RU2453944C2 - Electric switch - Google Patents

Abstract

FIELD: electric engineering.

SUBSTANCE: electric switch includes body (1), shaft (4) provided with, at least one tooth (18), at least two cavities (11-14) in switch, each provided with, at least, two movable electric contact elements (8), with one for each cavity (11,14). In addition, the shaft (4) is realised so that the movable contact elements (11-14) can be shifted due to the action of at least one tooth (18) while shaft (4) is rotated. The switch contains also movable separating element (5), located between the shaft (4) and movable electric contact elements (8) to transfer shaft (4) action to movable contact elements (8).

EFFECT: simple design and assembly.

17 cl, 6 dwg

Description

FIELD OF THE INVENTION

The present invention relates to an electric switch comprising a housing, a shaft provided with at least one cam, at least two switch chambers, each of which is equipped with at least one fixed electric contact element, at least two movable electric contact elements, one at a time on each chamber of the switch, the shaft being configured to bias the movable contact elements by the action of at least one cam when the shaft is rotated.

The switch is preferably a so-called switch in a side-controlled housing. As a rule, it is designed to operate in installations with low voltage, with a current in the range preferably 16-40 A. However, other ranges are also included in the scope of the invention. As a rule, contact elements of various circuit breaker chambers are designed to pass currents of different phases.

State of the art

Side-operated switches have been known for a long time. As a rule, they contain a shaft with which a plurality of movable electrical contact elements are actuated to connect or disconnect them from the corresponding plurality of fixed contact elements located in the switch housing. Thus, the shaft is manually controlled using a handle located outside the switch housing. The main advantage of the switch with side control compared to the switch with front control is that the case or casing of the switch can be opened without having to remove the handle. However, the design of circuit breaker components known in the art either complicates the assembly too much or contains complex large moving elements.

Disclosure of invention

The objective of the invention is to provide an electric switch, the design of which is such that it has the advantages of a switch with side control and at the same time is relatively simple, easy and easier to assemble than switches with side control, known from the prior art.

Accordingly, the circuit breaker according to the invention should easily open without removing the external handle attached to the circuit breaker shaft. Components, such as fixed electrical contacts (terminals), should also be easily accessible when opening the switch enclosure and are designed to be removed and installed.

The objective of the invention is solved using an initially defined switch, characterized in that it contains a movable separation element located between the shaft and the movable electrical contact elements and configured to transmit the effects of the shaft on the movable contact elements. The spacer element serves as a seat for a plurality of movable electrical contact elements, each of which is connected to a separate switch chamber. Preferably, the housing comprises at least two parts that can be separated from each other. Thus, the assembly of the switch is simple, since it only requires placing the shaft in one of the parts of the housing, installing the spacer element on the shaft and installing the movable electrical contact elements in separate saddles located for this purpose on the spacer element. The fixed contact elements are preferably attached to the housing and are located relative to the movable elements so that they are connected or disconnected from the latter as a result of the movement of the separation element, caused in turn by rotation of the shaft and the resulting action of the cam or cams. The fixed contact elements must also be configured to provide easy access to them when opening the casing to allow easy installation. Preferably, the shaft extends in such a way that it passes through at least one, and preferably through all of said switch chambers, two or more cams being provided for acting on the spacer element, preferably one for each switch chamber.

The spacer element is preferably common to all of the plurality of movable contact elements, each of which contact elements are located in a corresponding receptacle or seat in the spacer element.

According to a preferred example, in each chamber of the switch there are two fixed electrical contact elements, at least one of which is electrically connected or electrically disconnected from the movable electric contact element when the shaft is rotated. The advantage of having double electrical contact elements in each circuit breaker chamber is that it provides a design that simplifies circuit breaker assembly, since all parts can be mounted in place in the same direction, and fixing them until the circuit breaker is completely assembled is not required. The fixed contact elements associated with the same movable contact element are preferably arranged so that the movable element simultaneously connects to or disconnects from both the fixed contact elements when moving the movable contact element.

