KR20180105638A - Circuit breaker, and the exhaust structure - Google Patents

Abstract

Circuit breaker, and its exhaust structure. The circuit breaker includes exhaust ports (101, 102, 103). The exhaust port is aligned with the tail of the arc extinguishing chamber 106. The exhaust space of the exhaust port overlaps with the joining apparatuses (401, 402) of the circuit breaker. In the case of incompatibility, the joining apparatus occupies the exhaust space. In the case of the joining of the joining device, the exhaust space is emptied. The exhaust structure of the circuit breaker greatly improves the exhaust capacity by utilizing the unoccupied space of the joining device, increasing the number of exhaust ports, and extending the exhaust space. Further, the exhaust structure has a partition projection 104 for partitioning an electric arc, the partition projection achieves a function of supporting the SO room, and the SO &sub2; capacity is prevented from being reduced due to the impact change of the SO room .

Description

Circuit breaker, and the exhaust structure

The present invention relates to the field of low-voltage electrical devices, and more particularly to the exhaust structure of circuit breakers.

With technological advances, the size of circuit breakers is getting smaller, but the technical performance indicators are getting even higher. The circuit breaker will generate a high temperature inflation gas during the short-circuit breaking process. As the size of the circuit breaker is reduced, if the hot inflation gas can not be removed in time, an airflow will be formed to prevent the arc from entering the arc extinguishing chamber efficiently. Retention of the arc will form an arc reflux, causing the arc to stagnate within the arc channel and leading to severe combustion at long interruption times to the arc discharge plate and the movable / stationary contact.

In the case of small circuit breakers, improvements in exhaust capacity have always been an important means of improving performance indicators. CN201796768U discloses an electric wiring switching device having a soffit device, particularly an electric wiring switching device having a casing, a terminal connecting chamber and a soffit device. The wiring switch device includes a small room. The SOH plate laminate having the SOHO plates stacked mutually in parallel is disposed in the SOHO chamber, and the SOHO plates are held apart from each other in the stacking direction. In addition, the exhaust flow can be discharged from the SOHO chamber at the position of the exhaust side. The first flow guide wall element is disposed within the wiring switch device casing and is guided at least partially through the terminal connecting chamber with the aid of the first flow guide wall element. CN 102243945A discloses an installation switching device including a housing. The housing includes an upper wide side, a lower wide side, a front side, a fixed side, a narrow side and a soffit device. The intermediate piece is disposed in the housing in such a manner as to accommodate the SOHO device in a partial space between the upper wide side and the intermediate piece. The first exhaust channel is formed between the exhaust wall extending in a manner parallel to the wide side and the upper wide side. The first exhaust channel directs the exhaust flow from the SOHO device end towards the narrow side to the first exhaust hole in the narrow side of the housing. The end insulating portion is disposed between the narrow side portion and the bottom wide side portion located on the exhaust gas wall of the intermediate piece. An intermediate hole is provided on the exhaust gas wall of the intermediate piece. The middle hole is aligned with the insulating portion hole in the end insulating portion to form the second exhaust gas channel. The second exhaust gas channel directs the first branch flow from a portion between the end spatial compartment and the lower wide side to a second exhaust gas hole in the narrow side wall. CN201796768U and CN102243945A increase the exhaust capacity by guiding the exhaust to the air flow through the configuration of the exhaust channel, thereby improving the problem of air flow stagnation caused by the turbulence of the air flow. However, due to the continued miniaturization of the circuit breaker, even though the space in the circuit breaker becomes smaller and the air flow can properly drain out along the exhaust channel, the large gas volume and small space in the circuit breaker, Will affect the outcome of SOHO.

CN203013659U discloses a circuit breaker with an arc running channel. The pedestal and the cover are symmetrically disposed with a long positioning protruding diameter. The other side of the fire extinguishing chamber, far from the arc travel channel, is adjacent to the long positioning protruding diameter of the pedestal and the cover. The arc partition protrusion diameter is symmetrically arranged on the lower side of the long positioning protruding diameter of the pedestal and the cover. The arc partitioning protruding diameter can be used to form a curved arc running channel, the pedestal behind the arc partitioning diameter and the side walls of the cover have an arc ejection port. CN203013659U assists SOHO by blocking the arc, but CN203013659U does not solve the problem that the airflow can not be exhausted in time.

