KR102088395B1 - hammer link type circuit breaker - Google Patents

Abstract

The present invention provides a hammer link-type circuit breaker which is able to have a simplified constitution, rapidly block a flow of current when an overcurrent occurs, and improve driving reliability. According to the present invention, provided is a hammer link-type circuit breaker which comprises: a housing unit in which a power input unit and a load output unit are arranged on a front side and a rear side to be apart from each other; an operation switching unit which is arranged between the power input unit and the load output unit, and in which a front end unit is connected to the power input unit by a contact point but is selectively apart from the power input unit by providing an elastic restoring force upwards, and a rear end unit side is electrically connected to the load output unit; a crossbar in which a passing unit is formed on one side to be open to allow a front end side of the operation switching unit to cross, and which is elastically supported upwards through an elastic means arranged on a lower end unit; a trip unit which is arranged on a rear surface side of the crossbar, rotates around a lower end unit forward and backward, and has an inclination end bump protruding forward from a front surface unit; a latch unit in which a front end unit is arranged on an upper surface of the crossbar to face the upper surface, and a rear end unit comes in contact with and is supported by an upper surface of the inclined end bump to allow the power input unit and the operation switching unit to be connected to each other by a contact point, thereby pressurizing the crossbar downwards; a handle unit which is joined with the housing unit to be operated to rotate forward and backward, and in which a pressurizing member is connected to a lower end unit to rise and fall to pressurize the latch unit downwards in accordance with the rotating direction; and an absorption rotor made of magnetic materials, in which a hinge unit is arranged on a lower end unit to be elastically supported in an access direction, the trip unit is hit through an inertia absorbed and rotated in a direction of blocking around the hinge unit by an absorption magnetic force generated in the operation switching unit when an overcurrent occurs, and a hammer is linked to an upper end unit to make the latch unit, which pressurizes the crossbar, move backward to be apart from the inclined end bump.

Description

Hammer link type circuit breaker

The present invention relates to a hammer link type circuit breaker, and more particularly, to a hammer link type circuit breaker with improved driving reliability by quickly blocking the flow of current when an overcurrent occurs while the configuration is simplified.

In general, the circuit breaker prevents damage to electrical products and lines connected to the load side by rapidly switching the opening and closing operation of the electric line when an overcurrent exceeding a set value or a short circuit occurs in the circuit to block the flow of current. Device. Such a circuit breaker is driven by manual or automatic operation, and preferably can be operated to automatically short circuit the current when an overcurrent occurs.

Here, in the related art, a bimetal type circuit breaker using a property in which two metal plates having different thermal expansion coefficients are attached and bend to a smaller thermal expansion rate when heat due to overcurrent is applied. In a bimetal circuit breaker, when a current is supplied to a circuit, a resistance is generated to heat the bimetal, and when an excess current of a certain level or more flows, the bimetal is bent and drives a trip portion that is in close contact. In addition, the contact terminal coupled to the lower portion of the bimetal is driven with a structure in which the flow of current is cut off by being separated from the input terminal.

However, the conventional bimetal type circuit breaker has a problem in that it does not immediately cut off the current and is delayed due to the time during which the bimetal is deformed. Moreover, as the speed at which the current is cut off is relatively delayed, there is a problem in that the components inside the circuit breaker as well as the electrical products connected to the load side and the line may be damaged.

Accordingly, in some cases, a circuit breaker of an image current transformer method that controls a trip bar to be driven through a signal transmitted when an overcurrent occurs is disclosed. However, such a video current transformer type circuit breaker has a problem in that the manufacturing cost and the manufacturing cost of the circuit breaker itself increase because it includes complicated and expensive parts such as the video current transformer, solenoid part, and printed circuit board. In addition, since complicated parts are densely installed inside the breaker, manufacturing difficulty increases, and there is a problem in that malfunction occurs due to excessively adjacent parts.

