KR101700657B1 - Modular electrical switch - Google Patents

Abstract

The present invention includes a plurality of electrical switch modules 100, 200, at least one operating assembly 300, and coupling means 402 for coupling the plurality of electrical switch modules 100, 200 The electric switch 400 is provided. Coupling means 402 couples the plurality of electrical switch modules 100, 200 so that the operation of the plurality of electrical switch modules 100, 200 is substantially synchronized.

Description

[0001] MODULAR ELECTRICAL SWITCH [0002]

The present invention relates to an electrical switch used to open and close an electrically conductive path between an electric supply and an electrical load. More particularly, the present invention relates to an electrical switch based on modular design.

In conventional electrical switches, a movable contact (not shown) is used to establish or disconnect an electrically conductive path between supply-side and load-side stationary contacts. Are displaced with respect to the set of fixed contacts. The supply-side and load-side fixed contacts are respectively connected to the electrical supply and the electrical load. An actuating assembly is provided to cause displacement of the moving contacts from the normal position to an actuated position.

When the mobile contact is disengaged from a corresponding pair of stationary contacts, the electrically conductive path between the electrical supply and the electrical load is disconnected. This position is known as an "open position ". On the other hand, when the mobile contact is brought into contact with a corresponding pair of fixed contacts, the electrically conductive path between the electrical supply and the electrical load is established. This position is known as a "closed position ".

Thus, electrical switches can be classified as normally-open type electrical switches and normally-closed type electrical switches. In the case of normally-open electrical switches, the actuating assembly displaces the moving contacts from an open position to a closed position. When the operating force is removed, various biasing means return the moving contacts back to the open position, whereby the electrically conductive path is disconnected. In the case of normally-closed electrical switches, the operation is reversed.

In conventional electrical switches as described above, the size of the electrical switch is determined by the electrical rating of the electrical switch, i.e., the operating current and / or operating voltage that the electrical switch is expected to depend upon during its operation It is based on size. As the operating current and / or operating voltage increases, the size of the electrical switch must also be increased accordingly.

The various constituent elements included in the electrical switch, such as fixed and movable contacts, a carrier assembly, an operating assembly, a housing structure and the like, can be enlarged proportionally as the size of the electrical switch increases it should be scaled up. Thus, a large electrical switch would require large magnets, large plastic casings with sufficient mechanical strength to support the various constituent elements, and the like.

In the state of the art, special large molding tools and machines are used to manufacture the large housing structure required for large electrical switches. This adversely affects the cost of manufacturing large size electrical switches.

In addition, various special tools used to manufacture and assemble metal parts used in smaller electrical switches can not be used to fabricate and assemble the corresponding metal parts required for large electrical switches, The reason is that the expense to enlarge is expensive enough. Thus, depending on the state of the art, large electrical switches are typically custom-made and manually assembled. This leads to inconsistency and lower precision of the various mechanical and electrical characteristics of the large electrical switch which, in turn, leads to unsatisfactory performance during operation and, in extreme cases, failure of the electrical switch during operation, .

In view of the foregoing, there is a need to provide an electrical switch design that is suitable for manufacturing electrical switches having high electrical ratings, without custom designing and manufacturing various construction elements.

It is therefore an object of the present invention to provide an electrical switch design suitable for manufacturing electrical switches having high electrical ratings, without custom designing and manufacturing various construction elements.

The object of the present invention is achieved by an electric switch according to claim 1. Further embodiments of the invention are dealt with in the dependent claims.

SUMMARY OF THE INVENTION In accordance with the above-mentioned objects, the present invention provides a power supply system comprising a plurality of electrical switch modules, at least one actuating assembly, and coupling means for coupling the plurality of electrical switch modules Thereby providing an electric switch. Each electrical switch module includes a contact assembly and a carrier assembly. The contact assembly includes at least one pair of fixed contacts for connection to the electrical supply and electrical load, and at least one movable contact for establishing an electrical path between at least one pair of the fixed contacts. The at least one mobile contact is displaceable relative to a corresponding at least one pair of stationary contacts. The carrier assembly is configured to couple to the at least one mobile contact and displace the at least one mobile contact to a first position and a second position with respect to at least one pair of fixed contacts. The at least one mobile contact in the first position and the second position respectively open and close the electrically conductive path between the corresponding pair of stationary contacts. The at least one actuating assembly selectively provides an actuating force to effect a displacement of the carrier assembly in at least one of the plurality of electrical switch modules in a first direction causing displacement of the at least one movable contact . The coupling means is arranged such that the displacements of the respective carrier assemblies in each of the plurality of electric switch modules are substantially synchronized, that is, each carrier assembly in the plurality of electric switch modules Moving in the same direction with a minimum relative displacement relative to any other carrier assembly so that at least one mobile contact in the plurality of electrical switch modules within such a short time window in which no negative electrical phenomenon occurs, And a plurality of electrical switch modules to be displaced to the second position.