The present invention proposes an exhaust structure of a circuit breaker that solves the exhaust problem of a miniature circuit breaker by enlarging the exhaust space and increasing the exhaust volume.

According to an embodiment of the present invention, an exhaust structure of a circuit breaker is provided. The exhaust structure includes an exhaust port, the exhaust port is aligned with a tail of an arc extinguishing chamber, and an exhaust space of the exhaust port overlaps with a wiring device of the circuit breaker. When not connected to the wiring device, the wiring device takes up the exhaust space. When connected to the wiring device, the exhaust space is emptied.

According to one embodiment, three exhaust ports are provided. The three exhaust ports are formed on the housing of the circuit breaker, and are aligned with the upper, middle, and lower portions of the tail of the SO room. The three exhaust ports are arranged at equal intervals. The exhaust space of the exhaust port aligned with the middle portion of the tail of the SOHO chamber overlaps with the wiring device of the circuit breaker.

According to one embodiment, the base and cover of the circuit breaker each have corresponding grooves. When the base and the cover are mounted, the groove forms the three exhaust ports, and at least one exhaust port is divided by the components of the circuit breaker.

According to one embodiment, the exhaust structure further includes at least one block protrusion. The block protrusions extend laterally from the tail of the small room to the position of the at least one exhaust port and extend longitudinally from one exhaust port to another adjacent exhaust port.

According to one embodiment, the block protrusion is formed on the housing of the circuit breaker. One end of the block protrusion contacts the tail of the SO room and supports the SO room.

According to an embodiment of the present invention, a circuit breaker is provided. At least one exhaust port is formed on the housing of the circuit breaker, and the exhaust port is aligned with the tail of the SOHO chamber. The exhaust space of the exhaust port overlaps the wiring device of the circuit breaker. When not connected to the wiring device, the wiring device takes up the exhaust space. When connected to the wiring device, the exhaust space is emptied.

According to one embodiment, three exhaust ports are formed on the housing of the circuit breaker. The three exhaust ports are respectively aligned with the upper, middle, and lower portions of the tail of the SO room. The three exhaust ports are arranged at equal intervals. And the exhaust space of the exhaust port aligned with the middle portion of the tail of the SOHO chamber overlaps with the wiring device of the circuit breaker.

According to one embodiment, the housing of the circuit breaker includes a base and a cover. The base and the cover each have a corresponding groove. When the base and the cover are mounted, the groove forms the three exhaust ports, and at least one exhaust port is divided by the components of the circuit breaker.

According to one embodiment, at least one block protrusion is formed on the housing of the circuit breaker. The block protrusions extend laterally from the tail of the small room to the position of the at least one exhaust port and extend longitudinally from one exhaust port to another adjacent exhaust port.

According to one embodiment, one end of the block protrusion contacts the tail of the aloha chamber and supports the aloha chamber.

The exhaust structure of the circuit breaker of the present invention significantly improves the exhaust capacity by utilizing the unoccupied space of the wiring device, increasing the number of exhaust ports, and extending the exhaust space. Further, the exhaust structure has a block protrusion for blocking the arc. In addition, the block protruding portion functions as a support for the small room, thereby avoiding the reduction of the small capacity due to the change of the small room caused by the impact.

BRIEF DESCRIPTION OF THE DRAWINGS The features, nature and advantages of the present invention will become apparent from the following description of an embodiment including the drawings.
1 is a plan view of an exhaust structure of a circuit breaker according to an embodiment of the present invention;
2 is a perspective view of an exhaust structure of a circuit breaker according to another embodiment of the present invention,
Figures 3a and 3b show the structure for the base and cover of a circuit breaker having an exhaust structure,
4 is a view showing an operating state of a circuit breaker having an exhaust structure with respect to a wiring device;

The present invention discloses an exhaust structure of a circuit breaker. The exhaust structure includes an exhaust port, and the exhaust port is aligned with the tail of the SOHO chamber. The exhaust space of the exhaust port overlaps the wiring device of the circuit breaker. When not connected to the wiring device, the wiring device occupies an exhaust space. When connected to the wiring device, the exhaust space is emptied.

