RU223925U1 - ISOLATING CONTACTOR CONSTRUCTION - Google Patents

Abstract

The utility model relates to the field of electrical products - contactors. The technical result consists in providing electrical insulation between the main cavity and the auxiliary cavity by preventing the spread of an electric arc between them. The insulating structure of the contactor contains a housing assembly, a contact holder and a spark screen. The housing assembly contains a main body and an auxiliary body of a composite type, connected to each other in the height direction of the contactor, the housing assembly is provided with a sliding cavity, the main body is provided with a main cavity configured to install the main contact, the auxiliary housing is equipped with an auxiliary cavity configured to install auxiliary contact, and both the main cavity and the auxiliary cavity are in communication with the sliding cavity. The contact holder is positioned to slide in the sliding cavity and is configured to install a movable contact bridge, and when the contact holder moves along the sliding cavity, the movable contact bridge leads to the separation of the movable contact from the fixed contact. The spark screen is located between the main cavity and the sliding cavity and is connected to the housing assembly, which reduces the possibility of the electric arc passing in the main cavity to the auxiliary cavity, and also reduces the possibility of the electric arc passing in the auxiliary cavity to the main cavity. 8 salary f-ly, 5 ill.

Description

The utility model relates to the field of contactor technology, and more specifically to the insulating structure of a contactor.

Prerequisites for the utility model

A contactor is an automatic electromagnetic switch capable of causing a moving contact to contact a fixed contact and separate them by electromagnetic force, thereby turning on or off the contactor current in a circuit, and is widely used in power on/off switches and control circuits. The contactor contains a block of main contacts and a block of auxiliary contacts. Between the electric arc generated in the main contact block and the electric arc generated in the auxiliary contact block, mutual convective diffusion easily occurs, which affects the normal use of the contactor. Therefore, it is necessary to install an insulation structure between the main contact block and the auxiliary contact block to improve the electrical insulation effect between the main contact block and the auxiliary contact block.

Essence of a utility model

In view of the above problems, the utility model proposes a contactor insulation structure that can effectively provide electrical isolation of the main cavity from the auxiliary cavity.

According to one aspect of embodiments of the utility model, an insulating contactor structure is provided. The insulating structure of the contactor contains a housing assembly, a contact holder and a spark screen. The housing assembly contains a main body and an auxiliary body of a composite type, connected to each other in the height direction of the contactor, the housing assembly is provided with a sliding cavity, the main body is provided with a main cavity configured to install the main contact, the auxiliary housing is equipped with an auxiliary cavity configured to install auxiliary contact, and both the main cavity and the auxiliary cavity are in communication with the sliding cavity. The contact holder is positioned to slide in the sliding cavity and is configured to install a movable contact bridge, and when the contact holder moves along the sliding cavity, the movable contact bridge leads to the separation of the movable contact from the fixed contact. The spark screen is connected to the housing assembly and is located between the main cavity and the sliding cavity, and is configured to block the electric arc that occurs when the moving contact is separated from the fixed contact, ensuring electrical isolation of the main cavity from the auxiliary cavity.

Thanks to the above solution, the spark shield is located between the main cavity and the sliding cavity, in case the electric arc generated by the separation of the main moving contact and the main fixed contact in the main cavity propagates to one side close to the spark shield of the main cavity and collides with the spark shield screen, the spark screen will change the propagation path of the electric arc so that the electric arc only propagates in the main cavity and cannot easily propagate to the sliding cavity, thereby reducing the possibility of the electric arc in the main cavity propagating to the auxiliary cavity through the sliding cavity. Similarly, in case the electric arc generated by the separation of the auxiliary moving contact and the auxiliary fixed contact in the auxiliary cavity propagates from the auxiliary cavity to one side close to the spark shield of the sliding cavity and collides with the spark shield, the spark shield will also change the propagation path electric arc so that the electric arc propagates only in the auxiliary cavity or in the sliding cavity and cannot easily propagate to the main cavity, thereby reducing the possibility of the electric arc in the auxiliary cavity propagating to the main cavity through the sliding cavity.

In some embodiments, the movable contact bridge comprises at least one main movable contact bridge. Both ends of each main movable contact bridge respectively correspond to one main cavity, both openings of the cavities representing two main cavities corresponding to each main movable contact bridge face the sliding cavity, and the opening of the cavity representing each main cavity is provided with a spark screen.

With the above solution, the electric arc generated in each main cavity is blocked by a spark shield located in the opening of the cavity constituting the main cavity, so that the electric arc propagates only in the main cavity and cannot easily propagate to the sliding cavity, thereby reducing the possibility propagation of the electric arc in the main cavity to the auxiliary cavity through the sliding cavity. In addition, the spark shield located in the opening of the cavity constituting the main cavity is also capable of reducing the possibility of the electric arc in the auxiliary cavity spreading to the main cavity through the sliding cavity, and enhancing the electrical insulation effect between the main cavity and the auxiliary cavity.

In some embodiments, two side walls of the spark shield are in contact with two opposing side walls of the cavity opening to cover a portion of the cavity opening.

Due to the above solution, when the electric arc generated in the main cavity propagates to one side close to the spark screen of the main cavity, the electric arc does not easily bypass the spark screen and propagates from both sides of the spark screen to the sliding cavity, thereby reducing the possibility of propagation electric arc in the main cavity to the auxiliary cavity through the sliding cavity. Similarly, when the electric arc originating in the auxiliary cavity propagates to one side close to the spark shield of the sliding cavity, the electric arc does not easily bypass the spark shield and propagates from both sides of the spark shield to the main cavity, thereby reducing the possibility of arc propagation in the auxiliary cavity to the main cavity through the sliding cavity. Therefore, the insulation effect of the spark shield arc is improved, the electrical insulation between the main cavity and the auxiliary cavity is ensured, the influence of the main cavity and the auxiliary cavity on each other is reduced, and the safety of using the contactor is improved.

