NO121234B - - Google Patents

Description

Installation circuit breaker, especially screw- or socket-shaped.

In line with increasing electrification, switch technology requires greater switch effects with the same or, if possible, smaller switch dimensions. In this connection, the design of all individual parts, the mechanism and the arc chamber as well as the spatial distribution itself, i.e. the mutual arrangement of the switch lock, contacts, coil and arc chamber, play a decisive role.

The coil not only serves for rapid release, but also has the task of driving the arc as far apart as possible by its lines of force and to tear it off quickly. The arrangement of the contacts is closely related to the arrangement of the arc chamber and the coil, as the arc's propagation direction is always perpendicular to the coil's lines of force, so that the arc is pushed away from the place where its own force field has the same direction as the coil's.

To achieve a good switching effect it is

furthermore, it is important that the switch's mechanical equipment allows small intrinsic times, and that within the scope of this requirement, i.a. a. the switch's control mechanism is as close as possible to the breaking point of the contacts, so that only short and light control elements are needed.

In the case of such switches, one knows so far

essentially the 5 room distributions shown in fig. 1 to 5. The surface, or the space occupied by the mechanical equipment, is completely filled in some places. The room for the coil is strongly shaded downwards from the right and the arc chamber slightly shaded downwards from the left. The contacts are indicated dotted.

A device in accordance with

fig. 1 allows short transmission links from

the control mechanism of the contacts, and the switch chambers are suitably separated. However, the arc chamber is relatively small compared to the entire switch volume, and the arc propagation plane moves away from the front end of the coil. This is unfavorable and leads to the arc being piled up as, according to its nature, it seeks to proceed immediately around the coil.

With a device as shown in fig. 2, the still relatively small arc chamber extends over the entire cross-section of the switch and is limited by this. For that reason, one also has| have already switched to deflecting or extending the arc chamber in the lengthwise direction of the switch partly beyond the circumference of the coil. For constructive reasons, however, this system does not result in any significant increase in space — see the chambers K — because already the placement of the coil, arc chamber and control mechanism above each other in and of itself affects the switch height unfavourably, and the coil must therefore be made short with a large diameter , so there is little room left for the deflection of the chamber. In addition, this is further reduced by normal continuous, insulated fixing screws in the longitudinal direction. With such a device, the arc is also guided near the connection elements (threaded sleeves), so that there is a risk of arc flashover.

A device in accordance with fig. 3 shows an improved spatial distribution with a continuous arc chamber in the longitudinal direction of the switch and in addition deflection under the coil in its longitudinal direction. Here, too, the arc is forced forward mainly in the direction of the front of the coil, i.e. in an unfavorable manner.

Likewise, the above applies to the devices shown in fig. 4 and 5. To the side views in figs 1-4, further sections have been added in the planes which. the arrows indicate. The direction of movement of the contacts is also indicated by arrows.

The object of the invention avoids the disadvantages of the known space distributions, and a new one is proposed which is shown in Figures 6 to 15. With this device, even with a small switch height, it is made possible to give the arc the greatest conceivable propagation space in its physically conditioned directions . In connection with the usual double contact break used, which also occurs in examples 1 to 5, the two arcs can spread from the contact break points over the front end of the coil and almost around the entire coil; in addition to this, propagation or pressure equalization over the entire height of the switch is also possible.

In accordance with the invention, there is proposed an installation automatic switch, especially in screw or socket form, with a coil whose longitudinal axis is approximately in the middle of the switch and perpendicular to the switch's longitudinal axis, and with a double contact break arranged in front of the coil's front end and controlled in the switch's longitudinal direction by a mechanism placed above the coil, and where covers that extend from the wall of the switch capsule enclose the coil and control mechanism in the same way as a balcony, and these covers together with the other capsule walls form an arc chamber with a U-shaped cross-section, while at least the room's side chambers , extends over the entire length of the switch, so that the propagation of the arc, besides in a plane at the front of the coil, will also take place in at least two planes, perpendicular to this plane, on the long sides of the coil, and in at least two of these planes will take place over the whole the length of the switch.

Furthermore, it is also possible to extend the switch chamber in front of the coil over the entire length of the switch right up into the lid, and shield it from the room for the control mechanism by a partition in the lid. All the arc chambers run together under the coil so the space there is used to expand them. The control mechanism, which is placed above the coil, has a narrow design, no wider than the coil diameter. Its space in the lid and the coil chamber which is pressed out in the switch housing have approximately the same cross-section, so that they form two continuous spark chambers which are parallel to the switch axis and are connected to each other at the switch chamber in front of the coil. This, in turn, is divided in two by a dividing wall. This partition can start already in the lid and, after an interruption in the area at the contacts, is carried on to the bottom of the switch so that it also divides the space under the coil in two. If the switch chamber in front of the coil also reaches up into the lid, it forms a U-shaped arc space together with the other kidney-shaped extensions of the arc chamber. The control mechanism is mounted on a partition, fixed between the lid and the switch housing, with openings for the contact and magnetic release control devices and for the arc chambers.

