RU2700790C1 - Automatic circuit breaker and reflector therefor - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: invention relates to the field of low-voltage electrical equipment, in particular, to a reflector for cutting off arcs and air flow in an automatic circuit breaker. Automatic circuit breaker comprises reflectors arranged on both sides of automatic circuit breaker housing, reflector on one side is located inside angle of arc of static contact, and this reflector cuts off space inside arc angle of static contact, wherein reflectors on both sides have a symmetrical structure; reflector can be a partition with a straight edge, or arc-shaped partition, wherein the reflector either dissects the arc angle of the static contact, or occupies the arc angle of the static contact so as to cut off the space inside the arc angle of the static contact. Deflector solves the problem that during process of disconnection at short circuit high-temperature gas is returned from side of angle of static contact arc back into area between movable contact and static contact, causing arc to move repeatedly in arc channel, which leads to long time of disconnection and strong burning of movable and static contacts. Deflector effectively cuts air flow and arc so that arc can effectively penetrate into arc-extinguishing chamber for further damping.

EFFECT: disconnection time is considerably reduced.

8 cl, 8 dwg

Description

Technical field

The present invention relates to the field of low-voltage electrical equipment, in particular to a reflector for cutting off arcs and air flow in a circuit breaker.

BACKGROUND OF THE INVENTION With the development of technology, the size of circuit breakers is decreasing, but their performance is getting higher. During a short circuit shutdown, circuit breakers generate expanding high temperature gases that interfere with the arc in confined spaces. High-temperature expanding gas prevents the effective penetration of the arc into the arcing chamber, which leads to an increase in the duration of the arc outside the arcing chamber. A long stay of the arc outside the arcing chamber, for example, in the case of being in the arc channel, leads to an increase in shutdown time and a decrease in productivity. An arc that stays outside the arcing chamber for a long time also causes strong burning of the arcing plate, movable and static contacts.

High-temperature expanding gas causes a backward flow along the arc, causing the arc to remain outside the arcing chamber, and the arc cannot enter the arcing chamber. The phenomenon of backflow along an arc mainly occurs in the angular region of the arc of a static contact, and in this region the phenomenon of backflow is especially serious. Most existing breakers are not able to prevent the occurrence of the backflow effect along the arc in the angular region of the static contact arc and, therefore, have the aforementioned disadvantages.

Chinese Patent Application CN103123872A discloses a mounting switch with pre-chamber and guide ribs. The mounting switch comprises a housing, a contact assembly in the preliminary chamber, an arcing chamber, and first and second arc guides. The contact node contains a static (fixed) contact and a movable contact. The first and second arc guides lead the arc created in the contact node at the time of inclusion into the arcing chamber. The first arc guide is connected with a static contact, while the preliminary chamber has a plurality of protruding guide ribs on at least one subsurface inside the housing. The protruding guide ribs are located in the direction from the area of the contact node to the area of the arcing chamber, approximately along the direction of movement of the arc. The preliminary chamber has protruding inserts with an annular closed peripheral contour in the area of static contact on at least one subsurface inside the housing. The protruding inserts are located between the guide ribs next to the static contact and the first arc guide, so that the circulation of gas flowing around the insert can be adjusted so that it flows between the guide rib next to the static contact and the first guide arc. The design of the described automatic interrupter takes into account the phenomenon of backward flow along the arc in the angular region of the arc of the static contact and designed the reverse circulation structure in the static contact and the angular region of the arc. The air flow is directed inside the angular region of the arc, the reverse air flow inside the angular region of the arc is reduced, and the difficulty of moving the arc into the arcing chamber caused by the air flow in the angular region of the arc is reduced. However, in an area outside the arc angle, an air flow close to the arc angle, especially air flow just above the arc angle, will also have a significant effect on the arc. The specified circuit breaker does not perform any processing of the air flow outside the angular region of the arc, therefore, the arc will remain for a long time as a result of exposure to air flow in this region.

Disclosure of invention

The invention is a reflector for an automatic chopper and an automatic chopper in the construction of which this reflector is used. The reflector is able to cut off the air flow inside the zone of the angle of the arc of the static contact and beyond.

