISOLATION MECHANISM OF CONTROLLER FOR CIRCUIT BREAKER [0002]

The present invention relates to a circuit breaker, and more particularly, to a separator for separating a control unit for a DC circuit breaker from a power source.

A DC circuit breaker, for example, a DC circuit breaker (abbreviated as a DC air circuit breaker or DC ACB) is a control unit. An overcurrent relay (commonly referred to as an OCR) (Voltage) between the positive terminal and the negative terminal of the circuit, that is, the DC potential difference (voltage) between the positive and negative terminals connected to the power source side of the circuit, or between the positive and negative terminals connected to the load side of the circuit, Used as power source.

In such a DC air circuit breaker, the overcurrent relay is usually electrically connected to the terminal to receive the DC power. In the insulation test for the DC air circuit breaker, a very large current, for example, 2500A (amperes) It is necessary to electrically isolate (isolate) the relay from the terminal.

Therefore, in such a test, the overcurrent relay, which is a control unit, is electrically isolated (separated) from the terminal. Normally, the means for electrically connecting the terminal to the terminal to supply the DC power, that is, the selective ON / OFF means, Is required.

An example of the isolation device for the control unit for the DC circuit breaker will be described with reference to FIGS. 1 and 2. FIG.

The isolation device of the control unit for the DC circuit breaker according to the related art is a device having a width of about 10 cm and a length of about 10 cm.

The isolator of the controller for the DC circuit breaker according to the prior art includes a pin-type fixed contact 13, a movable contact 11c, a clip 11d for a movable contact, a threaded shaft 11a, A support nut 12, and an operation end 11b.

The pin-type fixed contact 13 is formed of an electric conductor and is electrically connected to a terminal (not shown) of the DC circuit breaker.

The movable contactor 11c is movable in accordance with the movement of the spiral shaft 11d which is formed of an electric conductor and is connected to the spiral shaft 11d to move forward or backward, And a second position electrically disconnected from the pin-type fixed contact 13.

The movable contactor 11c can be electrically connected to a control unit for an unshown DC circuit breaker, that is, an overcurrent relay, for example, through a power supply line.

The movable contact clip 11d is formed of an electric conductor and is coupled to the movable contact 11c so as to be movable along with the forward or backward movement of the movable contact 11c, And is movable to a position separated from the pin-type fixed contact 13.

The helical axis 11d may be formed of an electrically insulating material such as a synthetic resin material and is advanced or retracted through the support nut 12 as it is helically engaged with the support nut 12 and rotates clockwise or counterclockwise.

The support nut 12 may also be formed of an electrically insulating material such as a synthetic resin material and is helically engaged with the helical axis 11d and supports the helical axis 11d.

The operation end portion 11b is a portion that provides the operation portion for allowing the user to move the spiral shaft 11d and is coupled to the opposite end of the spiral shaft 11d on the side connected to the movable contact 11c .

The operating end 11b may be provided with, for example, a "+" type driver connection groove to which a screw driver can be connected.

The operation of the isolator of the control unit for the DC circuit breaker according to the above-described prior art will be described.

First, the operation from the isolation state (OFF state) shown in Fig. 1 to the connection state (ON state) shown in Fig. 2 will be described.

When the screwdriver is connected to the operating end 11b in the isolated state (also referred to as the separated state or OFF state) as shown in Fig. 1 and the user operates the operating end 11b in the clockwise direction, The combined spiral shaft 11d advances while rotating.

When the user further manipulates the operation end 11b in the clockwise direction through the screw driver, the spiral shaft 11d further advances and the movable contactor clip 11d of the movable contact 11c is moved to the pin fixed contact 13 2, which are in contact with each other. This completes the operation of the isolator from the isolated state (OFF state) to the connected state (ON state).

Next, the operation from the connection state (ON state) shown in Fig. 2 to the isolated state (OFF state) shown in Fig. 1 will be described.

When a screw driver is connected to the operating end 11b in a connected state (also referred to as an ON state) as shown in Fig. 2 and the user operates the operating end 11b counterclockwise, The combined spiral shaft 11d is rotated and retracted.

When the user further manipulates the operation end 11b in the counterclockwise direction through the screwdriver, the spiral shaft 11d further retracts and the movable contactor clip 11d of the movable contactor 11c contacts the pin fixed contact 13 which are separated from each other. This completes the operation of the isolator from the connected state (ON state) to the isolated state (OFF state).

However, in the isolator of the control unit for a DC circuit breaker according to the related art, the spiral axis 11d must be rotated due to the distance that the spiral axis 11d must be moved backward to ensure insulation between the fixed contact and the movable contact Is relatively large and the time required is relatively short.

In addition, the isolator of the control unit for the DC circuit breaker according to the above-described prior art is inconvenient to operate by using a tool such as a screwdriver.