Korean Utility Model No. 20-0341427

In order to solve the above problems, the present invention is to solve the problem of providing a hammer link type circuit breaker with improved driving reliability by quickly blocking the flow of current when an overcurrent occurs while the configuration is simplified.

In order to solve the above problems, the present invention, the power input unit and the load output unit is provided with a housing spaced apart at the front and rear sides; A movable switching unit disposed between the power input unit and the load output unit, the front end being contact-connected to the power input unit, providing elastic recovery force to the upper side so as to be selectively spaced, and the rear end side being electrically connected to the load output unit. ; A crossbar formed on one side via a transverse opening which is opened such that the front end side of the movable switching portion is transverse, but supported by an elastic means provided at the lower end, and supported by a cross bar; A trip unit disposed on the rear side of the crossbar and rotated back and forth around the lower end portion, but with an inclined step forward protruding toward the front portion; A front end portion facing the upper surface of the crossbar, but a rear end portion in contact with the upper surface of the inclined step so that the power input portion and the movable switching portion are in contact with each other; a latch portion for pressing the crossbar downward; A handle unit coupled to the housing unit to be rotated back and forth, and a pressing member connected to the lower end to move upward and downward to press the latch unit downward according to a rotation direction; And a hinge portion provided at the lower end and supported in the connection direction, and when the overcurrent occurs, the crossbar is pressed by hitting the trip portion through an inertia that is sucked and rotated in the blocking direction around the hinge portion by the suction magnetic force generated in the movable switching portion. A hammer for retracting the latch portion so as to be spaced apart from the inclined step includes a suction rotor made of a magnetic material linked to an upper end portion, wherein the suction rotor extends backward from the hinge portion and is spaced apart from the upper surface of the movable switching portion. A suction extension portion, a link extension portion extending upward from the hinge portion and having a link fastening portion in which a link shaft is laterally fastened at the upper end, and a link groove portion in which the link shaft is loosely fitted so as to be inertialy rotated in the link fastening portion, and A striking portion extending in a tangential direction from the outer periphery of the link groove portion Provides a hammer link-type breaker characterized in that it comprises the hammer to hereinafter.

Through the above solutions, the hammer link breaker according to the present invention provides the following effects.

First, when the suction rotor is first sucked and rotated toward the magnetizing face portion that is magnetized when an overcurrent occurs, the linked hammer is loosely fitted on the upper side, and the linked hammer is rotated at a high speed and secondly inertial at a high speed through the inertia. A circuit breaker with a faster current blocking speed than a bimetal bent through resistance heat can be provided.

Second, when the position of the hitting projection is rotated to the rear side than the link shaft by inertia, the force of hitting the hitting guider through its own load increases as the center of gravity of the hammer moves to the rear side, so the tripping section is retracted clearly in the blocking direction. The additionally reliably spaced apart from the sloped step can significantly improve the reliability of the cut-off operation.

Third, when the suction magnetic force of the magnetization facing part disappears due to the interruption of the current, the suction rotor is pushed upward and rotated as if the suction rotor bounces through the recovery force of the return spring, and the hammer increases and the acceleration through inertia increases and rotates together, but from the link extension Since the return angle is limited through the forwardly protruding stopper parts, it can be accurately returned to the initial position.

Fourth, when the suction rotor rotates, the trip part is retracted through the blow of the hammer due to inertia, and the current is cut off in a simple way that the latch part supported on the front side is physically released. Therefore, expensive parts such as a video current transformer are not required. Therefore, the manufacturing cost can be reduced and the number of parts is minimized, so that the economic efficiency through the compactness of the product can be significantly improved.

1 is a perspective view showing a state where the cover of the hammer link type circuit breaker according to an embodiment of the present invention is separated and exposed inside.
Figure 2 is a perspective view showing the coupling state of the components except the housing portion in the hammer link type circuit breaker according to an embodiment of the present invention.
Figure 3 is an exploded perspective view of the suction rotor provided in the hammer link type circuit breaker according to an embodiment of the present invention.
Figures 4a and 4c is an exemplary view showing the operating state of the hammer link breaker according to an embodiment of the present invention.

