DE102016218322B4 - Breaker unit for a circuit breaker and a circuit breaker with such a breaker unit - Google Patents

Abstract

Interrupter unit (2) for a circuit breaker (1), comprising - two electrically conductive arcing contact pieces (5, 6) running along a switching path (26) between a switch-off position in which the arcing contact pieces (5, 6) pass through the switching path (26) from one another are separated, and a switch-on position in which the arcing contact pieces (5, 6) are in galvanic contact with one another can be moved relative to one another, - an insulating material nozzle (7) at least partially surrounding the switching path (26) with a through the insulating material nozzle (7) Nozzle channel (8) through which the switching path (26) runs, and a storage chamber (13) which stores an insulating medium (14) in its liquid state and an outer surface of a passage section (15) which is permeable to the liquid insulating medium (14) Isolierstoffdüse (7) surrounds, which separates the storage chamber (13) from the nozzle channel (8), characterized in that the passage Absc Cut (15) runs annularly around a channel section of the nozzle channel (8).

Description

The invention relates to an interrupter unit for a circuit breaker.

In particular, the invention relates to an interrupter unit for an enclosed circuit breaker, such as. B. from the US 2,152,283 A is known in which an insulating gas is used to extinguish an arc, which is formed during a switching operation between arcing contact pieces of the interrupter unit.

The invention has for its object to provide an improved circuit breaker unit.

The object is achieved by the features of claim 1.

Advantageous embodiments of the invention are the subject of the dependent claims.

An interrupter unit according to the invention for a circuit breaker comprises two electrically conductive arcing contact pieces, an insulating material nozzle and a storage chamber. The arcing contact pieces can be moved relative to one another along a switching path between a switch-off position in which the arcing contact pieces are separated from one another by the switching path and an on position in which the arcing contact pieces are in galvanic contact with one another. The insulating material nozzle at least partially surrounds the switching path. A nozzle channel runs through the insulating material nozzle, through which the switching path runs. The storage chamber stores an insulating medium in its liquid state and surrounds an outer surface of a passage section of the insulating material nozzle which is permeable to the liquid insulating medium and which separates the storage chamber from the nozzle channel.

The passage section of the insulating material nozzle enables liquid insulating medium to get from the storage chamber through the passage section into the nozzle channel. During a switch-off process in which the arcing contact pieces are separated from one another, an arc burns between the two arcing contact pieces. The arc heats insulating medium located in its surroundings, which has diffused from the storage chamber through the passage section into the nozzle channel. The insulating medium in the nozzle channel then evaporates, thereby increasing the pressure in the nozzle channel and acting as an extinguishing gas for extinguishing the arc. If there is also an insulating gas in the nozzle channel, the vaporized insulating gas increases its effect and forms an extinguishing gas with it to extinguish the arc. The insulating medium thus advantageously increases an extinguishing gas pressure due to the evaporation of the liquid and itself contributes to extinguishing the arc. At the same time, the insulating medium advantageously lowers a temperature of the extinguishing gas by absorbing energy when the liquid evaporates.

According to the invention, the passage section extends in a ring around a channel section of the nozzle channel. This enables a uniform and large-scale dispensing of liquid insulating medium from the storage chamber into the nozzle channel.

One embodiment of the invention provides that the passage section is arranged in the region of a channel constriction of the nozzle channel. As a result, the insulating medium advantageously has a particularly effective effect, since an arc in the region of a channel constriction of the nozzle channel can be extinguished particularly effectively due to the channel diameter which is reduced there.

A further embodiment of the invention provides that the storage chamber runs in a ring around the insulating material nozzle. This advantageously achieves a uniform distribution of the insulating medium around the insulating material nozzle.

Another embodiment of the invention provides that the storage chamber has a chamber wall connected to the insulating material nozzle. As a result, the storage chamber can advantageously be formed by only one chamber wall, since the insulating material nozzle itself acts as a further chamber wall.

A further embodiment of the invention provides that the insulating medium is a medium that evaporates in the nozzle channel when an arc burns in the nozzle channel between the arcing contact pieces. This has the above-mentioned advantages of increasing the pressure and lowering the temperature in the nozzle channel by evaporating liquid insulating medium when an arc burns in the nozzle channel.