In addition, the isolator of the controller for the DC circuit breaker according to the related art has a complicated structure such as a support nut and a spiral shaft as well as an unshown outer casing.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a control circuit for a circuit breaker which is capable of operating a connection / Of the present invention.

It is an object of the present invention to provide an isolator for a control section for a circuit breaker,

A fixed contact electrically connected to a terminal of the circuit breaker;

A movable contact movable to a first position contacting the fixed contact and a second position separated from the fixed contact, the movable contact electrically connected to the control unit for the circuit breaker;

An insulating operating member for transmitting an operating force from a user and having electrical insulation;

A first link coaxially connected to the insulating operation member and linearly movable in accordance with the motion of the insulating operation member;

A lever mechanism that receives power of the first link moving linearly and is rotatable in accordance with a linear movement of the first link; And

And a second link which is connected to the movable contact and receives power from the lever mechanism so as to be vertically movable so as to convert the rotational power of the lever mechanism into linear movement and transmit the linear power to the movable contact, Can be achieved by providing an isolator of the control unit.

According to a preferred aspect of the present invention, the isolator of the control section for a circuit breaker according to the present invention further comprises at least one supporting member for supporting the first link in a linearly movable manner.

According to another preferred aspect of the present invention, the isolator of the control section for the circuit breaker according to the present invention further comprises at least one guide member for linearly guiding the second link.

According to another preferred aspect of the present invention, the insulating operation member has a screw portion on the outer surface, and the support member includes a screw support portion screwed with the screw portion.

According to another preferred embodiment of the present invention, the threaded portion is formed of a threaded hole portion provided on a front cover of the control portion.

According to another preferred aspect of the present invention, the lever mechanism is characterized in that the lever mechanism comprises: a rotatable lever shaft; A first lever which is connected to one end of the lever shaft and extends toward the first link so as to receive power from the first link and is rotatable together with the lever shaft in accordance with a linear movement of the first link; A second lever that is connected to the lever shaft at one end and extends toward the second link to transmit power to the second link and that transmits power to the second link while rotating in accordance with the rotation of the first lever; ; A center coil portion wound around a portion of the lever shaft between a portion to which the first lever is connected and a portion to which the second lever is connected, a first end supported by the positionally fixed spring support member, And a torsion spring including a second end supported by a spring support protrusion provided on the first lever and transmitting the rotational power of the first lever to the second lever.

According to another preferred aspect of the present invention, the first link includes a power transmitting projection, and the other end of the first lever contacts the power transmitting projection to receive power.

According to another preferred aspect of the present invention, the second link has the power reception protrusion, and in order to receive the power for moving the second link, the power reception protrusion contacts the other end of the second lever .

According to another preferred embodiment of the present invention, the isolator of the controller for the circuit breaker according to the present invention comprises: a stationary support member for providing a fixed base on which the spring support member is installed; And a return spring which is supported by the second link at one end thereof and is supported by the fixed support member and which applies an elastic force to return the movable contact to the first position via the second link.

According to another preferred aspect of the present invention, the spring support member is constituted by a support protrusion fixedly mounted on the fixed support member.

According to another preferred aspect of the present invention, the insulating operating member is composed of an insulating screw member and is rotatable.

According to still another preferred aspect of the present invention, the insulated operating member is composed of an insulated button member and is linearly movable as the user presses it.

The isolator of the control unit for a DC circuit breaker according to the present invention is movable to a first position which is in contact with the stationary contact and a second position which is separated from the stationary contact electrically connected to the terminal of the DC circuit breaker And a movable contact electrically connected to the control unit for the circuit breaker, so that power from the power source of the circuit or the terminal connected to the load side can be supplied to or blocked from the circuit breaker control unit, and the operation force from the user is transmitted A first link which is coaxially connected to the insulated operation member and is linearly movable in accordance with the movement of the insulated operation member; A lever mechanism connected to the first link and capable of pivoting in accordance with a linear movement of the first link; And a second link which is connected to the movable contact and receives power from the lever mechanism so as to be vertically movable so as to convert the rotational power of the lever mechanism into linear movement and transmit it to the movable contact, The lever mechanism and the second link can transmit the operation force from the user to the movable contact to provide power to the control unit or isolate the control unit from the power source.

The isolation device of the control unit for the DC circuit breaker according to the present invention further includes at least one support member, so that the effect that the first link can be linearly supported by the support member can be obtained.

Since the isolator of the control unit for the DC circuit breaker according to the present invention further includes at least one guide member, the second link can be guided linearly movably.

In the isolating device for a control part for a DC circuit breaker according to the present invention, the insulating operation member has a screw part on the outer surface, and the support member includes a screw supporting part screwed to the screw part, When the insulated operation member is turned, the first link coaxially connected to the insulated operation member can move forward or backward.

In the isolator of the control part for a DC circuit breaker according to the present invention, the screw support part is composed of a screw part provided on a front cover of the control part, so that it is casted with an electrically insulating material such as a synthetic resin material, The screw supporting portion can be easily formed by simply screwing the front cover of the control portion, so that the screw supporting portion can be easily constructed.