Hereinafter, a hammer link type circuit breaker according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view showing a state in which the cover of a hammer link type circuit breaker according to an embodiment of the present invention is separated, and FIG. 2 is a configuration except for a housing part in a hammer link type circuit breaker according to an embodiment of the present invention It is a perspective view showing the coupling state of the parts, 3 is an exploded perspective view of the suction rotor provided in the hammer link type circuit breaker according to an embodiment of the present invention, Figures 4a and 4c is a hammer link according to an embodiment of the present invention It is an exemplary diagram showing the operating state of the type breaker. At this time, it is preferable to understand the hammer link breaker and the breaker to be described below in the same sense. In addition, Figures 4a to 4c is preferably understood that the illustration of the electric wire and the load output unit is omitted.

1 to 4c, the hammer link type circuit breaker 200 according to an embodiment of the present invention includes a housing part 10, a movable switching part 220, a crossbar 230, a trip part 240, It includes a latch part 50, a handle part 60 and a suction rotor 270.

In detail, the housing part 10 includes an internal space in which components of the circuit breaker 200 are accommodated, and is preferably formed of an insulating and non-combustible synthetic resin material. A partition partition wall, an installation groove, or a hole is formed inside the housing part 10 so that each component is installed and assembled. Here, the front side of the housing portion 10 is provided with a power input unit 11 connected to the power supply side, a rear side is provided with a load output unit 12 connected to the load side, and the power input unit 11 has a fixed contact unit ( 13) is provided.

In addition, the movable switching unit 220 is disposed between the power input unit 11 and the load output unit 12.

In detail, the movable switching unit 220 includes a magnetization facing portion 223 in which the front end portion is adjacent to the fixed contact portion 13 but extends rearward. Here, the front end portion of the magnetizing face portion 223 is provided with a movable contact portion 225 that is in contact with the fixed contact portion 13. That is, the movable switching unit 220 is preferably understood to include the magnetization facing portion 223 and the movable contact portion 225 provided on the front end side thereof. At this time, the magnetization-facing portion 223 is preferably formed of a conductive metal material that provides elastic recovery force so that the movable contact portion 225 is in contact with the fixed contact portion 13 so as to be energized and selectively spaced apart. Moreover, the magnetization-facing portion 223 is preferably formed of a metal material that has conductivity while being magnetized through an electric current.

In addition, the rear end side of the magnetizing face portion 223 is electrically connected to the load output portion 12 through the electric wire 15. Therefore, when the front end portion of the magnetization facing portion 223 is pressed downward, the fixed contact portion 13 and the movable contact portion 225 are contacted, and the power input unit 11, the movable switching unit 220, A current flows through the wire 15 and the load output section 12.

Meanwhile, the crossbar 230 is provided to press the front end of the movable switching unit 220 downward. Here, the crossbar 230 is provided on the front end side of the movable switching unit 220, the transit portion 231 is formed so as to cross the front end of the movable switching unit 220. At this time, it is preferable to understand that the front end portion of the movable switching portion 220 is substantially pressed as the front end portion of the magnetization facing portion 223 is pressed. The crossbar 230 is pressurized to the lower side by the pressing force applied from the upper side, but is supported by the upper side through the elastic means 233 provided in the lower portion.

In detail, in the normal state, the force to which the crossbar 230 is pressed downward acts more than the elastic force of the elastic means 233. Therefore, the state in which the crossbar 230 is pressed downward is maintained, and the elastic means 233 is compressed. Then, the front end portion of the movable switching portion 220 disposed across the light oil portion 231 is bent and pressed downward. Through this, the movable contact portion 225 is contacted with the fixed contact portion 13. At this time, when an overcurrent occurs or the force pressing the crossbar 230 through operation of the handle unit 60 is lost, the crossbar 230 is moved upward by the elastic restoration force of the elastic means 233. At the same time, since the pressing force used to press the movable switching unit 220 is lost, the movable contact unit 225 is spaced apart from the fixed contact unit 13 as the magnetized face unit 223 is unfolded through the elastic restoration force.