According to an embodiment of the present invention, each electrical switch module is associated with an individual operating assembly. The individual actuating assemblies are selected from at least one actuating assembly. Thus, each electrical switch module includes an actuating assembly for performing displacement of the carrier assembly in a first direction. These technical features ensure that each electrical switch module creates an operating force for displacement of the respective carrier assembly. In this embodiment, the coupling means only serves to synchronize the displacement of the carrier assemblies in the plurality of electrical switch modules.

In accordance with another embodiment of the present invention, each electrical switch module includes a housing structure for housing a contact assembly. This technical feature eliminates the need to fabricate a large housing structure for housing all of the constituent elements of the electrical switch in a single housing, since each electrical switch module is provided with a separate housing structure in accordance with this technical feature , And thus this technical feature advantageously eliminates the need to design a specialized molding structure according to the total size of the electrical switch.

In accordance with another embodiment of the present invention, at least one actuating assembly includes an actuating coil configured to generate a magnetic field, the magnetic field comprising at least one electrical switch module of a plurality of electrical switch modules in a first direction, Lt; RTI ID = 0.0 > a < / RTI > displacement of the carrier assembly. This technical feature facilitates the use of low-voltage circuitry to control the operation of the electrical switch. Such a low-voltage circuit is electrically isolated from a main circuit that is opened or closed by an electrical switch.

According to still another embodiment of the present invention, the electrical switch comprises a control module configured to regulate at least one actuating assembly through regulating a coil current through the actuating coil, and a control module. The control module is a relatively low-voltage circuit electrically isolated from the main circuit electrically opened or closed by the electrical switch. Thus, this technical feature advantageously facilitates controlling the operation of the electrical switch using a relatively low-voltage circuit. Additionally, the use of a single control module for regulating at least one actuating assembly facilitates synchronizing the displacements of the carrier assemblies in the electrical switch modules.

According to still another embodiment of the present invention, the electrical switch further comprises biasing means for performing displacement of the carrier assembly in at least one electrical switch module of the plurality of electrical switch modules in a second direction. This technical feature facilitates restoring moving contacts to the normal position, i.e., the open position of the normally-open electrical switch and the closed position of the normally-closed electrical switch, following removal of the operating force provided by the operating assembly.

According to still another embodiment of the present invention, the coupling means couples the carrier assemblies in the plurality of electrical switch modules. This technical feature means that the displacement of the carrier assembly in the plurality of electrical switch modules is substantially synchronized, that is, each carrier assembly in the plurality of electrical switch modules has a minimum Moves in the same direction with relative displacement to ensure that at least one mobile contact in the plurality of electrical switch modules is displaced to the first position and the second position within such a short time window in which no negative electrical phenomenon occurs.

According to still another embodiment of the present invention, each electrical switch module comprises one pair of fixed contacts. This technical feature ensures that single-phase electrical switch modules can be integrated to assemble a multi-phase electrical switch.

According to still another embodiment of the present invention, each electrical switch module comprises three pairs of fixed contacts. This technical feature ensures that three-phase electrical switch modules can be integrated to assemble an electrical switch having a desired electrical rating higher than the electrical ratings of the individual electrical switch modules.

Each pair of stationary contacts includes a supply-side stationary contact and a load-side stationary contact. According to another embodiment of the invention, the electrical switch further comprises at least one pair of terminal plates. Each pair of terminal plates includes a first terminal plate and a second terminal plate. The first terminal plate is coupled to the plurality of supply-side stationary contacts and the second terminal plate is coupled to the corresponding plurality of load-side stationary contacts. According to this technical feature, the terminal plates are directly connected to a plurality of fixed contacts. In accordance with this technical feature, there is no need for an intermediate connection structure between the fixed contacts and the terminals used in the present state of the art and introducing additional electrical resistance in the electrically conductive path between the supply and the load. Thus, this technical feature prevents deterioration of the electrical characteristics of the electric switch.

According to another embodiment of the present invention, a plurality of supply-side fixed contacts and a corresponding plurality of load-side fixed contacts are selected from at least two adjacent positioned electrical switch modules. This technical feature ensures that the supply-side fixed contacts and the corresponding plurality of load-side fixed contacts are most optimally combined to be directed to the desired number of terminals for each connection to the supply and load.

According to another embodiment of the present invention, the electrical switch includes a base plate. A plurality of electrical switch modules are mounted on the base plate. This technical feature ensures that each electrical switch module can be mechanically integrated with a plurality of electrical switch modules having their respective housing structures to form an electrical switch.