In the isolator of the control unit for a DC circuit breaker according to the present invention, the lever mechanism may include a lever shaft, a first lever, a second lever, and a torsion spring, Can be switched to the rotation of the lever shaft and the first lever, and the second lever can be transmitted through the torsion spring to rotate the second lever.

In the isolator of the control unit for a DC circuit breaker according to the present invention, the first link includes a power transmitting protrusion, and the other end of the first lever contacts the power transmitting protrusion for receiving power, Can receive power to pivot while being contacted and pressed against the power transmitting projection of the first link.

In order to receive the power for moving the second link, the power receiving protrusion is provided on the second lever so as to receive the power from the second lever. In order to receive the power for moving the second link, So that the second link can receive power for vertical movement from the second lever which contacts and presses the power receiving projection.

Since the isolator of the control unit for circuit breaker according to the present invention further includes a fixed support member and a return spring whose one end is supported by the second link and the other end is supported by the fixed support member, When the movable contact is separated from the fixed contact by the movement of the second link due to the external force, the elastic force of the return spring returns to the first position where the movable contact contacts the fixed contact when the external force is lost It is possible to obtain an effect of returning automatically.

In the isolator of the controller for a circuit breaker according to the present invention, since the spring support member is constituted by a support protrusion fixedly installed on the fixed support member, an effect of supporting one end of the torsion spring on the support protrusion Can be obtained.

In the isolator of the control section for a circuit breaker according to the present invention, since the insulated operation member is constituted by an insulated screw member and is rotatable, there is an effect that the insulated operation member can be operated in a state in which the user is electrically safely protected, There is an effect that it can be obtained by the turning operation of the insulating operation member.

In the isolator of the control unit for a circuit breaker according to the present invention, the insulated operation member is constituted by an insulated button member and is linearly movable as the user presses it, There is an effect that the operation member can be operated and the drive force can be obtained by the linear drive according to the pressing operation of the insulated operation member, so that the isolation device can be driven promptly.

FIG. 1 is a diagram showing the configuration and operation of a isolator of a control unit for a DC circuit breaker according to the related art, and is an operational state diagram showing an operation state in an isolated state (separated state, an OFF state)
FIG. 2 is a diagram showing the configuration and operation of the isolation device of the control unit for the DC circuit breaker according to the related art, and is an operational state diagram showing a connection state (also referred to as an ON state)
FIG. 3 is a view showing an installation state of a circuit breaker main body of the present invention, in which the isolator of the control unit for the circuit breaker of the present invention is installed. FIG. 3 is a perspective view of the circuit breaker main body viewed obliquely from above,
4 is a side view showing the configuration of the isolator of the controller for the circuit breaker according to the preferred embodiment of the present invention,
5 is a vertical cross-sectional view showing a detailed structure of a fixed contact among the isolators of the controller for a circuit breaker according to a preferred embodiment of the present invention,
6 is a partial longitudinal cross-sectional view showing a detailed configuration of an insulation operation member and a first support member among the isolation devices of the control unit for a circuit breaker according to a preferred embodiment of the present invention,
FIG. 7 is a partially enlarged view showing a detailed configuration of a second supporting member of the isolator of the control unit for a circuit breaker according to the preferred embodiment of the present invention,
8 is a side view of a lever mechanism showing a detailed configuration of a lever mechanism of an isolator of a controller for a circuit breaker according to a preferred embodiment of the present invention.

The above and other objects, features and advantages of the present invention will become more apparent from the following detailed description of the present invention when taken in conjunction with the accompanying drawings.

3, the circuit breaker main body 100 includes a switching mechanism 110, a closing spring discharge handle 111, an opening / closing main shaft 112, a soot mechanism 113, an overcurrent relay 120, an electromagnetic trip device 130, and a controller isolation device 140. [

The opening / closing mechanism 110 is provided with a circuit breaker, a circuit breaker, a circuit breaker, a circuit breaker, A trip spring, a plurality of links and levers, and the like.

The closing spring bushing handle 111 is a manual operation handle for accumulating elastic energy in the closing spring for driving the circuit breaker to the closing position. The manual bushing handle 111 includes a rachet wheel, A power transmission mechanism such as a spopper, a shaft, or a cam may be provided.

The opening / closing main shaft 112 is provided as a shaft for simultaneously driving and opening a plurality of movable contacts commonly connected to the opening / closing main shaft 112.

The SOHO mechanism unit 113 includes a plurality of grids, an arc barrier having a plurality of outlets, and the like as a mechanism for arc extinguishing an arc generated between the contacts when the circuit is shut down Lt; / RTI >

When the overcurrent relay 120 detects an abnormal state of the current flowing in the circuit (for example, a state of occurrence of an overcurrent or a shortcircuit current) as a control unit of the circuit breaker as described above, And a function of outputting a control signal (magnetizing control signal).