On the other hand, the trip portion 240 is disposed on the rear side of the crossbar 230, and is provided to be rotated back and forth around a pivoting end portion 240a formed at the lower end. At this time, an inclined stepped portion 241 is protruded forward on the front portion of the trip portion 240. In addition, the latch portion 50 has a front end portion 50a facing the upper surface of the crossbar 230 and a rear end portion 50b extending to a length facing the front portion of the trip portion 240. At this time, the rear end portion 50b of the latch portion 50 is formed to be in contact with or adjacent to the inclined stepped portion 41. In addition, the handle portion 60 is coupled to the housing portion 10 to be rotated back and forth, and a pressing member 61 that is moved up and down to press the latch portion 50 downwardly according to the rotational direction is connected to the lower portion. . At this time, the rotational direction means that the movable contact portion 225 and the fixed contact portion 13 are operated in contact with each other, and the movable contact portion 225 and the fixed contact portion 13 are operated apart from each other. It is desirable to understand that it covers the blocking direction. Hereinafter, the connection direction will be described and illustrated in a direction that rotates to the front, and the blocking direction will be described and illustrated in a direction that rotates to the rear.

In detail, the pressing member 61 is moved downward while the handle portion 60 is rotated in the connection direction. At this time, the pressing member 61 is hinged to the lifting connecting portion 51 formed on the central side of the latch portion 50. Therefore, when the pressing member 61 is moved downward, the latch portion 50 is moved in conjunction, but the rear end portion 50b of the latch portion 50 is supported in surface contact with the inclined upper surface of the inclined stepped portion 241. . Then, while the rear end portion 50b of the latch portion 50 is supported by the inclined stepped portion 241, the front end portion 50a is rotated downward to contact the latch pressing portion 232 and the crossbar 230. By pressing, the fixed contact portion 13 and the movable contact portion 225 are contact-connected.

On the other hand, the suction rotor 270 is provided on the upper side of the magnetization facing portion 223. And, it is provided on the rear side of the crossbar 230, but is supported in the connection direction through a return spring 277 seated on the upper side of the magnetization facing portion 223. At this time, a hinge portion 271 is provided at a lower end of the suction rotor 270, and a hammer 274 striking one side of the trip portion 240 is rotated inertia in a blocking direction through inertia. That is, the trip part 240 is retreated to the rear side through the blow applied while the hammer 274 is inertiaally rotated. The suction rotor 270 is preferably provided with a magnetic material. For example, the suction rotor 270 may be provided with a metal containing a large amount of ferrous (Fe) components, such as pure iron or cast iron.

In detail, when a current flows through the power input unit 11, the current flows to the movable switching unit 220 and is magnetized. At this time, when the overcurrent flows in, the suction magnetic force that sucks metal in the surroundings increases in response to the current through which the movable switching unit 220 flows. Here, as the suction rotor 270 is provided as a magnetic material, the suction is rotated primarily in the blocking direction around the hinge portion 271 by the suction magnetic force.

At this time, the hammer 274 is linked to the upper end portion of the suction rotor 270, but rotates inertia secondaryly through inertia to strike one side of the trip unit 240. Here, since the hammer 274 is loosely fitted to the link extension portion 273, suction rotation of the suction rotor 270 and inertia rotation of the other hammer 274 are instantaneously made in a moment. . Accordingly, as the trip portion 240 is retracted, the rear end portion 50b of the latch portion 50 is spaced apart from the inclined stepped portion 241, and the restraining force that pressurized and supports the latch portion 50 is lost. Through this, the pressing force applied to the crossbar 230 is removed, and the movable contact portion 225 and the fixed contact portion 13 may be spaced apart while the magnetized face portion 223 is recovered and unfolded.

