KR102514962B1 - Trip device for molded case circuit breaker - Google Patents

Abstract

An object of the present invention is to improve the breaking performance of a circuit breaker trip device by inducing a stable armature operation by increasing the attractive force of the trip device even under a low operating current.
To this end, the present invention is installed adjacent to the heater or the bimetal to be magnetized by the fault current flowing in the heater or the bimetal formed of a ferromagnetic material; a supporter fixed to an enclosure of the magnet, the heater, or a circuit breaker; an armature rotatably installed on the supporter and rotating toward the magnet by the magnetic force of the magnet to move the opening/closing mechanism to a tripped position; an elastic member installed between the supporter and the armature to elastically support the armature in a direction opposite to the magnet; It provides a tripping device for a circuit breaker, characterized in that it includes at least one auxiliary armature installed on the armature surface facing the magnet.

Description

Circuit breaker trip device {TRIP DEVICE FOR MOLDED CASE CIRCUIT BREAKER}

The present invention relates to a circuit breaker, and more particularly, to a tripping device for a circuit breaker that senses when a fault current such as a short circuit occurs and induces a switch mechanism to cut a circuit.

Molded-Case Circuit Breaker (MCCB) is an integral assembly of a switch mechanism and a trip device in an insulated container. It is an electrical device that can automatically trip the circuit when an error occurs.

1 as a front cross-sectional view of a wiring circuit breaker according to the prior art, referring to FIG. 1, the wiring circuit breaker according to the prior art includes an enclosure 10 and a fixed contact electrically connected to a power supply side not shown and installed in the enclosure 10 ( 20), the movable contact 30 installed rotatably so that it is electrically connected to the load side (not shown) and electrically connected or separated from the fixed contact 20. A switching mechanism 40 for positioning, a tripping device 50 for automatically inducing a blocking operation of the switching mechanism 40 according to an abnormal current such as overload or a fault current such as short circuit, and a movable contactor 30 from a fixed contactor 20 ) is composed of an extinguishing device 60 disposed on the moving path of the movable contact 30 so as to extinguish the arc generated between the fixed contact 20 and the movable contact 30 when they are separated.

The trip device 50 is a so-called thermal-electromagnetic trip device, which detects an abnormal current such as an overload by using the deformation of a bimetal that is deformed when an overcurrent flows on a circuit, and then opens and closes the mechanism ( After detecting a fault current such as a short circuit by using the thermal detection mechanism unit 70 that induces the blocking operation of 40) and the magnetic force induced when a large current flows on the circuit, inducing the blocking operation of the opening and closing mechanism 40 It is composed of an electronic detection mechanism unit 80.

Figure 2a is a schematic diagram of a circuit breaker trip device according to the prior art, Figure 2b is an exploded perspective view of Figure 2a, Figure 3a is a schematic diagram of another trip device of the prior art, Figure 3b is an exploded view of Figure 3a It is a perspective view.

First, referring to FIGS. 1 to 2B, the thermal detection mechanism 70 of the trip device 50 includes a heater 71 having one end electrically connected to the movable contactor 30 and the other end connected to a load, It consists of a bimetal 72 fixed in contact with the heater 71.

The bimetal 72 is indirectly heated (indirect heating method) by the heat of the heater 71 to which overcurrent is applied and is disposed so as to be curved toward the cross bar 41, and at the top thereof, the tripping (blocking) of the opening/closing mechanism 40 ) is provided with a rod 73 that rotates the cross bar 41 in a counterclockwise direction in contact with the cross bar 41 of the opening and closing mechanism 40 so as to induce the opening and closing mechanism 40.

In the wiring circuit breaker according to the configuration of FIGS. 1 to 2B, a high rated current is usually applied to the heater 71, and a low rated current is applied in some cases.

However, when only a low rated current is applied to the circuit breaker, the heater 71 is omitted as shown in FIGS. 3A and 3B, and one end is electrically connected to the movable contactor 30 and the other end is connected to the load. It may be configured as a bimetal 72 so that the bimetal 72 is directly heated (direct heating method) by an overcurrent applied to the bimetal 72 and is bent toward the crossbar 41.