A further embodiment of the invention provides that the nozzle channel is filled with an insulating gas which contains the insulating medium in its gaseous state. In other words, the insulating medium is not only stored in its liquid state in the storage chamber, but is also used in its gaseous state as part of an insulating gas of the interrupter unit. The effect of the insulating gas in the quenching of an arc is supported in the manner described above by the evaporation of the liquid insulating medium in the nozzle channel.

Another embodiment of the invention provides that the insulating medium contains sulfur hexafluoride or a fluoronitrile or C ₅ ketone. Due to their high electrical strength and high thermal conductivity, these insulating media are particularly suitable as media for extinguishing arcs in interrupter units.

A further embodiment of the invention provides that the passage section of the insulating material nozzle is made from a material that is resistant to erosion, for example from a ceramic material or a ceramic-filled plastic. Plastics and ceramic materials are particularly suitable for producing a passage section which is permeable to a liquid insulating medium.

A circuit breaker according to the invention has an interrupter unit according to the invention. The advantages of such a circuit breaker result from the above-mentioned advantages of an interrupter unit according to the invention.

The above-described properties, features and advantages of this invention and the manner in which they are achieved can be more clearly understood in connection with the following description of exemplary embodiments which are explained in more detail in connection with a drawing. The single figure shows a sectional view of a circuit breaker 1 in the area of an interrupter unit 2 of the circuit breaker 1 ,

The circuit breaker 1 is encapsulated with a circuit breaker housing 12 in which the breaker unit 2 is arranged, executed.

The breaker unit 2 has an essentially rotationally symmetrical structure, which extends around a longitudinal axis 11 extends. The breaker unit 2 has a first arcing contact piece 5 and a second arcing contact 6 on. The first arcing contact 5 is a first nominal current contact piece 3 assigned. The second arcing contact 6 is a second rated current contact piece 4 assigned. The rated current contact pieces 3 . 4 as well as the arcing contact pieces 5 . 6 are each rotationally symmetrical to the longitudinal axis 11 shaped and coaxial to the longitudinal axis 11 arranged.

The first arcing contact 5 is tubular and has a second arcing contact piece 6 facing contact end 20 with a tulip-shaped contact opening 21 on. An end portion of the first arcing contact 5 is from a protective cover 10 surrounded, which is made of an electrically insulating material and over the contact end 20 of the first arcing contact 5 protrudes. Is optional between the first arcing contact 5 and the protective cover 10 a burning cap 9 arranged, which are made of a highly erosion-resistant material, for. B. is made of graphite.

The second arcing contact 6 is bolt-shaped to make galvanic contact in the contact opening 21 of the first arcing contact 5 to be retractable. The first rated current contact 3 and the first arcing contact 5 point regardless of a switching state of the interrupter unit 2 always the same electrical potential. The second rated current contact piece 4 and the second arcing contact 6 also have independent of the switching state of the interrupter unit 2 always the same electrical potential.

The rated current contact pieces 3 . 4 and the arcing contact pieces 5 . 6 are along the longitudinal axis 11 movable relative to each other between a switch-off position shown in the figure and a switch-on position. The two arcing contact pieces are in the off position 5 . 6 through a switching path 26 separated from each other. The two nominal current contact pieces are correspondingly in the off position 3 . 4 separated from each other. The second arcing contact piece is in the switch-on position 6 into the contact opening 21 of the first arcing contact 5 retracted and the nominal current contact pieces 3 . 4 are in galvanic contact with each other. The arc contact pieces make contact during a switch-on process 5 . 6 one another in time before the nominal current contact pieces 3 . 4 , When switching off, the rated current contact pieces first separate 3 . 4 and chronologically following the arcing contact pieces 5 . 6 ,

When contacting and when the arcing contact pieces are separated 5 . 6 an arc arises between the arcing contact pieces 5 . 6 , An insulating material nozzle is used to direct and guide the arc 7 intended. The insulating material nozzle 7 has a nozzle channel 8th on. The nozzle channel 8th is rotationally symmetrical and has a channel constriction 24 on, the diameter of which corresponds to a diameter of the second arcing contact piece 6 corresponds. The insulating material nozzle 7 surrounds the switching path 26 at least partially and is coaxial to the longitudinal axis 11 aligned. The nozzle channel 8th widens on the part of the first arcing contact 5 to a nozzle channel end section 25 into which the first arcing contact piece 5 protrudes.

