EP4035188A1 - Resistor assembly for tap changer and tap changer - Google Patents

Abstract

The invention relates to a resistor assembly (10) for a tap changer (1), having at least one resistor element (20) which is held by at least two resistor holders (30). The resistor assembly (10) comprises: a baseplate (11) with at least one opening (12), on which the at least two resistor holders (30) for holding the resistor element (20) are arranged; and a guide (31), which is formed in each resistor holder (30), each guide (31) positioning a first end (201) and a second end (202) of the resistor element (20) between the two resistor holders (30) in relation to a longitudinal direction (L). According to the invention, a contact point (24) of the resistor element (20) comes into electrical contact with contacts (40) of the tap changer (1) when a resistor element (20) is inserted into the resistor holder (30).

Description

RESISTANCE ARRANGEMENT FOR TAP SWITCHES AND TAP SWITCHES

The invention relates to a resistor arrangement for a tap changer and a tap changer with such a resistor arrangement.

The German patent application DE 4231 353 A1 discloses a tap changer. A current limiting resistor is connected at one end to one of the tap selectors and at its other end to the neutral point. The resistance is built in permanently and unchangeably.

The German utility model DE 7707461 U discloses a diverter switch resistor. The diverter switch resistor consists of round, oval, rectangular or square resistor material with rounded edges, which is bent to form resistance spirals and installed in a self-supporting manner in chambers. The curved resistance spiral is built into a chamber formed from two insulating rods.

On-load tap-changers, in particular on-load tap-changers, are used for uninterrupted switching between winding taps of a transformer. With known on-load tap-changers based on the high-speed resistance switching principle, the circulating current that flows when the currently connected tap-changer and the preselected new tap-changer are simultaneously contacted is limited by ohmic resistances, thereby ensuring an uninterrupted change in the transformation ratio of the transformer. The ohmic resistance must be designed depending on the specific circuit topology, the individual operating conditions as well as the load current and the step voltage, i.e. in particular the respective application of the on-load tap-changer. The step voltage is the voltage between the currently connected and the preselected step contact of the on-load tap-changer. The resistance design is complex and affects the entire manufacturing process, in particular the assembly process of the tap changer. Because, depending on the application, a different number and dimensioning of the resistors is required, so that the structural design of the tap changer may also have to be adapted. This results in a large number of different variants of tap changers depending on their respective application. At the moment, the tap changer is fitted with the necessary switching resistors during assembly according to the resistance value determined for a specific order and then fully assembled. In view of the high number of variants, this leads to increased effort when installing the tap changer. The object of the invention is therefore to provide an improved concept for a resistor arrangement for a tap changer that can be easily and quickly adapted to different applications of the tap changer and thereby ensures the operational safety of the tap changer.

This object is achieved by a resistor arrangement for a tap changer which comprises the features of claim 1. Further embodiments are described in the dependent claims.

The resistor arrangement according to the invention for a tap changer comprises at least one resistor element which is held by at least two resistor holders. The resistor holders are provided at least on a base plate with at least one opening on which the at least two resistor holders for receiving the resistor element are arranged. The resistor element can be inserted through the opening into the guide of the resistor holder provided in the resistor holder. Guides are formed in each resistor holder. Each guide of the two resistance elements positioned a first end and a second end of the resistance element with respect to a longitudinal direction between the two resistance holders. In each case one contact point of the resistance element is electrically contacted by contacts of the tap changer when a resistance element is placed in the resistance holder.

The improved concept for the tap changer with a resistor arrangement has the advantage that it is possible to change or replace the resistors easily and quickly if required (such as changing the operating conditions of the tap changer) and still guarantee the operational reliability of the tap changer .

According to one possible embodiment of the resistor arrangement for a step switch, the one contact point of the resistor element is provided in an edge region at the first end and at the second end of each resistor element.

According to a possible embodiment of the resistor arrangement for a step switch, each resistor holder comprises a guide for fixing the resistance element. Each guide can be designed as a slot with a closed end and an open end. At least in part, the slot is provided with a side wall which can extend in part along the slot. The resistance element can be inserted through the open end of the slot. The resistance arrangement is designed in such a way that the resistance element after assembly of the tap changer is fixed between the at least two resistance holders by means of the guide of the resistance holder.