The electromagnetic trip device 130 includes a coil magnetizing or demagnetizing according to whether the excitation control signal is applied from the overcurrent relay 120 and an output part driven by excitation of the coil For example, a plunger, a return spring for returning the plunger to its original position when the coil element is turned on, and the like.

Although not shown in FIG. 3, a plurality of terminals, which can be electrically connected to the power supply side and the load side, of the DC power circuit (DC circuit), respectively, are provided on the power supply side and the load side, respectively, on the rear surface of the circuit breaker main body 100 . The plurality of terminals may each be composed of a bus bar made of a conductive metal, for example, as is well known.

3, the front surface of the overcurrent relay 120 is exposed at the front of the circuit breaker main body 100, and thus the electromagnetic trip device 130 is installed at the rear of the overcurrent relay 120.

3 and 4, the controller isolator 140 may be installed on the sides of the overcurrent relay 120 and the electromagnetic trip device 130 according to the preferred embodiment of the present invention.

4, the isolator of the controller for the circuit breaker according to the preferred embodiment of the present invention, that is, the controller isolator 140 includes a fixed contact 141, a movable contact 142, An insulating operating member 143, a first link 144, a lever mechanism 145, and a second link 146.

4, the stationary contact 141 may be fixedly mounted on the upper side of one side of the electromagnetic trip device 130. As shown in FIG.

According to a preferred embodiment, a supporting base plate SB for supporting the main components of the controller isolation device 140 may be fixedly installed on one side of the electromagnetic trip device 130, 141 may be fixedly mounted on the upper portion of the support substrate SB by fixing means such as a fixing screw.

 The fixed contact 141 is electrically connected to the circuit breaker, that is, the terminal provided on the rear surface of the circuit breaker main body 100.

According to a preferred aspect of the present invention, the stationary contact 141 can be constituted by a spring contact in which the contact portion is supported by a buffer spring.

4, the stationary contact 141 can be configured to include the contact portion 141a, the buffer spring 141b, the cylinder portion 141c, and the contact support portion 141d have.

Reference numeral 141c1 denotes a contact base portion connected to the cylinder portion 141c and having a cross-sectional area larger than that of the cylinder portion 141c. The contact point receiving portion 141c1 is naturally formed of an electrically conductive material and is supported by the contact supporting portion 141d and fixed in position.

The contact portion 141a is a portion of the fixed contact 141 that directly contacts the movable contact 142. The contact portion 141a may be formed of a conductive material and a pair of the movable contact 142 facing the movable contact 142 may be provided.

5, the contact portion 141a has a vertical cross-sectional shape of "T" shape and includes a base portion 141a1 and a leading end portion 141a2.

The base portion 141a1 is large in diameter and is positioned in the cylinder portion 141c and supported by the buffer spring 141b so as to be movable up and down in the cylinder portion 141c.

 The tip portion 141a2 is a columnar portion extending from the center of the base portion 141a1 and is smaller in diameter than the base portion 141a1 and is provided so as to be movable in and out of the cylinder portion 141c.

The buffer spring 141b is provided in the cylinder portion 141c and can be constituted by a compression spring according to a preferred embodiment. The buffer spring 141b is supported by the base portion 141a1 of the contact portion 141a which is supported by the contact base portion 141c1 whose upper end portion is fixed and the lower end portion is movable.

The buffer spring 141b applies an elastic force to the contact portion 141a downwardly or in the direction toward the movable contact 142. When the movable contact 142 contacts the contact portion 141a of the fixed contact 141 The shock applied to the contact portion 141a is buffered. The buffer spring 141b has a function of buffering the contact portion 141a and a function of returning the contact portion 141a to the initial position (the position protruding toward the movable contact) when the movable contact 142 is separated Lt; / RTI >

The cylinder portion 141c is a housing portion for housing the contact portion 141a and the buffer spring 141b therein.

The cylinder portion 141c is provided at its lower center with a through hole allowing the front end portion 141a2 of the contact portion 141a to penetrate and move.

The upper portion of the cylinder portion 141c is blocked by the contact point receiving portion 141c1.

The contact supporting portion 141d may be formed by molding an artificial resin material according to a preferred embodiment and may include a terminal portion (not shown) connected to an external electric wire, And a conductor connecting portion for electrically connecting the base portion 141c1.

The contact supporting portion 141d may be fixed to the outer wall surface of the electromagnetic trip device 130 by a fixing means such as a fixing screw according to a preferred embodiment.

The movable contact 142 is movable to a first position where it contacts the stationary contact 141 and a second position which separates from the stationary contact 141. [

The movable contact 142 is electrically connected to the controller for the circuit breaker, that is, the overcurrent relay 120.