On the other hand, referring to Figures 1 to 3b, the electronic detection mechanism unit 80; A magnet 81 formed of a ferromagnetic material such as steel so as to be installed adjacent to the heater 71 or the bimetal 72 and magnetized by a fault current such as a short circuit current flowing through the heater 71 or the bimetal 72, the magnet A supporter (82) fixed to (81) is rotatably installed on the supporter (82) and rotates toward the magnet (81) by the magnetic force of the magnet (81) to bring the circuit breaker's opening/closing mechanism (40) to the tripped position. An elastic member such as a spring 84 installed between the supporter 82 and the armature 83 to elastically support the moving armature 83 and the armature 83 in the opposite direction of the magnet 81. consists of

Here, the spring 84 does not move by the attractive force of the magnet 81 magnetized by the rated rectification or overcurrent applied to the heater 71 by the armature 83, but is resistant to the short-circuit current applied to the heater 71. The elastic force is adjusted so that it can move toward the magnet 81 by the attractive force of the magnet 81 magnetized by.

When the armature 83 is attracted toward the magnet 81 by the magnetic force of the magnet 81 magnetized by the short-circuit current applied to the heater 71, the upper end of the armature 83 contacts the cross bar 41 to form a cross bar ( 41) is set to rotate counterclockwise.

On the other hand, although the supporter 82 is shown as being fixed on the magnet 81 by the rivet 85 in FIGS. 2A and 2B, it may be fixed to various coupling means such as bolts or welding. Depending on the example, it may be fixed to the heater 71 and the enclosure 10 as known in the art.

In the conventional circuit breaker configured as described above, when the handle H is closed and the circuit breaker is turned on, an overcurrent exceeding the rated current is generated through the heater 71 (see FIGS. 2A and 2B) or the bimetal 72 ( 3a and 3b), the heating of the heater 71 or the bimetal 72 causes the bimetal 72 to be bent toward the cross bar 41, and accordingly, the rod 73 of the bimetal 72 is attached to the cross bar ( 41) to rotate the cross bar 41 counterclockwise.

At this time, when the deformation force of the bimetal 72 exceeds the trip load of the opening/closing mechanism 40, the opening/closing mechanism 40 moves the movable contact 30 to a trip position separating the fixed contact 20.

On the other hand, as shown in FIGS. 4A and 4B, when a short-circuit current exceeding several tens of times the rated current is applied in a state in which the circuit breaker is turned on, the heater 71 or the bimetal 72 (FIGS. 3A and 4B) 3b) generates heat, but before the bimetal 72 is bent toward the cross bar 41 by this heat, the magnet 81 disposed adjacent to the heater 71 is affected by the short-circuit current applied to the heater 71. Since it is magnetized, the magnet 81 overcomes the elastic force of an unshown spring (see “84” in FIGS. 2B and 3B) and instantly attracts the armature 83.

Thereafter, the upper end of the armature 83 strikes the cross bar 41 in a counterclockwise direction, and when the amount of impact caused by the armature 83 exceeds the trip load of the opening/closing mechanism 40, the cross bar 41 ) further rotates counterclockwise, and accordingly, the opening/closing mechanism 40 moves the movable contact 30 to a trip position separating the fixed contact 20 from the contact.

In the tripping process, the movable contact 30 is separated from the fixed contact 20, and the arc generated in the process of separating the movable contact 30 from the fixed contact 20 is the path of the movable contact 30 shown in FIG. It is extinguished by the extinguishing device 60 disposed on the top.

In the circuit breaker trip device 50 according to the prior art configured as described above, the attraction force between the magnet 81 and the armature 83 according to the magnetic force of the magnet 81 is the square of the fault current applied to the magnet 81 determined by size.

Meanwhile, the operating current value of the circuit breaker for blocking the fault current is determined by the manufacturer as a multiple of the rated current (for example, 10 times the rated current) according to the characteristics of the circuit breaker.

Therefore, in the case where a high-rated current is applied as in the circuit breakers of FIGS. 1 to 2B, the operating current value (eg, 10 times the high-rated current) is large, so the armature 83 is used for the magnet 81. Sufficient magnetic force for suction is generated, and accordingly, the armature 83 strikes the cross bar 41 with a force strong enough to overcome the trip load of the opening and closing mechanism 40 to stably trip the opening and closing mechanism 40. there is.