According to a possible further embodiment, the guide can comprise a folding element which can be designed as a reversibly and elastically pivotable leg with a snap hook provided at a free end. The snap hook secures the resistance element pushed into the guide and holds it in position between the two resistance holders. The resiliently pivotable leg gives way when the resistance element is pushed into the guide and also forms part of the guide.

According to one possible embodiment of the invention, the at least one resistance element comprises a resistance carrier and a current-limiting element.

According to a possible embodiment of the invention, the resistor carrier can be designed as a plate and the current-limiting element can be designed as a metallic wire that is wound around the plate. According to a possible embodiment, the resistance carrier can be designed as a frame and the current-limiting element in the form of one or more metallic springs which are tensioned in the frame

According to one possible embodiment of the invention, each resistance element at the first end and at the second end can each have an edge region that is free of the current-limiting element. The closed end of the guide defines an end position for the resistance element in the resistance holder. As a result, a part of the edge region of the resistance element essentially interacts with the slot of the guide in a form-fitting manner.

Essentially, the form-fitting interaction means that the edge regions of the resistance element are at least partially surrounded by the guide on at least three sides in a form-fitting manner, that is to say with an accurate fit. The open end of the guide thus forms an open side of the guide, via which the resistance element can be inserted into the resistance holder. When inserting the at least one opposing element into the guide, the resiliently pivotable leg gives way, and the at least one resistance element is locked in this when it reaches the end position in the guide.

According to at least one possible embodiment, the snap hook forms a part the guide of the resistance holder in such a way that the snap hook surrounds the resistance element, when it has reached the end position in the guide, to at least part of it and thereby locks it in the end position. The snap hook can also simply be released from the locking position, so that the resistance element can be removed again and exchanged for another (with a different specification), for example.

According to at least one possible embodiment, the resistor holder and the guide are made in one piece and made of insulating material. According to at least one embodiment, the resistor holder, the guide and the holding element are formed in one piece. The resistor holder can preferably be produced from a plastic by means of an injection molding process.

According to at least one possible embodiment, the base plate has at least one opening in the area of the at least two resistor holders, which is designed such that the at least one resistor element can be fixed through the opening between the at least two resistor holders by means of the guides of the resistor holders.

This enables the insertion of the resistance elements (resistors) after assembling the tap changer and a simple adaptation of the tap changer to different applications by exchanging the resistance elements. Since the electrical contacting of the resistance elements is also ensured.

According to one possible embodiment, the at least one opening can be designed to be essentially rectangular.

According to a possible embodiment of the invention, the resistance element can comprise two contact points made of electrically conductive material, which are electrically conductively connected to the current-limiting element. The contact points of the resistance element are essentially provided in an edge region at the first end and at the second end of each resistance element.

According to one possible embodiment, each contact point is designed as a metal plate.

According to one possible embodiment, the resistor arrangement comprises at least two contacts which can connect the resistor element to current-carrying lines of the tap changer via the at least one contact point. The contacts can be designed as spring contacts. Via the current-carrying lines, the resistance element is preferably connected in an electrically conductive manner to the discharge line and / or contacts and / or switches and / or other current-carrying components of the tap changer. The contacts can be selector contacts and corresponding step contacts, for example, via which the voltage ratio of the transformer windings is preselected or set. The switches can be designed, for example, as vacuum interrupters and / or as other mechanical switching elements, via which the load switchover from the currently connected to the preselected step contact takes place. According to at least one embodiment, the contacts are formed as spring contacts which are designed with a defined mechanical preload such that the spring contacts press against the contact points of the resistor carrier when the resistor element is positioned in the resistor holders.

According to a possible further embodiment, the contacts can be integrated into the resistance holder. For example, the contacts would also make up part of the tour.

According to a possible further embodiment of the invention, the at least two resistor elements can be arranged between the resistor holders essentially parallel to one another and / or one above the other in the vertical direction.

According to a possible embodiment of the invention, the at least two resistance elements form a resistance module.

According to the improved concept, a tap changer is also specified which comprises the resistor arrangement according to the invention.

According to one possible embodiment of the invention, the tap changer comprises at least the first base plate and a second base plate, which are held in spatial relation to one another via at least two winder holders.

According to a possible embodiment of the invention, the at least two resistance holders can be arranged perpendicular to the at least two base plates.

According to a possible embodiment of the invention, the at least two winder spacers can be arranged between the at least two base plates.