The movable contact 142 can supply DC power from the terminal located on the rear surface of the DC circuit breaker main body 100 to the overcurrent relay 120 at a first position in contact with the fixed contact 141. [

The movable contact 142 can cut off the DC power supply to the overcurrent relay 120 at a second position separated from the fixed contact 141. [

4, the movable contact 142 may be configured to include the contact portion 142a and the contact support portion 142b.

The pair of contact portions 142a may correspond to the contact portions 141a of the stationary contact 141.

The contact supporting portion 142b may be formed by casting an artificial resin material according to a preferred embodiment as a portion for supporting the contact portion 142a and may include a terminal portion (not shown) connected to an external electric wire And a conductor connecting portion (not shown) for electrically connecting the terminal portion and the contact portion 142a.

The insulating operation member 143 has electrical insulation as a means for transmitting operation force from the user.

According to a preferred embodiment of the present invention, the insulating operation member 143 is constituted by an insulating screw member and is rotatable. That is, the insulating operation member 143 may be formed by casting an artificial resin material having electrical insulation, and the outer side surface may be a screw surface.

According to a preferred aspect of the present invention, the control unit isolation device 140 for a circuit breaker according to the present invention further includes at least one support member for linearly movably supporting the first link 144.

Wherein the support member may include a first support member 147 and a second support member 148,

When the insulated operating member 143 is constituted by an insulated screw member, the first supporting member 147 may be constituted by a screw supporting portion screwed to the threaded portion of the insulating operation member 143.

According to one preferred aspect of the present invention, the first support member 147 may include a front cover (see reference numeral 121 in FIG. 3) of the control section, that is, the overcurrent relay 120, As shown in Fig.

Generally, the front cover 121 is made by molding an artificial resin material having electrical insulation. The first support member 147 is formed by simply tapping a screw hole in the conventional front cover 121 .

Further, when the insulating operation member 143 is constituted by an insulating screw member, the insulating operation member 143 is rotatable.

According to another preferred embodiment of the present invention, the insulated operating member 143 is composed of an insulated button member and is linearly movable as the user presses it.

The first link 144 is coaxially connected to the insulating operation member 143 and is linearly movable in accordance with the motion of the insulating operation member 143.

The outer diameter of the first link 144 is formed to be smaller than the inner diameter portion of the first support member 147 where the threaded surface of the first link 144 is formed, The adjacent tip end 144a can penetrate the inner diameter portion of the first support member 147 without contacting the inner diameter portion of the first support member 147 as the insulating operation member 143. [

The first link 144 and the insulating operation member 143 may be connected to each other by a connecting member such as a connecting pin not shown. For example, the distal end portion of the first link 144 is inserted into the insertion groove portion provided at the rear end of the insulating operation member 143, and the connection pin is connected to the rear end of the insulating operation member 143 and the rear end of the first link 144 The connection assembly of the first link 144 and the insulating operation member 143 can be accomplished by penetrating the tip end portion and pressing both ends of the connection pin.

According to a preferred embodiment, the rear end 144b of the first link 144 is formed smaller in diameter than the tip end 144a.

The second support member 148 is installed at a predetermined position to allow the rear end 144b of the first link 144 among the outer wall surfaces of the electromagnetic trip device 130 to pass therethrough.

According to a preferred embodiment, the second support member 148 may be composed of a pair of rubber rollers 148b which are installed at upper and lower positions facing each other as can be seen from Fig. 7, One roller (upper roller) of the pair of rollers 148b is fixed to a fixed support member 152 fixed on the outer wall surface of the electromagnetic trip device 130, that is, And the other roller (lower roller) can be rotatably supported by a shaft 148a1, and the other roller (lower roller) can be supported by a predetermined one of the outer wall surfaces of the electromagnetic trip device 130, Can be rotatably supported by the second lever shaft 148a2.

The distance between the pair of rollers constituting the second support member 148 is greater than the diameter of the rear end 144b of the first link 144 and the distal end 144a of the first link 144 Or may be configured to be larger by a predetermined clearance.

The rear end 144b of the first link 144 is movable without touching the pair of rollers constituting the second support member 148 during the forward and backward linear movement of the first link 144, The leading end 144a of the second supporting member 144 can be guided smoothly without contacting or contacting with the pair of rollers constituting the rotating second supporting member 148. [

According to a preferred embodiment of the present invention, a predetermined one of the rear end portions 144b of the first link 144 is connected to the lever mechanism 145 by the power of the first link 144, The power transmitting protrusion 149 is provided for transmitting the power transmission protrusion 149 to the power transmission protrusion 149.

In a configuration in which the power of the first link 144 is directly transmitted to the lever mechanism 145 according to another embodiment, that is, in the configuration in which the first link 144 and the lever mechanism 145 are directly connected, The protrusion 149 is unnecessary since it is unnecessary.

The power transmitting protrusion 149 is integrally formed with the first link 144 by embossing or is formed of a member such as a bolt nut and is connected to the first link 144 separately from the first link 144 Can be installed and provided.

