EP3559966A1

EP3559966A1 - Electrical switching device

Info

Publication number: EP3559966A1
Application number: EP18704417.7A
Authority: EP
Inventors: Thomas Chyla; Stefan Giere; Volker Lehmann; Jens Schimmelpfennig; Jörg Teichmann
Original assignee: Siemens AG
Current assignee: Siemens Energy Global GmbH and Co KG
Priority date: 2017-02-21
Filing date: 2018-01-22
Publication date: 2019-10-30
Also published as: CN110313046A; BR112019015398B1; CN110313046B; BR112019015398A2; WO2018153582A1; DE102017202739A1

Abstract

The invention relates to an electrical switching device comprising at least one switching point (5, 6). A switching resistor (11a, 11b) is associated with the switching point (5, 6) and is switched electrically in parallel to the switching point (5, 6). The switching resistor (11a, 11b) has a stack of resistance elements.

Description

description

The invention relates to an electrical switching device for ^{¬ at} least one switching point and at least one Schaltwider ^¬ stood having, which is electrically connected in parallel to the Schaltstel ^¬ le. Such an electrical switching device is ^¬ example, from the published patent application DE 10 2006 004 811 AI be ^¬ known. For potential control, a switching resistor is electrically connected in parallel to a switching point. Electrical switching devices are preferably manufactured in a modular design, so that assemblies can be used several times in different series. Furthermore, electrical components can be adapted to changing requirements in a simplified manner by means of modular assemblies. Therefore, it is an object of the invention to develop a switching device such that it can be variably ^{ausgestat ¬} Tet.

According to the invention the object is an electrical

Switching device of the type mentioned solved in that the switching resistor has a stack of Widerstandselemen ^¬ th.

An electrical switching device is a device which serves to interrupt or to produce a current path. In this case, the electrical switching device can interrupt an electrical current or switch on an electrical current by interrupting or producing a current path. Depending on the design of the electrical switching device, the amount of the electrical current to be controlled can vary. For example, an electrical

Switching device can be designed as a load switching device that, ie the electrical switching device controls Strö ^¬ me that correspond to their maximum size. However, it can also be provided that the electrical switching device is designed as a so-called disconnecting switching device, that is, except for negligible charging and discharging ^¬ currents, the electrical switching device is ^rich tet switched to dominate no electric current. An electrical switching device can also be designed as so-called power ^¬ switching device, that the electric switching means is also a mastering of streams which are above their rated current. Thus, it is possible to play at ^¬ that a power switching device controlled short currents which are a multiple of the rated current ^¬. Electrical switching devices can be used depending on their design at different locations of electric power transmission networks. Electrical switching ^{¬ devices} can be found in low, medium, high and high voltage range use. It is advantageous if a switching point of the switching device is a mechanical switching point. At a mechanical switching point, an impedance of the switching point is changed by relatively movable switching ^¬ contact pieces. Al ternatively ^¬ a switching point may be formed on the semiconductor base, however, for example, the impedance of the switching point may vary due to a harshest operating circuitry.

Regardless of the design of the switching point can be provided that a switching resistor is arranged parallel to the switching point. A switching resistor supports the function of the switching point. For example, in an interrup ^¬ chen a phase conductor of the train and an optionally associated interrupting an electric current reactions take place in the switching point. For example, oscillations or oscillations of energy flows can occur in electric power transmission networks, resulting in a

Voltage overshoot lead over the switching point. By means of a switching resistor so-called recurrence voltages can are limited, whereby a safe and fast manufacture ^¬ len a high-impedance state of the switching point is supported ^¬ . For example, oscillatory processes can occur in AC voltage networks, which lead to voltage overshoots over a switching point, which are greater than the rated voltage for which the electrical switching point is designed. However, it can also be provided that the electrical switching device is used in a DC voltage system, there to interrupt a Phasenlei- terzuges a swinging of the DC, for example, by a current zero crossing through an external wiring, can be forced to a simplified interruption of a Phasenleiterzuges and therefore, if necessary to force a interrup ^¬ chen the direct current.