However, if a low-rated current is applied to the wiring circuit breaker of FIGS. 1 to 3B, when the operating current value is adopted as a multiple equal to the fixed rating (eg, 10 times the low-rated current), the magnet ( Since the magnetic force generated in 81) is weak, whether or not the circuit cut-off is tripped is sensitively affected by the trip load set in the opening/closing mechanism 40.

In other words, in the case where a low-rated current is applied to the circuit breaker of FIGS. 1 to 3B, when a large fault current that greatly exceeds the operating current value occurs in the circuit, the magnet 81 has a magnet 81 for attracting the armature 83. Sufficient magnetic force is generated.

Accordingly, the armature 83 can stably trip the opening/closing mechanism 40 by hitting the cross bar 41 with force strong enough to overcome the trip load of the opening/closing mechanism 40 .

However, in the case where a small fault current within the minimum operating current range occurs in the circuit, magnetic force for attracting the armature 83 is generated in the magnet 81, but the magnetic force is weak and the armature is attracted toward the magnet 81. 83 sometimes fails to hit the cross bar 41 to the extent that it cannot overcome the trip load of the opening/closing mechanism 40, which leads to the failure of the opening/closing mechanism 40 to trip.

This causes a so-called operating current distribution phenomenon in which the switching mechanism 40 is irregularly tripped according to the magnitude of the fault current.

In order to solve this problem, in the wiring circuit breaker according to Korean Patent Registration No. 10-1015333, as shown in FIG. 5, a coil 83' that generates a large magnetic force even at a low current fault current to improve the breaking ability of the wiring circuit breaker operates. We provide a trip device of the method.

However, since the circuit breaker trip device according to FIG. 5 has a complicated component configuration, there are problems in that product space is limited, productivity decreases, and manufacturing cost increases.

The present invention has been devised in view of these problems, and in a circuit breaker trip device, by increasing the attractive force of the trip device even under a low operating current, stable armature operation is induced, thereby improving the breaking performance of the circuit breaker trip device. aims to do

In order to achieve this object, the present invention includes a magnet formed of a ferromagnetic material installed adjacent to a heater or bimetal to be magnetized by a fault current flowing in the heater or the bimetal; a supporter fixed to an enclosure of the magnet, the heater, or a circuit breaker; an armature rotatably installed on the supporter and rotating toward the magnet by the magnetic force of the magnet to move the opening/closing mechanism to a tripped position; an elastic member installed between the supporter and the armature to elastically support the armature in a direction opposite to the magnet; It provides a tripping device for a circuit breaker, characterized in that it includes at least one auxiliary armature installed on the armature surface facing the magnet.

Here, the attractive force between the magnet and the armature may be increased by increasing the number or size, or the number and size of the auxiliary armatures.

In addition, the lower portion of the armature includes a first body portion facing the magnet, and first and second side portions formed on both sides of the first body portion and protruding toward the magnet, and the auxiliary armature includes the first body portion of the armature. A flat second body portion fixed to an inner surface of the body portion may be provided.

In addition, the second body portion may further include third and fourth side portions formed on both sides of the second body portion and protruding toward the magnet so as to be fixed to inner surfaces of the first and second side portion portions.

When the auxiliary armature is installed under the armature, it is preferable that the auxiliary armature does not protrude outside the outer line of the armature.

In addition, at least one first hole is formed in the first body part under the armature, and a second hole is formed in a position corresponding to the first hole in the second body part of the auxiliary armature. The auxiliary armature may be fixed to the lower portion of the armature by performing rivet coupling, bolt and nut coupling, screw coupling, or tab bolt coupling through two holes.

In addition, the auxiliary armature may be composed of a permanent magnet.

In the fault current trip function, which is the main function of a wiring circuit breaker, the present invention additionally fixes an auxiliary armature to the armature to increase the attraction force of the armature attracted to the magnet even by the same magnitude of magnetic force, thereby providing stable instantaneous operation even at a low operating current value. Blocking operation is possible.

According to the present invention, it is also possible to implement a function of simply step-by-step adjusting the operating current value without changing the spring according to the stacked structure and quantity of auxiliary armatures.

Through this, the present invention can obtain the effect of improving productivity and reducing cost by relatively simplifying the trip device compared to the coil type trip device, as well as improving the quality of the circuit breaker.