The power transmitting projections 149 can be linearly moved together with the linear movement of the first link 144. [

The lever mechanism 145 is installed at a position capable of directly or indirectly receiving the power of the first link 144 moving linearly so as to receive the power of the first link 144 that moves linearly, It is rotatable in accordance with the linear movement of the arm 144.

4, the lever mechanism 145 includes a lever shaft 145a, a first lever 145b, a second lever 145c, and a torsion spring 154 .

One end (the other end not visible in Fig. 4) of the lever shaft 145a can be supported by the supporting substrate SB so as to be rotatable. More specifically, the one end of the lever shaft 145a is inserted through the support substrate SB, for example, by inserting a pin or a rivet in the direction crossing the penetrating portion of the lever shaft 145a, Can be prevented.

 The lever shaft 145a can coaxially support the first lever 145b, the second lever 145c, and the torsion spring 154 at different positions on the respective axes.

According to a preferred embodiment, a first lever 145b is provided at a portion nearest to an end portion of the lever shaft 145a shown in Fig. 4, The second lever 145c may be installed at a position closest to the one end of the torsion spring 154 that is farthest from the visible end and not visible in FIG.

The first lever 145b is extended toward the first link 144 so that one end is connected to the lever shaft 145a and the other end receives power from the first link 144. [ Here, the other end of the first lever 145b is provided as a free end.

According to a preferred embodiment, the first lever 145b is rotatable together with the lever shaft 145a in accordance with the linear movement of the first link 144 so that the other end can contact the first link 144. [

According to a preferred embodiment, the first lever 145b contacts the power transmitting protrusion 149 provided at the other end of the first link 144, And is rotatable together with the lever shaft 145a by the pressing of the projection 149. [

4, the first link 144 is linearly moved in the leftward direction, and the other end of the first lever 145b, which is the free end, is connected to the first link 144 through the power transmitting protrusion 149 provided on the first link 144 When pushed, the first lever 145b rotates clockwise together with the lever shaft 145a.

The second lever 145c has one end connected to the lever shaft 145a and the other end extended toward the second link 146 to transmit power to the second link 146. [ Wherein the other end is provided as a free end.

According to a preferred embodiment, the second link 146 is provided with the power reception protrusion 150, and in order to receive the power for the movement of the second link 146, the power reception protrusion 150 2 lever 145c.

The other end of the second lever 145c is in contact with the power reception protrusion 150 and transmits power to the power reception protrusion 150 while rotating in accordance with the rotation of the first lever 145b.

Therefore, the second lever 145c can move the second link 146 while rotating in accordance with the rotation of the first lever 145b.

Like the power transmitting protrusion 149, the power receiving protrusion 150 is integrally formed with the second link 146 by embossing or is formed of a member such as a bolt nut, 2 link 146, as shown in FIG.

According to a preferred embodiment, the second lever 145c has a spring support protrusion 145c1 for supporting one end of the torsion spring 154. [

The torsion spring 154 includes a center coil portion 154a, a first end 154c and a second end 154b.

According to a preferred embodiment, the center coil portion 154a is wound around a portion between the portion of the lever shaft 145a to which the first lever 145b is connected and the portion to which the second lever 145c is connected .

The center coil portion 154a is installed in close contact with the outer circumferential surface of the lever shaft 145a and can rotate in the same direction together with the rotation of the lever shaft 145a.

According to one preferred embodiment, the first end 154c is supported by a position-fixed spring support member 152a. The spring support member 152a may be a support protrusion protruding from the fixed support member 152 toward the front so as to support the second end 154c of the torsion spring 154. [

According to a preferred embodiment, the second end 154b is supported by a spring support protrusion 145c1 provided on the second lever 145c.

 When the first link 144 is moved forward (that is, leftward in FIG. 4) by the user turning the insulating operation member 143 clockwise, the first link 144 is coupled to the rear end 144b of the first link 144 The power transmitting protrusion 149 presses the first lever 145b and rotates clockwise.

Then, according to the clockwise rotation of the first lever 145b, the lever shaft 145a also rotates in the clockwise direction, and the central coil portion 154a of the torsion spring 154 also rotates clockwise.

Therefore, the first end 154b of the torsion spring 154 also rotates in the clockwise direction and rotates the second lever 145c clockwise through the spring support protrusion 145c1.

At this time, the second end 154c of the torsion spring 154 is not moved by the spring support member 152a of the fixed support member 152 which is fixed in position.

4, the second link 146 is connected to the movable contact 142 and is vertically movably received by the lever mechanism 145 and is connected to the movable contact 142 .

The second link 146 converts the rotational force of the lever mechanism 145, in particular, the second lever 145c of the lever mechanism 145, into linear motion and transmits it to the movable contact 142. The movable contact 142 can move to the first position or the second position by the power from the second link 146 connected thereto.

The controller isolation device 140 according to the present invention may further include at least one guide member 153 for guiding the second link 146 in a linearly movable manner.