In some embodiments, the gap between one side proximate the contact holder, the spark shield and the contact holder is greater than 0 and less than or equal to 0.5 mm; and/or the size of the spark shield in the direction along the length of the contactor is greater than or equal to 0.5 mm.

The above solution can ensure the normal movement of the contact holder along the sliding cavity, reduce the possibility of tilting caused by the contact holder driving the movable contact bridge, thereby affecting the normal contact between the movable contact and the fixed contact on the movable contact bridge, and reduce the possibility of electric arc propagation, caught in the sliding cavity, from one side of the gap to the other side, thereby affecting the electrical insulation effect between the main cavity and the auxiliary cavity. In addition, the arcing resistance of the spark screen is also increased, thereby achieving the arc insulation effect of the spark screen.

In some embodiments, the spark shield is removably coupled to the main body, or the spark shield and the auxiliary housing are integrally formed.

Thanks to the above solution, when the spark shield is detachably connected to the main body, after the contact holder equipped with the movable contact bridge passes into the sliding cavity, the spark shield is connected to the main body, so the spark shield provides the arc isolation effect without affecting the installation of the movable contact bridge. When the spark shield and the auxiliary housing are formed as one piece, the number of components used is reduced and the number of installation operations of the spark shield is reduced, thereby improving the installation efficiency of the contactor.

In some embodiments, one side proximal to the main body of the auxiliary body is provided with a protruding member, the protruding member extends into the main cavity and is attached to a wall of the cavity constituting the main cavity, and the auxiliary body is connected to the main body by the protruding member.

Thanks to the above solution, the protruding element extends into the main cavity without occupying additional space in the height direction of the contactor, so it is possible to select a larger size of the protruding element extending into the main cavity. Thus, when the auxiliary body is connected to the main body by a protruding member extending into the main cavity, the flexibility of the connection arrangement between the protruding member and the main body is increased, and the reliability of the connection between the auxiliary body and the main body is improved.

In some embodiments, the protruding member is a U-shaped structure adapted to the main cavity and having an opening proximate the spark screen, the spark shield is a U-shaped structure having an opening proximate the protruding member, and the opening of the protruding member is connected to the opening spark screen, such that the spark screen is connected to the auxiliary housing through a protruding member.

Thanks to the above solution, based on the fact that there is no influence on the fact that the spark screen is located in the hole in the wall of the cavity close to the sliding cavity, the main cavity, which prevents the mutual convective diffusion of the electric arc in the main cavity and the electric arc in the sliding cavity, and there is no causing the protruding member to extend into the main body to connect the auxiliary body to the main body through the protruding member, the spark shield is also connected to the protruding member, so that the spark shield is connected to the auxiliary body through the protruding member, which provides a variety of ways to connect the spark shield and auxiliary building.

In some embodiments, one side proximal to the main body of the auxiliary body is provided with a partition wall, the partition wall is located between the main cavity and the auxiliary cavity, and one side proximal to the spark screen of the partition wall is in contact with the spark screen.

Thanks to the above solution, the separating partition can effectively separate the main cavity in the upper layer from the auxiliary cavity in the lower layer in the height direction of the contactor, thereby blocking the propagation of the electric arc of the main cavity to the auxiliary cavity, and also blocking the propagation of the electric arc of the auxiliary cavity to the main cavity and improves the electrical insulation efficiency of the main cavity and auxiliary cavity. In addition, one side close to the spark screen of the partition wall is in contact with the spark screen, so that there is no gap between the partition wall and the spark screen. Thus, an electric arc occurring in the main cavity does not propagate easily between the spark shield and the partition wall to the auxiliary cavity, and an electric arc occurring in the auxiliary cavity does not propagate easily between the spark shield and the partition wall toward the main cavity.

In some embodiments, the composite type auxiliary housing includes a first auxiliary housing portion and a second auxiliary housing portion. At least one of the first auxiliary body part and the second auxiliary body part is provided with a protruding portion located near the other of them, the protruding portion is provided with a slot for a latch, and the other of the first auxiliary body portion and the second auxiliary body portion is provided with a latch. The latch slot and the latch are connected to each other by a latch connection to connect the first auxiliary housing portion to the second auxiliary housing portion.

With the above solution, the first auxiliary body part and the second auxiliary body part are connected in the above manner, and a sliding cavity portion is formed between the first auxiliary body part and the second auxiliary body part, which facilitates movement of the contact holder.

The above description provides only general information regarding technical solutions of embodiments of the utility model; In order that the technical means of the utility model embodiments that can be implemented in accordance with the contents of the description can be better understood, and so that the above and other purposes, features and advantages of the utility model embodiments can be more clearly understood, specific embodiments of the utility model will be described below.

Brief description of graphic materials

In order to more clearly illustrate the technical solutions in the embodiments of the utility model, the graphic materials used in the description of the embodiments will be briefly described below. It is obvious that the graphic materials in the description below represent some embodiments of the utility model. Without creative effort, those skilled in the art can also obtain other graphics based on these graphics.

In fig. 1 is a schematic representation of the design of an insulating structure of a contactor according to an embodiment of the utility model.

In fig. 2 shows an exploded view of the auxiliary housing and contact holder according to an embodiment of the utility model.

In fig. 3 shows a schematic representation of the structure of the main body according to an embodiment of the utility model.

In fig. 4 is a sectional view in section plane A-A in FIG. 1.

In fig. 5 is a sectional view in the section plane B-B of FIG. 1.

List of reference positions in graphic materials:

1 - housing assembly; 11 - main body; 111 - main cavity; 1111 - cavity opening; 112 - thrust surface; 12 - auxiliary building; 121 - auxiliary cavity; 122 - protruding element; 123 - dividing partition; 124 - first part of the auxiliary housing; 125 - second part of the auxiliary housing; 126 - protruding section; 13 - sliding cavity; 2 - contact holder; 21 - main holder; 211 - cavity for the main contact bridge; 22 - auxiliary holder; 221 - cavity for an auxiliary contact bridge; 3 - movable contact bridge; 4 - spark screen; 41 - cutout; 5 - anchor holder; X - direction along the length of the contactor; Y - direction along the width of the contactor; Z - direction along the height of the contactor.