According to one embodiment, the exhaust structure includes at least three exhaust ports. The at least three exhaust ports are aligned with the tail of the SO room, and the at least three exhaust ports are arranged at equal intervals. According to one embodiment, the exhaust structure includes three exhaust ports, and the three exhaust ports are respectively aligned with the upper, middle, and lower portions of the tail of the SO room. The exhaust space of the exhaust port aligned with the middle portion of the tail of the SOHO chamber overlaps with the wiring device of the circuit breaker. The exhaust structure further includes at least one block protrusion. The block protrusions extend laterally from the tail of the small room to the position of the at least one exhaust port and extend longitudinally from one exhaust port to another adjacent exhaust port.

As shown in Figs. 1 and 2, Figs. 1 and 2 respectively show a plan view and a perspective view of an exhaust structure of a circuit breaker according to an embodiment of the present invention. According to the illustrated embodiment, the exhaust structure includes three exhaust ports, that is, a first exhaust port 101, a second exhaust port 102 and a third exhaust port 103, and a block protrusion 104. Three exhaust ports and block protrusions are all formed on the housing of the circuit breaker. As shown in Figs. 3A and 3B, the housing of the circuit breaker is formed by combining the base 105 and the cover 108. Fig. 3A, the base 105 has a first base groove 501, a second base groove 502, a third base groove 503, and a base projection 504. The base 105 further includes a base contact plate 507. 3B, the cover 108 has a first cover groove 801, a second cover groove 802, a third cover groove 803, and a cover projection 804. The cover 108 further includes a cover contact plate 807. The first base groove 501, the second base groove 502, the third base groove 503, the base protrusion 504 and the base contact plate 507 have a first cover groove 801, a second cover groove Quot; one-to-one "correspondence with the third cover groove 802, the third cover groove 803, the cover projection 804 and the cover contact plate 807. [ When the base 105 and the cover 108 are mounted, the base and the grooves and protrusions on the cover are connected to the first exhaust port 101, the second exhaust port 102, the third exhaust port 103 and the block protrusion 104 ). Here, the second exhaust port 102 is formed directly by splicing the second base groove 502 and the second cover groove 802. The third exhaust port 103 is formed directly by splicing the third base groove 503 and the third cover groove 803. The block protrusion 104 is formed directly by splicing the base protrusion 502 and the cover protrusion 804. The second exhaust port 102, the third exhaust port 103, and the block protrusion 104 are both embodied as a single structure. The first exhaust port 101 is divided into two parts. The base contact plate 507 and the cover contact plate 807 form a complete contact plate when spliced. The end face 571 of the base contact plate 507 and the first base groove 501 form a first portion 101a of the first exhaust port. The end face 871 of the cover contact plate 807 and the first cover groove 801 form a second portion 101b of the first exhaust port. The first portion 101a and the second portion 101b form the first exhaust port 101 as shown in Fig. According to the illustrated embodiment, at least one exhaust port (first exhaust port) of the three exhaust ports is divided by a component (contact plate) of the circuit breaker.

1, the first exhaust port 101 is aligned with the upper portion of the tail of the small chamber 106, the second exhaust port 102 is aligned with the middle portion of the tail of the small chamber 106, The third exhaust port 101 is aligned with the lower portion of the tail of the SOHO chamber 106. According to the embodiment shown in Fig. 1, the block projection 104 has a zigzag shape similar to the "Z" character. The upper end 141 of the block projection 104 comes into contact with the tail of the soot chamber 106. The block projection 104 contacts the tail of the small room 106 to support the small room 106. [ If an arc enters the small chamber 106 during the blocking process, a strong thrust will be instantaneously generated to act on the small chamber 106. In order to prevent the small room 106 from being biased by the thrust, the block protrusion 104 plays a role of supporting and positioning, thereby avoiding the reduction of the small capacity due to the change of the small room caused by the impact . 1, the position at which the upper end 141 of the block projection 104 contacts the alumina chamber 106 when viewed from the longitudinal direction is located approximately in the middle of the alumina chamber 106, Lt; RTI ID = 0.0 > 102 < / RTI > The position of the lower end of the block protrusion 104 is approximately at the lower portion of the soot chamber 106 or at the same height as the third exhaust port 103. The block protrusion 104 extends from the small chamber 106 to a position below the second exhaust port 102 so as to extend from the closest exhaust port (second exhaust port 102) to the small chamber 106 ) In a direction substantially perpendicular to the surface of the substrate. In the case of the above-described configuration, the block projection 104 can effectively block arc and air flow. Although the illustrated block projection 104 has a zigzag shape similar to the "Z" character, the block projection 104 may have a different shape. However, the shape of the block protrusion 104 satisfies the following condition: the block protrusion 104 extends laterally from the tail of the small chamber to the position of the at least one exhaust port, and the block protrusion extends from one exhaust port And extend in the longitudinal direction to another adjacent exhaust port.