Here, the guide member 153 may be formed of a block having a rectangular cross-section according to an embodiment in which the guide member 153 is fixed to an outer wall surface of a predetermined position in an outer wall surface of the electromagnetic trip device 130, And a rubber roller that is rotatable around the shaft. And may also be configured as various modified embodiments that perform the function of guiding the second link 146 in a linearly movable manner.

4, the control unit isolation device 140 according to the present invention may further include a fixed support member 152 and a return spring 151. As shown in FIG.

The fixed support member 152 may be fixedly mounted on a support substrate SB provided at a predetermined position on the outer wall surface of the electromagnetic trip device 130, that is, on the outer wall surface of the electromagnetic trip device 130. [

The fixed support member 152 is composed of, for example, a block having a square cross-sectional shape, and may be fixedly mounted on the support substrate SB by a fixing means such as a fixing screw, for example.

The stationary support member 152 may provide means for at least partially supporting the second support member 148 as described above and may include means for supporting one end of the return spring 151 directly or through another element .

According to a preferred aspect of the present invention, the return spring 151 has one end supported by the second link 146 and the other end supported by the fixed support member 152, (142) to return to the first position.

According to a preferred aspect of the present invention, the return spring 151 is composed of a compression spring that stores elastic energy in a compressed state.

That is, when the user retracts the first link 144 by operating the insulating operation member 143 to resume the power supply to the control unit, i.e., the overcurrent relay 140, The pressing force of the second lever 145c applied to the link 146 disappears, so that the compressed return spring 151 expands the elastic energy accumulated while moving the second link 146, thereby moving the second link 146 upward. Therefore, as the second link 146 moves upward due to the elastic force of the return spring 151, the movable contact 142 connected to the second link 146 contacts the corresponding fixed contact 141 1 position.

The operation of the isolator of the controller for the circuit breaker according to the preferred embodiment of the present invention will now be described with reference to FIGS. 3 to 8. FIG.

An operation of interrupting the power supply to the overcurrent relay 120 during the insulation test at the first position where the movable contact 142 is in contact with the fixed contact 141 will be described.

In the case of the embodiment in which the insulating operation member 143 is constituted by an insulating screw member, the user grasps the insulating operation member 143 or inserts a screwdriver into the driver insertion groove portion provided in the insulating operation member 143, 143 in the clockwise direction.

In the case of the embodiment in which the insulating operating member 143 is constituted by the insulating button member, the user presses the insulating operating member 143.

4, the first link 144 coaxially coupled to the insulating operation member 143 is moved forward by a forward movement distance of the insulating operation member 143, that is, And moves linearly in the left direction in Fig.

The power transmitting protrusion 149 provided at the rear end 144b of the first link 144 presses the first lever 145b of the lever mechanism 145 to push it to rotate it clockwise.

Then, the lever shaft 145a also rotates in the clockwise direction, and the central coil portion 154a of the torsion spring 154 also rotates clockwise.

8, the first end 154b of the torsion spring 154 is also rotated in the clockwise direction, and the second lever 145c is rotated clockwise through the spring support protrusion 145b1 .

The second lever 145c that rotates in the clockwise direction presses the power reception protrusion 150 downward and the second link 146 linearly moves downward in accordance with the guide of the guide member 153. [

At this time, the return spring 151 compresses and charges elastic energy.

At this time, the movable contact 142 connected to the second link 146 moving downward moves to the second position separated from the fixed contact 141, and is fixed according to the movement of the movable contact 142 to the second position. The power supplied from the contact 141 to the overcurrent relay 120 through the movable contact 142 is cut off.

Therefore, the overcurrent relay 120 can be electrically isolated (isolated) from the terminal, thereby protecting the overcurrent relay 120 from a large current applied to the terminal during the insulation test.

On the other hand, for example, when the DC power supply is resumed to the overcurrent relay 120 after the insulation test, the user grasps the insulation operation member 143 or inserts a screwdriver into the driver insertion recess provided in the insulation operation member 143 , The insulating operation member 143 is rotated counterclockwise.

In the case of the embodiment in which the insulating operating member 143 is constituted by the insulating button member, the user releases the insulating operating member 143 without pressing the insulating operating member 143.

4, the first link 144 coaxially coupled to the insulating operation member 143 by the retreat movement distance of the insulating operation member 143 is moved in the direction Backward, that is, moves linearly in the right direction in Fig.

The power transmitting protrusion 149 provided at the rear end 144b of the first link 144 releases the first lever 145b of the lever mechanism 145 which is being pressed.

Then, the lever shaft 145a also rotates counterclockwise, and the central coil portion 154a of the torsion spring 154 also rotates counterclockwise.

8, the first end 154b of the torsion spring 154 also rotates counterclockwise, so that the pressing force applied to the spring support protrusion 145b1 is lost.

At this time, the compressed return spring 151 is elongated and discharges the elastic energy.