According to another embodiment of the present invention, the electrical switch includes a top cover for mechanically shielding the plurality of electrical switch modules. This technical feature ensures that the various constituent elements of the electrical switch outside the individual housing structures can be mechanically shielded from the external environment.

The electrical switch according to the present invention is advantageously based on a modular design such that the desired electrical rating of the electrical switch is achieved through proper coupling of the plurality of electrical switch modules. The individual electrical switch modules can be mass produced and the appropriate number of electrical switch modules can be combined to achieve the desired electrical rating of the electrical switch. Since individual electrical switch modules can be manufactured using precision tools and machines, the accuracy and reliability of these electrical switch modules and, consequently, resulting electrical switches is significantly higher when compared to custom-built electrical switches. Thus, the present invention provides a significant reduction of costs for manufacturing electrical switches having high electrical ratings. Thus, the present invention provides an advantageous paradigm shift from a custom design to a modular design that results in significantly improved technical and economic viability.

Additionally, the present invention provides a method of providing a working assembly corresponding to only a selected set of electrical switch modules contained within an electrical switch, depending on the operating force required to displace the carrier assemblies in each of the plurality of electrical switch modules . Due to the provision of the operating assembly in the selected set of electrical switch modules, the overall cost of the electrical switch is further reduced.

Also, various constructional elements, such as the connecting rod, base plate, and top cover, required to assemble what is required for an electrical switch according to the present invention, are based on desired operating electrical parameters To produce different sizes. Alternatively, these construction elements may also be assembled from smaller units based on a modular design.

The invention will be further described hereinafter with reference to the illustrated embodiments shown in the accompanying drawings.
Figures 1A-1D illustrate a set of configuration elements of a three-phase electrical switch module in accordance with an embodiment of the present invention.
Figures 2a-2d illustrate a set of configuration elements of a single-phase electrical switch module in accordance with an alternative embodiment of the present invention.
Figure 3 illustrates a perspective view of a working assembly in accordance with an embodiment of the present invention.
4A-4B illustrate perspective and side views of an electrical switch in accordance with an embodiment of the present invention.
Figure 5 illustrates a cross-sectional front view of an electrical switch in accordance with an embodiment of the present invention.
6 illustrates a side cross-sectional view of an electrical switch in accordance with an embodiment of the present invention.
7 illustrates a top cross-sectional view of an electrical switch according to an embodiment of the present invention.

Various embodiments are described with reference to the drawings, wherein like reference numerals are used to refer to like elements throughout. In the following description, for purposes of explanation, numerous specific details are set forth in order to provide a thorough understanding of one or more embodiments. It may be evident that such embodiments may be implemented without these specific details.

1A-1D illustrate a set of configuration elements of a three-phase electrical switch module 100 in accordance with the present invention. In particular, FIG. 1A illustrates an exploded view of a three-phase electrical switch module 100. The three-phase electrical switch module 100 includes a housing structure 102, a contact assembly 104, a carrier assembly 106, and a mid-cover 108. The housing structure 102 includes three pairs of two end walls 110, two side walls 112, and slots 114. The contact assembly 104 includes three pairs of fixed contacts 116 and corresponding three movable contacts 118. Figures 1B, 1C, and 1D illustrate a perspective view, side view, and exploded view of the carrier assembly 106, respectively. The carrier assembly 106 includes three carriers 120. Each carrier 120 includes a mounting socket 122, and a coupling socket 124. The middle-cover 108 includes three slots 126.

The housing structure 102 surrounds a portion of the carrier assembly 106 and the contact assembly 104. The middle-cover 108 is mounted to the top of the housing structure 102 to provide physical and electrical isolation of the space enclosed by the housing structure 102.

The housing structure 102 includes two end walls 110. Each end wall 110 also includes three pairs of slots 114. One or more terminal plates (not shown in the figures) extend inwardly through the slots 114 and are connected to two or more fixed contacts 116. 4A and 4B, two sidewalls 112 extend from an adjacent electrical switch module 100 to the electrical switch module 100 while assembling a plurality of electrical switch modules 100 in accordance with the present invention, And is provided for physically partitioning the module 100.

As mentioned above, the contact assembly 104 includes three pairs of stationary contacts 116 and corresponding three movable contacts 118.

Each pair of fixed contacts 116 includes a supply-side fixed contact and a load-side fixed contact. The supply-side and load-side fixed contacts are disposed on either side of the carrier assembly 106. 4A and 4B, the supply-side and load-side fixed contacts are connected to the input and output terminal plates, which in turn are connected to the electrical supply and the electrical load respectively do.

Each movable contact 108 is configured to establish an electrically conductive path between the electrical supply and the electrical load when the movable contact 118 is in contact with the pair of fixed contacts 116; And is displaceable relative to a corresponding pair of stationary contacts 116 such that the electrically conductive path between the electrical supply and the electrical load is disconnected when the movable contact 118 is not in contact with the pair of stationary contacts 116 .

