ES2618052T3 - Circuit breaker with magnetic fixing means - Google Patents

Abstract

Circuit breaker comprising: a heater (140) configured to generate heat due to a conduction current induced to a moving contact (104) of the circuit breaker; a bimetallic (106) configured to deform due to the heat generated by the heater (140) to separate a contact point from the mobile contact (104); a magnet (160) configured to generate a magnetic force to move an armature rod (150) when a current is induced above the previously set reference current; and a housing (102) configured to accommodate the bimetallic (106) and the magnet (160), characterized in that at least part of the housing (102) is composed of a synthetic resin material, and the circuit breaker further comprises: a portion of magnetic fastener (130) is integrally formed in the housing (102), and composed of a synthetic resin material; the heater (140) is fixed to the magnetic fixing portion (130) by a heater fixing bolt (142); the magnet (160) is fixed to the magnetic fixing portion (130) by a magnetic fixing bolt (162); and a bimetallic fixing bolt (144) is configured to fix the bimetallic (106) to the heater (140), in which there is a separation portion (G) between the heater (140) and the magnet (160), and a Bolt housing portion (146) is formed in the heater (140) to prevent the magnetic fixing bolt (162) from contacting the heater (140).

Description

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DESCRIPTION

Circuit breaker with magnetic fixing means Background of the invention

1. Field of the invention

The present disclosure refers to a circuit breaker with magnetic fixing means, and more particularly, to a circuit breaker with magnetic fixing means for fixing a magnet used to suppress an overcurrent that is occurring instantly.

2. Description of the related technique

In general, a circuit breaker is an electrical device provided within a distribution panel that has a low voltage circuit (15-30 A) with 110 / 220V AC to be used in order to prevent an electric shock in a body human, a fire caused by a short circuit, an accident due to an overcurrent and a short circuit, and the like.

A circuit breaker of this type, such as a device to detect a fault current when the fault current and a short circuit current occur and suppress a cable to protect the load and a cable connected to it, is widely used instead of a circuit breaker combined with a toggle switch and a fuse in the related art since it is small in size and handled safely as well as presenting no problem when inserting a fuse.

The circuit breaker fault current detection function may include an overcurrent protection function and an instantaneous current protection function, and the overcurrent protection function performs a disconnection operation using a heater and a bimetallic provided within of the circuit breaker, allowing the bimetallic to bend, and the function of protection against instantaneous currents performs a disconnection operation using a magnet magnetized by a high current generated instantly.

Depending on the use of the circuit breaker, the size and the current conduction time are variablely adjusted to those in which a disconnection operation must be carried out, and in the case of a thermal-electronic circuit breaker having the previous structure, it is not set to perform a disconnection operation when the current flows below 105% of the nominal current but to perform a disconnection operation above 130% of the nominal current. Also, when the current flows above 105% and below 130%, a time is set individually to begin the disconnection operation according to the size of the current.

Figure 1 is a cross-sectional view illustrating the internal structure of a typical circuit breaker. Referring to Figure 1, the bimetallic 10, heater 11, and magnet 12 above are fastened by a fixing bolt. The heater 11 generates heat due to its induced current, and the generated heat is conducted inside the bimetallic 10. When an overcurrent flows, sufficient heat is generated to deform the bimetallic 10, thereby suppressing the conduction of the overcurrent. Meanwhile, when describing the protection function against instantaneous currents, when a current above the reference current flows instantaneously through it, the magnet 12 is magnetized to pull an armature bar 13 arranged in the right side (with respect to figure 1) of the magnet 12 to the side of the magnet 12 to perform a disconnection operation.

In the above structure, the heat generated by the heater while an overcurrent flows through it is conducted to the side of the magnet along the fixing bolt as well as the bimetallic element. Because of this, the amount of heat driven to the bimetallic element is reduced, thereby producing the problem that the operation of the bimetallic is inaccurate. Because of this, the amount of heat transferred to the side of the bimetallic must be taken into account during the design of the circuit breaker, thereby producing the problem that the design becomes difficult. In addition, the amount of heat conducted varies according to the degree of abrasion of the fixing bolt and the difference in the clamping force, and as a result, there is the problem that the operating characteristics of the circuit breaker become uneven.

US 2009/0295532 discloses a circuit breaker that includes an element heater that includes an elongated bimetallic. US 3 345 591 discloses an electric circuit breaker with disconnecting means including a heating band in the thermal disconnecting means and adjustable air spaces in the magnetic disconnecting means. WO 2013/126061 discloses a magneto-thermal disconnection unit for a circuit breaker. An additional circuit breaker that includes a disconnecting device is disclosed in document KR 2004 0070544.

Summary of the invention

The present disclosure refers to overcoming the above problems in the related technique, and a technical task

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of the present disclosure is to provide a circuit breaker that can constantly maintain the operational characteristics of a circuit breaker.

Another technical task of the present disclosure is to provide a circuit breaker that can allow a bimetallic to be operated accurately according to regulations such as a conduction time, a conduction current value, and the like.