Detailed Description of Embodiments

To make the goals, technical solutions and advantages of the utility model embodiments even more clear, a clear and complete description of the technical solutions in the utility model embodiments is presented with reference to graphic materials in the utility model embodiments. Of course, the described embodiments are only part of the embodiments of the utility model, and not all embodiments. All other embodiments obtained by specialists in the field of technology based on embodiments of a utility model without applying creative efforts are included in the scope of legal protection of the utility model.

Unless specifically defined otherwise, all technical and scientific terms appearing in this application have the same meaning as terms commonly understood by those skilled in the art to which the utility model relates. The terms appearing in the text of the description of the utility model are intended solely to describe specific embodiments and not to limit the utility model. The words “contain” and “include” and any derivatives from them in the description, formula of the utility model and brief description of the graphic materials of the utility model are considered to be of an inclusive and not exclusive nature.

The reference in the text to “embodiment” implies that the particular feature, structure or property described in relation to the embodiment may be contained in at least one embodiment of the utility model. The use of the expression “embodiment” in different places in the description does not necessarily imply the same embodiment or a separate or alternative embodiment mutually exclusive of another embodiment. Those skilled in the art will appreciate, both explicitly and implicitly, that the embodiments described herein can be fully combined with other embodiments.

The directional words appearing later in the description indicate the directions shown in the figures and are not intended to limit specific designs of the contactor insulation structure according to the utility model. For example, in the description of a utility model, the relative position or positional relationship, indicated by the words “above”, “under”, “left”, “right”, “vertical”, “horizontal”, “inside”, “outside”, etc. , are based on the relative position or positional relationship shown in the graphics and are intended solely to provide convenience in describing the utility model and simplify the description. The description is not intended to indicate or imply that the stated device or element must necessarily have a particular relative position, be configured and operate in a particular relative position, and therefore should not be construed as limiting the utility model.

Moreover, expressions such as, for example, X-direction, Y-direction and Z-direction, intended to describe said directions of operation and execution of various components of the contactor insulation structure according to the embodiments, are not absolute, but relative, and although When the various components of the contactor insulating structure are in the positions shown in the figures, these directions are shown accordingly, however, when these positions are changed, then these directions must be treated differently to accommodate the changes.

In addition, in the description, utility model claim and graphic materials of the utility model, the words “first”, “second”, etc. are used to distinguish different objects, and not to describe a given sequence, and may explicitly or implicitly contain one or more of these signs.

In the description of a utility model, unless otherwise indicated, the word “several” means two or more (contains two); similarly, the expression "multiple groups" means two or more groups (contains two groups).

It should be noted that in the description of a utility model, unless specifically defined or stated otherwise, the words “install”, “link” and “connect” should be understood in a broad sense; for example, "binding" or "joining" a mechanical structure may imply a connection based on physical principles; for example, the connection based on physical principles may be a rigid connection, for example, a rigid connection through locking elements, for example, a rigid connection through threads, bolts or other locking elements; the physics-based connection may also be a detachable connection, such as a mutual quick release or snap connection; and the connection based on physical principles may also be a permanent connection, for example, a connection obtained by welding, gluing or forming one piece. Those skilled in the art may understand the specific meaning of the above terms in a utility model in a particular situation.

In order for specialists in the art to better understand the solutions according to the utility model, a clear and complete description of the technical solutions in the embodiments of the utility model is presented below with references to graphic materials.

In fig. 1 is a schematic representation of the design of an insulating structure of a contactor according to an embodiment of the utility model. In fig. 2 is an exploded view of the auxiliary housing 12 and the contact holder 2 according to an embodiment of the utility model. In fig. 3 shows a schematic diagram of the structure of the main body 11 according to an embodiment of the utility model. As shown in FIG. 1-3, the insulating structure of the contactor contains a housing unit 1, a contact holder 2 and a spark screen 4. The housing unit 1 contains a main body 11 and an auxiliary housing 12 of a composite type, connected to each other in the Z direction along the height of the contactor, the housing unit 1 is provided with a cavity 13 sliding, the main body 11 is provided with a main cavity 111 configured to install the main contact; the auxiliary body 12 is provided with a auxiliary cavity 121 configured to receive an auxiliary contact, and both the main cavity 111 and the auxiliary cavity 121 are in communication with the sliding cavity 13. The contact holder 2 is slidably located in the sliding cavity 13, and the contact holder 2 is configured to install a movable contact bridge 3. When the contact holder 2 moves along the sliding cavity 13, the movable contact bridge 3 causes the movable contact to be separated from the fixed contact. The spark screen 4 is connected to the housing assembly 1, the spark screen 4 is located between the main cavity 111 and the sliding cavity 13 and is configured to block the electric arc that occurs when the moving contact is separated from the fixed contact, ensuring electrical isolation of the main cavity 111 from the auxiliary cavity 121.

The contactor is generally rectangular in shape, and if one takes the relative placement position shown in FIG. 1 of the contactor as an example, the generally left-right direction represents the X direction along the length of the contactor, the generally forward-backward direction represents the Y direction along the width of the contactor, and the generally up-down direction represents the Z direction along the height of the contactor.

The housing unit 1 includes a main body 11 and a auxiliary body 12 connected to each other in the Z direction along the height of the contactor, so that the formed contactor is formed by the main and auxiliary bodies. The auxiliary body 12 is composite, for example, the auxiliary body 12 is composed of two parts, three parts, four parts, etc. In other words, if we take the relative placement position shown in FIG. 1 of a contactor as an example, the contactor includes a main body 11 and an auxiliary body 12 configured as upper and lower in position; and the auxiliary body 12 includes auxiliary body parts configured in the positional relationship of left and right, and/or auxiliary housing parts configured in the positional relationship of the front and rear.