In accordance with one embodiment, the switch comprises sealing elements between the chambers of the switch. The purpose of the sealing elements is to prevent the occurrence of an electric arc in the ionized gas generated in the switch during operation, between the contact elements of the different chambers of the switch, that is, between different phases. Accordingly, the sealing elements are configured to prevent the passage of gas from one chamber of the switch to another. However, preventing the occurrence of an arc is not required to the full extent, but only to a degree that provides sufficient suppression of the occurrence of an electric arc. Accordingly, despite the presence of sealing elements, there can be channels through which a certain amount of gas can pass from one chamber to another, but only in a limited amount. The sealing elements are preferably designed so that, regardless of the position of the separation element between the circuit breaker chambers, there is no direct or wide channel, but only narrow channels between adjacent elements. Of course, the sealing elements are preferably made of dielectric material.

According to another embodiment, the sealing elements comprise a wall provided on the dividing element.

The sealing elements preferably contain at least one wall of the housing, said wall of the housing being configured to overlap said wall of the spacer element regardless of the position of the shaft. The wall of the housing may be in the form of a flange that overlaps the wall of the spacer element, or preferably a recess, into which the mating wall provided on the spacer element enters. It should be noted that the overlapping walls extend either in a direction corresponding to the longitudinal direction of the shaft to provide lateral sealing, or in a direction transverse to the longitudinal direction of the shaft to provide sealing in the specified longitudinal direction.

According to a preferred embodiment, the wall of the housing comprises a recess into which said wall of the spacer element enters, wherein the wall of the spacer element can slide in said recess. In this way, the recess serves as a guide element and at the same time contributes to the seal between the circuit breaker chambers.

According to one embodiment, said wall of the spacer element extends in a plane transverse to the longitudinal direction of the shaft. On the side of the spacer element, to which at least one cam of the shaft does not move when the shaft rotates from the working position to the inoperative position, a side wall of the spacer element is provided, said side wall overlapping an adjacent housing wall irrespective of the position of the spacer element. This is especially important when creating the space between the shaft and the separation element when the shaft is rotated to the position in which it raises the separation element. Preferably, this position corresponds to the disconnected phases in the circuit breaker, disconnected as a result of lifting the movable contact elements from the stationary contact elements. The side wall prevents the formation of free space between the chambers of the switch when lifting the separation element. Such side walls may be provided on one or more sides of the spacer member.

According to a preferred embodiment, at least one cam forms part of the sealing elements. Thus, an even more compact design of the switch is provided, since the characteristic side sealing walls on the side of the dividing element on which the cams are moved are eliminated.

The sealing elements preferably comprise a wall of the separation element, said wall being located between two adjacent switch chambers and separating them, wherein at least one cam of the shaft overlaps said wall when acting on the separation element. The cam also, or as an alternative to such overlap, may overlap the wall of the housing regardless of its position between the inoperative and the operating positions. Such overlapping can be carried out in a plane transverse or perpendicular to the longitudinal direction of the shaft. The cams also fill the space or channel, which otherwise, if there were no cams, would form between the switch chambers and the shaft due to the lifting effect of the cams.

At least one cam preferably overlaps said wall (either of a spacer element or housing) regardless of its position between the operating and non-operating positions.

According to one embodiment, the shaft is movable between a working position in which the spacer element is raised by at least one cam and an idle position, wherein the sealing elements irrespective of the position of the shaft between the operating and idle position define a wall that completely separates the two adjacent chambers of the switch in the longitudinal direction of the shaft. Preferably, there are also lateral sealing elements providing lateral sealing. Preferably, such elements include the walls described above, as well as cams.

In accordance with the invention, the sealing elements comprise pairs of adjacent overlapping surfaces of the separation element and the housing and adjacent overlapping surfaces of the separation element and at least one cam.

The housing preferably comprises a first part that forms a seat for the shaft and the spacer member, and a second part that forms the top. Thus, assembly of the circuit breaker is simplified.

According to one embodiment, the switch comprises a preload element adapted to act on the shaft. The purpose of the preload element is to further rotate the cam or shaft cams into the working or inoperative position.

According to a preferred embodiment, the preloading element is a spring element provided on a shaft side opposite the shaft side on which the spacer element is located.

The preload element is preferably located in the region of the circuit breaker chamber, wherein the circuit breaker chamber in the region of which the preload element is located is preferably a circuit breaker chamber used for neutral or auxiliary contact.