On an outside of a middle portion of the insulating nozzle 7 is a storage chamber 13 arranged which is an insulating medium 14 saves in its liquid state. The storage chamber 13 surrounds an outer surface of one for the liquid insulating medium 14 permeable passage section 15 the insulating material nozzle 7 that the storage chamber 13 from the nozzle channel 8th separates. The passage section 15 runs in a ring around a channel section of the nozzle channel 8th which is the narrow passage 24 of the nozzle channel 8th having. The storage chamber 13 has one with the insulating nozzle 7 connected chamber wall 16 on the middle section of the insulating nozzle 7 surrounds like a ring. The insulation medium 14 contains, for example, sulfur hexafluoride or a fluoronitrile or C ₅ ketone.

The breaker unit 2 is arranged, for example, rotated clockwise by 90 degrees with respect to the illustration in the figure, so that the first arcing contact piece 5 below the second arcing contact 6 is arranged and located in the storage chamber 13 a liquid level 17 of the insulating medium 14 forms that is perpendicular to the longitudinal axis 11 is.

In operation of the breaker unit 2 is especially the nozzle channel 8th filled with an insulating gas, for example with sulfur hexafluoride, nitrogen or another suitable gas. The insulating gas can in particular be the insulating medium 14 be in its gaseous state. Also penetrates in the storage chamber 13 stored liquid insulation medium 14 the passage section 15 and gets into the nozzle channel 8th ,

During a switch-off process in which the arcing contact pieces 5 . 6 are separated from each other, there is a burning of an arc between the two arcing contact pieces 5 . 6 , The arc heats the insulating gas in its vicinity and that from the storage chamber 13 through the passage section 15 in the nozzle channel 8th diffused insulating medium 14 , The insulation medium 14 in the nozzle channel 8th then evaporates and contributes to the pressure increase in the nozzle channel 8th which is also caused by the heated insulating gas. The evaporated insulation medium 14 and the insulating gas together form an extinguishing gas that extinguishes the arc.

Although the invention has been illustrated and described in detail by preferred exemplary embodiments, the invention is not restricted by the disclosed examples and other variations can be derived therefrom by a person skilled in the art without departing from the scope of protection of the invention.

Claims (9)

Interrupter unit (2) for a circuit breaker (1), comprising - two electrically conductive arcing contact pieces (5, 6) running along a switching path (26) between a switch-off position in which the arcing contact pieces (5, 6) pass through the switching path (26) from one another are separated, and a switch-on position in which the arcing contact pieces (5, 6) are in galvanic contact with one another can be moved relative to one another, - an insulating material nozzle (7) at least partially surrounding the switching path (26) with a through the insulating material nozzle (7) Nozzle channel (8) through which the switching path (26) runs, and a storage chamber (13) which stores an insulating medium (14) in its liquid state and an outer surface of a passage section (15) which is permeable to the liquid insulating medium (14) Surrounding the insulating nozzle (7), which separates the storage chamber (13) from the nozzle channel (8), characterized in that the passage section (15) runs annularly around a channel section of the nozzle channel (8). Interrupter unit (2) after Claim 1 , characterized in that the passage section (15) is arranged in the region of a channel constriction (24) of the nozzle channel (8). Interrupter unit (2) according to one of the preceding claims, characterized in that the storage chamber (13) extends in a ring around the insulating material nozzle (8). Interrupter unit (2) according to one of the preceding claims, characterized in that the storage chamber (13) has a chamber wall (16) connected to the insulating material nozzle (7). Interrupter unit (2) according to one of the preceding claims, characterized in that the insulating medium (14) is a medium which evaporates in the nozzle channel (8) when an arc burns in the nozzle channel (8) between the arcing contact pieces (5, 6) , Interrupter unit (2) according to one of the preceding claims, characterized in that the nozzle channel (8) is filled with an insulating gas which contains the insulating medium (14) in its gaseous state of matter. Interrupter unit (2) according to one of the preceding claims, characterized in that the insulating medium (14) contains sulfur hexafluoride or a fluoronitrile or C ₅ ketone. Interrupter unit (2) according to one of the preceding claims, characterized in that the passage section (15) of the insulating material nozzle (8) is made of a fire-resistant material and / or is made of a ceramic material and / or of a ceramic-filled plastic. Circuit breaker (1) with an interrupter unit (2) designed according to one of the preceding claims.

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