The main body 11 is provided with at least one pair of main cavities 111 in the Y direction along the width of the contactor, one main cavity 111 in each pair of main cavities 111 is located on one side of the main body 11 in the X direction along the length of the contactor, and the other main cavity 111 is located on the other side of the main body 11 in the X direction along the length of the contactor. The auxiliary housing 12 is provided with at least one pair of auxiliary cavities 121 in the Y direction along the width of the contactor, one auxiliary cavity 121 in each pair of auxiliary cavities 121 is located on one side of the auxiliary housing 12 in the X direction along the length of the contactor, and the other auxiliary cavity 121 is located on the other side of the auxiliary housing 12 in the X direction along the length of the contactor. In one main cavity 111, a pair of a main movable contact and a main fixed contact interacting with each other is installed; and in one auxiliary cavity 121, a pair of an auxiliary movable contact and an auxiliary fixed contact interacting with each other is installed.

The sliding cavity 13 includes a first sliding cavity portion and a second sliding cavity portion in communication with each other. The first sliding cavity portion is located in the Z direction along the height of the contactor in the composite type auxiliary body 12, and the second sliding cavity portion is located in the Z direction along the height of the contactor in the main body 11. Any main cavity 111 is in communication with the first sliding cavity portion and the second part of the sliding cavity, and any auxiliary cavity 121 is also in communication with the first sliding cavity part and the second sliding cavity part.

The movable contact bridge 3 includes at least one main movable contact bridge (abbreviated as the main contact bridge) and at least one auxiliary movable contact bridge (abbreviated as the auxiliary contact bridge). The contact holder 2 includes a main holder 21 and a auxiliary holder 22 connected to each other by a snap connection. The main holder 21 is provided with at least one main contact bridge cavity 211 having holes on both sides in the X direction along the length of the contactor, and one main contact bridge is passed through one main contact bridge cavity 211 in the X direction along the length of the contactor and installed in cavity 211 for the main contact bridge by means of a first contact spring. The auxiliary holder 22 is provided with at least one auxiliary contact bridge cavity 221 having holes on both sides in the X direction along the length of the contactor, and one auxiliary contact bridge is passed through one auxiliary contact bridge cavity 221 in the X direction along the length of the contactor and installed in cavity 221 for an auxiliary contact bridge by means of a second contact spring. It should be noted that in the Y direction along the width of the contactor, the number of cavities 211 for the main contact bridge and the number of main contact bridges are the same as the number of pairs of main contact bridges 111. Similarly, in the Y direction along the width of the contactor, the number of cavities 221 for the auxiliary contact bridge and the number of auxiliary contact bridges are the same as the number of pairs of auxiliary cavities 121.

The main contact contains a main moving contact and a main fixed contact. Both ends of the main contact bridge are respectively provided with one main movable contact, and after the main contact bridge is installed in the main contact bridge cavity 211, the main movable contacts at both ends of the main contact bridge are respectively located in the corresponding main contact cavity 111 (that is, both ends each main contact bridge correspondingly corresponds to one main cavity). The auxiliary contact contains an auxiliary moving contact and an auxiliary fixed contact. Both ends of the auxiliary contact bridge are respectively provided with one auxiliary contact bridge, and after the auxiliary contact bridge is installed in the auxiliary contact bridge cavity 221, the auxiliary contact bridges at both ends of the auxiliary contact bridge are respectively located in the corresponding auxiliary contact cavity 121 (that is, both ends each auxiliary contact bridge correspondingly corresponds to one auxiliary cavity 121). The contactor provides a normally open contact type and a normally closed contact type. Taking a normally open type contactor as an example, when the contact carrier 2 moves along the sliding cavity 13 in the downward direction (that is, in the direction from the auxiliary body 12 to the main body 11), the main contact bridge causes the main movable contact to move in the downward direction. by ensuring contact of the main movable contact with the main fixed contact, thereby enabling the circuit connected to the main contact to be turned on. On the other hand, by moving the contact holder 2 along the sliding cavity 13 in an upward direction (that is, in the direction from the main body 11 to the auxiliary body 12), the main movable contact is separated from the main fixed contact, thereby switching off the circuit connected to the main contact . Likewise, when the contact holder 2 moves along the sliding cavity 13 in a downward direction, the auxiliary contact bridge moves the auxiliary movable contact in a downward direction to bring the auxiliary movable contact into contact with the auxiliary fixed contact, thereby enabling the circuit connected to the auxiliary contact to be turned on. On the other hand, by moving the contact holder 2 along the sliding cavity 13 in an upward direction, the auxiliary moving contact is separated from the auxiliary fixed contact, thereby switching off the circuit connected to the auxiliary contact. It should be noted that the utility model presents a situation in which the contact and separation of the movable contact and the fixed contact, as well as the inclusion of the associated circuit when moving the movable contact bridge and the movable contact following the contact holder 2 along the sliding cavity 13 in the upward or downward direction below are described for the case where a contactor of a type with normally open contacts is taken as an example. As for the situation in which the normally closed type contactor is taken as an example, one can refer to the description of the situation with the normally open contact type, which will not be described again here.

As shown in FIG. 2, the spark screen 4 is located in the Z direction along the height of the contactor and is located between the main cavity 111 and the sliding cavity 13 in the X direction along the length of the contactor, the spark screen 4 is provided with two surfaces with opposite positions in the X direction along the length of the contactor, the two surfaces are large surfaces in the spark screen 4, and one of the two surfaces faces the main cavity 111, and the other of them faces the sliding cavity 13. It should be noted that according to the utility model, each of the openings of the cavities, representing two main cavities 111, corresponding to each main contact bridge, is equipped with a spark screen 4, and the openings of the cavities, representing two main cavities 111, corresponding to each main contact bridge, face the cavity 13, that is, between each main cavity 111 and the sliding cavity 13, a spark screen 4 is arranged. Moreover, regarding multiple spark screens 4 located on the same side of the contact holder 2 in the X direction along the length of the contactor, multiple spark screens 4 are configured separately from each other or connected to each other into one whole. When multiple spark screens 4 are connected as one, the monolithic spark screen 4 is provided with multiple cutouts 41 in the Y direction along the width of the contactor, and the positions and numbers of the multiple cutouts 41 correspond to the positions and numbers of cavities 211 for the main contact bridge, respectively, which helps ensure that when connection of the auxiliary body 12 with the main body 11, there will be no cavity wall on one side located near the sliding cavity 13 of the main body 11.