In accordance with one embodiment of the invention, the circuit breaker comprises at least one ventilation opening extending from the at least one circuit breaker chamber to the outside of the enclosure, the distances between adjacent sealing elements between said at least one circuit breaker chamber and the free space between the separation element and shaft, are selected in such a way that the pressure difference between the specified chamber of the switch and the free space is greater than the pressure difference between the specified camera switch and the space outside the housing due to the specified ventilation holes. In other words, the sealing elements are configured to guarantee the release of ionized gas through the vent and prevent said gas from passing from one chamber of the switch to another through the free space between the shaft and the separation element. Preferably, each switch chamber is provided with a vent.

Other features and advantages of the invention are presented in the following detailed description.

Brief Description of the Drawings

The following is a description of embodiments of the invention with reference to the accompanying drawings, in which:

figure 1 is an exploded view of an electric switch according to the invention;

figure 2 is a section of the switch Assembly in the first position of the shaft of the switch;

figure 3 is a section of the switch according to figure 2, taken along the line III-III in figure 4, in which the switch with the shaft are in the second position;

figure 4 is a section taken along the line IV-IV in figure 3;

figure 5 is a perspective view of a separator element of the switch;

6 is a perspective view of a first part of a circuit breaker housing.

The implementation of the invention

1 shows the main components of a circuit breaker according to the invention. The switch comprises a housing, generally indicated by the reference number 1 and containing the first part 2 and the second part 3, a shaft 4, a separation element 5, a plurality of fixed electrical contact elements 6, means 7 for fixing the fixed contact elements, a plurality of movable electrical contact elements 8, springs 9 for displacing the contact elements 8 to the separation element 5 and the pre-loading element 10 to stabilize the position of the shaft 4. The switch is preferably enclosed in a casing (not shown), and respectfully it also comprises a lever or handle (not shown) that connects the shaft 4 to a handle or the like on the outside of the casing. The handle is designed to be moved manually to turn the switch on and off. The switch is a side-controlled switch that allows you to open the casing or housing 1 without having to remove the handle or shaft 4.

When the switch is assembled, the housing 1 together with the dividing element 5 demarcate a plurality of chambers 11, 12, 13 of the switch (see FIGS. 2-4). In each of these chambers 11-13 of the switch there are two stationary electrical contact elements 6 'and 6' 'located opposite each other. Each pair of contact elements 6 ', 6' 'represents one electrical phase. In this example, there are three cameras 11-13 of the switch, one for each phase of the electrical distribution network connected to the switch. There is also an additional, fourth switch chamber 14, used for neutral or as an auxiliary switch chamber. The cameras 11-14 of the switch are arranged in series, and the shaft 4 passes in the direction of this sequence of cameras 11-14, so that it passes under each camera 11-14. The shaft is separated from the chambers 11-14 of the switch by the lower part of the separation element 5.

The dividing element 5, contributing to the differentiation of the circuit breaker chambers 11-14, forms a saddle for a plurality of movable electrical contact elements 8, one for each circuit breaker chamber 11-14. The separating element 5 is movable, preferably by sliding from the first inoperative position of the switch, in which the movable contact elements are in contact with the stationary electric contact elements 6, to the operating position in which the movable contact elements 8 are moved and are thus electrically disconnected from the fixed contact elements 6. The separation element 5 comprises a plurality of walls 15 that separate the switch chambers 11-14 from each other and are made as possible Stu sliding in recesses 16 arranged in the walls 17 of the housing 1. The walls 15 of the separating element 5 and the recesses 16 of the walls 17 of the housing overlap each other in such a manner as to seal between the separate chambers 11-14 switch. The seal helps to prevent the formation of an electric arc between the individual chambers 11-14 of the switch due to the flow of ionized gases between the individual chambers 11-14 of the switch.

The shaft 4 contains a plurality of cams 18, one for each camera 11-14 of the switch, aligned with each camera in the longitudinal direction of the shaft 4. In the idle position shown in figure 2, in which the cams 18 of the shaft 4 do not act on the spacer element 5, the cams are directed toward the first side wall 19 of the first part 2 of the housing 1. In the operating position shown in FIGS. 3 and 4, in which the shaft 4 is rotated 90 ° relative to the idle position, the cams 18 are directed towards the separation element 5 and thereby raise him and moving contact ele cops 8 are located in the separation element 5 in such a way that they are disconnected from the fixed contact elements 6.

