The present invention relates to an electric switch housing.
An arc emerges when the contacts of an electric switch are disconnected from each other. Gas produced by the arc is to be exhausted from the housing.
Various solutions have been tried to exhaust the gases from the housing but there is still room for improvement for the gas exhaust arrangements.
An object of the present invention is to provide a switch so as to alleviate the above disadvantages. The object of the invention is achieved with a switch housing, which is defined in the independent claim. Some embodiments are disclosed in the dependent claims.
In the following, the invention will be described in greater detail by means of some embodiments with reference to the accompanying drawings, in which
A rotary electric switch may comprise a plurality of switch modules, which are stacked together. Each switch module may comprise two halves that are settable against each other.
The housing 100 comprises a bottom wall 102, which serves as a mounting base for mounting the housing to a rail, for instance. The direction of the bottom wall is called as “horizontal direction” in the following. The housing also comprises side walls 104 and 106, which are substantially perpendicular to the bottom wall. The top wall 108 is parallel to the bottom wall.
It can be seen that the walls may have small indentations, such as the bottom wall has an indentation in the middle usable in mounting purposes of the housing. The walls, such as the side walls 104 and 106 are not completely straight in
The housing is arranged to house a rotary actuator 110. The rotary actuator is used for rotating a rotary contact 112. The rotary contact may, for example, be such that is pushed through the rotary actuator as in
The housing also comprises spaces for two stationary contacts 114, 116. The stationary contacts may be at the opposite ends of the housing, substantially at the middle of the housing in vertical direction. The rotary contact blade serves in making and breaking an electrical contact between the stationary contacts. When the rotary actuator 110 is turned clockwise, the ends 112A, 1128 of the contact blade make contacts with the respective stationary contacts 114 and 116. Turning of the rotary actuator counter-clockwise causes the contact blade to disconnect from the stationary contacts at both ends of the contact blade.
When the rotary contact is disconnected from the stationary contacts, an arc is formed at each disconnection point. That is, an arc is formed at both ends 112A, 1128 of the rotary contact blade 112.
For the purpose of extinguishing the arcs, there are provided an arc chamber at the proximity of the area, where the contact blade disconnects from the stationary contacts. At a first end of the housing, there is provided an arc chamber 120 for extinguishing an arc formed by disconnection of the rotary contact end 1128 from the stationary contact 116, and at a second end of the housing, there is provided an arc chamber 124 for extinguishing an arc formed by disconnection of the rotary contact end 112A from the stationary contact 114.
Each arc chamber may comprise one or more arc plates 122. In
The housing may also comprise a permanent magnet 118 for directing the arc. In
It can be seen that the arc chambers 120, 124 are placed to opposite corners of the substantially rectangular housing 100. The first chamber 120 is placed to a corner of the housing that is close the bottom wall 102 of the housing, and the second chamber 124 is further away from the bottom wall 102 than the first chamber.
In the arc chambers, the extinguishing of the arc produces gas that needs to be exhausted from the housing 100. There is provided a gas exhaust channel 130, 132 in the proximity of each arc chamber. However, as can be seen from
The second gas exhaust channel is arranged close to the corner between the side wall 104 and the top wall 108. In the shown embodiment, the outlet opening leading out of the housing is arranged to the top part of the side wall 104. Alternatively, it could be close to the end of the top wall 108. The second exhaust channel may be substantially in 45 degree angle with respect to the side wall 104 and the top wall. Thus, the gases exhausted via the channel are led to a direction that is away from the base. This is important, as the conductive gases are in different electrical potential than the mounting rail to which the housing is mounted to, and an arc could emerge if the gases could contact the base.
The first gas exhaust channel 130 resides physically close to the bottom wall, and there is risk that gases react electrically with the mounting rail. The first gas exhaust channel comprises therefore a guiding portion 130A, which is substantially parallel to the side wall 106. The guiding portion 130A is thus substantially vertical leading away from the bottom wall 102. At the end of the guiding portion, there is provided an outlet opening leading the gases away from the housing 100. The gases are thereby led towards the stationary contact 116 that is partly residing exterior of the housing. This can be permitted as the gases and the stationary contact are in the same electrical potential.
The first gas exhaust channel 130 may also comprise an inlet portion 130B, which is divergent from the guiding portion 130A. The inlet portion 130B and the guiding portion 130A may be arranged about 45 degrees angle to each other.
The gas exhaust channel may be arranged as an indentation/recess to the side wall of the housing.
There is arranged a gas exhaust channel 130 in the housing for exhausting gas generated in the arc chamber 120 due to extinguishing of the arc. The gas exhaust channel 130 is located in the corner of the housing. It is arranged behind the arc plates when seen from the geometrical centre point of the housing module or the rotation axis of the rotary contact.
The gas exhaust channel comprises a portion, which leads the gases away from the bottom wall. The gas exhaust channel may thus have a portion which is substantially perpendicular to the bottom wall. The portion of the gas exhaust channel is thus substantially parallel to the side wall of the housing.
The exhaust channel may also comprise an inlet portion. This refers to the vertically lowest portion of the housing, which is arranged into an angle with respect to the side wall 106.
The exhaust channel may be arranged as a recess in the bottom and/or side walls of the housing. The channel may be such that it enlarges towards the outlet 130C.
As can be seen, the housing comprises a gas shield 134 for limiting the gas flow outside the housing. The gas shield may comprise a front wall for preventing the gas exhausted from the outlet opening 130C to flow to perpendicular direction from the side wall. Furthermore, the gas shield 134 may comprise side portions 134 for preventing gas flow to a direction perpendicular to the end wall of the housing.
It will be obvious to a person skilled in the art that, as the technology advances, the inventive concept can be implemented in various ways. The invention and its embodiments are not limited to the examples described above but may vary within the scope of the claims.
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/FI2013/050412 | 4/15/2013 | WO | 00 |