To achieve the above technical tasks, according to the present invention as a circuit breaker that includes a heater configured to generate heat due to a conductive current induced to a mobile contact of the circuit breaker; a bimetallic configured to deform due to the heat generated by the heater to separate a contact point from the mobile contact; a magnet configured to generate a magnetic force to move an armature bar when a current is induced above the previously set reference current; and a housing configured to accommodate the bimetallic and the magnet, at least part of which is composed of a synthetic resin material, is provided the circuit breaker that includes a magnetic fixing portion formed integrally in the housing, and composed of a material of synthetic resin; a magnetic fixing bolt configured to hold the magnet to the magnetic fixing portion; and a bimetallic fixing bolt configured to fix the bimetallic to the heater, in which there is a separation portion between the magnet and the heater, and a bolt housing portion is formed in the heater to prevent the magnetic fixing bolt Contact the heater.

In this case, the circuit breaker may also include heater fixing means configured to fix the heater to the disconnect housing, in which the heater fixing means are attached to the magnetic fixing portion.

In addition, a bimetallic side separation portion may be provided between the heater and the bimetallic element. In this case, the two separation portions can be arranged respectively in the remaining portion excluding the contact portion.

In addition, only a portion of the side end of the magnet can be fixed to the magnetic fixing portion. In addition, the magnet can be separated from the disconnect housing except for the end portion fixed to the magnetic fixing portion.

In addition, an interference avoidance portion may be formed in the heater to accommodate part of the magnetic fixing means.

According to aspects of the present disclosure, a heater and a magnet can be independent of each other and held individually, thereby minimizing the amount of heat transferred from the heater to the magnet, and consequently, keeping the operational characteristics of a bimetallic element constant. . In particular, the magnet can be attached to a magnetic fixing portion composed of a synthetic resin material having a low thermal conductivity, and a magnet side separation portion can be arranged between the heater and the magnet, thereby minimizing further the amount of heat conducted from the heater.

In addition, a portion of bimetallic side separation between the heater and the bimetallic element can also be provided, thereby minimizing the deformation and positional and similar divergence of the bimetallic due to the expansion of the heater.

In addition, only a portion of the side end of the magnet can be attached to the magnetic fixing portion, thereby minimizing the thermal conduction path connected from the heater to the magnet.

Brief description of the drawings

The accompanying drawings, which are included to provide an additional understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention.

In the drawings:

Figure 1 is a schematic diagram illustrating the internal structure of a circuit breaker according to the related technique;

Figure 2 is a partial cross-sectional view illustrating the internal structure of a circuit breaker according to an embodiment of the present disclosure;

Figure 3 is an enlarged partial cross-sectional view illustrating a part of the embodiment illustrated in Figure 2; Y

Figure 4 is an enlarged cross-sectional view illustrating another part of the embodiment illustrated in Figure 2. Detailed description of the invention

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Next in the present document, a circuit breaker will be described in detail according to an embodiment of the present disclosure with reference to the attached drawings.

Before describing, it should be noted that the terms and words used in the description and claims should not be limited or interpreted as typical or literal, and should be interpreted as meaning and concept in accordance with the technical concept of the invention based on the fact that The inventor can define the concept of terms and words to describe the invention in the best way.

Therefore, since the embodiments described in the present invention and configurations shown in the drawings are only the most preferred embodiments and do not represent the entire technical concept of the invention, it should be understood that there may be various equivalents and modification examples that may replace them in the time of application of the present invention.

Figure 2 is a partial cross-sectional view illustrating the internal structure of a circuit breaker according to an embodiment of the present disclosure, and Figure 3 is an enlarged partial cross-sectional view illustrating a part of the embodiment illustrated in Figure 2 Referring to Figures 2 and 3, embodiment 100 may include a housing 102 in which a switch is provided rotatably to selectively switch a current supplied from the power side to the load side, a movable contact 104 rotatably provided inside the housing 102, at an end portion of which a current contact point is provided, and a bimetallic 106 connected to the mobile contact 104 through a traction cable.

The housing 102 is an injection molded part composed of a synthetic resin material, which functions as a circuit breaker shell.

A first fixed contact 108 formed of a conductive material to be fixed to the housing, which is a stationary power side contact point, and a second fixed contact 110, which is a stationary load side contact point, are provided within the housing 102. A space between the first fixed contact and the second fixed contact is electrically connected or disconnected while rotating the mobile contact 104, and Figure 1 illustrates a state in which the mobile contact is not brought into contact with the first and second fixed contact, specifically, a disconnected state.

A disconnect assembly 112 configured to activate the mobile contact and a drive mechanism 114 mechanically connected to the disconnect assembly to operate the disconnect assembly are further provided within the housing 102.

In addition, the drive mechanism 114 may include a plurality of nails 116 mechanically connected to the disconnect assembly 112.

Referring to FIG. 3, the disconnect assembly 112 may include a trigger rotatably fixed 118, and the trigger 118 transfers power between the nail 116 and a crossbar 120.

On the other hand, a magnetic fixing portion 130 provided as a single or individual element with the housing 102 is provided within the housing 102. The magnetic fixing portion 130 is composed of a synthetic resin material, and a part of a contained element in disconnect assembly 112 is fixed thereto.

