EP2981979A1

EP2981979A1 - Method for performing a switching process in an on-load tap changer

Info

Publication number: EP2981979A1
Application number: EP14716255.6A
Authority: EP
Inventors: Thomas Strof
Original assignee: Maschinenfabrik Reinhausen GmbH; Maschinenfabrik Reinhausen Gebrueder Scheubeck GmbH and Co KG
Current assignee: Maschinenfabrik Reinhausen GmbH; Scheubeck GmbH and Co
Priority date: 2013-04-04
Filing date: 2014-03-21
Publication date: 2016-02-10
Anticipated expiration: 2034-03-21
Also published as: HK1214677A1; JP6275244B2; UA118102C2; KR20150140308A; US20160018840A1; JP2016519922A; RU2658290C2; RU2015146988A3; BR112015024604B1; RU2015146988A; KR102167439B1; EP2981979B1; BR112015024604A2; DE102013103360A1; WO2014161729A1; ES2647825T3; CN105164770A; US9513654B2; CN105164770B

Abstract

The invention relates to a method for performing a switching process in an on-load tap changer between winding taps of a tapped transformer. The switching process for an on-load tap changer is subdivided into a plurality of phases according to the reactor switching principle. In these phases, the switching contacts in use are monitored during the actuation and are completely opened or closed by capacitors in the controller in the event of failure of the energy supply. Thereby critical switching states are prevented.

Description

Method for performing a switching operation in an on-load tap-changer

The invention relates to a method for performing a switching operation in an on-load tap changer between winding taps of a tapped transformer.

On-load tap-changers have been in worldwide use for many years for uninterrupted switching between different winding taps of tapped transformers in large numbers. So-called reactor switches, which are particularly common in North America, have a switching reactance, which allows a slow, continuous switching. On-load tap changers according to the resistance fast-switching principle usually consist of a selector for powerless selection of the respective winding tap of the tapped transformer to be switched to, and a diverter switch for the actual switching from the previous to the new, preselected winding tapping. The diverter switch usually has switching contacts and resistance contacts. The switch contacts are used for direct connection of the respective winding tap with the load dissipation, the resistor contacts for short-term wiring, d. H. Bridging by means of one or more switching resistors. The developments of recent years, however, led away from load switches with mechanical switching contacts in insulating oil. Instead, more and more vacuum switching cells are used as switching elements.

Such on-load tap changer with vacuum interrupters is known for example from DE 10 2009 043 171 A1. Here, a diverter switch carries a drivable by a power storage drive shaft with at least one cam. The cam has a plurality of control cams, wherein two arranged on the cam front control cams have a deviating from a circular contour in the manner of cams on the contact a respective connected via a rocker arm with a vacuum interrupter roller is performed, the profiled contour of the respective control cam taps.

Due to the constructive design of this on-load tap-changer, this requires a spring energy storage for sudden switching by means of the contact system. From the prior art known energy storage are mounted at the beginning of each actuation of the on-load tap-changer by a drive shaft, that is stretched. The known energy storage consist essentially of a lift carriage and a jump carriage, between which power storage springs are arranged as energy storage. Such energy storage, for example, DE 198 55 860 C1 and DE 28 06 282 B1 can be removed. Despite these decades of used energy storage, it comes again and again to the failure of these devices. Since the on-load tap-changers are used for a long time, it often happens that the pressure or tension springs break and thus prevent a changeover. Furthermore, it may happen that a carriage does not reach the end position, the shift shaft thus does not rotate completely and the switch contacts do not reach their end position. In the worst case, this can lead to the destruction of the entire tapped transformer.

The latest on-load tap-changer models of the applicant have no mechanical energy storage for performing switching compared to the prior art. Actuation takes place directly via an electric drive. In the event of a sudden failure of the power supply for such a drive during a changeover, however, critical positions can occur in the on-load tap-changer. These are especially close to closing or after opening a switching contact. Hereby, it may e.g. come to a welding of the contacts inside the vacuum interrupter.

The object of the invention is therefore to provide a method for performing a switching operation in an on-load tap-changer, in order to increase the safety of on-load tap-changers.

This object is achieved by a method having the features of the first claim. The subclaims relate to particularly advantageous developments of the method.

The general inventive idea consists in a method for carrying out a changeover operation of an on-load tap changer, which subdivide the switching sequence underlying the switching operation in several phases, the critical and uncritical switching states of each switch contacts used to monitor each of these phases during a switching operation and in dependence on a parameterized in a controller decision logic that processes the detected at the beginning of an intended switching operation by a voltage monitoring device value of the supply voltage as basis for decision and only then starts the switching or enters the next defined phase of the switching, when a supply voltage is detectable and In addition, at a voltage drop of the mains or supply voltage, and thus in case of failure of the power supply of the electric drive, during a switching operation using the existing in the capacitors of the control energy overcomes each identified for a switching sequence critical switching states of the respective switching contacts over by the next, as uncritically identified phase of the switching states is switched.

According to the invention, after the initiation of the switching in the first phase, a voltage monitoring device checks whether a voltage is applied to a selected phase line. If the voltage is not applied, the changeover is aborted and continued when the voltage is applied.

During the second phase of the method according to the invention, an electric drive is actuated via a controller which opens the second switching contact. During opening, the power supply to the electric drive is monitored by a controller. When a voltage dip in the power supply of the electric drive energy from the capacitors of the controller is used to fully open the second switching contact. Following, ie during the third phase, an adjacent winding tap is approached by a second selector contact.