1 is a front sectional view of a circuit breaker according to the prior art.
Figure 2a is a schematic diagram of a tripping device of a circuit breaker according to the prior art.
Figure 2b is an exploded perspective view of Figure 2a.
3A is a schematic diagram of a tripping device of another circuit breaker according to the prior art.
Figure 3b is an exploded perspective view of Figure 3a.
4A and 4B are exemplary diagrams illustrating a blocking operation of an electronic detection unit of a circuit breaker according to the prior art.
5 is an exploded perspective view of a portion of a trip device having a coil operating method of another circuit breaker according to the prior art.
6A is a perspective view of a trip device of a circuit breaker according to the present invention.
FIG. 6B is a perspective view of the circuit breaker tripping device from which the supporter is removed in FIG. 6A.
7A is a perspective view of an armature assembly in which an auxiliary armature is coupled to an armature according to the present invention.
Figure 7b is an exploded perspective view of Figure 7a.
Fig. 7c is a perspective view of the auxiliary armature according to Fig. 7a;
Fig. 7d is a longitudinal cross-sectional view of Fig. 7a.
8 is a perspective view of an armature assembly in which a planar auxiliary armature is coupled to an armature according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings, which are intended to be described in detail so that those skilled in the art can easily practice the invention. It does not mean that the technical spirit and scope of the invention are limited.

The trip device 500 of the circuit breaker according to the present invention is a so-called thermal-electronic trip device 500, particularly related to the electronic detection mechanism unit 800, but some of the thermal detection mechanism unit ( 700) is also related.

Therefore, in describing the present invention, the thermal-electronic trip device 500 will be generally described.

6A is a perspective view of a tripping device for a circuit breaker according to the present invention, and FIG. 6B is a perspective view of the tripping device for a wiring circuit breaker in which the supporter is removed in FIG. 6A.

First, referring to FIG. 6A, one end of the thermal detection mechanism 700 of the trip device 500 of the circuit breaker according to the present invention is electrically connected to a movable contact (see “30” in FIG. 1), not shown. The other end is composed of a heater 710 connected to a load (not shown) and a bimetal 720 fixed to be in contact with the heater 710.

The bimetal 720 is indirectly heated (indirect heating method) by heat generation of the heater 710 to which overcurrent is applied, and is disposed to be curved toward a cross bar (see “41” in FIGS. 1, 4A and 4B) do.

In the wiring circuit breaker according to the configuration of FIGS. 2A and 2B, a high rated current is usually applied to the heater 710, and a low rated current is applied in some cases. In describing the present invention, the low rated current is It will be explained as an approved case.

In addition, when only the low-rated current is applied to the circuit breaker, although not shown, the heater 710 is omitted in FIGS. 6A and 6B, and one end is electrically connected to the movable contactor 30 and the other end is connected to the load. Consisting of a bimetal 720, the bimetal 720 is directly heated (direct heating method) by an overcurrent applied to the bimetal 720 to form a cross bar (not shown) (“41” in FIGS. 1, 4A, and 4B) Reference) may be configured to be curved to the side.

In addition, as shown in FIGS. 6A and 6B, the electronic detection mechanism unit 800 of the trip device 500 of the circuit breaker according to the present invention; A magnet 810 formed of a ferromagnetic material such as steel so as to be installed adjacent to the heater 710 or the bimetal 720 and magnetized by a fault current such as a short circuit current flowing through the heater 710 or the bimetal 720; The supporter 820 fixed to the magnet 810 by the illustrated rivet (see “85” in FIGS. 2B and 3B) is rotatably installed in the groove 821 formed in the supporter 820 and the magnet 810 An armature 830 formed of a ferromagnetic material such as steel that rotates toward the magnet 810 by the magnetic force of ) to move the unshown opening/closing mechanism (see “40” in FIG. 1) of the circuit breaker to the trip position, the armature ( 830) such as a spring (not shown) installed between the supporter 820 and the armature 830 (see 84 in FIGS. 2B and 3B) to elastically support the magnet 810 in the opposite direction. It is composed of an elastic member.

Here, the not-shown spring (see “84” in FIGS. 2B and 3B) is moved by the attractive force of the magnet 810 magnetized by the rated rectification or overcurrent applied to the heater 710 by the armature 830. However, the elastic force is adjusted so that it can move toward the magnet 810 by the attractive force of the magnet 810 magnetized by the short-circuit current applied to the heater 710 .