Meanwhile, the suction rotor 270 preferably includes the hinge part 271, the suction extension part 272, the link extension part 273, and the hammer 274.

In detail, the hinge portion 271 is hinged to the upper surface side of the crossbar 230 through a hinge shaft 271a. At this time, it is preferable that the hinge shaft 271a is loosely fitted to the hinge portion 271. Therefore, the suction rotor 270 may react immediately to the suction magnetic force of the magnetizing face portion 223, thereby rapidly suctioning and rotating. In addition, the suction extension portion 272 extends backward from the hinge portion 271 and is spaced apart from the upper surface of the movable switching portion 220. At this time, the return spring 277 is provided between the suction extension portion 272 and the movable switching portion 220.

In addition, the link extension portion 273 extends upward from the hinge portion 271, but a link fastening portion 273b is formed at an end portion of which the link shaft 273a is fastened in the lateral direction. In addition, the hammer 274 is extended in a tangential direction from the outer periphery of the link groove portion 275 and the link groove portion 275 to which the link shaft 273a is loosely fitted so as to be inertialy rotated to the link fastening portion 273b. It is provided, including a hitting projection (276). That is, the suction extension portion 272 and the link extension portion 273 are provided to extend in a direction crossing each other around the hinge portion 271.

Here, the hammer 274 is provided in a separate configuration and is linked to the end of the link extension portion 273 through the link shaft 273a. In this case, the link fastening portion 273b is formed in a pair so that the link groove portion 275 is fastened to the upper end portion of the link extending portion 273, but the spaced apart portions are formed to correspond to the widths on both sides of the link groove portion 275. This is preferred. The suction extension portion 272, the hinge portion 271 and the link extension portion 273 is preferably formed integrally with a magnetic material.

In addition, when the suction extension portion 272 is pulled downward and sucked and rotated through the suction magnetic force of the movable switching portion 220 when an overcurrent occurs, the link extension portion 273 moves toward the rear side with respect to the hinge portion 271. It is rotated. At this time, the hammer 274 is loosely fitted to the link fastening portion 273b through the link shaft 273a. Therefore, even if the rear end of the suction extension portion 272 contacts the upper surface of the magnetizing face portion 223, rotation is inertia in the blocking direction by inertia even when rotation is stopped.

At this time, it is preferable that the hitting guider 242 in which the hitting surface 242a is inclined on the front side to be inertly hit by the hitting protrusion 276 is integrally protruded in the forward direction at the upper end of the trip portion 240. That is, when the hammer 274 is rotated inertia, the hitting protrusion 276 hits the hitting surface 242a, and through this, the trip portion 240 is rotated around the pivoting end portion 240a and retracted.

Here, the rotation speed of the hammer 274, which is rotated through the inertia in which the suction rotor 270 is sucked and rotated, is increased by the load of the striking protrusion 276. In addition, when the hammer 274 is rotated through the inertia, the center of gravity of the hammer 274 is moved to the rear side when the position of the striking protrusion 276 is rotated to the rear side than the link shaft 273a. Moreover, since the striking protrusion 276 protrudes in a tangential direction from the outer side in the blocking direction side of the link groove portion 275, the center of gravity of the hammer 274 can be quickly moved to the rear side.

 Therefore, even if the suction rotor 270 is slightly rotated by the suction magnetic force toward the magnetization facing portion 223, the force hitting the trip unit 240 may act even more while the hitting projection 276 is rotated inertia. have. Through this, since the trip portion 240 is clearly rotated and retracted in the blocking direction, the inclined step 241 and the latch portion 50 can be surely separated. Moreover, since the hitting surface 242a is inclined, the contact area with the hitting protrusion 276 rotated inertia increases. Therefore, since the hitting guider 242 is clearly hit, the trip unit 240 may be accurately retracted.