According to a possible embodiment of the invention, the two resistance holders can be arranged parallel to one another. In the following, the invention is explained in detail on the basis of exemplary embodiments with reference to the drawings. Components that are identical or functionally identical or have an identical effect can be provided with identical reference symbols. Identical components or components with identical functions may only be explained with reference to the figure in which they first appear. The explanation is not necessarily repeated in the following figures.

Show it

Figure 1 is a partial view of a tap changer with the arrangement of a counter stand element;

FIG. 2 shows a perspective illustration of an exemplary embodiment of a resistor arrangement according to the improved concept;

FIG. 3 shows a longitudinal sectional illustration of an exemplary embodiment of a resistor holder for a resistor arrangement according to the improved concept;

FIG. 4 shows a detailed view of the resistor arrangement from FIG. 2; FIG. 5 shows a perspective illustration of an exemplary embodiment of a resistance element according to the improved concept;

FIG. 6 shows a perspective illustration of the arrangement of the resistance element from FIG. 2 in electrical contact with lines of the tap changer;

FIG. 7 shows another view of the perspective representation of the arrangement of the resistance element from FIG. 6;

FIG. 8 shows a perspective illustration of a further exemplary embodiment of a resistor arrangement according to the improved concept;

FIG. 9 shows a side view in longitudinal section of the resistor arrangement from FIG

8th;

FIG. 10 shows a longitudinal sectional illustration of an exemplary embodiment of several resistance elements fixed in a resistance holder according to the improved concept. Identical reference characters are used for elements of the invention that are identical or function in the same way. Furthermore, for the sake of clarity, only reference symbols are shown in the individual figures which are necessary for the description of the respective figure. Components of the tap changer, which are essential for the following description of the resistor arrangement, have not been shown in these figures for the sake of clarity. The figures merely represent exemplary embodiments of the invention without, however, restricting the invention to the illustrated exemplary embodiments.

FIG. 1 shows a partial view of a tap changer 1. The tap changer 1 comprises at least one switching element 2 with which a switchover from one tap (not shown) to the next tap (not shown) of a transformer winding takes place. The switching element 2 is assigned a resistance element 20 with which a circulating current that flows when switching during the simultaneous con tacting of a currently connected and the preselected new step contact is limited. This guarantees an uninterrupted change in the transformation ratio of the transformer. The resistance element 20 is held in two resistance holders 30 and is thus positioned in relation to the switching element 2. The resistance element 20 defines a first end 20i and a second end 2O2 with which it is held in the two resistance holders 30. An electrically conductive connection is established from the switching element 2 to the resistance element 20 in the region of the first end 20i and the second end 2O2 via electrical contacts 40.

FIG. 2 shows a perspective illustration of an exemplary embodiment of a resistor arrangement 10 for a tap changer 1. The resistor arrangement 10 comprises two resistor holders 30 which are arranged or mounted on a base plate 11. A resistance element 20 is held and fixed at a first end 20i and at a second end 2O2 by the resistance holder 30. The resistance element 20 is positioned in the longitudinal direction L by the resistance holder 30.

As can be seen from FIG. 3, each resistor holder 30 has a guide 31 which facilitates the insertion of the resistor element 20 and the inserted resistor element 20 is positioned in its longitudinal direction L between the two resistor holders 30. The guide 31 serves as a fold for the first end 20i and the second end 2O2 of the resistance element 20. The guide 31, according to this exemplary embodiment, consists of a slot 32 formed in the resistance holders 30. The slot 32 is at least partially with a side wall 33, which extends only partially along the entire length of the slot 32. The two side Borrowed walls 33 represent a lateral limitation for the resistance element 20, which facilitates the insertion of the resistance element 20 into the guide 31 of the two resistance holders 30 and prevents the resistance element 20 from being pushed in or in the end position in the longitudinal direction L of the resistance element 20 can be pushed. The guide 31 also has a closed end 37 and an open end 36. The guide 31 is formed in the resistor element 20 such that the closed end 37 is located in the resistor holder 30 and is arranged at a distance B from the base plate 11. Furthermore, the guide 31 is inclined at an angle α to the base plate 11 when the resistance holders 30 are mounted on the base plate 11. In the case of the resistor holder 30 mounted on the base plate 11, the open end 36 of the guide 31 of the resistor holder 30 is provided opposite one of the openings 12 in the base plate 11. Furthermore, the resistance holder 30 comprises a holding element 34 for the resistance element 20 when this is inserted into the guides 31 of the resistance holder 30. The folding element 34 is designed as a reversible and elastically pivotable leg 38 which has a snap hook 39H formed at a free end 39. The pivotable leg 38 of the folding element 34 forms part of the guide 31. When the resistance element 20 is inserted into the resistance holder 30, the elastic folding element 34 recedes so that the resistance element 20 can be pushed into the guide 31. One end position of the resistance element 20 in the guide 31 is reached when it comes to rest on the closed end 37 of the guide 31. When the resistance element 20 reaches the end position in the guide 31, the pivotable leg 38 moves into the starting position and the elastic snap hook 39H at the free end 39 returns to its starting position and thus locks the resistance element 20 in the guide 31. The resistance element 20 is then essentially fixed in operative connection with the guide 31 in the area of the first end 20i and the second end 2O2 and the snap hooks 39H and thus in the two resistance holders 30.