To design the switching resistor may advantageously be provided that this is composed of a plurality of resistive elements, so that in sum of the combined resistance elements of the desired resistance of the switching resistance is achieved. The resistance ^¬ elements can be interconnected adds ^¬ example in the manner of a stack. The resistance elements can ^¬ example, have each a cylindrical shape, in particular with a circular cylindrical or hollow cylindrical cross section. The end faces of a plurality of resistance elements can be arranged lying against each other and form a stack. For Ver ^¬ improvement of the electrical contact, an arrangement of contact-making between the resistance elements may be provided. The stack of resistance elements can be joined together to form a rigid-angle composite. To form a rigid-angle composite and to avoid falling apart of a stack of resistance ^¬ elements, the resistance elements can be pressed against each other by applying an external force. Alternatively or additionally, the stack of elements Widerstandsele ^{¬ be} surrounded by a sheath, which serves for axial guidance of the stack of resistance elements. The enclosure should act electrically insulating. In ^¬ example, the stack of resistive elements can be positioned within a tube of electrically insulating material, wherein the tube can serve to apply contact forces of the resistance stack. Thus, for example, it is possible for the electrically insulating tube to receive the stack of resistance elements and to arrange contact points for electrical parallel connection of the switching resistance to a switching point at the end of the insulating tube. For example, the Kontaktierungs ^¬ dots can also serve a holding and positioning of the switching resistor.

Advantageously, it can be provided that the number of resistance elements which form a stack, is available for electrical ^¬ rule resistance of the stack of resistive elements in ohms in a ratio of less than or equal to 2, in particular less than or equal to 1.5. With a ratio of the number of resistive elements of the stack to the electrical resistance of less than or equal to 2, in particular less than or equal to 1.5, a favorable release of heat from the stack of resistive elements is made possible. Furthermore, the length of the stack of resistance elements is limited such that an electrical parallel switching to the switching point is made possible in a simplified manner. By a Festle ^¬ account the number of resistor elements to the electrical resistance of the stack to the interpretation of the individual opponent ^¬ stand element is defined with respect to the part of resistance, which contributes to the total resistance, the resistance element of the stack. Further, the mass of the stack of cons ^¬ stand elements is limited. As has been found particularly advantageous if the ratio of the number of reflection ^¬ stand elements to the electrical resistance of the stack in ohms at the limits of about 0.5 ... 0.7 to about 1.0 ... 2 moves. By dimensioning the resistance elements, for example, using sintering process ren, in particular of ceramics or the like, are manufactured inexpensively.

A further advantageous embodiment may provide that the length of the switching resistance in mm to the electrical ^{resistance of} the switching resistor in ohms has a ratio of less than or equal to 8, in particular less than or equal to 6.

In this ratio of the length of a switching resistor to the electrical resistance in ohms is given the opportunity to form the switching resistance, for example, from one or more stacks of resistive elements. The load capacity of the switching ^resistors can be improved by a parallel ^{scarf ¬} tion of multiple columns. However, it can also be provided that the switching resistor only one

Has stack of resistance elements, wherein also in such an embodiment, the ratio of length to resistance in ohms of the on-resistance, in particular the Sta ^¬ pels of resistive elements, the dimensioning specification corresponds. It has proved to be advantageous, the Ver ^¬ ratio of length of the switching resistor to the amount of

Switching resistance in ohms in a range of 3 ... 4 to 6 ... 8 set. Advantageously, it can further be provided that the electrical switching device has a multi-interrupting switching path having a first switching point and a second switching point, which are electrically contacted with each other, wherein between terminals of the multi-interrupting switching path is a distance in mm, which is a maximum of 30 times , In particular, at most 25 times the amount of the switching resistance in ohms.