The carrier assembly 106 includes three carriers 120. Each carrier 120 includes a mounting socket 122 and a coupling socket 124. The carriers 120 extend vertically when assembled within the electrical switch module 100. Each carrier 120 includes a mounting socket 122 for receiving and supporting the mobile contact 118. As described further below, the carrier assembly 106 may be coupled to the actuating assembly, further comprising a coupling socket 124 for engaging the carrier 120 with a connection rod (not shown). A portion of each carrier 120 between the mounting socket 122 and the coupling socket 124 extends outwardly from the housing structure 102 through the slot 126 of the mid-

A middle-cover 108 is mounted on each electrical switch module 100 such that the contact assembly 104 enclosed within the housing structure 102 is physically isolated from the rest of the portions of the electrical switch 100. The middle-cover 108 includes one or more slots 126 that allow at least a portion of the carrier assembly 106 to extend beyond the housing structure 102. A portion of the carrier assembly 106 that extends beyond the housing structure 102 is used to couple the electrical switch module 100 to a working assembly (not shown).

The carrier assembly 106 is configured to displace the mobile contacts 118 to a first position and a second position with respect to a corresponding pair of the stationary contacts 116. [ The first position may be a position where the mobile contact 118 does not contact a corresponding pair of stationary contacts 116 and thus the electrically conductive path between the pair of stationary contacts 116 is disconnected ). Similarly, the second position may be the position at which the mobile contact 118 contacts a corresponding pair of stationary contacts 116, and thus the electrically conductive path between the pair of stationary contacts 116 is set (closed position).

As shown, the mobile contacts 118 mounted in the mounting sockets 122 of the carrier assembly 106 are in line with the pair of stationary contacts 116. Following application of the operating force, the carrier assembly 106 undergoes a downward movement, causing the mobile contacts 118 to contact respective pairs of stationary contacts 116, thereby causing each pair of stationary contacts 116 An electrically conductive path is established between the two stationary contacts. When the operating force is removed, the biasing means as will be described with respect to Figs. 4A and 4B may be used to connect the carrier assembly (not shown) to disconnect the electrically conductive path between the two fixed contacts of each pair of stationary contacts 116 106). ≪ / RTI >

During movement of the carrier assembly 106, the slots 126 of the mid-cover 108 facilitate the alignment of the stationary contacts 116 and the carrier assembly 106 and hence of the mobile contacts 118 .

Figures 2a-2d illustrate a set of configuration elements of a single-phase electrical switch module 200 in accordance with the present invention. In particular, FIG. 2A illustrates an exploded assembly view of the single-phase electrical switch module 200. The single-phase electrical switch module 200 includes a housing structure 202, a contact assembly 204, a carrier assembly 206, and a mid-cover 208. The housing structure 202 includes two pairs of end walls 210, two sidewalls 212, and one pair of slots 214. The contact assembly 204 includes one movable contact 218 corresponding to one pair of stationary contacts 216. Figures 2B, 2C, and 2D illustrate a perspective view, side view, and exploded view, respectively, of the carrier assembly 206. The carrier assembly 206 includes a carrier 220. Each carrier 220 includes a mounting socket 222, and a coupling socket 224. The middle-cover 208 includes a slot 226.

The various elements used in the three-phase electrical switch module 100 as described in connection with FIG. 1 may be implemented with a single phase electrical switch < RTI ID = 0.0 > Is adapted to the module (200). Details are not provided for clarity.

The present invention will be described below with reference to a three-phase electric switch module 100. However, the various embodiments of the present invention as described below are equally applicable to single-phase electrical switch modules 200.

Figure 3 illustrates a perspective view of a working assembly 300 in accordance with the present invention.

The actuating assembly 300 includes a stationary sub-assembly and a movable sub-assembly. The fixed sub-assembly includes a base plate 302, a yoke 304, and a bobbin 306. The moving sub-assembly includes a holder 308, an anchor 310, and a pivot 316. The holder 308 includes pivoting arms 312 and coupling arms 314.

The base plate 302 provides a platform for mounting the yoke 304. In turn, the yoke 304 provides a support to the bobbin 306. Similarly, the holder 308 provides a support to the anchor 310. The pivoting arms 312 are connected to the pivot 316. The coupling arms 314 provide a means for engaging the carrier assembly 106. As noted above, in an exemplary embodiment of the present invention, a connecting rod is used to cause coupling arms 314 to engage with carrier assembly 106 through coupling sockets 224. The fixed and movable sub-assemblies are arranged such that yoke 304 and anchor 310 are assembled in a complementary manner as is commonly known in the art.

