EP2601661A1 - Switching apparatus for a low-voltage electrical switching device - Google Patents

Abstract

The invention relates to a switching apparatus (100) for a low-voltage electrical switching device with a rotary contact having switching pieces (400) bearing at least two end contacts (410) and with means for applying a contact-pressure force (300), with a housing and with an arc quenching chamber (600). Precisely in the case of DC applications, a large isolating distance is required between the contacts. In order to enlarge this isolating distance, the invention proposes mounting the contact pieces (400) bearing end contacts (410) at spatially variable pivot points (216, 226).

Description

 SWITCHING DEVICE FOR AN ELECTRICAL

 LOW VOLTAGE SWITCHGEAR

The invention relates to a switching device for an electrical

Low-voltage switchgear according to the preamble of the main claim.

Such switching devices typically include single-break or double-break contact arrangements.

From EP 1 523 020 AI a switching device with easy interrupting rotary contact in particular for a multi-pole low-voltage switch-disconnector is known. In this case, the switch has an insulating housing, in which two chambers are formed, of which a first chamber acts as an extinguishing chamber and a second chamber with a comparable volume as a connection chamber. A simply interrupting rotary contact is movable in a bearing, wherein the rotary contact is designed as a two-armed lever, the first lever arm carries a contact piece, which with a fixed contact to a first power supply rail in

Switching contact comes. The second lever arm of the rotary contact is connected to a flexible conductor, which is in conductive connection with a second

Power connection rail stands. There are contact force springs available on the

Rotary contact and a switching shaft or a switching shaft segment attack.

From DE 100 61 394 AI a switching device is known which includes a double-break rotary contact having a pole associated with each switching drive. The rotary contact is rotatably mounted in bearings in the insulating housing about an axis perpendicular to the longitudinal extent of the rotary contact. The actual switch consists of two fixed, connected to busbars

Contact pieces, and a floating, two-armed trained rotatable contact piece, which carries end contacts with the fixed Interact contact pieces. Two contact pressure springs, preferably designed as torsion springs, are based on a bearing pin on the rotary contact piece and each exert a directed in closing movement torque on the

Turning contact piece off.

The known switching devices thus have a fixed contact and a movable contact piece. The fixed contact limits the achievable

Separation distance between the contacts. For DC applications (DC applications), large separation distances are required. In the prior art, for DC applications, conventional switching devices suitable for

 AC applications (AC applications) are used. In order to realize the required large contact distances, two existing current paths are connected in series. Thus, to realize a DC switching device with an existing switching device, a four-pole AC switching device can be used in which two phases are connected in series, e.g. Moeller switch-disconnector for 1000V DC such as N2-4-160-S 1-DC to N4-4-1400-S 1-DC. The disadvantage of such solutions lies in the large footprint of such 4-pole switching devices, the high cost, in particular by doubling the existing commonly made of silver alloys required contact pads, and not adapted to the DC application blowing effect of the contact arrangement on the in the switching or Tripping case resulting arc.

Object of the present invention is to provide a switching device for a low-voltage electrical switching device, in particular for DC applications, which avoids these disadvantages.

Starting from a switching device of the type mentioned, the object is achieved by the totality of the features of the main claim 1. Further advantageous embodiments of the invention are described in the dependent claims 2 to 8. The switching device according to the invention is characterized in that there are two movable contact pieces for each phase. The two switching pieces of a phase are mounted via a lever system in the housing of the switching device. In this case, this lever system each comprises a guide and a pivot lever, which are each secured with a rigid axle on the housing of the switching device and with a movable axis on the respective contact piece. In the event of a break, the swivel lever is moved from the ON position to the OFF position, thereby pivoting the two contact pieces far apart. The switching device is therefore particularly suitable for DC and high voltages where large opening distances are required to shut down.

According to the invention the levers are connected via movable joints with the switching pieces, that the joints move in the case of switching on circular arcs. In a preferred embodiment of the invention, the levers are made of insulating material.

In another embodiment, the levers include a core and a shell. In this case, the core material of a heavy-duty material, such. Steel or aluminum. The jacket material can consist of insulating material.

In a further preferred embodiment, contact force springs engage the pivoting lever. It has proved to be advantageous to design the contact force springs as tension springs, which exert a force on the contacts in the ON position, which acts in the direction of the respective other contact piece.

In an advantageous embodiment, the contact pieces comprise contact plates at a first end.

In a particularly preferred embodiment, the trajectory through which the contact plates pass during their switching movement, from a quenching chamber accompanied. It has proved to be particularly advantageous, this quenching chamber

continuously over the entire traversed by the contact plate trajectory interpreted. The switching device according to the invention is suitable for AC applications, but especially for DC applications.

Reference to the embodiments illustrated in the figures, the invention is explained in detail. Show it:

1 shows the switching device as a schematic diagram in the ON position

2 shows the switching device as a schematic diagram in side view in the OFF position. 3 shows the switching device as a schematic diagram in a plan view and as a section.