As described at the outset, an electrical switching device serves to switch a current path or to switch an electric current. If one uses now several switching points, which together a switching of a current path serve the / electrical current, an electrical switching device is formed with multiple interrupting switching path. The switching points are preferably electrically interconnected in series, so that the switching path at the end points of the interconnected switching points have connection points of the electrical switching device, between which a switching of a phase conductor train (current paths) or an electric current is made. To connect the first and the second switching point with each other, for example, serve a contact element, which spaced the two switching points from each other. This contact element is preferably designed to be electrically conductive, so that an electrically conductive connection of the first and second switching point via the contact element takes place. As a contact element, for example, transmission elements, such. B. a gear head, serve, which serves to couple a movement to the first or the second switching point. The switching points can carry on from the contacting element. In particular, the switching points can be arranged on opposite sides of the contacting element. Advantageously, the switching points with opposite direction sense to each other substantially flush from the contacting element. Kön- on the side remote from the ends of the element PLEASE CONTACT ^¬ approximately two switching points NEN the connection points of the multi-disruptive switching path lie. Thus, it is for example possible to form an outdoor switching device in live tank design, which may have, for example, a plurality of encapsulating housing in T-shape forerun by an electrically insulating support means.

For the first switching point, a first switching resistor may be electrically connected in parallel. For the second switching point, a second switching resistor can be electrically connected in parallel. It can be provided that both the first and the second switching point is assigned in each case a switching ^¬ resistance. However, it can also be provided be that only the first switching point or only the second switching point is assigned a switching resistor electrically pa ^¬ rallel switched. By an electrically pa ^¬ rallele switching circuit of resistors, the operational mode is le to which the Schaltwiderstnd is electrically parallel ge ^¬ switches bridged by the circuit resistance. With ande ren ^¬ words, in addition to the impedance variable switching a parallel current path through the switch resistance will be ^¬ builds. However, the switch resistance to such a high amount that the switching ^¬ put in the high impedance state can flow to vernachläs ^¬ sigender leakage current via the on-resistance only. Optionally, in order to avoid a leakage current, a temporary separation of the parallel current path produced via the respective switching resistor is additionally to be provided. Such ^¬ on separate parallel flow path can preferably be effected by one he followed ^¬ Interrupting a phase conductor and the train after successful ^¬ rich solidifying the switching point. In particular, in a mechanical switching point, a hardening of the switching point is necessary, for example, in the field of

Removing foreign bodies such as sedimentation or other interfering particles from the switching point. Through the use of multiple switching points, there is also an advantage of keeping an electrical voltage to be separated over the switching path distributed over a plurality of switching points, so that each of the switching points only has to take over a partial size of the voltage to be controlled between the contacting points of the switching path. For forming an electrically insulating encapsulating tubular structures can be used, which are provided to the end-side openings of fittings in Wesentli ^¬ chen. The fittings can be designed to be electrically conductive, the fittings also for electrical see contacting the first and the second switching point, which are arranged in the interior of the respective encapsulating, serve. Furthermore, over the fittings can also the switching resistors are electrically connected in parallel to the first or the second switching point. In addition, Kings ^¬ nen the fixtures serve as support elements for supporting or carrying of switching resistors. This can be advantageous in particular if the switching resistors are arranged outside the encapsulating housing. A switching resistor can also be arranged within an encapsulating housing.

The above statements regarding the possibility of arranging an encapsulating housing and a consequent structure for an electrical switching device are independent of the number of switching points, regardless of the position and the position of the switching points and regardless of the formation or position of the switching resistors also applicable for the following ^variants from ^¬ leadership in an analogous manner.

A further advantageous embodiment can provide that the first or the second switching point is surrounded by an encapsulating housing, wherein a switching resistor is arranged outside of the encapsulating housing.

An environment of a switching point with an encapsulating housing has the advantage that the switching point can be protected from external influences. An encapsulating housing can be designed, for example, in the form of an electrically insulating tubular body, in the recess of which a switching point is arranged. End of the tubular body may be provided with fittings to an electrical contact of the switching point to he ^¬ possible located in the in- side of the encapsulating housing. In one arrangement, a switching resistance au ^¬ ßerhalb of such encapsulating the Kapse ^¬ lung housing can be designed with its cross section to the dimension of each ^¬ weiligen switching point. If necessary, then a switching resistance can be arranged outside of the encapsulating. As a result, a modular structure of an electrical switching device is further supported, in which the Switching resistor is arranged outside only on Kapse ^¬ ment housing when needed, the encapsulating itself can be opti ^¬ optimized in its dimensions to the switching point.