As a further distinguishing feature of the invention, the fixing screws that hold the cover and switch housing together are led through the arc chambers in such a way that they can simultaneously take over the function of spark distributors and thus replace the special metal inserts that are needed in the known switch designs. In certain cases it may be necessary to surround these iron screws with metal sleeves to avoid the direct attack of the arc. Fig. 6 to 15 illustrate the ideas of the invention in an exemplary embodiment. The principle arrangement of the new room distribution will be shown, without thereby claiming to have pointed out all the possibilities that follow from the invention. In particular, the invention can also be used for element and socket switches. Thus, it is e.g. it is not necessary for the switch capsule with the coil chamber to be made in one piece. Coil chamber, separator plate and chamber for steering mechanism could, for example, performed in one piece as a kind of effort. Fig. 6 and 7 show the switch in two side-by-side vertical sections. The switch capsule 1 is, for example, as indicated in the drawing, made in one piece together with the partition wall 6 and the walls 2 which form the coil chamber. The threaded part is open on the underside and is covered by a special plate 3 which is held in place by the threaded sleeve 4. The threaded sleeve 4 is screwed onto the switch capsule and secured against rotation. From the coil chamber wall 2 there extends a partition 6 (not cut through in the figure) which on the one hand goes down to the bottom of the switch and on the other hand extends up between the stationary contacts, in front of the coil.

In fig. 7, only the switch capsule is shown cut through so that you can see the switch chamber in front of the coil. As usual with screw switches, there is a bottom plug 8, in addition to the threaded sleeve 4.

In the case of element and base versions, the lower part of the switch capsule would normally be made rectangular or square and the threaded sleeve or bottom plug replaced with connection clamps. This embodiment is indicated faintly dashed in fig. 1 and shown in more detail in fig. 16—21. Fig. 8 shows a section through the switch along the line A—A, where you can see the further design of the coil chamber 5 together with the walls 2. When designing the coil chamber in accordance with the invention, a horseshoe-shaped arc chamber 9 appears in the plane of the switch around the coil. As shown, the coil 10 is inserted in the coil chamber 5. A fixed contact piece 7 can be led directly to the bottom plug 8. The other contact piece can be connected directly to the coil winding.

Fig. 10 shows the lid 15 folded open and seen from the underside. On top of the switch capsule 1 is the cover plate 11. The control mechanism 19, which is not shown, is attached to the cover plate 11 and is held firmly in position on the switch capsule 1 by means of the lid 15 above the plate 11 and screws (also not shown) in holes 16.

The narrow control mechanism which extends over the switch plane above the coil lies within the walls 17 and is protected by them against attack from the electric arc.

Together with the holes 12 in the plate, the recesses 18 in the lid form the extensions of the arc chambers 9 above the coil. Through the plate hole 14, the contact bridge 20 can be moved by the control mechanism in the direction of the arrow. Through the plate hole 13, for example, a release armature protrudes from the control mechanism down into the coil space 5.

As a result of this structure, the mechanical equipment and the coil can be installed with minimal costs, and are used against the damaging effects of the electric arc in a simple and extremely effective way. Compared to previous designs, a significantly more favorable space distribution occurs, where the necessary space for the coil and mechanical equipment is relatively small, and where practically all of the remaining space in the switch is utilized for extinguishing the arc. The resulting arc chamber extends over the entire front end of the coil, further around the entire perimeter of the coil and further on both long sides of the coil in the entire height of the switch. A buildup of the arc does not occur as with arc chambers that only extend in front of the coil end.

Fig. 11 shows the progression of the arc in a switch designed in accordance with the invention. The directions of propagation are

schematically indicated. Starting from the double contact breaking point 7, 20, the pair of arcs is first driven apart in the plane in front of the coil end in the direction 22, and then guided in the direction 23 along the coil sides, during which the two continuous longitudinal chambers 9 allow a further expansion of the arc in the directions 24 and further down under the coil to the bottom of the switch. With the hitherto known switches, only the propagation directions 22 and partly 23 were utilized, and not to the same extent as with the object of the invention. The device according to the invention also makes it possible to utilize a third deflection or propagation direction 24.

Figs 12 to 15 show a further development of the inventive idea, as the switch chamber in front of the coil is led all the way up into the lid 15. In this case, the room for the control mechanism must be protected against the influence of the electric arc by means of the wall 26. The partition wall 6 has a continuation up in the lid, but this is made thicker to enable the control elements from the control mechanism to the contacts through a gap 25. It is appropriate to extend this partition beyond the lid opening and down into the switch chamber to prevent the arc from jumping onto the contact -the bridge's control elements. With this design, the openings 12 in the cover plate 11 can be made horseshoe-shaped and continuous (see fig. 15).

A comparison of Figures 6 and 10 with Figures 12 and 13 clearly shows the expansion of the space available for the propagation of the arc by this continuation of the invention.