In various embodiments of the present invention, any suitable yoke design may be used. 3, the yoke 304 is configured in the form of a three-legged structure using laminated sheets of ferromagnetic material according to known techniques (see, for example, . On the intermediate leg of the yoke 304, a bobbin 306 is mounted. Thus, the yoke 304 is provided to provide mechanical support to the bobbin 306 and also to strengthen the magnetic field set by the bobbin 306. [

The bobbin 306 includes an actuation coil configured to generate a magnetic field for providing an actuation force to the carrier assembly 210. [ The magnetic field is generated through the application of a coil current. Therefore, the magnetic flux is set in the yoke 304. [ The anchor 310 is provided to complete the magnetic circuit by providing a return path to the magnetic flux in the yoke 304.

In the absence of coil currents, the moving sub-assemblies, and particularly the anchors 310, are separated from the fixed sub-assemblies, particularly the yokes 304, by the biasing means as described in connection with Figs. 4A and 4B. This position of the mobile sub-assembly is referred to as the open position. The anchor 310 is pulled magnetically toward the yoke 304 and consequently the moving sub-assembly, particularly the anchor 310, is magnetically attracted to the yoke 304, The anchors 310 are brought into contact with the yoke 304. The anchors 310 are moved toward the fixed sub-assemblies, particularly the yoke 304, This position of the moving sub-assembly is referred to as the closed position.

When the carrier assembly 210 is coupled to the moving sub-assembly through the coupling arms 314 and the connecting rod, movement of the moving sub-assembly causes the corresponding displacement of the carrier assembly 210 from the open position to the closed position ≪ / RTI >

It should be noted that the base plate 302 is an optional element. In an alternative embodiment of the present invention, in addition to the base plate 302, the various configuration elements of the actuating assembly 300 may be assembled directly on the mid-cover 108 in a similar manner.

4A and 4B illustrate perspective and side views of an electrical switch 400 in accordance with an embodiment of the present invention. The electrical switch 400 includes two electrical switch modules 100a and 100b, two operating assemblies 300a and 300b, a connecting rod 402, biasing springs 404, 406 and a top cover 408. The electrical switch 400 also includes a control module 416 that is separately referred to as input terminal plates 410, output terminal plates 412, two partition plates 414, Lt; RTI ID = 0.0 > 416a < / RTI >

The electrical switch 400 provides a means for opening and closing an electrically conductive path between the electrical supply and an electrical load (not shown in the figure).

The three-phase electrical switch module 100 includes a housing structure 102, a contact assembly 104, a carrier assembly 106, and a mid-cover 108, as described in connection with FIG. The housing structure 102 surrounds a portion of the carrier assembly 106 and the contact assembly 104. The middle-cover 108 is mounted to the top of the housing structure 102 to provide physical and electrical isolation of the various constituent elements enclosed by the housing structure 102.

The actuating assembly 300 is mounted on the middle-cover 108 and is coupled to the electrical switch module 100. The actuating assembly 300 provides an actuating force for performing the displacement of the carrier assembly 106 to open and close the electrically conductive paths through the electrical switch 400. [

As shown in Figure 4a, the actuating assemblies 300a and 300b are coupled to the electrical switch modules 100a and 100b, respectively, via connecting rods 402. [ In an exemplary embodiment, the connecting rod 402 is configured to allow the connecting rod 402 to couple the operating assemblies 300a and 300b to the electrical switch modules 100a and 100b, respectively, Span across the electrical switch modules 100a and 100b such that the displacement of each carrier assembly 106 within the switch modules 100a and 100b is provided to couple the electrical switch modules 100 such that they are substantially synchronized. Thus, the connection rod 402 provides coupling means for coupling the electrical switch modules 100. In the embodiment of the invention shown in FIG. 4A, the connection rod 402 couples the carrier assemblies 106 in the electrical switch modules 100. In alternative embodiments of the present invention, it is possible to couple other elements, such as moving parts of the actuating assembly 300, using the same technical effect. In addition, in various alternative embodiments, any suitable mechanical structure, such as rectangular plates, rods having any suitable cross-section other than a circular cross-section (as depicted in Figure 4a), etc., May be used to couple the modules 100.

In an embodiment of the present invention as shown in Figures 4A and 4B, each electrical switch module 100 is coupled to a corresponding actuating assembly 300. However, in an alternative embodiment of the present invention, operating assemblies 300 corresponding to only a selected set of electrical switch modules 100 are provided. Since the carrier assemblies 106 in the remaining electrical switch modules 100 are coupled to the carrier assemblies 106 in the selected set of electrical switch modules 100, The required movement of the carrier assemblies 106 is achieved in all of the slots 100. [

It should be noted that for clarity only, the working assembly 300 has been described as a separate assembly external to the electrical switch module 100. In various embodiments of the present invention as described herein, the actuation assembly 300, when present, includes, in addition to the contact assembly 104 and the carrier assembly 106, May be considered to form the part.