As for the method of connecting the spark shield 4 to the housing assembly 1, in some embodiments, the spark shield 4 is connected to the main body 11. And in other embodiments, the spark shield 4 is connected to a composite type auxiliary housing 12. The embodiments of the utility model are not limited to this. When the spark screen 4 is connected to the main body 11, to facilitate installation of the main contact bridge, the spark screen 4 is connected to the main body 11 by a detachable connection method such as a bolt connection, a snap connection, etc. When the spark screen 4 is connected to a composite type auxiliary body 12, then in some embodiments, one side proximate the main body 11 of the auxiliary body 12 is connected to the spark shield 4 by a detachable connection method, such as a snap connection, a bolt connection, etc. In other embodiments implementation, the spark screen 4 is also formed integrally with one side located near the main body 11, the auxiliary body 12, so that the number of components used can be reduced, the number of installation operations of the spark screen 4 and the auxiliary body 12 is reduced, and the installation efficiency is increased.

In an embodiment, the spark screen 4 is located between the main cavity 111 and the sliding cavity 13, in case the electric arc generated by the separation of the main moving contact and the main fixed contact in the main cavity 111 extends to one side close to the spark screen 4 of the main cavity 111 and collides with the spark shield 4, the spark shield 4 will change the propagation path of the electric arc so that the electric arc propagates only in the main cavity 111 and cannot easily propagate to the sliding cavity 13, thereby reducing the possibility of the electric arc propagating in the main cavity 111 to the auxiliary cavity 121 through the sliding cavity 13. Similarly, in the event that an electric arc generated by the separation of the auxiliary moving contact and the auxiliary fixed contact in the auxiliary cavity 121 propagates from the auxiliary cavity 121 to one side close to the spark screen 4 of the sliding cavity 13 and collides with the spark screen 4, the spark screen 4 will also change the propagation path of the electric arc so that the electric arc propagates only in the auxiliary cavity 121 or in the sliding cavity 13 and cannot easily propagate to the main cavity 111, thereby reducing the possibility of the electric arc propagating in the auxiliary cavity 121 to the main cavity 111 through the sliding cavity 13. Briefly, the spark screen 4 located between the main cavity 111 and the sliding cavity 13 is capable of reducing the possibility of an electric arc in the main cavity 111 passing to the auxiliary cavity 121, and is also capable of reducing the possibility of passing an electric arc in the auxiliary cavity 121 to the main cavity 111. Therefore, it is ensured electrical insulation between the main cavity 111 and the auxiliary cavity 121, the influence of the main cavity 111 and the auxiliary cavity 121 on each other is reduced, and the safety of using the contactor is improved. In addition, the auxiliary body 12 is configured as a composite body, in other words, made up of multiple parts, so that one-step molding of the auxiliary body 12 can be dispensed with, which can reduce the pressure associated with the need to mold several auxiliary cavities 121 in one-step in the auxiliary body 12, and reduce difficulties in processing and manufacturing.

In some embodiments, as shown in FIG. 3, two side walls of the spark screen 4 are in contact with two opposite side walls of the cavity opening 1111 in the Y direction across the width of the contactor to cover a portion of the cavity opening 1111.

The main cavity 111 must be in communication with the sliding cavity 13, so the cavity wall of one side adjacent to the sliding cavity 13 of the main cavity 111 must be provided with a cavity opening 1111, and the cavity opening 1111 is generally configured to accept the main contact bridge. The cavity opening 1111 extends through the cavity wall of one side adjacent to the sliding cavity 13 of the main cavity 111 in the Z direction along the height of the contactor. The size of the spark screen 4 is smaller than the size of the cavity wall in the Z direction along the height of the contactor, and the spark screen 4 is located on one side close to the auxiliary cavity 121 of the cavity wall, so that in the cavity hole 1111, the part located under the spark screen 4 is ensures the transmission of the main contact bridge. It should be noted that the size of the spark screen 4 in the Z direction along the height of the contactor is determined taking into account the position in which, when the contactor is unlocked, the movable contact bridge 3 moves in the upward direction until it stops, and it is only necessary to ensure that when moving the movable contact bridge 3 in the upward direction, the gap between the lower side of the spark screen 4 (that is, one side located near the movable contact bridge 3, the spark screen 4) and the movable contact bridge 3 does not interfere with the movement of the movable contact bridge 3. It can be understood that if the spark screen 4 does not interferes with the movement of the movable contact bridge 3, then the gap is made smaller, so that the size of the spark screen 4 in the Z direction along the height of the contactor is set to a larger value, which thereby increases the area of the spark screen 4 for blocking the electric arc, which helps to improve the effect of isolating the spark arc screen 4. For example, the gap may be 0.1 mm, 0.3 mm, 1 mm, etc. In embodiments of the utility model, the numerical value of the gap is not particularly limited.

In the Y direction across the width of the contactor, the size of the spark shield 4 is smaller than the size of the cavity opening 1111. To enhance the arc isolation effect, the size of the spark screen 4 in the contactor width Y direction is set so that both sides of the spark screen 4 in the contactor width Y direction are in contact respectively with the side adjacent to the cavity opening 1111. It can be understood that both arc extinguishing elements for extinguishing the electric arc are located in the main body 11 and the auxiliary body 12. If the magnitude of the electric arcs that propagate from both sides of the spark screen 4 in the Y direction along the width of the contactor is small, then the electric arcs of small magnitude in the process of continuous propagation can be extinguished by the arc extinguishing elements and do not significantly affect the main contact in the main cavity 111 or the auxiliary contact in the auxiliary cavity 121. Therefore, in the Y direction along the width of the contactor between both sides of the spark screen 4 and the side cavity adjacent to the hole 1111, a smaller gap is also allowed, for example, the gap is 0.1 mm, 0.2 mm, etc.