When applying the idea of the invention to socket switches, designs such as those shown in fig. 16 to 18 and 19 to 21.

The space available as an arc chamber is shown in faint shading. The purely schematic representations show in fig. 16 a switch in accordance with the invention seen through a side wall which is assumed to be transparent. The switch chamber encloses the space for the control mechanism and U-shaped coil, cf. fig. 18, and extends from the bottom of the switch all the way up into the switch cover. The space from the coil and control mechanism likewise extends from the bottom of the switch all the way up into the lid, as the space under the coil may have to be used for additional mechanical equipment, auxiliary contacts, impact anchors, etc.

In fig. 19 and the corresponding sections 20 and 21, the space under the coil is also used as an expansion chamber for the arc.

Once again, the device is clearly visible

of the partition in the switch chamber, where-

as it is interrupted in the area of con-

the strokes and divides the arc chamber into two angular parts which are only connected to each other in the contact area where they form a continuous U-shaped space.

Fig. 20 again clarifies the arrangement of the movable contacts' control elements, which are brought forward from the room for the control mechanism

the nism through the split partition to protect against the impact of the arc.

Claims (14)

1. Installation circuit breaker, especially in screw or socket form, with a coil that lies with its longitudinal axis approximately in the middle of the switch and perpendicular to its longitudinal axis and with a contact device with double breaking placed in front of the front end of the coil and controlled in the longitudinal direction of the switch by a mechanism placed above the coil , characterized in that covers extending from the wall of the switch enclosure enclose the coil and control mechanism in the form of a balcony, that these covers, together with the other capsule wall, form an arc chamber with a U-shaped cross-section, and that at least the room's side chambers (the legs of the U) extend over the entire length of the switch. 2. Installation circuit breaker as specified in claim 1, characterized in that the arc chamber left by the covers for coil and mechanism encloses the coil, respectively the coil chamber, U-shaped both with regard to its longitudinal axis and its cross-section, so that the space under the coil down to the bottom of the switch is also used as an arc chamber. 3. Installation automatic switch as stated in claim 1, resp. 1 and 2, characterized in that the breaking chamber, which is arranged in front of the coil vertically on its longitudinal axis, is divided by a partition wall which divides the U-shaped arc space into two approximately equal arc chambers, and that the two fixed edge bars are placed on both sides of the partition wall. 4. Installation automatic circuit breaker as specified in claim 1 to 3, characterized in that the circuit breaker chamber also in front of the coil extends over the entire length of the circuit breaker and is separated from the room for the control mechanism by a special partition placed in the lid of the capsule, so that the arc chamber that encloses the coil and control mechanism U -shaped, extends; over the entire length of the switch in three planes parallel to the length of the switch axis. 5. Installation circuit breaker as specified in claims 1 to 4, characterized in that all arcing rooms, resp. chambers, passes into the space below the coil so this is used as an extension of them down towards the bottom of the switch. 6. Installation circuit breaker as stated in claims 1 to 5, characterized in that the partition wall which is placed in the switch chamber is interrupted in the area of the contacts so that only at this point does a continuous arc chamber occur which encloses the coil. 7. Installation circuit breaker as specified in claims 1 to 6, characterized in that the covers that enclose the mechanism and coil are integrated with the capsule, resp. its lids, almost covering each other, and when the cover is closed forms an all-round closed space, which is divided into a chamber for the coil and one for the control mechanism by means of a dividing plate fixed between the capsule and the lid. 8. Installation circuit breaker as specified in claims 1 to 7, characterized in that the covers that enclose the coil and control mechanism, together with the separating plate, form a whole in the form of an insert. 9. Installation circuit breaker as stated in claims 1 to 8, characterized in that a narrow control mechanism with a width equal to or less than the coil diameter is attached to the separating plate, resp. the effort. 10. Installation circuit breaker as specified in claims 1 to 9, characterized in that the covers for the coil and control mechanism, together with a partition wall which is placed in the switch chamber, and which reaches down to the bottom of the switch and below the coil extends over the entire diameter of the switch, divides the arc space into two closed rooms, which are roughly the same size. 11. Installation automatic switch as specified in claim 1 to 10, characterized in that the upper part of the wall which divides the switch chamber in two, is one with the cap of the capsule — being wider than the other part of the partition — has a slot in which the control elements for the movable contacts are inserted and (at the same time) protected against the electric arc. 12. Installation circuit breaker as specified in claims 1 to 11, characterized in that the cover, cover plate, insert and capsule are held together by fastening screws which are placed in the arc chamber in such a way that they take over the function as spark distributors directly or with attached metal sleeves. 13. Installation circuit breaker as stated in claims 1 to 12, characterized in that the arc spaces are divided in a known manner by radially oriented, labyrinth packing-like support walls so that the arc path is extended. 14. Installation automatic switch as stated in claim 1 to 13, characterized in that the switch capsule which is produced in one piece open above and below, is closed with an inserted switch base which is provided with a bottom plug connected to the capsule by means of the threaded contact sleeve in such a way that it cannot turn.