The distance between the first exhaust port 101, the second exhaust port 102, and the third exhaust port 103 is substantially the same, which is approximately one half of the height of the SOHO chamber 106. The sizes of the openings of the first exhaust port 101, the second exhaust port 102 and the third exhaust port 103 are both 1.8 mm-3 mm and the sizes of the first exhaust port 101, the second exhaust port 102, And the opening size of the third exhaust port 103 are not generally set to be the same, they can be set to be the same. In general, only one aperture range needs to be limited. The first exhaust port 101, the second exhaust port 102 and the third exhaust port 103 formed on the base 105 and the cover 108 increase the number of exhaust passages and increase the volume of the exhaust space .

It should be noted that the position where the second exhaust port 102 is located overlaps with the wiring device of the circuit breaker. Fig. 4 shows the operating state of the circuit breaker having the exhaust structure with respect to the wiring device. As shown in Fig. 4, two wiring devices of a circuit breaker are disclosed, and include a first wiring device 401 on the left side and a second wiring device 402 on the right side. It should be noted that the wiring device of the circuit breaker shown in Fig. 4 is intended to show the position of the second exhaust port 102, and this is not intended to limit the wiring device itself. The exhaust space 122 corresponding to the second exhaust port 102 overlaps with the wiring device. When the wiring device such as the first wiring device 401 on the left side of FIG. 4 is not connected, the wiring device will occupy the exhaust space 122. When the wiring device such as the second wiring device 402 on the right side of FIG. 4 is connected, the wiring device is lifted upward to empty the exhaust space 122. When a circuit breaker is used, the wiring device is inevitably lifted upwardly for connection, leaving the exhaust space 122 free. Thus, when the circuit breaker is used, the second exhaust port 102 and the exhaust space 122 are used, thereby increasing the exhaust space.

Although the above-described embodiment has three exhaust ports and block protrusions, one skilled in the art can configure the number and position of the exhaust ports according to actual requirements, and configure or cancel the block protrusions as necessary. The exhaust structure proposed by the present invention mainly includes an exhaust port, and the exhaust port is aligned with the tail of the SOHO chamber. The exhaust space of the exhaust port overlaps with the wiring device of the circuit breaker. When not connected to the wiring device, the wiring device occupies the exhaust space. When connected to a wiring device, the exhaust space is emptied.

Further, the present invention provides a circuit breaker having the exhaust structure described above. At least one exhaust port is formed on the housing of the circuit breaker, and the exhaust port is aligned with the tail of the SOHO chamber. The exhaust space of the exhaust port overlaps with the wiring device of the circuit breaker. When not connected to the wiring device, the wiring device occupies the exhaust space. When connected to a wiring device, the exhaust space is emptied.

According to one embodiment, at least three exhaust ports are formed on the housing of the circuit breaker. At least three exhaust ports are aligned with the tail of the SOHO chamber, and at least three exhaust ports are arranged at equal intervals. At least one block protrusion is formed on the housing of the circuit breaker. The block protrusions extend laterally from the tail of the small chamber to the position of the at least one exhaust port and extend longitudinally from one exhaust port to another adjacent exhaust port. It should be noted that those skilled in the art will be able to configure the number and position of the exhaust ports and provide or cancel block protrusions according to actual requirements.