Due to the solution according to the embodiment, when the electric arc generated in the main cavity 111 propagates to one side close to the spark screen 4 of the main cavity 111, the electric arc does not easily bypass the spark screen 4 and propagates from both sides of the spark screen 4 in the direction along width to the sliding cavity 13, which thereby reduces the possibility of propagation of the electric arc in the main cavity 111 to the auxiliary cavity 121 through the sliding cavity 13. Likewise, when the electric arc generated in the auxiliary cavity 121 propagates from the auxiliary cavity 121 to one side close to the spark screen 4 of the sliding cavity 13, the electric arc does not easily bypass the spark screen 4 and propagates from both sides of the spark screen 4 in the direction along width to the main cavity 111, which thereby reduces the possibility of propagation of the electric arc in the auxiliary cavity 121 to the main cavity 111 through the sliding cavity 13. Therefore, the arc insulation effect of the spark shield 4 is improved, the electrical insulation between the main cavity 111 and the auxiliary cavity 121 is ensured, the influence of the main cavity 111 and the auxiliary cavity 121 on each other is reduced, and the safety of using the contactor is improved.

In some embodiments, the gap between one side proximal to the contact holder 2 of the spark screen 4 and the contact holder 2 is greater than 0 and less than or equal to 0.5 mm.

The gap between one side adjacent to the contact holder 2 of the spark shield 4 and the contact holder 2 represents the gap between the spark shield 4 and the contact holder 2 in the X direction along the length of the contactor.

On the one hand, if the spark shield 4 is in contact with the contact holder 2 in the X direction along the length of the contactor, then the spark shield 4 prevents the contact holder 2 from moving along the sliding cavity 13 in the upward direction or in the downward direction, so there is a in the X direction along the length of the contactor there may be a non-zero gap to reduce the influence of the spark screen 4 on the movement of the contact holder 2. On the other hand, if the gap between the spark screen 4 and the contact holder 2 is too large in the X direction along the length of the contactor, then when the contact holder 2 moves along the cavity 13 When sliding up and down, wobbling easily occurs, which causes the movable contacts located at both ends of the movable contact bridge 3 to tilt easily, thereby affecting the normal contact between the movable contacts and the fixed contacts. In addition, if the gap is too large, the electric arc entering the slide cavity 13 spreads from one side of the gap to the other side, thereby affecting the electrical insulation effect of the main cavity 111 and the auxiliary cavity 121. Therefore, the gap between the spark screen 4 and contact holder 2 in the X direction along the length of the contactor cannot be too large.

In view of the above analysis, in the embodiment, the gap between the spark shield 4 and the contact holder 2 in the X direction along the length of the contactor is limited to the range of 0 to 0.5 mm, which allows the normal movement of the contact holder 2 along the sliding cavity 13, reducing the possibility of inclined movement caused by the actuation contact holder 2 into the movement of the movable contact bridge 3, which thereby affects the normal contact between the movable contact and the fixed contact on the movable contact bridge 3, and also reduces the possibility of the electric arc entering the sliding cavity 13 from spreading from one side of the gap to the other side, which thereby affects the electrical insulation effect between the main cavity 111 and the auxiliary cavity 121.

In some embodiments, the size of the spark shield 4 in the X direction along the length of the contactor is greater than or equal to 0.5 mm.

An electric arc contains high-temperature gas particles. The electric arc, when propagating, collides with the spark screen 4 and burns through the spark screen 4. If the size of the spark screen 4 in the X direction along the length of the contactor (that is, the thickness of the spark screen 4) is smaller, then the electric arc easily burns through the spark screen 4, which thereby affects arc isolating effect of the spark screen 4. Accordingly, in the embodiment, the size of the spark screen 4 in the X direction along the length of the contactor is selected to be greater than or equal to 0.5 mm in order to improve the electric arc burning resistance of the spark screen 4, thereby achieving an arc isolating effect spark screen 4.

As for the method of connecting the auxiliary body 12 to the main body 11, in some embodiments, one side adjacent to the main body 11 of the auxiliary body 12 is directly connected to the main body 11 by, for example, a snap connection, a bolt connection, or the like. In some other embodiments, as shown in FIG. 2, one side adjacent to the main body 11 of the auxiliary body 12 is provided with a protruding member 122, the protruding member 122 extends into the main cavity 111 and is attached to the wall of the cavity constituting the main cavity 111, and the auxiliary body 12 is connected to the main body 11 through the protruding element 122.

The protruding member 122 extends into the main cavity 111 adjacent to the wall of the cavity constituting the main cavity 111 in a downward direction. Since the protruding member 122 extending into the main cavity 111 does not occupy additional space in the Z direction along the height of the contactor, it is possible to select a larger size of the protruding member 122 extending into the main cavity 111. Thus, when the auxiliary body 12 is connected to the main body 11 by the protruding member 122 extending into the main cavity 111, the flexibility of the connection arrangement between the protruding member 122 and the main body 11 is increased, and the reliability of the connection between the auxiliary body 12 and the main body 11 is increased.

One of the protruding member 122 and the main body 11 is provided with a latch slot, and the other of them is provided with a latch. The latch slot and the latch are connected to each other by a latch connection to connect the protruding member 122 and the main body 11, thereby connecting the sub housing 12 to the main body 11 through the protruding member 122.

The protruding element 122 is a structure of any shape. For example, the protruding member 122 is a U-shaped structure adapted to the main cavity 111 and having an opening adjacent to the spark screen 4. Accordingly, in some embodiments, as shown in FIG. 4, the spark screen 4 is a U-shaped structure having an opening adjacent to the protruding member 122, and the opening of the protruding member 122 is connected to the opening of the spark shield 4, so that the spark shield 4 is also connected to the auxiliary housing 12 through the protruding member 122.

The hole of the projection member 122 and the hole of the spark screen 4 are connected by a detachable connection method such as a bolt connection, a snap connection, etc. It can be understood that the projection member 122 is also integrally formed with the spark screen 4 and the auxiliary body 12, so that the number of components used is further reduced and the number of assembly operations for the protruding member 122 and the spark screen 4, as well as the number of assembly operations for the protruding member 122 and the auxiliary housing 12, are reduced.