Therefore, the second link 146, to which the one end is connected, is linearly moved in accordance with the guide of the guide member 153.

At this time, the movable contact 142, which is connected to the second link 146 that moves up, moves to the first position where it contacts the fixed contact 141, and when the movable contact 142 moves to the first position, Supply of DC power from the contact 141 to the overcurrent relay 120 via the movable contact 142 is resumed.

As described above, the isolator of the control unit for a circuit breaker according to the present invention includes a fixed contact electrically connected to a terminal of a circuit breaker, a first position contacting the fixed contact, The movable contact can be moved to the second position and is electrically connected to the control unit for the circuit breaker, so that power from the power source of the circuit or the terminal connected to the load side can be supplied to or blocked from the control unit for the circuit breaker. In accordance with another aspect of the present invention, there is provided an isolation device for a control unit for a DC circuit breaker, including: an insulation operation member that transmits an operation force from a user and has electrical insulation; A first link coaxially connected to the insulating operation member and linearly movable in accordance with the motion of the insulating operation member; A lever mechanism connected to the first link and capable of pivoting in accordance with a linear movement of the first link; And a second link which is connected to the movable contact and receives power from the lever mechanism so as to be vertically movable so as to convert the rotational power of the lever mechanism into linear movement and transmit it to the movable contact, The lever mechanism and the second link can transmit the operation force from the user to the movable contact to provide power to the control unit or isolate the control unit from the power source.

11a: Spiral shaft 11b: Operation end
11c: Operation contactor 11d: Clip for operation contactor
13; Pin type fixed contactor 12: support nut
100: DC circuit breaker main body 110: opening / closing mechanism
111: closing spring discharge handle 112: opening / closing main shaft
113: Loop section 120: Overcurrent relay
130: Electromagnetic trip device 140: Control isolator
141: fixed contact point 142: movable contact point
143: Insulation operating member 144: First link
145: lever mechanism 146: second link
147: first support member 148: second support member
149: power transmitting projection part 150: power receiving projection part
151: return spring 152: fixed support member
153: guide member

Claims (12)

In the isolator of the control section for circuit breaker,
A fixed contact electrically connected to a terminal of the circuit breaker;
A movable contact movable to a first position contacting the fixed contact and a second position separated from the fixed contact, the movable contact electrically connected to the control unit for the circuit breaker;
An insulating operating member for transmitting an operating force from a user and having electrical insulation;
A first link coaxially connected to the insulating operation member and linearly movable in accordance with the motion of the insulating operation member;
A lever mechanism that receives power of the first link moving linearly and is rotatable in accordance with a linear movement of the first link; And
And a second link which is connected to the movable contact and receives power from the lever mechanism so as to be vertically movable so as to convert the rotational power of the lever mechanism into a linear movement and transmit it to the movable contact, Device. The method according to claim 1,
Further comprising at least one supporting member for linearly movably supporting the first link. ≪ RTI ID = 0.0 > 21. < / RTI > The method according to claim 1,
Further comprising at least one guide member for guiding the second link in a linearly movable manner. 3. The method of claim 2,
Wherein the insulating operation member has a threaded portion on an outer surface thereof,
Wherein the support member includes a screw support portion that is screwed with the screw portion. 5. The method of claim 4,
Wherein the screw supporting portion is formed of a threaded hole portion provided on a front cover of the control portion. The method according to claim 1,
The lever mechanism includes:
A pivotable lever shaft;
A first lever which is connected to one end of the lever shaft and extends toward the first link so as to receive power from the first link and is rotatable together with the lever shaft in accordance with a linear movement of the first link;
A second lever that is connected to the lever shaft at one end and extends toward the second link to transmit power to the second link and that transmits power to the second link while rotating in accordance with the rotation of the first lever; ; And
A center coil portion wound around a portion of the lever shaft between a portion to which the first lever is connected and a portion to which the second lever is connected, a first end supported by the positionally fixed spring support member, And a torsion spring including a second end supported by the provided spring supporting protrusion and transmitting the rotational power of the first lever to the second lever. The method according to claim 6,
The first link includes a power transmitting projection portion,
And the other end of the first lever is in contact with the power transmission protrusion to receive the power. The method according to claim 6,
The second link has a power reception protrusion,
And the power reception protrusion is in contact with the other end of the second lever in order to receive the power for moving the second link. The method according to claim 6,
A stationary support member for providing a fixed base on which the spring support member is installed; And
And one end of the return spring being supported by the second link and the other end being supported by the fixed support member and applying an elastic force to return the movable contact to the first position via the second link. The isolator of the control section for the circuit breaker. 10. The method of claim 9,
Wherein the spring support member comprises a support protrusion fixedly installed on the fixed support member. The method according to claim 1,
Wherein the insulating operation member is composed of an insulating screw member and is rotatable. The method according to claim 1,
Wherein the insulated operation member is composed of an insulated button member and linearly movable according to a user's pressing.

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