NO130963B - - Google Patents

Description

Break chamber for self-blowing,

electric compressed gas circuit breakers.

The invention relates to a breaking chamber for a self-blowing, electric compressed gas circuit breaker, and the purpose of the invention is to provide an improved blast opening unit for such circuit breakers,

which provides significant improvement with respect to the breaking chamber performance compared to the previously known types.

Compressed gas circuit breakers are already well known and widely used in electricity supply technology.

Particularly well known are the axial blast breaking chambers used in

this type of circuit breaker, and their shape in the various designs, has been determined using thoroughly worked-out principles.

Such breaking chambers with associated blister opening units

is known, for example, from Italian patent no. 791 6?1 (corresponding

Swedish patent no. 311 392). These breaking chambers are equipped with a blast opening unit with decompression holes and ring-like depressions which are designed to favor the outflow of both the gases that develop during the breakdown of the materials in the blast opening unit itself, and of the extinguishing gas. Thus, a simultaneous flow of the former and the latter gases is achieved, the downstream or end part of the blister opening unit being dependent on the nominal operating voltage of the circuit breaker in accordance with

U

the experimental equation L ^ ' 1.5 " V~ 2~' (simplified form:

YT

L *U ), where L is the length of the opening unit's end part, stated in mm, and Un is the circuit breaker's nominal operating voltage expressed in kV.

However, it has been shown that the hitherto known axial blast breaker chambers do not provide maximum performance with regard to the outflow of the arc extinguishing gas and the protection of the parts which . lies outside the chamber against the influence of the arc, as well as the displacement speed of the chamber's moving equipment, on which the speed of separation from the fixed contact in a single-pole circuit-breaker is directly dependent.

An object of the invention is thus to provide

a breaking chamber for pressurized gas circuit breakers which is structurally improved compared to the known technique, and where the holes formed through the walls of the blast opening unit, to a significant extent, favor the decompression in the area where the holes have their mouths, and consequently make the extinguishing gas outflow particularly easy.

Another object of the invention is to provide

an axial blister breaking chamber in which it is simultaneously possible to

achieve and improve the combination of the effects of d..a rapid decompression in the mouth area of the holes passing through the wall, and of the simultaneous outflow of the decomposition gases and the extinguishing gas through the end part of the opening unit, and consequently accelerate the total gas outflow through the outlet opening of the opening unit and reduce the vortex effects which occurs in this discharge current.

Furthermore, it is an object of the invention to provide a suitably shielded breaking chamber in order to achieve effective protection of the parts outside the chamber, and in particular of the insulating cylinder of Bakelite paper or another similar insulating jacket which surrounds the chamber externally, against the effects of the electric arc at , power failure.

A further object is to provide a breaking chamber in which at least part of the extinguishing gas, being directed in a suitable direction, cooperates with the circuit breaker's control devices to achieve a faster disconnection function for the circuit breaker.

The aforementioned objects are achieved by an axial blast breaker chamber for a self-blowing, 'electric compressed gas current breaker', with a blast opening unit which is internally designed so that in the outlet direction it has a first conical and converging area, a second cylindrical area and a third mainly conical and divergent region with a length L determined by the known experimental equation

where ^n is the breaker's nominal operating voltage, where the second area has the smallest cross-section compared to the other internal areas and is provided with a number of decompression holes with inlet areas that are parallel to the axis of the breaker chamber, and the third area has a number of ring-like grooves which has a mainly triangular cross-section with an open base facing the outlet opening of the breaking chamber, which breaking chamber is characterized by the fact that the decompression holes are designed as mainly slanted, truncated cones with axes that rather in the direction of gas outflow and form an angle of less than 90° with the axis of the chamber ? as the holes are through the part of the chamber's wall that corresponds to the second cylindrical area where they have their inlet area, that outside and concentrically with the actual breaking chamber a mantle is arranged which thus has a larger outer diameter than the chamber, that in the mantle which is preferably of the same material as the breaking chamber, is. arranged with, the chamber concentric toroid-shaped recess with a mainly triangular cross-section with an open base towards the outlet opening of the chamber, where the generatrix of the recess which is farthest from the torus axis coincides with the axis of the chamber, rather in the direction of gas outflow and with the axis of the chamber forms an angle which

is less than 90°? as the decompression holes open towards the recess, whereby the mantle and the recess form a protective screen that completely covers the decompression holes' outlet areas.

The mentioned mantle is preferably made of the same material as the breaking chamber and is in one piece with it or consists of one or more parts which are separated from, but juxtaposed in close contact with, the breaking chamber.

The invention shall be described in more detail in the following in connection with an exemplary embodiment with reference to the drawing, where fig. 1 schematically shows a longitudinal section of part of a breaking chamber's blister opening unit which includes both the cylindrical area and. at least cross section and with decompression hole according to the invention, and the conical and divergent end area, and fig. 2 shows under the same conditions as in fig. 1, but 1 larger scale, a detail of a decompression hole.