On the other hand, the first stopper portion 278a seated and restrained on the upper surface of the crossbar 230 is restrained forwardly at the lower front end of the link extension portion 273 to constrain the rotation angle of the suction rotor 270 in the connection direction. . Further, it is preferable that the second stopper portion 278b on which the lower surface of the striking protrusion 276 is seated is protruded forwardly at the front upper end portion of the link extension portion 273 to constrain the rotation angle of the hammer 274 in the connection direction. Do.

In detail, when the latch portion 50 is spaced apart from the inclined stepped 241 and the restraining force is released, the return spring 277 is elastically restored and pushes the suction extension portion 272 upward. Then, the link extension portion 273 is rotated to the front side around the hinge portion 271. At this time, the first stopper portion 278a is protruded forward in a direction orthogonal to the link extension portion 273. Accordingly, the angle at which the first stopper portion 278a is seated on the upper surface of the crossbar 230 and rotated back may be limited.

In addition, the hammer 274 is rotated to the front side through the inertia even when the link extension portion 273 is rotated. At this time, the second stopper portion 278b is protruded forward from each front edge of the pair of link fastening portions 273b, but the inner surface portion is preferably protruded toward the center. Accordingly, when the striking protrusion 276 is rotated so as to return through inertia around the link groove 275, the lower surface of the striking protrusion 276 is seated on the upper surface of the second stopper part 278b, and the rotation angle is Can be limited.

In detail, when the latch portion 50 is spaced apart from the inclined stepped 241 and the current is cut off, the suction magnetic force of the magnetizing face portion 223 is extinguished. Accordingly, the suction extension portion 272 is pushed upward through the elastic restoring force of the return spring 277, and the link extension portion 273 is rotated to the front side around the hinge portion 271. At this time, the suction rotor 270 is moved by being pushed to the front side as if bouncing through the elastic restoring force of the return spring 277. Therefore, while the suction rotor 270 is quickly returned to the initial placement position, the acceleration through the inertia increases when the hammer 274 is returned and rotated, so that it can be clearly returned to the initial placement position.

At this time, as the first stopper portion 278a contacts the upper surface of the crossbar 230, the rotation and rotation of the link extension portion 273 is stopped to return to the initial arrangement position. Here, even if the return rotation of the link extension portion 273 is stopped, the hammer 274 is rotated inertia forward by inertia. Then, while the lower surface of the striking protrusion 276 is in contact with the upper surface of the second stopper portion 278b, the rotation of the inertia of the hammer 274 is stopped and returned to the initial arrangement position.

As described above, the present invention is rotated quickly while increasing the impact force hitting the trip unit 240 through the inertia according to the rotation of the suction rotor 270 and the load of the hammer 274. The return is made immediately. Therefore, driving reliability can be improved when repeated use is ensured while safety of surrounding electronic components is secured through the circuit breaker.

On the other hand, the rear end portion is connected to the rear end portion of the movable switching unit 220, but the front end portion of the front end of the bending portion extending in the upward direction crossing the movable switching unit 220 is disposed opposite to the front side of the trip unit 240 It may further include (224). In addition, the load output unit 12 may be electrically connected to the current transfer unit 224 through the electric wire 15. That is, current flows through the power input unit 11, the movable switching unit 220, the current transfer unit 224, the electric wire 15 and the load output unit 12.

Here, the current transfer unit 224 may be formed of a metal material that is magnetized through current while having conductivity as well as the movable switching unit 220. Alternatively, in some cases, the current transfer unit 224 may be formed of a bimetal having a different thermal expansion coefficient at the front and rear surfaces while being magnetized. That is, when the temperature of the current moving part 224 is increased due to the resistance current passing through the overcurrent, it may be formed to be bent toward the rear side having a low coefficient of thermal expansion.