The biasing springs 404 provide biasing means for restoring the moving sub-assembly of the actuating assembly 300 and, accordingly, the carrier assembly 106 and the moving contacts 118 to their normal position. When the electric switch 400 is normally open, the normally open position is the open position. Similarly, when the electrical switch 400 is normally closed, the normally position is the closed position. According to an exemplary embodiment of the present invention as shown in FIG. 4A, biasing springs 404 engage coupling arms 314 of actuation assembly 300. In various alternative embodiments of the present invention, it is possible to couple the biasing springs 404 with other movable components of the electrical switch 400, such as the carrier assembly 106.

The base plate 406 provides a support for mounting the electrical switch modules 100 in an adjacent manner such that the electrical switch modules 100 are assembled to form the electrical switch 400. [ According to an embodiment of the present invention, the housing structure 102 includes horizontal and vertical flanges (or walls) having apertures formed therein. The horizontal flanges are used to secure the electrical switch modules 100 to the base plate 406 and the vertical flanges are used to connect the electrical switch modules 100a and 100b. The base plate 406 may be manufactured based on a monolithic design or a modular design. In an embodiment of the modular design, each individual base plate corresponds to a size of a single electrical switch module 100, and a plurality of such base plates may be formed, for example, by nuts and bolts or other similar means The base plate 406 is mechanically bonded and appropriately sized.

The top cover 408 extends over an upper portion of the electrical switch 400 and provides a mechanical shield for the various configuration elements that are assembled to form the electrical switch 400. The top cover 408 may be manufactured based on a monolithic or modular design, similar to the base plate 406 as described above.

4A and 4B, three input terminal plates 410 are connected to the supply-side fixed contacts and three output terminal plates 412 are connected to the load-side fixed contacts < RTI ID = 0.0 >Lt; / RTI > Each of the terminal plates 410 and 412 is connected to two fixed contacts. Thus, each of the three groups of two adjacent supply-side fixed contacts of the electrical switch modules 100 is coupled to the input terminal plate 410. Similarly, each of the three groups of two adjacent load-side fixed contacts of electrical switch modules 100 is coupled to output terminal plate 412.

During installation of the electrical switch 400, electrical cables are fixed to the input terminal plates 410 and the output terminal plates 412 to respectively establish an electrical connection to the electrical supply and the electrical load.

Partitioning plates 414 are mounted between input terminal plates 410 and also between output terminal plates 412 to provide electrical isolation therein.

The control module 416 is configured to regulate the actuating assemblies 300. The control module 416 is a relatively low-voltage circuit electrically isolated from the main circuit that is electrically opened or closed by the electrical switch 400. In an exemplary embodiment, the control module 416 is implemented as a printed circuit board (PCB). The control module 416 simultaneously triggers the actuating assemblies 300 and thereby assists in synchronizing the movement of the carrier assemblies 106 in the electrical switch modules 100.

During operation of electrical switch 400, control module 416 regulates the coil current in operating assembly 300. In order to switch on the electrical switch 300, the control module 416 switches on the coil current in the operating coil of the bobbin 306.

It is critical to mention that printed circuit boards (PCBs) are mentioned for illustrative purposes only. In various alternative embodiments of the present invention, the control module 416 may be implemented using any suitable component as will be readily apparent to those skilled in the art.

Additionally, it should be noted that in alternative embodiments of the present invention, multiple control modules 416 may be included. For example, each of the actuating assemblies 300 may be associated with a corresponding control module 416. In the case of multiple control modules 416, the operation is synchronized.

Due to the coil current, the operating force is set. Following application of the actuating force, the moving sub-assembly of the actuating assembly 300 and the resulting carrier assembly 106 undergoes a downward movement, which may be referred to as a first direction. As a result, the mobile contacts 118 are contacted with respective pairs of stationary contacts 116, thereby establishing an electrically conductive path between two stationary contacts of each pair of stationary contacts 116. Next, in order to switch off the electrical switch 400, the control module 416 switches off the coil current in the operating coil of the bobbin 306. The biasing springs 404 will cause the moving sub-assembly of the actuating assembly 300 and, accordingly, the upward movement of the carrier assembly 106. This upward translation movement may be referred to as the displacement in the second direction. As a result, the electrically conductive path between the two fixed contacts of each pair of fixed contacts 116 is disconnected. Thus, the first and second directions as used herein are opposite to each other along a straight or curved path.

During movement of the carrier assembly 106, the slots 126 of the mid-cover 108 facilitate the alignment of the stationary contacts 116 and the carrier assembly 106 and hence of the mobile contacts 118 .