When the armature 830 is attracted toward the magnet 810 by the magnetic force of the magnet 810 magnetized by the short-circuit current applied to the heater 710, the upper end, that is, the arm 831, is a cross bar (not shown). (See "41" in Figs. 1, 4A and 4B) and rotate the crossbar counterclockwise.

On the other hand, although the supporter 820 is shown as being fixed on the magnet 810 in FIG. 6A, as is known in the art, depending on the embodiment, the heater 710 or an enclosure not shown (FIG. 1 (see "10" of) may be fixed.

The above configuration is the same as the configuration of the trip device 50 of the circuit breaker according to the prior art, and the parts related to the auxiliary armature 930 of the electronic detection mechanism unit 800 related to the features of the present invention will be described below.

7A is a perspective view of an armature assembly in which an auxiliary armature 930 is coupled to an armature 830 according to the present invention, FIG. 7B is an exploded perspective view of FIG. 7A, and FIG. 7C is a perspective view of the auxiliary armature 930 according to FIG. 7A , and FIG. 7d is a longitudinal cross-sectional view of FIG. 7a.

Referring to FIGS. 7A to 7D , the auxiliary armature 930 is fixedly installed on the surface of the armature 830 facing the magnet 810 (see FIGS. 6A and 6B ) and magnetized by the fault current. It serves to transfer the suction force applied to the auxiliary armature 930 by the magnetic force of the 810 to the armature 830 as it is.

Like the armature 830, the auxiliary armature 930 is made of a material that can be attracted toward the magnet 810 by the magnetic force of the magnet 810, and is preferably made of a steel material like the armature 830.

Since the auxiliary armature 930 is installed on the side of the armature 830 facing the magnet 810, the distance between the auxiliary armature 930 and the magnet 810 is the distance between the magnet 810 and the armature 830 in the circuit breaker according to the prior art. ) closer than the set distance between them.

In addition to this, the area through which the magnetic flux of the magnet 810 passes is increased by the auxiliary armature 930 .

To explain this in more detail, in the trip device 50 of the circuit breaker according to the prior art, the magnetic flux of the magnet 81 passes only through the armature 83, but in the trip device 500 of the circuit breaker according to the present invention, the magnet 810 Since the magnetic flux passes through the armature 830 and the auxiliary armature 930, when the present invention is applied to a circuit breaker, the area through which the magnetic flux of the magnet 810 passes increases as much as the portion corresponding to the auxiliary armature 930. It will be.

On the other hand, in general, it is known that the suction force by magnetic force increases as the distance between the magnetic force generating source and the object to be attracted by the magnetic force of the magnetic force generating source is close, and increases as the magnetic flux passage area of the magnetic force generating source increases.

Therefore, as described above, the auxiliary armature 930 according to the present invention closes the distance to the magnet 810 and increases the area through which magnetic flux passes. Assuming that a magnetic force of the same magnitude is generated by the magnet 810 by a current, the attractive force substantially applied to the armature 830 and the auxiliary armature 930 according to the present invention by the magnet 810 according to the prior art It is increased compared to the armature 83.

Therefore, the armature 830 moving along with the auxiliary armature 930 toward the magnet 810 by the fault current is enough to overcome the tripping load of the unshown opening/closing mechanism (see “40” in FIG. 1), which is not shown. The bar (see “41” in FIGS. 1 and 4A and 4B) is hit hard, and accordingly, the unshown opening/closing mechanism (see “40” in FIG. 1) is stably tripped.

Accordingly, when the auxiliary armature 930 according to the present invention is applied to a wiring circuit breaker, a so-called operating current distribution phenomenon in which a trip failure of an unshown switching mechanism (see “40” in FIG. 1) occurs according to the magnitude of the fault current is prevented.

Meanwhile, the suction force between the magnet 810 and the armature 830 may be increased by increasing the number or size of the auxiliary armatures 930 .

As described above, the auxiliary armature 930 may be made of a steel material attracted by the magnet 810, but the auxiliary armature 930 may be made of a permanent magnet itself. In this case, the magnet magnetized by the short circuit current ( 810), the permanent magnet may be placed in a polar position so that the permanent magnet is attracted by the magnetic force.