Due to the above solution, based on the fact that there is no influence that the spark screen 4 is located in the hole in the cavity wall close to the sliding cavity 13 of the main cavity 111, thereby preventing the mutual convective diffusion of the electric arc in the main cavity 111 and the electric arc in the cavity 13 sliding, and there is no influence that the protruding member extends into the main body to connect the auxiliary body to the main body through the protruding member 122, the spark screen 4 is also connected to the protruding member 122, so that the spark shield 4 is connected to the auxiliary body 12 through protruding element 122, which provides a variety of ways to connect the spark screen 4 and the auxiliary housing 12.

In some embodiments, as shown in FIG. 2, one side close to the main body 11 of the auxiliary body 12 is provided with a partition wall 123, the partition wall 123 is located between the main cavity 111 and the auxiliary cavity 121, and one side close to the spark screen 4 of the partition wall 123 is in contact with the spark screen 4.

The partition wall 123 is located between the main cavity 111 and the auxiliary cavity 121 and is capable of serving as both a lower wall of the auxiliary cavity 121 and an upper wall of the main cavity 111. In the X direction along the length of the contactor and the Y direction along the width of the contactor, the size of the partition wall 123 is larger than the size the auxiliary cavity 121 and the size of the main cavity 111, so that the dividing wall 123 is able to effectively separate the main cavity 111 in the upper layer from the auxiliary cavity 121 in the lower layer in the Z direction along the height of the contactor, thereby blocking the propagation of the electric arc of the main cavity 111 to the auxiliary cavity 121, and also blocks the propagation of the electric arc of the auxiliary cavity 121 to the main cavity 111 and improves the electrical insulation efficiency of the main cavity 111 and the auxiliary cavity 121.

One side close to the spark screen 4 of the partition wall 123 is in contact with the spark screen 4, so that there is no gap between the partition wall 123 and the spark screen 4. Thus, the electric arc generated in the main cavity 111 does not propagate easily between the spark screen 4 and the partition wall 123 to the auxiliary cavity 121, and the electric arc generated in the auxiliary cavity 121 does not propagate easily between the spark screen 4 and the partition wall 123 to the main cavity 111. Therefore, the electrical insulation effect between the main cavity 111 and the auxiliary cavity 121 is further ensured, the influence of the main cavity 111 and the auxiliary cavity 121 on each other is reduced, and the safety of using the contactor is improved.

The composite auxiliary housing 12 contains several auxiliary housing parts. As for the method of connecting multiple sub-casing parts to each other, in some embodiments, the composite-type sub-casing 12 includes a first sub-casing part 124 and a second sub-casing part 125. At least one of the first auxiliary housing portion 124 and the second auxiliary housing portion 125 is provided with a protruding portion 126 adjacent the other of them, the protruding portion 126 is provided with a latch slot, and the other of the first auxiliary housing portion 124 and the second auxiliary housing portion 125 is provided with latch. The latch slot and the latch are connected to each other by a latch connection to connect the first sub-casing portion 124 to the second sub-casing portion 125 .

The composite type auxiliary body 12 is provided with a first sliding cavity portion in the Z direction along the height of the contactor, in case the composite type auxiliary housing 12 includes a first auxiliary housing portion 124 and a second auxiliary housing portion 125, then the first sliding cavity portion is formed between the first auxiliary housing portion 124 and a second auxiliary housing portion 125 after connecting the first auxiliary housing portion 124 to the second auxiliary housing portion 125.

If the first auxiliary housing portion 124 is provided with a protruding portion 126, the protruding portion 126 is located on one side or both sides of the first auxiliary housing portion 124 in the Y direction along the width of the contactor, and the number of protruding portions 126 is one or more. The embodiments of the utility model are not limited to this. A latch slot is formed in each protruding portion 126, and latches are located on both sides of the second sub-casing portion 125 in the Y direction along the width of the contactor and in a corresponding portion of the latch slot. When the first auxiliary body part 124 and the second auxiliary body part 125 are moved in opposite directions until the latch slot and the latch are connected to each other through the latch connection, the first auxiliary body part 124 is connected to the second auxiliary body part 125. As for the description of the case in which the protruding portion 126 is located on the second auxiliary body portion 125, a description of how the protruding portion 126 is disposed on the first auxiliary housing portion 124 can be referred to, and it will not be described here again.

It is worth noting that the structures of the first auxiliary housing portion 124 and the second auxiliary housing portion 125 are the same. When installing the first auxiliary housing part 124 and the second auxiliary housing part 125, any of the first auxiliary housing part 124 and the second auxiliary housing part 125 is rotated relative to the other in the rotation plane by 180 degrees, as a result of which the correspondingly located latch and latch slot are connected to each other by means of a snap connection for connecting the first auxiliary housing portion 124 to the second auxiliary housing portion 125. Thus, when the first auxiliary body part 124 and the second auxiliary body part 125 are produced, only one of them needs to be mass produced, thereby saving processing and manufacturing operations. In this case, the rotation plane is a plane formed in the X direction along the length of the contactor and the Y direction along the width of the contactor.

The contactor includes a main contact, an auxiliary contact, a main contact bridge, an auxiliary contact bridge, a contactor insulation structure, etc. from the above embodiments. Since the contactor insulation structure and its beneficial effects have already been described in detail above, they will not be described again in this application.

As shown in FIG. 5, the contactor additionally includes an armature holder 5. The armature holder 5 is connected to one end close to the main body 11 of the contact holder 2. One side away from the auxiliary body 12 of the main body 11 is provided with a thrust surface 112. When the contactor opens the circuit at reduced voltage, the armature holder 5, the contact holder 2 and The movable contact bridge 3 moves together in the upward direction. After the movable contact bridge 3 causes the movable contact to be separated from the fixed contact, the armature holder 5 is blocked by the thrust surface 112 and cannot continue to move in the upward direction, and the contact holder 2 and the movable contact bridge 3 are also unable to move in the upward direction.