In the exemplary embodiment shown in FIGS. 4A and 4B, two electrical switch modules 100 are assembled to form the electrical switch 400. Note that the actual number of electrical switch modules 100 assembled to form the electrical switch 400 depends on the individual current ratings of the electrical switch module 100 and the desired current rating of the electrical switch 400 . For example, if each electrical switch module 100 has an electrical rating of 1000 amperes and the desired rating of the electrical switch 400 is 4000 amperes, then the four electrical switch modules < RTI ID = 0.0 > (100) can be assembled.

In addition, it should be noted that the number of pairs of fixed contacts included in the electrical switch module 100, the corresponding number of movable contacts can be varied as desired. In the exemplary embodiment shown in Figs. 4A and 4B, electrical switch modules 100 having three pairs of respective fixed contacts were used. When the two or more such three-phase electrical switch modules 100 are assembled to form the electrical switch 400, the individual "phases" of the three-phase electrical switch module 100 are connected to the electrical supply Does not correspond to the three phases because it will be appreciated that the individual ' phases ' are suitably combined to bring about the electrical rating of the electrical switch 400 of the desired electrical rating. In an alternative embodiment of the present invention, electrical switch modules 200 each having a single pair of fixed contacts are used.

 As is well known in the state of the art, electrical switches are classified as normally-open type electrical switches and normally-closed type electrical switches. It should be noted that electrical switch 400 as described herein is a normally-open electrical switch. However, as will be apparent to those skilled in the art, various embodiments of the present invention are equally applicable to normally-closed electrical switches having appropriate modifications in relative positions of fixed and mobile contacts.

Figure 5 illustrates a cross-sectional front view of an electrical switch 400 in accordance with the present invention. A cross-sectional view is made along the line 1-1 'shown in FIG. 4A.

As can be seen in the front sectional view, the electrical switch 400 includes two electrical switch modules 100a and 100b, two operating assemblies 300a and 300b, and a connecting rod 402.

The various constructional elements have already been described in detail in connection with the preceding figures.

6 illustrates a side cross-sectional view of an electrical switch 400 in accordance with the present invention. A cross-sectional view is made along line 2-2 'shown in FIG. 4A.

Sectional side views illustrate an arrangement of a contact assembly 104, particularly a pair of fixed contacts 116 and a mobile contact 118, and a carrier assembly 106 contained within electrical switch module 100.

Figure 7 illustrates a top cross-sectional view of an electrical switch 100 in accordance with the present invention. A cross-sectional view is made along line 3-3 'shown in FIG. 4A.

As shown, the electrical switch module 100a includes the supply-side stationary contacts 116a and the load-side stationary contacts 116a '. Similarly, electrical switch module 100b includes supply-side fixed contacts 116b and load-side fixed contacts 116b '. 7 also shows input terminal plates 410a, 410b, and 410c, and output terminal plates 412a, 412b, and 412c.

As can be seen, the input terminal plate 410a is connected to the two supply-side fixed contacts 116a and the input terminal plate 410b is connected to the two supply-side fixed contacts 116a and 116b And the input terminal plate 410c is connected to the two supply-side stationary contacts 116b. Output terminal plates 412a, 412b, and 412c are coupled to load-side fixed contacts 116a 'and 116b' in a similar manner.

As noted above, the embodiment shown in Figs. 4-7 is exemplary by nature and can be implemented in a similar manner depending on the individual electrical rating of the electrical switch modules 100 or 200 and the desired electrical rating of the electrical switch 400 Any desired number of electrical switch modules 102 may be combined.

The electrical switch according to the invention is advantageously based on a modular design such that the desired electrical rating of the electrical switch is achieved through proper coupling of the plurality of electrical switch modules. The individual electrical switch modules can be mass produced and the appropriate number of electrical switch modules can be combined to achieve the desired electrical rating of the electrical switch. Thus, the present invention greatly facilitates the manufacture of electrical switches with significantly improved electrical characteristics and operational accuracy and reliability. The present invention further facilitates a reduction in the manufacturing cost of electrical switches having high electrical ratings.

While the invention has been described in detail with reference to specific embodiments thereof, it should be recognized that the invention is not limited to such embodiments. In light of the present disclosure, many modifications and variations will appear to those skilled in the art without departing from the scope and spirit of this invention. The scope of the invention is, therefore, indicated by the following claims rather than by the foregoing description. All changes, modifications, and variations that come within the meaning and range of equivalency of the claims are to be regarded as being within the scope of the following claims.