When the permanent magnet is installed in this way, since the magnetic force of the permanent magnet is added in addition to the magnetic force of the magnet 810, there is an effect of further increasing the attractive force between the magnet 810 and the armature 830.

Hereinafter, configurations of the armature 830 and the auxiliary armature 930 will be described in more detail with reference to FIGS. 7A to 7D.

The upper part of the armature 830 constitutes an arm 831 in contact with an unshown cross bar (refer to “41” in FIGS. 1, 4A and 4B), and the middle part is a spring (not shown) (see FIGS. 2B and 3B). (see "84" of) is inserted and supported in the groove 821 of the supporter 820 to constitute a rotating shaft 832, and the lower part is the first body portion 833 facing the magnet 810 and the It is formed on both sides of the first body portion 833 and constitutes first and second side portions 833' and 833'' formed to protrude toward the magnet 810.

As shown in FIG. 8 , the auxiliary armature 930 may be composed of only a planar second body portion 933 closely fixed to the inner surface of the first body portion 833 of the armature 830 .

However, as shown in FIGS. 7A to 7D , the auxiliary armature 930 widens the area through which the magnetic flux passes through the magnetic flux of the magnet 810 so that the magnetic flux can be more easily absorbed toward the magnet 810, the second body portion. 933 may further include third and fourth side parts 933' and 933'' protruding toward the magnet 810.

The third and fourth side parts 933' and 933'' are bent at both sides of the second body part 933 so that they can be closely fixed to the inner surfaces of the first and second side parts 833' and 833''. can be formed

As shown in FIG. 7D , when the auxiliary armature 930 is installed below the armature 830, the auxiliary armature 930 does not protrude outside the outer line of the armature 830. It is preferable not to

This connects the second body part 933 and the third and fourth side parts 933' and 933'' of the auxiliary armature 930 to the first body part 833 and the first and second side parts 833 of the armature 830. ', 833'').

If the auxiliary armature 930 is formed to be smaller than the armature 830 in this way, the operation stroke of the armature 830 of the circuit breaker according to the present invention can be maintained the same compared to the prior art.

To explain this in more detail, FIG. 6B shows that the front end of the first and second side parts 833' and 833'' of the armature 830 are attached to the magnet 810 by the attraction force of the magnet 810 caused by the fault current. It is a drawing showing that it is in contact with.

Therefore, if the third and fourth side parts 933' and 933'' of the second body part 933 of the auxiliary armature 930 are replaced with the first and second side parts 833' and 833' of the first body part 833, '), since the tips of the third and fourth side parts 933' and 933'' of the second body 933 come into contact with the magnet 810 first, the rotation range of the armature 830 is substantially (stroke) is shortened, and accordingly, the time during which the armature 830 can be accelerated by the attractive force of the magnet 810 is also shortened. (see "40") cannot secure enough momentum to overcome the trip load.

In addition to this, for example, the coupling between the auxiliary armature 930 and the armature 830 is inaccurate so that one of the front ends of the third and fourth side parts 933' and 933'' touches the magnet 810 first. In this case, the axis 832 of the armature 830 supported by the groove 821 of the supporter 820 is twisted, so that the rotation of the armature 830 becomes unstable, and accordingly, the reliability of the operation of the circuit breaker against the trip action A problem arises that cannot be guaranteed.

Therefore, in the present invention, the size of the auxiliary armature 930 is smaller than that of the armature 830 as described above.

Meanwhile, in coupling the auxiliary armature 930 to the armature 830, the auxiliary armature 930 may be coupled to the armature 830 through various methods such as welding, friction welding, and electric pressure welding.

As an embodiment of the present invention, at least one first hole 833''' is formed in the first body portion 833 under the armature 830, and the second body portion of the auxiliary armature 930 is formed. In 933, a second hole 933''' is formed at a position corresponding to the first hole 833''', and then the first and second holes 833''' and 933''' are formed. A method of fixing the auxiliary armature 930 to the armature 830 by combining a rivet 950, combining a bolt (not shown) and a nut (not shown), or combining a screw (not shown) or a tap bolt (not shown) through is taking

In the circuit breaker closing device 500 according to the present invention configured as described above, an overcurrent exceeding the low rated current is generated by the heater 710 or the bimetal 720 (FIG. 3A and “72” in 3b), the heater 710 or the bimetal 720 heats up the bimetal 720 to bend toward the cross bar, and accordingly, the bimetal 720 extends toward the cross bar (FIG. 1, not shown). 4a and 4b (see "41") to rotate the cross bar counterclockwise.