In an embodiment of the utility model, the main body 11 has a monolithic structure, and its thrust surface 112 also has a monolithic structure. When the armature holder 5 is prevented from moving in the upward direction by the thrust surface 112, both sides of the thrust surface 112 in the X direction along the length of the contactor apply equal forces to the armature holder 5. Therefore, the armature holder 5, when locked by the thrust surface 112, will not tilt, so that the contact holder 2 and the movable contact bridge 3 will not tilt, thereby ensuring the stability of the moving path of the movable contact at both ends of the movable contact bridge 3 and improving the performance of the contactor.

If, for example, the composite-type auxiliary housing 12 includes a first auxiliary housing portion 124 and a second auxiliary housing portion 125, and the spark shield 4, protruding member 122, and partition wall 123 are made detachable from the auxiliary housing 12, the spark shield is first connected to the contactor during installation. 4, the protruding member 122 and the partition wall 123 corresponding to the first sub-casing part 124 with the first sub-casing part 124, and then connect the spark shield 4, the protruding member 122 and the dividing wall 123 corresponding to the second sub-casing part 125 to the second part 125 auxiliary building. Then, the auxiliary contact bridge is installed in the auxiliary contact bridge cavity 221 of the auxiliary holder 22, the main contact bridge is installed in the main contact bridge cavity 211 of the main holder 21; and then the first auxiliary body part 124 and the second auxiliary body part 125 are respectively placed on both sides of the contact holder 2 in the X direction along the length of the contactor and connected to each other, so that the main holder 21 is located in the first sliding cavity part between the first auxiliary body part 124 and the second part 125 of the auxiliary building. Thereafter, the contact holder 2 and the auxiliary body 12 are inserted as a unit into the main body 11 in a downward direction, so that the auxiliary holder 22 is located in the second part of the sliding cavity, and this unit is connected to the main body 11 by, for example, a snap connection, bolted connection, etc.

It should be noted that the above is only a possible installation sequence, and during the installation process the sequence of some installation steps may change, unless this affects the installation of all structural elements. The embodiments of the utility model are not limited to this. The structure of the contactor is rationally designed so that the installation of all structural elements is relatively flexible, which contributes to increased installation efficiency.

The embodiments discussed above are intended only to describe technical solutions according to the utility model and do not serve to limit the utility model. Although the utility model has been described in detail in the above embodiments, it will be appreciated by those skilled in the art that they may still make changes to the technical solutions described in all of the above embodiments, or make equivalent substitutions with respect to part or all technical features without any change in technical solutions or deviations from the scope of technical solutions in embodiments of the utility model.

Claims (12)

1. Contactor insulation structure containing a housing assembly, wherein the housing assembly comprises a main body and an auxiliary body of a composite type connected to each other in the height direction of the contactor, the housing assembly is provided with a sliding cavity, the main body is provided with a main cavity configured to install the main contact, the auxiliary housing is provided with an auxiliary cavity, configured to install an auxiliary contact, and both the main cavity and the auxiliary cavity are in communication with the sliding cavity; a contact holder, wherein the contact holder is positioned to slide in the sliding cavity and is configured to install a movable contact bridge, and when the contact holder moves along the sliding cavity, the movable contact bridge leads to the separation of the movable contact from the fixed contact; And spark screen, wherein the spark screen is connected to the housing assembly and is located between the main cavity and the sliding cavity, and is configured to block the electric arc that occurs when the moving contact is separated from the fixed contact, ensuring electrical isolation of the main cavity from the auxiliary cavity. 2. The insulating structure of the contactor according to claim 1, characterized in that the movable contact bridge contains at least one main movable contact bridge, and both ends of each main movable contact bridge correspondingly correspond to one main cavity, both openings of the cavities representing two main cavities corresponding to each main movable contact bridge face the sliding cavity, and the opening of the cavity representing each main cavity is provided with a spark screen. 3. The contactor insulation structure of claim 2, wherein two side walls of the spark shield are in contact with two opposite side walls of the cavity opening to cover a portion of the cavity opening. 4. Insulating structure of the contactor according to any one of paragraphs. 1-3, characterized in that the gap between one side located near the contact holder, the spark screen and the contact holder is greater than 0 and less than or equal to 0.5 mm; and/or the size of the spark shield in the direction along the length of the contactor is greater than or equal to 0.5 mm. 5. The insulating structure of the contactor according to claim 1, characterized in that the spark screen is detachably connected to the main body, or the spark screen and the auxiliary body are formed as one piece. 6. The insulating structure of the contactor according to claim 1, characterized in that one side located near the main body of the auxiliary body is equipped with a protruding element, the protruding element extends into the main cavity and is attached to the wall of the cavity, which is the main cavity, and the auxiliary case is connected to the main body by means of a protruding element. 7. The insulating structure of the contactor according to claim 6, characterized in that the protruding element is a U-shaped structure adapted for the main cavity and has an opening located near the spark screen, the spark shield is a U-shaped structure having an opening located near the protruding member, and the opening of the protruding member is connected to the opening of the spark screen, so that the spark shield is connected to the auxiliary body through the protruding member. 8. The insulating structure of the contactor according to claim 1, characterized in that one side located near the main body of the auxiliary body is equipped with a dividing partition, the dividing partition is located between the main cavity and the auxiliary cavity, and one side close to the spark screen of the dividing partition is located in contact with the spark screen. 9. The insulating structure of the contactor according to claim 1, characterized in that the auxiliary housing of the composite type contains a first part of the auxiliary housing and a second part of the auxiliary housing, at least one of the first part of the auxiliary housing and the second part of the auxiliary housing is provided with a protruding section located near the other of these, the protruding portion is provided with a latch slot, and the other of the first auxiliary housing portion and the second auxiliary housing portion is provided with a latch; and the latch slot and the latch are connected to each other by a latch connection to connect the first auxiliary housing portion to the second auxiliary housing portion.