According to the invention, a reflector for an automatic chopper, comprising reflectors placed on both sides of the housing of the automatic chopper, the reflector on one side being located inside the corner of the arc of the static contact, and this reflector cuts off the space inside the corner of the arc of the static contact.

Advantageously, on one side of the housing on which the static contact is located, a first reflector is located located inside the corner of the arc of the static contact and cutting off the arc and / or air flow, while the second reflector is placed on the other side of the housing and also cuts off the arc and / or air flow.

At least one of the reflectors may be a partition with a straight edge, and this reflector cuts the angle of the arc of the static contact so as to cut off the space inside the corner of the arc of the static contact.

At least one of the reflectors may be an arched partition, this reflector occupying the angle of the arc of the static contact so as to cut off the space inside the corner of the arc of the static contact.

The invention is also an automatic chopper containing reflectors located on both sides of the case of the automatic chopper, the reflector on one side being located inside the corner of the arc of the static contact, and this reflector cuts off the space inside the corner of the arc of the static contact, while the reflectors on both sides have a symmetrical structure .

On one side of the housing on which the static contact is located, a first reflector located inside the corner of the arc of the static contact and cutting off the arc and / or air flow can be placed, while the second reflector is placed on the other side of the housing and also cuts off the arc and / or air flow.

At least one of the reflectors may be a partition with a straight edge, and this reflector cuts the angle of the arc of the static contact so as to cut off the space inside the corner of the arc of the static contact.

At least one of the reflectors may be an arched partition, this reflector occupying the angle of the arc of the static contact so as to cut off the space inside the corner of the arc of the static contact.

The reflector of the present invention solves the problem that during the short-circuit shutdown process, the high-temperature gas returns from the angle of the arc of the static contact back to the area between the movable contact and the static contact, causing the arc to repeatedly move in the arc channel, which leads to a long shutdown time and strong burning of mobile and static contacts. The reflector effectively cuts off the air flow and the arc so that the arc can effectively penetrate the arcing chamber for subsequent extinction. The shutdown time is significantly reduced, the shutdown effect is better.

Brief Description of the Drawings Specific features and advantages of the invention are set forth below with reference to the drawings, in which:

- in FIG. 1 is a structural diagram of a reflector of an automatic chopper according to claim 3;

- in FIG. 2 is a structural diagram of a reflector of an automatic chopper according to claim 4;

- in FIG. 3a and FIG. 3b is a block diagram of a circuit breaker according to claim 7;

- in FIG. 4a and FIG. 4b is a block diagram of a circuit breaker according to claim 8;

- in FIG. 5a and FIG. 5b is a block diagram of a circuit breaker, reflectors located on opposite sides of the housing have a different shape.

A specific embodiment of the invention In order to effectively reduce the difficulty of moving the arc into the arcing chamber caused by the high-temperature expansion gas generated by the arc during the short circuit shutdown process, the static contact design in the position of the arc angle should be optimized. In this case, it is necessary to take into account not only the influence of air flow inside the angular region of the arc, but also the effect of air flow outside the angular region of the arc. In accordance with the present invention, the reflector is located in the corner region of the arc of the static contact and cuts off the space inside the corner region of the arc. In addition, another reflector with a symmetrical structure is located on the other side of the housing in a position corresponding to the angular region of the arc, so as to cut off the air flow both inside the angular region of the arc and outside it, and thus reduce the effect of the reverse flow of the arc in its angular region . The arc has the ability to effectively penetrate the arcing chamber for subsequent arcing.

The circuit breaker is equipped with reflectors on both sides of the housing, the reflector on one side being located inside the corner of the arc of the static contact and cuts off the space inside the corner of the arc of the static contact. The reflector may have a different shape. The reflector on the opposite side has a symmetrical structure. In this case, the term "symmetrical structure" means that the second reflector on the other hand is located in a symmetrical position, that is, in a corresponding position on the other side of the housing, and has a corresponding size. This can also be interpreted as follows: if we assume that there is a symmetrical "virtual" static contact on the other side of the case, the reflector on the opposite side is located exactly in the corner of the "virtual" static contact arc and cuts off the space inside the arc angle. It should be noted that the term “symmetrical” here refers to the respective mounting positions and dimensions of the reflectors, while the shapes of the reflectors need not be the same.