By. the blast opening unit shown in the drawing, a mantle h is arranged which surrounds the breaking chamber and extends axially so that in the direction of gas outflow it encloses a first conical and converging area 1 of the blast opening unit, a second, cylindrical area 5 with a smaller cross-section, and finally a third, conical and divergent area 9 which is only partially enclosed, but sufficient to completely shield the outlet areas 11 for a number of decompression holes 6. The mantle h consequently has an outer diameter that is larger than the outer diameter of the actual breaking chamber. The mantle is also made of the same material as the breaking chamber, and these elements are constructed in one piece or as individual elements.

The decompression holes 6 are arranged through the part of the breaking chamber wall that corresponds to the cylindrical area 5" and these holes rather towards the area 9. The mouth areas 10 of the holes 6 facing the inside of the breaking chamber run parallel to the shape of the area 5 axis AA, and consequently parallel to the direction of the gas flow as indicated by arrows 7 (axis AA and the gas stream therefore have the same direction).

In contrast to previously known constructions, the 6 axes of the holes do not normally lie on the breaking chamber's axis AA. The holes therefore do not have the usual straight truncated cone or cone shape such as the holes according to previously known constructions. As already mentioned, do they, on the other hand, have a sloping direction from area 5 towards area 9? and the axis of the holes rather in the gas outflow direction with an angle a in relation to the axis AA which preferably varies from h5° to 65°. The holes thus have the shape of a crooked, truncated cone. The holes run transversely through the breaking chamber wall, and as stated above, the outlet area for a hole 6 from the chamber is denoted by 11 in the drawing. Unlike the known technique, however, the areas 11 do not open directly into the open air, but come out in an annular depression or a groove 16 which is arranged in the mantle h concentrically with the breaking chamber. This recess essentially has a triangular cross-sectional shape with an open base line or base in the direction towards the outlet opening 2 of the breaking chamber. The base line is denoted by 12 in the drawing and indicates in the plan of the drawing the ring that makes up the recess 16's outlet cross-section towards the open air. The recess can be regarded as a toroidal body formed by the generally triangular geometric figure bounded by the sides 11, 12 and 19 of fig. 1 and 2, as this figure is assumed to rotate about the chamber's axis AA, which consequently coincides with the axis of the torus. The generatrix line for the toroidal body which coincides with the triangular side 19 in the figures and which in the drawing plane lies opposite the outlet area 11 of the decompression holes 6, rather in the outflow direction and towards the axis AA of the breaking chamber with an angle (3 which preferably varies -between 30° and ^5° .

As shown by means of the arrows in the figures (especially fig. 2), the shown arrangement of the discharge channels 6 (the decompression holes) and their particular shape determines the flow of the extinguishing gas through the same holes. Thus, each inclined, truncated cone hole 6 directs this gas flow in the direction of the arrows 8. The gas then reaches the recess 16 and impinges at the center against the protective screen provided by the mantle h, so that it is subjected to a deflection in the direction of the arrows 17 in essentially parallel to the axis AA and the inner strbm 7 (in optical terms one can speak of a "reflection" of the extinguishing gas).

In this way, many significant results are achieved.

Firstly, a regulation of the gas flow is achieved through the decompression holes. by means of which the blow-out from these holes is made easier, and thus faster decompression of the cylindrical area 5 is achieved and reduction to completely negligible values of vortex

the phenomena in this area and generally inside the entire breaking chamber.

Second, the gas is given a final direction which is i

substantially parallel to the axis AA of the chamber, and it can then

is guided to join the gases flowing out from the chamber's outlet opening 2 without causing any vortex formation.

Thirdly, the mantle, and in particular a protective shield formed by the mantle in the area 19, prevents the hot gas (heated as a result of its contact with the arc) which flows out through the holes 6, coming into contact with an insulating cylinder of bakelite paper or another suitable insulating material, the body of which is denoted by 20 on. the drawing. Effective protection is thus achieved for the cylinder 20, which thus has a longer service life.

A further advantage of it. 'shown device (an advantage that does not exist in the previously known devices) consists in a reaction force which favors the opening of the circuit breaker by accelerating the displacement of the movable part (to the right in the direction of the arrow 18 in the chamber shown in the drawing, down in the most common, but not always used, operating position for the circuit breaker) with. to which the switch's movable contact 3 is connected. In reality, the gas coming in the direction of the arrows 8 bumps against the area 19 and develops a similarly directed pressure against the mantle h. The effects of this pressure can be analyzed by -loses in two orthogonal directions, one which is parallel to the axis AA

and another which is perpendicular to this.- The component which corresponds to the latter direction has no effect as the breaking chamber has no possibility of movement perpendicular to the axis AA, while the component which is parallel to the axis AA just has the effect that it favors the opening of the circuit breaker (see arrow 18 in fig. 2).

The advantages obtained by means of the invention are due to the advantages due to the special shape of the lower part 9 of the chamber which is provided with. ring-like .track 13

with triangular cross-section. By means of these traces, the resultants 15 of the generation lines lk of the decomposition gases get a component which is parallel to the axis AA, and which favors the outflow of both the quenching (or deionising) gas and the decomposition gas. Although this detail of the breaking chamber is previously known, it is clear that the combined effect of the present invention and the prior art feature, in that

the same breaking chamber enables more effective results with regard to achieving a faster and more complete arc extinguishment, than the results that can be achieved by using only the advanced solutions according to the invention.