A further advantageous embodiment may provide that the first and the second switching point are each surrounded by a cape ^¬ selungsgehäuse, wherein a switching resistance au ^¬ ßerhalb an encapsulating housing is disposed.

With an equipment both the first switching point and the second switching point with an encapsulating the possibility is given to install each of the switching points in a protected space, both switching points and only one switching point a switching resistance zugeord ^¬ net can be. An arrangement of the switching resistor except ^¬ half of the encapsulating allows a substantially parallel alignment of encapsulating and Schaltwider ^¬ stand each other. For example, the on-resistance can end on the encapsulating housing located electrically conductive members (fittings), each contacting the first and the second switching point, undergo a parallel electrical circuit ^¬. In this case, the switching resistance can be supported on the respective encapsulating housing.

A further advantageous embodiment can provide that the first or the second switching point is surrounded by an encapsulating ^¬ housing, wherein a switching resistor is disposed within ei ^¬ nes encapsulating.

An arrangement within the encapsulating housing, which surrounds the first or the second switching point, has the advantage that the switching resistance can benefit from the mechanical protective effect of the encapsulating housing and does not itself require a separate cladding. As a result, electrical contacting of the switching resistor with the respective switching point is made possible in a simplified manner. A further advantageous embodiment may provide that the first and the second switching point are each surrounded by a cape ^¬ selungsgehäuse, wherein a switching resistance of a domestic nerhalb encapsulating housing is disposed.

Equipping the first and the second switching point with a respective encapsulating housing makes it possible, also the first or the second switching point or both

Switching points each having a switching resistance auszustat ^¬ th, wherein the circuit resistance in the respective encapsulation ^¬ housing of the respective switching takes place assembly. Again, a protective effect of the respective encapsulating is expandable to the switching resistance.

An advantageous embodiment may provide that an encapsulating housing is a pressure vessel.

Advantageously, it can be provided that an encapsulating housing is filled with an electrically insulating fluid.

An embodiment of an encapsulating housing as a pressure container makes it possible to fill the interior of the encapsulating housing with an electrically insulating fluid and to pressurize this electrically insulating fluid, so that the

Interior of the encapsulating against the environment of Kap ^¬ selungsgehäuses a different pressure. The pressure vessel is designed such that it can withstand a Diffe ^¬ rence pressure. This makes it possible to enclose a suitable fluid within the capsule housing. Example ^¬ as can be filled with the encapsulating an electrically isolie ^¬ Governing oil or an electrically insulating gas. To be advantageous in particular gases or fluids have proven flues ^¬ with fluorine components, on the one hand an the other hand also have good arc extinguishing effect high electrical insulating effect. For example, sulfur hexafluoride, fluoroketones, fluoronitriles to be used. Next, however, other electrically insulating fluids such as nitrogen, oxygen, etc.

usable. In the following, an embodiment of the invention is sche ^¬ matically shown in a drawing and described in more detail below. It shows the

Figure shows a side view of an electrical switching device.

The electrical switching device according to the figure is as a free air circuit breaker in live tank design in the high voltage range, in particular for voltages above

800,000 volts designed. The electrical switching device has a support frame 1, which is generally formed of electrically conductive material and which leads Erd ^¬ potential. On the support frame 1 a Antriebseinrich ^¬ device 2 is positioned. The drive device 2 is also generally located at ground potential. By means of the drive device 2 is an actuation of the electrical switching device, ie a separation or producing a current path allows. The drive device 2 provides the necessary energy, in this case the necessary kinetic energy. On the support frame 1, an electrically isolie ^¬ render section of a support column 3 is arranged. The support column 3 is present composed of a first and a second driven elekt ^¬ insulating portion, wherein the electrically insulating portions are substantially tubular and the ends closed with valves. Mutually facing sides of the electrically insulating portions of the support column 3 are screwed together, so that an elongated tubular support column 3 is formed. With its one end face, the support column 3 is positioned on the support frame 1. The electrically insulating Ab ^¬ sections of the support column 3 are hollow and externally provided on the outside side with a ribbing. Through the ribbing is given an improved outdoor strength by

