DE1064592B - Compressed air switch with closed extinguishing chamber - Google Patents

Description

The invention relates to compressed air switches in which the arc blows in closed arcing chambers is, the vortex formation of the incoming compressed air practically eliminated by suitable means will.

The supply of compressed air into the extinguishing chamber must take place in such a way that the flow reaches a maximum Produces extinguishing performance. For this purpose care must be taken that the eddies are in the flow do not cause any losses in the extinguishing performance. One therefore has to supply the compressed air paid special attention. So you have avoided the compressed air during the supply to redirect in adaptation to the surrounding space. One therefore leaves the cross-section of the feeders Merge as steadily as possible into the cross-section of the arcing chambers. One also has in the feed channel Arranged baffles, which should determine the direction of the flow.

It has now been found that these measures are not yet sufficient to cause the vortex to form to eliminate. It is not only a question of the shape, the continuity and the size of the feed cross-sections, but there must also be a special one Means are applied which divides the flow. According to the invention it is therefore proposed to install a perforated disc in the feed line to the contact, the holes of which are rotationally symmetrical are arranged and together have a cross section which is at least equal to the Channel cross-section is in front of the contact zone.

Examples of such an arrangement are shown in FIGS.

1 shows an extinguishing chamber 1 with the contact 2, to which the compressed air is fed via the hollow insulator 3. The air first enters the space 4, then to the perforated disk 5, the space 6 and finally to the contact 2. The space 4 is conical, so that the cross section gradually widens in the direction of the perforated disk 5. In the perforated disc, the compressed air jet is divided into several jets, which are independent of one another. As a result, existing AV vortices in the flow are broken up and inequalities are evened out. In order to achieve this effect, the sum of the hole cross-sections must not exceed a certain ratio 1: n, for example 1: 3, compared to the total pane cross-section. On the other hand, the sum of the hole cross-sections must be at least equal to the flow cross-section between the perforated disc and the contact zone so that the pressure drop across the perforated disc is not too great and the blown air is not throttled too much. From the perforated disk 5, the cross section is steadily in that of the extinguishing chamber itself compressed air switch with closed
Extinguishing chamber

Applicant:

Public limited company Brown, Boveri & Cie., Baden (Switzerland)

Representative: Dr.-Ing. E. Sommerfeld, patent attorney,
Munich 23, Dunantstr. 6th

Claimed priority:
Switzerland from November 18, 1958

Dr. se. math. Paul Baltensperger,

Unter-Engstringen, Zurich (Switzerland),

has been named as the inventor

convicted. It is useful here to also make this cross section rotationally symmetrical.

Another embodiment is shown in FIG. 2. There, the perforated disk 7 itself is conical. the Holes 8 are distributed over the surface of the cone. While it is necessary in the arrangement of FIG. 1, the cross section to expand the chamber at the point of the perforated disc in order to obtain the required cross-section, In the arrangement according to FIG. 2, the cross section of the quenching chamber and the supply can be the same stay. This version is therefore cheaper and more space-saving; it can be integrated into existing constructions can be retrofitted easily. Here too, the sum of the hole cross-sections must be on the one hand smaller than a third of the surface of the cone and on the other hand at least equal to the flow cross section between perforated cone and nozzle.

The tip of the cone can point in or against the direction of flow.

The advantage of the arrangement is a practically completely vortex-free supply of the compressed air, with the Feeding special attention. the cross-section only in the immediate vicinity of the perforated disc, is necessary. Special calming areas and cross-sectional adjustments are not necessary. Using conical perforated disks, the cross section of the feed and the quenching chamber can be the same.

909 610/293

Claims (7)

Claims; 1. Compressed air switch, in which the arc is extinguished in the quenching chambers by blowing characterized in that a perforated disk is installed in the compressed gas supply line to the contact is whose holes are arranged rotationally symmetrical and together have a cross section which is at least equal to the channel cross-section in front of the contact zone. 2. Compressed air switch according to claim 1, characterized in that the perforated disc including the holes have a cross-section that is larger than the smallest of the one leading to the contact- .. the flow channel. 3. Compressed air switch according to claim 2, characterized in that the total cross section of the Orifice plate is at least three times as large as the smallest of the flow channel leading to the contact and the sum of the hole cross-sections at most one third of the total cross-section of the Disc is. 4. Compressed air switch according to claim 3, characterized in that the total cross section of the The space in front of the perforated disc expands continuously in a conical shape up to it. 5. Compressed air switch according to claim 3, characterized in that the on the perforated disc lying cross-section of the compressed gas supply steadily in the cross-section of the extinguishing chamber on Contact passes over and is rotationally symmetrical. 6. Compressed air switch according to claim 1, characterized in that the perforated disc itself is conical with the tip of the cone pointing in the direction of flow. 7. Compressed air switch according to claim 1, characterized in that the perforated disc itself is conical with the tip of the cone pointing against the direction of flow. 1 sheet of drawings . 909 610/293 8.