When moving the shaft 4 from the inoperative position shown in FIG. 2 to the operating position shown in FIG. 3, free space or channel 20 is formed between the shaft 4 and the lower part of the spacer element 5. To ensure the most compact design in the spacer element 5 between the walls 15 separating the switch chambers 11-14 have lateral openings, the cams being able to laterally enter these openings in the first position, in this case, the inoperative position, and barriers or filling eniya these holes regardless of the position between the working and non-working positions. Thus, the cams 18 of the shaft 4 contribute to the seal between the chambers 11-14 of the switch. If the cams 18 did not fill these side openings, an open channel would exist between the chambers of the switch due to the formation of free space 20 when the cam shaft 4 is moved. However, in a design alternative to the construction shown here, one or more cams can be excluded, and in this In this case, a side wall should be provided, preferably on the dividing element 5, in order to prevent the formation of a free connection or channel between the free space 20 and the switch chambers 11-14. Such side walls 21 are provided on the side of the separation element, on which there are no cams 18. Corresponding side walls 22 are located in the housing, so that the side walls 21 of the separation element are near these side walls 22 of the housing and overlap them regardless of the position of the separation element between the open and closed provisions described above.

To ensure the ventilation of each chamber 11-14 of the switch, in which ionized gas can be generated during operation, ventilation holes 30 pass from the chambers 11-14 of the switch to the outside of the housing 1. The ventilation holes 30 pass through the upper part of the second, upper part 3 of the housing 1. The dimensions of these ventilation holes are such that the pressure drop in each of them is less than the pressure drop between each respective chamber 11-14 of the switch and the free space 20 between the shaft 4 and the spacer element. Thus, the accumulation of ionized gas in the free space 20 is prevented, and the ionized gas generated in the chambers 11-14 of the switch during operation is discharged through said ventilation holes 30.

The first part 2 of the housing 1 contains a seat 23 for receiving the shaft 4. In this case, the saddle 23 contains many sectors in the form of an arch located in the lower part of the first part 2 of the housing 1. The walls 24, forming part of the walls 17, at least in the idle position pass from part 19 of the side wall of the first part 2 of the housing 1 and fill the space between the individual cams 18. On the opposite side of the first part 2 of the housing 1 are the above side walls 22, as well as the walls 17, in which there are recesses 16 for guiding the walls 15 ra dividing member 5.

The second part 3 of the housing 1 is associated with the first part 2 of the housing, in which there are also walls 17 in which are recesses 16 aligned with the corresponding walls and the recesses of the first part 2. The second part 3 of the housing 1 also contains side walls 25 extending between the walls 17 , thereby contributing to the delimitation of the cameras 11-14 switch. It also contains opposite end walls 26 and 27, transverse to the longitudinal direction of the shaft 4 and forming the end walls of the two extreme chambers 11 and 14 of the switch. These end boundary walls may, alternatively, be formed by walls such as walls 15 of the spacer element 5. However, the described preferred embodiment avoids the use of such additional walls 15 and provides a more compact and less material-intensive construction. The second part 3 of the housing 1 also contains saddles 28 for biasing elements 9 formed by helical springs and acting on the movable contact elements 8 towards the stationary contact elements 6. Accordingly, the saddles 28, as well as biasing elements 9, are located in the switch chambers.

The switch also contains a pre-loading element 10, formed by a leaf spring located in the lower part of the first part 2 of the housing 1 and acting on the cams of the shaft 4 in the direction of the separation element 5. This ensures proper sealing, even in the case of free play between the shaft 4 and a dividing element 5, for example, due to deformation or wear of any component of the switch. The presence and operation of the preload element also contribute to a more stable and reliable operation of the circuit breaker, since it prevents the occurrence of free play between the shaft and the splitter 5. In the shown embodiment, the preload element 10 is located in the region of one of the end chambers of the switch, more precisely in the chamber 14 used for neutral or auxiliary contact.