FIG. 4 shows a detailed view of the resistor arrangement with a resistor element 20 which is held by one of the resistor holders 30. As already mentioned in the description of FIG. 3, the resistance element 20 is seated with the first end 20i or the second end 2O2 in the guide 31 of the resistance holder. The elastic snap hook 39H at the free end 39 of the pivotable leg secures the resistance element 20 in the guide 31.

Figure 5 shows a perspective view of an exemplary embodiment of a resistor element 20. The resistor element 20 consists of a resistor carrier 21 and a current-limiting element 22 which, according to this exemplary embodiment, is designed as a metallic wire which is wound around the resistor carrier 21 and fixed at the first end 20i and the second end 2O2 by means of a clamp 25. Furthermore, the resistance element 20 at the first end 20i and at the second end 202 each has an edge region 23 which is not in contact with the current-limiting element 22, the metallic wire. Each of the edge areas 23 of the resistor carrier 21 has a contact point 24 in each case. The con tact points 24 are made of electrically conductive material and, for example, as brackets or plates. Also shown in Figure 5 and shown in the assembly in Figures 6 and 7 are spring contacts 40 which are connected at a first free end 42 to current-carrying lines 41 of the tap changer 1 and which are connected to the second free end 43 with a defined spring force against the Kontaktstel len 24 of the resistance element 20 are pressed.

Figures 6 and 7 show from different perspective views, the contacting of the resistance element 20 with the current-carrying lines 41 of the tap changer 1. The current-carrying lines 41 of the tap changer 1 are connected to the first free end 42 of the spring contacts 40. In order to release the electrical contact, the spring contacts 40 press against the contact points 24 formed in the resistance element 20 inserted through the opening 12 of the base plate 11.

FIG. 8 shows a perspective illustration of a further embodiment of a resistance arrangement according to the improved concept. FIG. 9 is a side view in longitudinal section of the resistor arrangement from FIG. 8. FIGS. 8 and 9 show the resistor arrangement in a three-phase tap changer 1. A base plate 11 made of insulating material thus has three openings 12 through which the resistance elements 20 enter the fully assembled tap changer 1 can be used. A second base plate 13 made of insulating material is arranged opposite the base plate 11. A total of six resistor holders 30 are placed between the two base plates 11 and 13. A resistor element 20 is fixed between two resistor holders 30. The two base plates 11 and 13 are connected to one another via the resistor holder 30. For this purpose, the resistance holders 30 preferably have pins 35 which can be inserted and riveted into corresponding holes (not shown) provided in the base plates 11 and 13.

FIG. 10 shows a longitudinal sectional view of an exemplary embodiment of several resistance elements 20 fixed in a resistance holder 30 according to the improved serten concept. A total of three resistor elements 20 are arranged here, for example, on the resistor holder 30 in a stack-like manner, one below the other or one above the other. For this purpose, the resistance holder 30 has three guides 31 and three snap hooks 34, which are of identical design.

With a resistor arrangement 10 or a step switch 1 according to the improved concept, it is possible to equip the step switch 1 flexibly, that is, depending on the application, with the required resistance elements 20 with regard to the size of the resistance (ohmic shear resistance). According to the improved concept, the resistance elements 20 can still be used after the complete tap changer 1 has been assembled and, if necessary, for example when the operating conditions of the tap changer 1 change, can also be simply replaced. As a result, the tap changer 1 can be built independently of the order and as a stock item. For example, the adaptation to the respective application of the tap changer 1 could also be completely outsourced from the manufacturing process, and the resistors could only be installed in the tap changer on site by the transformer manufacturer or the network operator.