Specifically, a heater 140 for generating heat to deform the bimetallic 106 when an overcurrent flows is fixed to an upper surface of the magnetic fixing portion 130. Referring to Figure 4, the heater 140 is immovably fixed to the portion of magnetic fixing 130 by the heater fixing bolt 142, and a lower end portion of the bimetallic 106 is fixed to the heater 140 by a bimetallic fixing bolt 144. In this case, the heater 140 is in a state of being set in contact with the bimetallic in a portion adjacent to the bimetallic fixing bolt 144, but separated from the bimetallic 106 in the remaining portion to form a bimetallic side separation portion (G1).

On the other hand, a rod of the armature 150 for rotating the crossbar 120 is provided on the right side of the bimetallic 106, and a magnet 160 formed from a ferromagnetic substance to generate a magnetic force using a current flowing through the heater 140 for pulling the armature bar 150 is provided on the left side of the heater 140. In this case, the magnet 160 is fixed to the magnetic fixing portion 130 by a magnetic fixing bolt 162. In addition, the magnet 160 is simply contacted the magnetic fixing bolt 162 and the magnetic fixing portion 130 but is not in contact with other elements in the remaining portion. In particular, a separation portion (G) exists between heater 140 and magnet 160, and therefore it is observed that all heat transfer paths generated from the heater directly to the side of magnet 160 are suppressed.

In this case, to prevent the magnetic fixing bolt 162 from contacting the heater 140, a bolt housing portion 146 is formed in the heater 140 to pass through it. The bolt housing portion 146 is formed to be larger than the head portion of the magnetic fixing bolt 162 so as not to allow the heater to contact the fixing bolt, and a tool such as a drive device or the like can approach the side of the magnetic fixing bolt.

The operation of the embodiment will be described below. First, heat generation is carried out in the heater 140 when an overcurrent flows, and therefore, heat is conducted to the bimetallic 106 in contact therewith. When the conducted heat reaches a sufficient degree to bend the bimetallic element, the cross bar 120 is rotated while the bimetallic 106 is bent. As a result, the restriction of the trigger 118 is released to rotate, and the nail 116 is rotated by the force of the trigger 118 to operate the drive mechanism 114. The drive mechanism 114 is mechanically connected with the mobile contact 104 to rotate the mobile contact 104, and therefore the circuit is opened.

During the previous procedure, a heat conduction path between the heater and the magnet is suppressed due to the existence of the separation portion (G), and therefore the mayona of the heat generated from the

10 heater is conducted to the bimetallic element. Therefore, the bimetallic can be operated correctly according to the intention at the time of design. In other words, the bimetallic can be operated according to the conduction time and the conduction current. Obviously, although there is a magnetic fixing portion between the heater and the magnet, the amount of heat conducted through them is very small since the magnet is composed of a synthetic resin material.

In addition, the bimetallic side separation portion (G1) performs the role of preventing the bimetallic from becoming deformed while the heater expands due to heat. When the bimetallic side separation portion (G1) does not exist, the expanded heater can push the bimetallic to move it out of the position of the bimetallic element, but the expanded amount of the heater can be absorbed since the side separation portion exists. bimetallic (G1).

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Claims (3)

10 fifteen 20 2. 3. 25 4. 5. 6. 30 Circuit breaker comprising: a heater (140) configured to generate heat due to a conductive current induced to a mobile contact (104) of the circuit breaker; a bimetallic (106) configured to deform due to the heat generated by the heater (140) to separate a contact point from the mobile contact (104); a magnet (160) configured to generate a magnetic force to move an armature rod (150) when a current is induced above the previously set reference current; and a housing (102) configured to accommodate the bimetallic (106) and the magnet (160), characterized in that at least part of the housing (102) is composed of a synthetic resin material, and the circuit breaker further comprises: a magnetic fixing portion (130) is integrally formed in the housing (102), and composed of a synthetic resin material; the heater (140) is fixed to the magnetic fixing portion (130) by a heater fixing bolt (142); the magnet (160) is fixed to the magnetic fixing portion (130) by a magnetic fixing bolt (162); Y a bimetallic fixing bolt (144) is configured to fix the bimetallic (106) to the heater (140), in which there is a separation portion (G) between the heater (140) and the magnet (160), and A bolt housing portion (146) is formed in the heater (140) to prevent the magnetic fixing bolt (162) from contacting the heater (140). Circuit breaker according to claim 1, wherein: the heater fixing bolt (142) is configured to fix the heater (140) to the housing (102), wherein the heater fixing bolt (142) is attached to the magnetic fixing portion (130). Circuit breaker according to claim 1, wherein a portion of separation of the bimetallic side (G1) is disposed between the heater (140) and the bimetallic (106). Circuit breaker according to claim 3, wherein the two separation portions (G, G1) are disposed respectively in the remaining portion excluding the contact portion. Circuit breaker according to claim 1, wherein only one side end portion of the magnet (160) is fixed to the magnetic fixing portion (130). Circuit breaker according to claim 5, wherein the magnet (160) is separated from the housing (102) except for the end portion fixed to the magnetic fixing portion (130).