It is obvious that the invention can be modified and changed in relation to the embodiment described and illustrated in the foregoing, except that the idea of the invention is deviated from. For example, the mantle h can be extended in the outflow direction so that it surrounds (in addition to areas 1 and 5) not only part of, but the entire area 9? so that the decompression holes open into the recess 16, which in this case transitions into a hollow with an annular cross-section that coaxially surrounds the entire breaking chamber, so that its outlet end part (equivalent to the part 12) lies in the same plane as the chamber's outlet opening 2. Alternatively, the decompression holes can 6,

instead of opening into the annular recess 16, continue 1 individual outflow channels which are direct extensions of the holes 5 and which have a cross-section corresponding to the shape of the same holes 6 or suitably pass into their outlet areas 11. It is thus possible that the outflow channels 16 can end with the part 12 as shown in the figures, or continue unchanged past the part 12 until they open out in the same plane as the outlet opening 2 as indicated above, in case the mantle is extended so that it encloses the entire area 9- It must it is also noted that the cross-section of the flow channels 16 can be circular, elliptical or have any other suitable and advantageous shape. The same applies to the cross-section of the decompression holes 6, although it can be stated here that the circular cross-section has proven to be preferable compared to the others. It should further be noted that the preferred embodiment of the breaking chamber is provided with four holes 6 which have a mutual angular distance of 90° (ie with axes lying in a plane passing through the breaking chamber's axis AA at right angles to each other). It is of course also possible to use more such four holes.

Claims (8)

1. Axial blast circuit breaker chamber for a self-blowing, electrically pressurized gas circuit breaker, with a blast opening unit which is internally designed so that in the outlet direction it has a first conical converging area (1), a second cylindrical area (5) and a third i the main case conical and divergent area (9). with a length L determined by the known experimental equation where ^n is the switch's nominal operating voltage, where the second range (5) has the smallest cross-section in relation to the other inner areas and is provided with a number of decompression holes (6) with inlet areas (10) which are parallel to the axis of the breaking chamber (A - A), and the third area (9) has a number of ring-like grooves (13) which have i main case triangular cross-section with a single-open base facing the breaking chamber's outlet opening (2), characterized by that the decompression holes (6) are designed as, in the main, obliquely stilted, truncated cones with axes that lean in the gas flow direction and form an angle (a) with the axis of the chamber (A - A) which is less than 90°? as the holes are fast through that part of the chamber wall corresponding to the second cylindrical area (5) where they have its inlet area (10), that outside and concentric with it actual breaking chamber is arranged a mantle (k) which thus has larger outer diameter than the chamber, that in the mantle ( h) as for step by step is of the same material as the breaking chamber, one is arranged with the chamber concentric toroidal recess (16) with i main the case triangular cross-section with an open base (12) towards the chamber's exit lop opening (2), where the generatrix (19) of the recess (16) is located furthest from the torus axis which coincides with the axis of the chamber (A - A), rather in the direction of gas outflow and with the axis of the chamber forms an angle (p) that is less than 90°, as the decompression holes (6) open towards the recess (16), whereby the mantle ( h) and the recess (16) form a protective screen that completely covers the decompression holes (6) outlet areas (11). 2. Breaking chamber according to claim 1, characterized in that the angle (a) which indicates the axial angle of the decompression holes (6) position in relation to the axis of the breaking chamber (A - A), lies in about advised h5° to 65°. 3. Breaker chamber according to claims 1 and 2, characterized in that the angle (B) which indicates the inclined position in relation to the chamber axis (A - A) of the generatrix (19) for the toroidal recess (16) which lies farthest from the torus axis (A - A ), lies in the range 30° to 1+5°. h. Breaker chamber according to one of claims 1-3"characterized in that the mantle (k) extends axially in the gas outflow direction so that it surrounds at least the first conical and converging area (1), the second cylindrical area (5) with the smallest cross-section, and a part of the third conical and divergent area (9), for complete shielding of the outlet areas (11) of the decompression holes (6), whereby it forms a protective screen against the same holes (6) along the entire surface described by the toroidal recess (16 ) said generatrix (19). 5. Breaker chamber according to one of claims 1-3?characterized in that the mantle (h) extends axially in the gas outflow direction so that it surrounds not only the first conical and converging area (1) and the second cylindrical area (5), but also the entire third conical and divergent area (9), so that the end area (12) which forms the outlet to free air of the toroidal recess (16) and of its extension coaxial with the breaking chamber, lies in the same plane as the chamber's outlet opening (2). 6. Breaking chamber according to one of the claims 1-5 "characterized in that the decompression holes (6) are at least four in number" and that their axes are normally on top of each other in a plane that passes through the breaking chamber's axis (A-A). 7. Breaker chamber according to one of claims 1-6, characterized in that the mantle (h) is produced in one piece with. the breaking chamber which it surrounds. 8. Breaking chamber according to one of the claims 1-6, characterized in that the mantle (h) consists of one or more parts which are arranged gas-tight next to each other and in side-s-position to the breaking chamber which is enclosed by the mantle itself..