In FIG. 1 shows a block diagram of a reflector of an automatic chopper according to paragraph 3 of the claims. The reflector 101, located on the housing 103, is a partition with a straight edge 111. Such a reflector 101 with a straight edge 111 cuts the angle of the arc 102 of the static contact so as to cut off the space inside the corner of the arc 102 of the static contact. According to FIG. 1, a reflector 101 with a straight edge 111 intersects the angle of the arc 102 in the longitudinal direction and divides the space inside the angle of the arc 102 into two parts separated from each other.

In FIG. 2 shows a block diagram of a reflector of an automatic chopper according to claim 4. The reflector 101, located on the housing 103, is a partition with an arched edge 112. The reflector 101 with an arched edge 112 cuts the angle of the arc 102 of the static contact so as to cut off the space inside the corner of the arc 102 of the static contact. According to FIG. 2, a reflector 101 with an arcuate edge 112 has a shape that corresponds to the angle of the arc 102, and occupies a space within the angle of the arc 102.

In addition to the shape of the reflectors shown in FIG. 1 and FIG. 2, other forms of reflectors may be used. It should be noted that the reflectors can be of any shape, which allows you to implement the function of cutting off the space inside the arc angle.

Two reflectors are provided on different sides of the circuit breaker case - the first and second. The first reflector is located on one side of the housing on which the static contact is located, and is inside the corner of the arc of the static contact. The second reflector is located on the other side of the housing. The first and second reflectors have a symmetrical structure. That is, assuming that there is a symmetrical “virtual” static contact on the other side of the housing, it can be argued that the reflector on the opposite side is located exactly in the corner of the “virtual” static contact arc and cuts off the space inside the arc angle. And the first and second reflectors perform the function of cutting off the arc and / or air flow.

The present invention also provides an automatic chopper using the aforementioned chopper. Reflectors are provided on both sides of the circuit breaker housing. The reflector on one side is located inside the corner of the arc of the static contact and cuts off the space inside the corner of the arc of the static contact. Reflectors on both sides have a symmetrical structure. The first reflector is located on one side of the housing on which the static contact is located, and is inside the corner of the arc of the static contact. The second reflector is located on the other side of the housing. Both the first and second reflectors perform the function of cutting off the arc and / or air flow. Each of the reflectors may have a straight edge, as shown in FIG. 1, or an arched edge, as shown in FIG. 2. Reflectors can have various shapes that allow you to implement the function of clipping space inside the corner of the arc.

In FIG. 3a and FIG. 3b shows a block diagram of a circuit breaker according to claim 7. The first 301 and second 302 reflectors, located on different sides of the circuit breaker, have the same shape and are symmetrical to each other. Both the first 301 and second 302 reflectors are straight-edge reflectors. As shown in FIG. 3a, the first reflector 301, located on the side of the housing where the static contact is located, is a reflector with a straight edge, and cuts off the arc and / or air flow. The arrow in FIG. 3a shows the trajectory of the arc and / or air flow. As shown in FIG. 3b, the second reflector 302 is located on the other side of the housing and also represents a reflector with a straight edge. The second reflector 302 is located in a position symmetrical to the first reflector 301. The second reflector 302 cuts off the arc and / or air flow. The arrow in FIG. 3b shows the trajectory of the arc and / or air flow.

In FIG. 4a and FIG. 4b shows a block diagram of a circuit breaker according to claim 8. The first 401 and second 402 reflectors, located on different sides of the circuit breaker, have the same shape and are located symmetrically to each other. Both the first 401 and the second 402 reflectors are reflectors with an arched edge. As shown in FIG. 4a, a first reflector 401, located on the side of the housing where the static contact is located, is a reflector with an arched edge and cuts off the arc and / or air flow. The arrow in FIG. 4a shows the trajectory of the arc and / or air flow. As shown in FIG. 4b, the second reflector 402 is located on the other side of the housing and also is a reflector with an arcuate edge. The second reflector 402 is located in a position symmetrical to the first reflector 401. The second reflector 402 cuts off the arc and / or air flow. The arrow in FIG. 4b shows the trajectory of the arc and / or air flow.