Claims (17)

1. An electrical switch comprising a housing (1); a shaft (4) provided with at least one cam (18); at least two switch chambers (11-14), each of which is provided with at least one fixed electric contact element (6); at least two movable electrical contact elements (8), one for each switch chamber (11, 14), the shaft (4) being configured to bias said movable contact elements due to the action of at least one cam (18) when turning shaft (4), while the electric switch contains a movable separation element (5) located between the shaft (4) and the movable electrical contact elements (8) and configured to transmit the effects of the shaft (4) to these movable contact elements (8); and sealing elements (4, 15, 17, 21, 22, 24, 26, 27) between the chambers (11-14) of the switch, characterized in that said sealing elements (4, 15, 17, 21, 22, 24, 26 , 27) contain a wall (15) provided on the dividing element (5). 2. An electric switch according to claim 1, characterized in that in each chamber (11-14) of the switch there are two fixed electrical contact elements (6 ', 6' '), at least one of which is made with the possibility of electrical connection or disconnection from the movable electric contact element (8) when turning the shaft (4). 3. An electric switch according to claim 1 or 2, characterized in that the sealing elements (4, 15, 17, 21, 22, 24, 26, 27) contain at least one wall (17) of the housing (1), wherein the wall (17) of the housing (1) is configured to overlap the specified wall (15) provided on the dividing element (5), regardless of the position of the shaft (4). 4. The electric switch according to claim 3, characterized in that the wall (17) of the housing (1) contains a recess (16), which includes the specified wall (15) of the separation element (5), moreover, the wall (15) of the separation element (5) ) made with the possibility of sliding in the specified recess (16). 5. Electric switch according to claim 1 or 2, characterized in that said wall of the spacer element (5) extends in a plane transverse to the longitudinal direction of the shaft (4), while on the side of the spacer element (5) to which at least one the cam of the shaft (4) does not move when the shaft (4) is rotated from the working position to the inoperative position, a side wall (21) of the separation element (5) is provided, said side wall (21) overlapping the adjacent wall (22) of the housing (1) independently from the position of the separation element (5). 6. Electric switch according to claim 1 or 2, characterized in that at least one cam (18) forms part of the sealing elements. 7. An electric switch according to claim 6, characterized in that the sealing elements (4, 15, 17, 21, 22, 24, 26, 27) comprise a wall (15) of a dividing element (5), said wall (15) being located between the two adjacent chambers (11-14) of the switch and separates them, while at least one cam (18) of the shaft (4) overlaps the specified wall (15) when exposed to the separation element (5). 8. An electric switch according to claim 7, characterized in that at least one cam (18) overlaps the specified wall (15) regardless of its position between the working and non-working positions. 9. An electric switch according to claim 1 or 2, characterized in that the shaft (4) is movable between the operating position, in which the spacer element (5) is raised by at least one cam (18), and the idle position, while the sealing elements (4, 15, 17, 21, 22, 24, 26, 27), regardless of the position of the shaft (4) between the working and non-working positions, limit the wall that completely separates two adjacent chambers of the switch in the longitudinal direction of the shaft (4). 10. An electric switch according to claim 1 or 2, characterized in that the sealing elements comprise pairs of adjacent overlapping surfaces of the separation element (5) and the housing (1) and adjacent overlapping surfaces of the separation element (5) and at least one cam (18) . 11. An electric switch according to claim 1 or 2, characterized in that the housing (1) comprises a first part that forms a seat (23) for the shaft (4) and a spacer element (5), and a second part that forms the upper part. 12. The electric switch according to claim 1, containing a preload element (10) configured to act on the shaft (4). 13. An electric switch according to claim 12, characterized in that the preloading element (10) is a spring element provided on the shaft side (4) opposite to that shaft side on which the dividing element (5) is located. 14. An electric switch according to claim 12 or 13, characterized in that the pre-loading element (10) is located in the chamber region (11-14) of the switch. 15. An electric switch according to claim 14, characterized in that the switch chamber (14) in the region of which the preload element (10) is located is a switch chamber (14) used for neutral or for auxiliary contact. 16. An electric switch according to claim 1 or 2, characterized in that it comprises at least one ventilation hole (30) extending from the at least one chamber (11-14) of the switch outside the housing (1). 17. An electric switch according to claim 16, characterized in that the distances between adjacent sealing elements (4, 15, 17, 21, 22, 24, 26, 27), between the at least one chamber (11-14) of the switch and the free space (20) between the spacer element (5) and the shaft (4) is selected so that the pressure difference between the specified chambers (11-14) of the switch and the free space (20) is greater than the pressure difference between the chamber (11-14) switch and the space outside the housing (1) due to the specified ventilation holes (30).

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