Creepage distances on the surface of the support column 3 extended who ^¬ and drip-noses are formed on the support column 3. At the end facing away from the support frame 1 end of the support column 3, a gear head 4 is arranged. The gear head 4 terminates the support column 3 and is rigidly connected to the support column 3 ver ^¬ connected. In the transverse direction to the axial course of the support column 3, a first switching point 5 and a second switching point 6 are mounted on the gear head 4. The first and the second switching point are for this purpose surrounded by a first encapsulating housing 7 and a second encapsulating housing 8. The two encapsulating housings 7, 8 are designed to be similar to an electrically insulating section of the support column 3. This means that the two encapsulating housings 7, 8 are essentially hollow-cylindrical, electrically insulating in the form of tubes, with a fitting for terminating the encapsulating housings 7, 8 being arranged at each end of the encapsulating housings 7, 8. With respect to the gear head 4, the two Kapse ^¬ ment housing 7, 8 are arranged on opposite sides of the transmission head 4 and protrude with opposite sense of direction of the gear head 4. The gear head 4 facing ends of the two encapsulating 7, 8 are mechanically connected via the local fittings of the encapsulating 7, 8 with the Ge ^¬ drive head 4, so that the Kapselungsge- housing 7, 8 abge ^¬ on the gear head 4 on the support column are supported. The housing of the gear head 4 is formed from a conductive material, wherein an electrical contact of the fittings, which are connected to the gear head 4, is given via the gear head 4.

In the interior of the encapsulating housing 7, 8, the first and the second switching point 5, 6 are arranged. The first and the second switching point 5, 6 each have relatively movable switching contact pieces. In this case, the relatively movable switch contact pieces are designed such that they can contact one another or can be separated from one another. To effect a change in the state of the first or the second switching point 5, 6 is in the interior of Tragsäu ^¬ le 3 a kinematic chain, for example arranged in the form of an axially displaceable shift rod, which acts before ^¬ given electrically insulating. Thus it is possible, a loading movement, which is discharged from the drive unit 2 on the frame 1, to be transported within the support column 3 to the transmission ^¬ head. 4 The gear head 4 a defense ^¬ development of the movement can in the two encapsulating 7, 8 carried into it, so that a relative movement of the Schaltkontaktstü- blocks of the first and the second switching point 5, 6 can be made. The switching points 5, 6 are attached in such a ^¬ arranged that the switching points with the armature of the respective encapsulating housing 7, are electrically contacted by 8, which are hinged to the gear head. 4 Thus, the

Switching points on the valves, which are connected to the gear head 4, electrically interconnected via the gear head 4 in series, so that a multiple interrupting ^¬ chende switching path is formed. The two switching points 5, 6 are electrically conductively connected to their respective other side with a fitting which at the free end of the respective encapsulating housing 7, 8, the respective encapsulating housing 7, 8 closes. The fittings positioned there form connection points 9, 10 for the multiple (twice) interrupting switching path of the electrical switching device. Between the connection points 9, 10 thus extending a distance D which the length of the electrically insulating portions of the encapsulating housing 7, 8 as well as of the electrically conductive contact-making, which at ^¬ the switching points 5, 6 serves includes a contacting of the.