100 Electric Contactor Module
102 Housing structure
104 Contact assembly
106 carrier assembly
108 Medium - Cover
110 end walls
112 sidewalls
A pair of 114 slots
116 fixed contacts
118 mobile contacts
120 carrier
122 Mounting Socket
124 Coupling socket
126 slots
200 electrical contactor module
202 Housing structure
204 contact assembly
206 carrier assembly
208 Medium - Cover
210 end walls
212 sidewalls
214 pairs of slots
216 fixed contacts
218 mobile contacts
220 carrier
222 Mounting Socket
224 Coupling socket
226 slots
300 operating assembly
302 base plate
304 yoke
306 bobbin
308 holder
310 anchor
312 pivoting arms
314 Coupling arms
316 Pivot
400 electrical contactor
100 electrical contactor module
300 operating assembly
402 Connection Load
404 biasing springs
406 base plate
408 Top - Cover
410 input terminal plate
412 Output terminal plates
414 partition plate
416 control module

Claims (14)

An electrical switch (400) comprising:
Each electrical switch module (100, 200)
A contact assembly (104, 204), the contact assembly (104, 204) comprising at least a pair of stationary contacts (116, 216) and at least one movable contact (118, 218), said at least one mobile contact (118, 218) being displaceable relative to at least one of said pair of fixed contacts (116, 216), and
A carrier assembly (106, 206), coupled to the at least one mobile contact (118, 218), coupled to the fixed contacts (116, 216) (118, 218) to a first position and a second position relative to the at least one pair of fixed contacts (116, 216), respectively, to disconnect and set the electrically conductive path between the pair of fixed contacts 2 position -
A plurality of electrical switch modules (100, 200) comprising:
At least one actuating assembly (300), wherein the at least one actuating assembly (300) is movable in a first direction causing displacement of the movable contacts (118, 218) Selectively providing an actuating force to displace the carrier assembly (106, 206) in at least one of the electrical switch modules (100, 200); And
Wherein the plurality of electrical switch modules (100, 200) and the plurality of electrical switch modules (100, 200) are arranged such that displacement of each of the carrier assemblies (106, 206) in each of the plurality of electrical switch modules Coupling means 402 for coupling at least one actuating assembly 300,
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Electric switch (400). The method according to claim 1,
Each electrical switch module 100, 200 is coupled to a respective one of the operating assemblies 300 selected from the at least one actuating assembly 300,
Electric switch (400). 3. The method according to claim 1 or 2,
Each electrical switch module 100, 200 further includes a housing structure 102, 202 for housing the contact assembly 104, 204,
Electric switch (400). 3. The method according to claim 1 or 2,
The at least one actuating assembly (300)
A movable sub-assembly coupled to the carrier assembly (106, 206) via the coupling means (402); And
Thereby causing a movement of the mobile sub-assembly, thereby causing a magnetic field to displace the carrier assembly (106, 206) in at least one of the plurality of electrical switch modules (100, 200) in the first direction A fixed sub-assembly with an actuating coil 306 configured to generate
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Electric switch (400). 3. The method according to claim 1 or 2,
A control module 416 configured to regulate operation of the actuating assembly 300,
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Electric switch (400). 3. The method according to claim 1 or 2,
Biasing means (404) for displacing the carrier assembly (106, 206) in at least one electrical switch module of the plurality of electrical switch modules (100, 200) in a second direction,
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Electric switch (400). 3. The method according to claim 1 or 2,
The coupling means (402) couples the carrier assemblies in the plurality of electrical switch modules (100, 200)
Electric switch (400). 3. The method according to claim 1 or 2,
The coupling means 402 comprises a connecting rod 402,
Electric switch (400). 3. The method according to claim 1 or 2,
Each contact assembly 104, 204 of each electrical switch module 100, 200 includes a pair of fixed contacts 116,
Electric switch (400). 3. The method according to claim 1 or 2,
Each contact assembly 104,204 of each electrical switch module 100,200 includes three pairs of fixed contacts 116,216,
Electric switch (400). 3. The method according to claim 1 or 2,
Each pair of stationary contacts 116 and 216 includes a supply-side stationary contact 116 and 216 and a load-side stationary contact 116 and 216 And the electrical switch (400) further comprises at least a pair of terminal plates, each pair of terminal plates having a first end coupled to the first plurality of supply-side stationary contacts (116, 216) And a second terminal plate (412) coupled to the terminal plate (410) and a corresponding plurality of load-side stationary contacts (116, 216).
Electric switch (400). 12. The method of claim 11,
The plurality of supply-side fixed contacts 116 and 216 and the corresponding plurality of load-side fixed contacts 116 and 216 are selected from at least two adjacent positioned electrical switch modules 100 and 200, felled,
Electric switch (400). 3. The method according to claim 1 or 2,
A base plate 406 for mounting the plurality of electric switch modules 100 and 200,
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Electric switch (400). 3. The method according to claim 1 or 2,
A top cover 408 for providing a mechanical shield,
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Electric switch (400).

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