Figure 1 shows a schematic diagram of the switching device according to the invention (100) in the ON position. The shift apparatus (100) includes two movable shift pieces (400) each movably supported at a first end of a guide lever (210) and a swing lever (220) in bearings having movable shafts (216, 226). The guide lever (210) and pivot lever (220) are mounted with their respective second end by means of bearings with a rigid axis (215, 225) in a housing (not shown). The movable axes of the guide levers (216) can move around their rigid-axis guide-lever bearings (215) on a circular path (218) in space. The movable axes of the pivoting levers (226) may also move on a circular path (228) about their rigid-axis pivotal lever bearing (225). The contact force is applied by means of contact force springs (300) which act on the pivoting levers (220). But it is also possible

Contact force springs (300) at other locations of the pivot lever (220) or on the contact pieces (400) attack itself. The pivoting lever (220) is shown here in simplified form to depict the rigid connection of the pivot points (225) and (226). In some embodiments, this function is through a shift shaft implemented. The guide lever (210), as well as the pivot lever (220) may be made of insulating material. But it is also possible, the leadership (210) and

Swing lever (220) to produce a sandwich with a core and a shell, wherein the core material may be a mechanically stable material that does not have to be insulating, and the jacket material may consist of an insulating material.

FIG. 2 shows a schematic diagram of the switching device (100) according to the invention in the OFF position. Both contact pieces have been rotated in space around the movable axes of guide lever and pivot lever (216, 226), said movable axes (216, 226) have moved on their circular paths (218, 228) accordingly. Although guide and pivot levers (210, 220) have moved only slightly, the end contacts (410) of the contact pieces have moved very far apart. Furthermore, one along the trajectory describing the end contacts (410) in their opening path is a continuous one

 Arc quenching chamber (600) to see. In the arc quenching chamber (600) arc extinguishing elements (610) are arranged. These arc quenching elements (610) may include sheets that divide and cool the arc thereby depriving it of energy to extinguish it. The arc (500), which arises when switching under a corresponding current load, runs from one contact plate to the other contact plate along this

Arc extinguishing chamber (600), so that an optimal arc extinction is possible. When the contacts are open, the arc with the contact piece (on both sides) forms a current loop, which quickly drives the arc into the quenching chamber and causes the arc to extinguish.

Figure 3 shows a section of the switching device as a principle sketch in a plan view and as a section. Parts of two housing halves (710, 720) can be seen in the figure, the guide levers with their rigid axles (215) being mounted between these housing halves (710, 720). The switching device shown has per switching piece (400) each one on a longitudinal axis with the switching piece (400) lying guide lever (210) and two pivoting lever (220), wherein the Pivot levers (220) are arranged parallel to the longitudinal axis of the contact piece (400) and laterally of the contact pieces (400) are located. In the housing halves (710, 720) are recesses (730) in which the levers (220, 210) and axes (216, 226) can move. The two housing halves (710, 720) together form the housing of the switching device, the separation extending in the direction of the longitudinal axis of the contact pieces (400).

Reference sign list

100 switching device for a low voltage electrical switch

210 guide lever

215 Guide lever bearing with rigid axle

 216 movable axis of the guide lever

 218 circle of possible geometric locations of the movable axis of the

guide lever

 220 pivot lever

225 Swivel lever bearings with rigid axle

 226 movable axis of the pivot lever

 228 circle of possible geometric locations of the movable axis of the

pivot lever

 300 contact force spring

400 contact piece

 410 end contact

 500 arc

 600 arc quenching chamber

 610 arc extinguishing elements

710 First housing half

 720 Second case half

 730 recess in housing for levers and axles

Claims

claims:

Switching device for a low-voltage electrical switch (100), comprising a rotary contact with contact pieces (400) carrying at least two end contacts (410) and means for applying a contact pressure force (300), a housing and an arc quenching chamber (600),

 characterized in that

 the at least two end contacts (410) carrying switching pieces (400) in spatially variable pivot points (216, 226) are mounted.

Switching device for a low-voltage electrical switch (100) according to claim 1,

 characterized in that

 spatially variable pivot points (216, 226) each have a guide (210) and a pivot lever (220).

Switching device for a low-voltage electrical switch (1) according to claim 2

 characterized in that

 the guide (210) and pivot levers (220) each engage a spatially rigid shaft (215, 225) on the housing and a movable axis (216, 226) on the shift member (400).

4. Switching device for a low-voltage electrical switch (100) according to one of the preceding claims,

 characterized in that

 the guide (210) and pivot levers (220) comprise insulating material.

Switching device for a low voltage electrical switch (100) according to

Claims 1 to 3,

 characterized in that

the guide (210) and pivot levers (220) have a core and a jacket comprise, wherein the jacket comprises insulating material.

Switching device for a low-voltage electrical switch (100) according to one of the preceding claims,

characterized in that

the means for applying a contact pressure force (300) comprise contact force springs.

Switching device for a low-voltage electrical switch (100) according to claim 4,

characterized in that

the contact force springs (300) are designed as tension springs

Switching device for a low-voltage electrical switch (100) according to one of the preceding claims,

characterized in that

the arc extinguishing chamber (600) is formed continuously over the entire possible opening path of the contact pieces.