Both the first switching point 5 and the second switching point 6 each have a switching resistance IIa, IIb zugeord ^¬ net. The two switching resistors IIa, IIb are in each case electrically connected in parallel to the first switching point 5 or to the second switching point 6. For this purpose, the Schaltwider ^¬ states IIa, IIb each with the fittings, which the Kapse ^¬ ment housing 7, 8 of the respective switching point 5, 6 end limit, electrically connected. In addition to an electrical contact of the switching resistors IIa, IIb on the fittings of the capsule housing 7, 8, a mechanical holding or wearing the switching resistors IIa, IIb on the fittings and on the encapsulating housing 7, 8 gege ^¬ ben. The switching resistors IIa, IIb are each constructed identically. The switching resistors IIa, IIb each have ei ^¬ nen stack of n-resistive ^elements . The resistance ^¬ elements are each arranged in a tubular electrically insulating cylinder, which on the one hand forms a mechanical protection for the respective stack of resistive elements. On the other hand, the cylinder also serves to apply a force to the resistance elements located in the interior of the switching resistor. The number of switching resistors can vary depending on the dimension of the respective encapsulating housings 7, 8 or of the gear head 4. Thus, a stack of resistive elements has n resistive elements. The encapsulating housings 7, 8, the support column 3 and the gearbox ^¬ head 4 are each designed as a pressure vessel, so that the interior of the encapsulating 7, 8, the support column 3 and the gear head 4 can be filled with an electrically insulating fluid, which is encapsulated , In this case, especially electrically insulating fluids are advantageous, which the

Insulation resistance in the interior of the support column 3 or in the interior of the encapsulating housing 7, 8 convey. Preferably, the electrically insulating fluid inside the encapsulating housing 7 can be set to 8 under positive pressure so that a differential pressure on the encapsulating housing 7, 8 and also on the support column 3 and can ^¬ attributable to the gear head. 4 In this case, the capsule housing are 7, 8 as a pressure vessel auszufüh ^¬ ren.

Claims

claims

1. electrical switching device at least one switching point (5, 6) and at least one switching resistor (IIa, IIb) pointing to ^¬ , which is electrically connected in parallel to the switching point ^¬ ,

d a d u r c h g e k e n e c i n e s, e s the switching resistor (IIa, IIb) has a stack of resistor elements (n).

2. Electrical switching device according to claim 1,

In other words, the number of resistive elements (n) forming a stack corresponds to the electrical resistance of the stack of resistive elements (n) in ohms in a ratio less than or equal to

2. in particular less than or equal 1.5 stands.

3. Electrical switching device according to claim 1 or 2, characterized in that the length of the switching resistor (IIa, IIb) in mm to elekt ^¬ cal resistance of the switching resistor (IIa, IIb) in ohms a ratio of less than or equal 8, in particular less than 6 has ,

4. Electrical switching device according to one of claims 1 to 3,

characterized in that the electrical switching device has a multi-interrupting switching path having a first switching point (5) and a second switching point (6), which are contacted with each other elekt ^¬ rically, between terminal points (9, 10) of the multi-interrupting switching path a distance (D) in mm, which is at most 30 times, in particular at most 25 times the amount of the switching resistance (IIa, IIb) in ohms.

5. An electrical switching device according to claim 4, wherein a first switching resistor is electrically connected in parallel to the first switching point, and / or a second switching resistor is electrically connected in parallel to the second switching point.

6. Electrical switching device according to claim 4 or 5, characterized in that the first or the second switching point (5, 6) is surrounded by a Kap ^¬ selungsgehäuse, wherein a switching resistance is arranged outside ^¬ half of the encapsulating.

7. Electrical switching device according to claim 4 or 5, characterized in that the first and the second switching point (5, 6) are each surrounded by egg ^¬ nem encapsulating (7, 8), wherein a switching ^¬ resistance (IIa, IIb) outside of a Encapsulation is ordered to ^¬ .

8. Electrical switching device according to claim 4 or 5, characterized in that the first or the second switching point (5, 6) of a capsule ^¬ selungsgehäuse (7, 8) is surrounded, wherein a switching resistance (Ha, IIb) within the encapsulating (7 , 8) is arranged.

9. Electrical switching device according to claim 4 or 5, characterized in that the first and the second switching point (5, 6) are each surrounded by egg ^¬ nem encapsulating (7, 8), wherein a switching ^¬ resistance (IIa, IIb) within a Encapsulation housing (7, 8) is arranged.

10. Electrical switching device according to one of claims 6 to 9,

characterized in that an encapsulating housing (7, 8) is a pressure vessel.

11. Electrical switching device according to one of claims 6 to 10,

That is, an encapsulating housing (7, 8) is filled with an electrically insulating fluid.