In addition, the blower guide hole 242 may be formed with a rotating clearance hole 243 through which the current moving portion 224 penetrates but includes a free space that accommodates the rotating range of the trip portion 240. have. That is, the current moving portion 224 may be disposed through the inside of the rotation clearance hole 243 in the extended state. Therefore, even if the hitting guider 242 is hit and retreated by the inertia rotation of the hammer 274, it can be prevented from being interfered by the current transfer unit 224. That is, even if the current moving part 224 extends upward, the trip part 240 is clearly retracted, so that when the overcurrent occurs, the latch part 50 can be operated to be clearly separated from the inclined step 241.

On the other hand, the handle portion 60 is hinged to the support frame provided in the housing portion 10, when the restraining force was pressed and supported by the latch portion 50 is lost through the recovery force of the return means provided on one side It is rotated in the blocking direction. At this time, the return means may be provided with a torsion spring or plate spring. In addition, the pressing member 61 hinged to the lower end of the handle portion 60 is moved upward, and the latch portion 50 can be completely separated from the crossbar 230 and the trip portion 240.

At this time, when the handle portion 60 is rotated in the connection direction so that the electric current is connected again, the pressing member 61 is moved downward, but the rear end portion 50b of the latch portion 50 moves toward the inclined stepped portion 241. It is supported to move and contact back to its upper surface. Then, when the pressing force of the pressing member 61 is continuously transmitted while the rear end portion 50b of the latch portion 50 is supported, the front end portion 50a of the latch portion 50 is moved downward. At this time, as the front end portion 50a of the latch portion 50 is contacted to the latch pressing portion 232 and the pressing force is transmitted to the lower side, the movable switching portion 220 is pressed downward and the movable contact portion ( 225) and the fixed contact portion 13 is manipulated to contact again.

In addition, a return means for returning the rotation angle of the trip portion 240 is further provided on the rotation end portion 240a side. Therefore, after the rear end portion 50b of the latch portion 50 is rotated in the rear direction so as to be spaced apart from the inclined step portion 241, the position is immediately returned through the return means. At this time, since the hitting projection 276 is in contact with the hitting surface 242a, when the position of the trip unit 240 is returned, the hitting projection 276 is pushed forward by the hitting guider 242 to return. The power for may increase. Through this, the suction rotor 270 and the hammer 274 linked to the end thereof can be quickly returned to the initial arrangement position in the normal state or the overcurrent is blocked of the circuit breaker 200.

As described above, in the hammer link type circuit breaker 200 according to the present invention, the suction rotor 270 is first sucked and rotated toward the magnetizing face portion 223 which is magnetized when an overcurrent occurs. Then, the hammer 274, which is loosely fitted on the upper side of the link, is rotated secondarily at high speed through inertia, and momentarily strikes the trip unit 240 to retreat. Through this, it is possible to be provided with a circuit breaker having a faster current blocking speed than a bimetal that is bent through a conventional resistance heat.

At this time, when the position of the hitting projection 276 is rotated to the rear side than the link shaft 273a by inertia, the center of gravity of the hammer 274 is moved to the rear side and the hitting guider 242 is transferred through its own load. The power to hit is increased. Therefore, since the trip portion 240 is clearly retracted in the blocking direction, the latch portion 50 is surely separated from the inclined step 241, so that the reliability of the blocking operation can be significantly improved.

In addition, when the current is cut off and the suction magnetic force of the magnetization-facing portion 223 is extinguished, the suction rotor 270 is pushed upward through the elastic restoring force of the return spring 270 to return and rotate. Then, when the suction rotor 270 is returned and rotated, the hammer 274 is accelerated through inertia and rotated together. At this time, since the return angles of the suction rotor 270 and the hammer 274 are restricted through the stopper portions protruding forward from the link extension portion 273, it can be accurately returned to the initial position.

As described above, when the suction part 270 rotates, the trip part 240 is retracted through the blow of the hammer 274 due to inertia, so that the restraint of the latch part 250 supported on its front surface is physically released. The current is cut off in a simple way. Therefore, costly parts such as a video current transformer are not required, so manufacturing cost is reduced and the number of parts is minimized, so that economical efficiency through product compactness can be significantly improved.