Reflectors located on opposite sides of the housing may have different shapes. In FIG. 5a and FIG. 5b is a block diagram of a circuit breaker according to a further embodiment of the present invention. The first 501 and second 502 reflectors, located on different sides of the circuit breaker, have a different shape, but are symmetrical to each other and have similar dimensions. As shown in FIG. 5a, the first reflector 501, located on the side of the housing where the static contact is located, is a reflector with a straight edge, and cuts off the arc and / or air flow. The arrow in FIG. 5a shows the trajectory of the arc and / or air flow. As shown in FIG. 5b, the second reflector 502 is located on the other side of the housing and is a reflector with an arcuate edge. A second arched-edge reflector 502 cuts off the arc and / or airflow. The arrow in FIG. 5b shows the trajectory of the arc and / or air flow. In FIG. 5a and FIG. 5b, the meaning of the term "symmetrical structure" in more detail is explained in the context of the present invention. Symmetric structure means that the second reflector is located symmetrically to the first reflector located on the opposite side of the housing. That is, the second reflector is located in a similar position on the other side of the housing and has corresponding dimensions. This can also be interpreted as follows: assuming that there is a symmetrical “virtual” static contact on the other side of the housing, it can be argued that the second reflector is located exactly in the corner of the “virtual” static contact arc and cuts off the space inside the arc angle. The term "symmetrical" here refers to the respective mounting positions and dimensions of the reflectors, while the shapes of the reflectors need not be the same.

The reflector of the present invention is able to solve the problem that during the short-circuit shutdown process, the high-temperature gas returns from the angle of the arc of the static contact back to the area between the movable contact and the static contact, causing the arc to repeatedly move in the arc channel, which leads to long shutdown times and strong burning of mobile and static contacts. The reflector effectively cuts off the air flow and the arc so that the arc can effectively penetrate the arcing chamber for subsequent extinction. Shutdown time is significantly reduced, the shutdown effect is better.

The above embodiments are presented to those skilled in the art for implementing or using the invention, provided that various modifications or changes are made by those skilled in the art without departing from the spirit and principle of the invention; The above embodiments may be modified and modified in various ways, therefore, the scope of legal protection of the present invention is not limited to the above embodiments and should correspond to the maximum amount of innovative features mentioned in the claims.

Claims (8)

1. A reflector for an automatic chopper, comprising reflectors placed on both sides of the housing of the automatic chopper, the reflector on one side being located inside the arc angle of the static contact, and this reflector cuts off the space inside the corner of the arc of the static contact. 2. The reflector according to claim 1, characterized in that on one side of the housing on which the static contact is located, there is a first reflector located inside the corner of the arc of the static contact and cutting off the arc and / or air flow, while the second reflector is placed on the other side of the housing and also cuts off the arc and / or air flow. 3. The reflector according to claim 2, characterized in that at least one of the reflectors is a partition with a straight edge, and this reflector cuts the angle of the arc of the static contact in such a way as to cut off the space inside the angle of the arc of the static contact. 4. The reflector according to claim 2, characterized in that at least one of the reflectors is an arc-shaped partition, and this reflector occupies the angle of the arc of the static contact so as to cut off the space inside the angle of the arc of the static contact. 5. An automatic chopper containing reflectors located on both sides of the case of the automatic chopper, the reflector on one side being located inside the corner of the arc of the static contact, and this reflector cuts off the space inside the corner of the arc of the static contact, while the reflectors on both sides have a symmetrical structure. 6. The automatic chopper according to claim 5, characterized in that on one side of the housing on which the static contact is located, there is a first reflector located inside the corner of the arc of the static contact and cutting off the arc and / or air flow, while the second reflector is placed on the other side of the housing and also cuts off the arc and / or air flow. 7. The automatic chopper according to claim 6, characterized in that at least one of the reflectors is a partition with a straight edge, and this reflector cuts the angle of the arc of the static contact in such a way as to cut off the space inside the corner of the arc of the static contact. 8. The automatic chopper according to claim 6, characterized in that at least one of the reflectors is an arcuate partition, and this reflector occupies the angle of the arc of the static contact so as to cut off the space inside the corner of the arc of the static contact.

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