At this time, when the deformation force of the bimetal 720 exceeds the trip load of the opening/closing mechanism (see “40” in FIG. 1), the opening/closing mechanism separates the movable contactor 30 from the fixed contactor 20. move it into position.

On the other hand, when a short-circuit current exceeding several tens of times the low-rated current is applied while the conventional circuit breaker is on, the heater 710 or the bimetal 720 (see “72” in FIGS. 3A and 3B) generates heat. However, before the bimetal 720 is bent toward the cross bar (refer to “41” in FIGS. 1, 4A and 4B) by this heat, the magnet 810 disposed adjacent to the heater 710 or the bimetal 720 Since is magnetized by the short-circuit current applied to the heater 710, the magnet 810 overcomes the elastic force of the not shown spring (see “84” in FIGS. 2B and 3B) to move the armature 830 and the auxiliary armature 930. momentarily aspirated.

Here, since the auxiliary armature 930 is fixed to the armature 830, the suction force applied to the auxiliary armature 930 is eventually transmitted to the armature 830.

Therefore, the suction force applied to the armature 830 according to the present invention is greater than the suction force applied to the armature 83 of the circuit breaker according to the prior art.

Consequently, when the auxiliary armature 930 according to the present invention is applied to the trip device 500 of the circuit breaker, in particular, the electronic detector unit 800, even if the magnet 810 is magnetized by a low-current fault current, the auxiliary armature 930 ), the armature 830 strikes the unshown crossbar (refer to “41” in FIGS. 1, 4A and 4B) strongly enough to overcome the trip load of the opening and closing mechanism, and accordingly, the unshown opening and closing mechanism The trip of (see “40” in FIG. 1) is stably performed.

Although the present invention has been described in relation to the above-mentioned preferred embodiments, it will be readily recognized by those skilled in the art that various modifications and variations can be made without departing from the gist and scope of the invention, and all such changes and modifications are attached. It is self-evident that it falls within the scope of the claims.

500: trip device 700: thermal detection mechanism
710: heater 720: bimetal
800: electronic detection mechanism 810: magnet
820: supporter 821: home
830: armature 831: arm
832: axis 833: first body
833', 833'': first and second side parts 833''': first hole
930: auxiliary armature 933: second body part
933', 933'': third and fourth side parts 933''': second hole
950: rivet

Claims (7)

a magnet formed of a ferromagnetic material installed adjacent to the heater or the bimetal to be magnetized by a fault current flowing through the heater or the bimetal;
a supporter fixed to an enclosure of the magnet, the heater, or a circuit breaker;
an armature rotatably installed on the supporter and rotating toward the magnet by the magnetic force of the magnet to move the opening/closing mechanism to a tripped position;
an elastic member installed between the supporter and the armature to elastically support the armature in a direction opposite to the magnet;
At least one auxiliary armature installed on the armature surface facing the magnet;
A lower part of the armature is a first body portion facing the magnet;
It is formed on both sides of the first body and has first and second side parts protruding toward the magnet,
The auxiliary armature has a planar second body portion fixed to an inner surface of the first body portion of the armature,
The second body portion is formed on both sides of the second body portion to be fixed to the inner surface of the first and second side portions and further includes third and fourth side portions protruding toward the magnet. According to claim 1,
The circuit breaker tripping device, characterized in that the attraction force between the magnet and the armature is increased by increasing the number or size, or the number and size of the auxiliary armatures. delete delete According to claim 1,
When the auxiliary armature is installed under the armature, the auxiliary armature does not protrude outside the outer line of the armature. According to claim 5,
At least one first hole is formed in the first body portion under the armature,
A second hole is formed at a position corresponding to the first hole in the second body of the auxiliary armature;
The circuit breaker tripping device, characterized in that the auxiliary armature is fixed to the lower portion of the armature by performing rivet coupling, bolt and nut coupling, screw coupling, or tap bolt coupling through the first and second holes. According to claim 1,
The auxiliary armature is a trip device of a circuit breaker, characterized in that the permanent magnet.

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