It is believed that the present disclosure and many of its accompanying advantages will be understood from the preceding description. Furthermore, it is obvious that various changes can be made to the shape, construction and arrangement of the components without deviating from the disclosed subject matter or without sacrificing any material advantages. The embodiment described is only illustrative and such changes are covered by the claims below. Furthermore, it should be understood that the invention is defined by the following claims.

REFERENCE MARK

1 step switch

2 switching element

10 resistor arrangement

11 base plate

12 opening

13 base plate

20 resistance element

20i first end

202 second end

21 resistance carriers

22 current-limiting element

23 Edge area

24 contact points

25 bracket

30 resistor holders

31 leadership

32 slot

33 side wall

34 retaining element

35 pens

36 open end

37 closed end

38 swiveling legs

39 free end 39H snap hook 40 Contact

41 lines

42 first free end

43 second free end B distance L longitudinal direction of the resistance element a angle

Claims

EXPECTATIONS

1. Resistor arrangement (10) for a tap changer (1), the resistor arrangement (10) comprising at least one resistor element (20) which is held by at least two resistor holders (30), characterized by: a base plate (11) with at least one opening ( 12), on which the at least two resistor holders (30) for receiving the resistor element (20) are arranged on;

- A guide (31) which is formed in each resistance holder (30), each guide (31) having a first end (20i) and a second end (2O2) of the resistance element (20) with respect to a longitudinal direction (L) between the two resistor holders (30) positioned; and

- In each case a contact point (24) of the resistance element (20), which is electrically contacted by con tacts (40) of the tap changer (1) when a resistance element (20) is inserted into the resistance holder (30).

2. resistor arrangement (10) according to claim 1, wherein the respective one Kontaktstel le (24) of the resistor element (20) in an edge region (23) at the first end (20i) and at the second end (2O2) of each resistor element (20) is provided.

3. Resistor arrangement (10) according to claim 1, wherein each guide (31) is designed as a slot (32) with a closed end (37) and an open end (36), and the slot (32) at least partially with a lateral one Wan extension (33) is provided which extends in part along the slot (32), wherein the resistance element (20) can be inserted via the open end (36).

4. resistor arrangement (10) according to claim 3, wherein the guide (31) comprises a Hal teelement (34) which is designed as a reversible and elastically pivotable leg (38) with a snap hook (39H) provided at a free end (39) , wherein the snap hook (39H) secures the resistance element (20) pushed into the guide (31) and holds it in position.

5. Resistance arrangement (10) according to claim 4, wherein the elastically pivotable leg (38) yields when the resistance element (20) is pushed into the guide (31).

6. resistor arrangement (10) according to any one of the preceding claims, wherein the at least one resistor element (20) comprises a resistor carrier (21) which carries a current-limiting element (22).

7. Resistor arrangement according to one of the preceding claims, wherein

- Each resistance element (20) at the first end (20i) and at the second end (20) each has an edge region (23) which is free of the current-limiting element (22); and

- The closed end (37) of the guide (31) defines an end position for the resistance element (20) in the resistance holder (30), such that in each case a part of the edge region (23) of the resistance element (20) essentially coincides with the slot ( 32) of the guide (31) interacts in a form-fitting manner.

8. resistor arrangement (10) according to any one of the preceding claims, wherein the Wi derstandshalter (30) and the guide (31) are integrally formed.

9. resistor arrangement (10) according to any one of the preceding claims, wherein each con tact point (24) of the resistance element (20) consists of electrically conductive material and is electrically conductive with the current-limiting element (22) verbun is the.

10. resistor arrangement (10) according to claim 1, wherein the contacts (40) are designed as Fe derkontakte, which are formed with a defined mechanical bias voltage, such that the spring contacts (40) against the contact (24) of the resistor carrier ( 21) when the resistance element (20) is positioned in the resistance holders (30).

11. Tap changer (1) comprising a resistor arrangement (10) according to one of claims 1 to 10.

12. Tap changer (1) according to claim 11, wherein the tap changer (1) comprises the first base plate (11) and a second base plate (12), between which the at least two resistance holders (30) are held and positioned relative to one another.