According to one embodiment, for example, in a circuit breaker having an exhaust structure as described above, three exhaust ports are formed on the housing of the circuit breaker. The three exhaust ports are aligned with the upper, middle, and lower portions of the tail of the small room, respectively. The exhaust space of the exhaust port aligned with the middle portion of the tail of the SOHO chamber overlaps with the wiring device of the circuit breaker. The housing of the circuit breaker includes a base and a cover. The base and the cover each have a corresponding groove. When the base and the cover are mounted, the groove forms three exhaust ports. The at least one exhaust port is divided by a component of the circuit breaker. For example, in a circuit breaker having an exhaust structure as described above, the first exhaust port is divided into two parts by the contact plate. One end of the block projection contacts the tail of the small room and supports the small room.

The exhaust structure of the circuit breaker of the present invention significantly improves the exhaust capacity by utilizing the unoccupied space of the wiring device, increasing the number of exhaust ports, and extending the exhaust space. Further, the exhaust structure has a block protrusion for blocking the arc. In addition, the block protruding portion functions as a support for the small room, thereby avoiding the reduction of the small capacity due to the change of the small room caused by the impact.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined by the appended claims. , The scope of protection of the present invention should not be limited to the embodiments described above but should be based on the maximum range of the innovative features described in the claims.

Claims (10)

An exhaust structure of a circuit-breaker, comprising an exhaust port,
Wherein the exhaust port is aligned with a tail of an arc extinguishing chamber and the exhaust space of the exhaust port overlaps with the wiring device of the circuit breaker and is not connected to the wiring device, The exhaust space occupying the exhaust space and being connected to the wiring device,
Exhaust structure.
The method according to claim 1,
Three exhaust ports are provided, the three exhaust ports are formed on the housing of the circuit breaker, the three exhaust ports are aligned with the upper, middle and lower portions of the tail of the SO room, The exhaust ports of the exhaust port being arranged at the same interval and aligned with the middle portion of the tail of the soot chamber overlap with the wiring device of the circuit breaker,
Exhaust structure.
3. The method of claim 2,
Wherein the base and the cover of the circuit breaker each have a corresponding groove, and when the base and the cover are mounted, the groove forms the three exhaust ports, and at least one exhaust port is connected to a component of the circuit breaker Divided by,
Exhaust structure.
3. The method of claim 2,
Wherein the block protrusions extend laterally from the tail of the SO room to the position of the at least one exhaust port and extend longitudinally from one exhaust port to another adjacent exhaust port ,
Exhaust structure.
5. The method of claim 4,
Wherein the block protrusion is formed on a housing of the circuit breaker, and one end of the block protrusion is in contact with a tail of the SO room and supports the SO room,
Exhaust structure.
In a circuit breaker,
Wherein at least one exhaust port is formed on the housing of the circuit breaker, the exhaust port is aligned with the tail of the SO room, the exhaust space of the exhaust port overlaps with the wiring device of the circuit breaker, The wiring device occupies the exhaust space, and when connected to the wiring device, the exhaust space is emptied,
Circuit breaker.
The method according to claim 6,
Wherein three exhaust ports are formed on a housing of the circuit breaker, the three exhaust ports are respectively aligned with upper, middle and lower portions of the tail of the SO room, the three exhaust ports are arranged at equal intervals, And the exhaust space of the exhaust port, which is aligned with the middle portion of the tail of the small room, overlaps with the wiring device of the circuit breaker,
Circuit breaker.
8. The method of claim 7,
Wherein the housing of the circuit breaker includes a base and a cover, each of the base and the cover has a corresponding groove, and when the base and the cover are mounted, the groove forms the three exhaust ports, Wherein the exhaust port of the circuit breaker is divided by a component of the circuit breaker,
Circuit breaker.
The method according to claim 6,
Wherein at least one block protrusion is formed on the housing of the circuit breaker and the block protrusion extends laterally from the tail of the SO room to the position of the at least one exhaust port and extends from one exhaust port to another adjacent exhaust port And extending in the longitudinal direction,
Circuit breaker.
10. The method of claim 9,
Wherein one end of the block projection is in contact with the tail of the small-
Circuit breaker.

Images