At this time, the terms "include", "compose", "have" or "have" as described above mean that the corresponding component can be intrinsic, unless otherwise stated. It should be construed that other components may be included rather than excluded. All terms, including technical or scientific terms, have the same meaning as generally understood by a person skilled in the art to which the present invention pertains, unless otherwise defined. Commonly used terms, such as predefined terms, should be interpreted as being consistent with the contextual meaning of the related art, and are not to be interpreted as ideal or excessively formal meanings unless explicitly defined in the present invention.

As described above, the present invention is not limited to the above-described embodiments, but may be modified and implemented by those skilled in the art without departing from the scope of the claims of the present invention. Such variations are within the scope of the present invention.

10: housing portion 50: latch portion
60: handle portion 220: movable switching portion
230: crossbar 240: trip section
270: suction rotor 272: suction extension
273: Link Extension 274: Hammer
200: hammer link breaker

Claims (5)

A housing unit provided with a power input unit and a load output unit spaced apart at the front and rear sides;
A movable switching unit disposed between the power input unit and the load output unit, the front end being connected to the power input unit and providing a resilient upward force to be selectively spaced apart, and the rear end side is electrically connected to the load output unit. ;
A crossbar formed on one side via an opening through which the front end side of the movable switching portion is transverse, but supported by an elastic means provided at a lower portion, to be supported upwards;
A trip unit disposed on the rear side of the crossbar and rotated back and forth around the lower end portion, but having an inclined step forward protruding toward the front portion;
A front end portion facing the upper surface of the crossbar, but a rear end portion in contact with the upper surface of the inclined step so that the power input portion and the movable switching portion are in contact with each other; a latch portion for pressing the crossbar downward;
A handle portion coupled to the housing portion to be rotated back and forth, and a pressing member connected to a lower portion to be moved upward and downward to press the latch portion downward according to a rotation direction; And
A hinge portion is provided at the lower end and supported in the connection direction, and when the overcurrent occurs, the crossbar is pressed by hitting the trip portion through an inertia that is sucked and rotated in the blocking direction around the hinge portion by the suction magnetic force generated in the movable switching portion. A hammer for retracting the latch portion to be spaced apart from the inclined step includes a suction rotor made of a magnetic material linked to an upper portion,
The suction rotor
A suction extension portion extending rearward from the hinge portion and spaced apart from an upper surface of the movable switching portion;
A link extending portion extending upward from the hinge portion and having a link fastening portion in which a link shaft is fastened laterally at an upper end portion;
Hammer link breaker characterized in that it comprises a link groove portion to which the link shaft is loosely fitted so as to be inertialy rotated at the link fastening portion, and the hammer including a striking portion extending tangentially from the outer circumference of the link groove portion. delete The method of claim 1,
A return spring is provided between the suction extension portion and the movable switching portion, and the hinge portion is hinged to one side of the crossbar,
A first stopper part seated and restrained on an upper surface of the crossbar is protruded forward to constrain the rotation angle of the suction rotor in the front lower end portion of the link extension portion, and the blow hits the front upper portion to constrain the rotation angle of the hammer connection direction. Hammer link type circuit breaker, characterized in that the second stopper portion on which the lower surface of the seat is seated. The method of claim 1,
A hammer link breaker, characterized in that the upper end portion of the trip portion has a striking guider inclined on the front surface so as to be inertia hit by the striking portion. The method of claim 4, wherein
A rear end portion is connected to the rear end portion of the movable switching portion, and a front end portion bent in an upward direction crossing the movable switching portion is disposed opposite to the front side of the trip portion, and further includes a current moving portion electrically connected to the load output portion. And
A hammer link type circuit breaker characterized in that the striking guider is formed with a rotating clearance hole penetrated in the vertical direction, including a clearance space through which the current moving portion is penetrated but accommodates the rotating range of the trip portion.

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