During the fourth phase of the method according to the invention, the electric drive is actuated via a controller and thereby the second switching contact is closed. During closing, the power supply of the electric drive is monitored by the controller and the energy from capacitors of the controller is used to fully close the second switching contact at a voltage dip of the power supply of the electric drive.

During the fifth phase of the method according to the invention, the first selector contact is applied to one winding tap and the second selector contact is applied to the adjacent winding tap. The first and the second switching contact are closed. During this time, a circulating current Ik is created.

During the sixth phase of the method according to the invention, the continuation of the switchover is checked by the voltage monitoring device as to whether a voltage is applied to a selected phase line. If the voltage is not present, the changeover is aborted, and the voltage continues. During the seventh, following phase, an adjacent winding tap is approached by the first selector contact. During the eighth phase of the method according to the invention, the electric drive is actuated via a controller and the first switching contact is closed. During closing, the power supply of the electric drive is monitored by a controller and used in a voltage dip in the power supply of the electric drive, the energy from capacitors of the controller to fully close the first switching contact. In the ninth phase, the switching is completed.

The inventive method will be explained in more detail by way of example below.

Figure 1 shows a schematic view of an on-load tap changer with necessary means for carrying out a switching operation, in which critical positions are avoided.

FIGS. 2a-2i depict an exemplary changeover operation of an on-load tap changer operating on the reactor switching principle.

FIG. 3 shows a schematic flow chart with different phases during a switching process.

FIG. 1 shows an on-load tap-changer 1, according to the reactor switching principle, which is located in a tapped transformer 2. The step-up transformer 2 has a high-voltage side 3, to which the on-load tap-changer 2 is arranged, and an undervoltage side 4. Both the high-voltage side 3 and the low-voltage side 4 each have three phase lines L1, L2, L3, 11, 12, 13. The on-load tap-changer 1 is actuated by an electric drive 5. A controller 6 initiates the individual switching operations of the electric drive 5. The controller 6 is connected via a controller 7 to the electric drive 5 and to a voltage monitoring device 8, referred to below as SUV 8. The SUV 8 monitors the voltage of the individual phase lines 11, 12 and 13 on the low voltage side 4. The power supply of the electric drive 5 via one of these phase lines 11 of the low voltage side 4 via a line 9. However, this is for each of the located on the low voltage sides 4 phase line 11, 12, or 13 suitable.

Inside the controller 6 buffer capacitors are arranged, which are able to store a defined amount of energy. These are often components of the controller 6, but can also be retrofitted. In the initiation of a switching operation of the on-load tap-changer 1, from a tap n via an intermediate stage n + 1/2 to a next tap n + 1 of the tap-changer, the Energy from a phase line 11, 12, or 13 used to open or close the switch contacts located in the interior of the on-load tap changer V1, V2, in particular vacuum interrupters. The critical positions arise in this switching process, especially in the so-called hard open or hard closing the switch contacts. Hard opening or closing occurs when the contacts are under load, ie they carry a current. This creates arcs inside the switching contacts, which have an effect on the life of the contacts and can even lead to destruction if the burning time is too long.

FIGS. 2a-2i show an exemplary switching operation of an on-load tap-changer 1, which operates on the reactor switching principle. The on-load tap-changer 1 consists of a first and a second switching contact V1 and V2, a first and a second movable selector contact W1 and W2 and a first and a second over-reacting X1 and X2. In addition, a load dissipation Y is disposed between the first and second reactances X1 and X2. The switching operation takes place from a first tap n a step winding to an adjacent second winding tap n + 1 a step winding of a tapped transformer 2, wherein an intermediate position n + 1/2 is allowed as a stationary operating position.

At the beginning of a switching process, Figure 2b, the second switching contact V2 is opened so that the second selector contact W2 can first be disconnected from the winding tap n de-energized. Subsequently, Figure 2c, the selector contact W2 moves to the second tap n + 1. After reaching the second winding tap n + 1, Figure 2d, the switching contact V2 is closed. This leads to the so-called circular current Ik, Figure 2e. The reactances X1 and X2 allow the on-load tap-changer 1 to remain in this position. This position is referred to as intermediate n + 1/2. After opening the first vacuum interrupter V1, Figure 2f, the circulating current Ik is interrupted and the first selector contact W1 moves in the direction of the second winding tapping n + 1, Figure 2g. As soon as the first selector contact W1 has arrived at the winding tap n + 1, FIG. 1 and FIG. 1, the first switching contact V1 is closed.

This switching operation can thus be divided according to the invention into nine phases. In the first phase (I) (Figure 2a), the switching is initiated. In the second phase (II), the second switching contact V2 is opened. In the third phase (III) (Figure 2c), the adjacent second winding tap n + 1 is approached by the second selector contact W2. In phase four (IV), the second switching contact V2 is closed. In phase five (V) (Figure 2d) both switching contacts V1 and V2 are closed. In phase six (VI) will the first switching contact V1 opened. In phase seven (VII) (FIG. 2g), the first selector contact W1 approaches the adjacent second winding tap n + 1. In phase eight (VIII) of the first switching contact V1 is closed. In phase nine (IX), the switching process is completed.

In Figure 3, the inventive method is shown by a schematic flow chart. In this case, upon initiation of the switching operation in the first phase (I), the SUV 8 first of all checks whether a voltage is applied to the phase line 11, 12, 13 selected for the energy supply. If this is not the case, the switching operation is not performed and the on-load tap-changer 1 remains in this position or the entire tapped transformer 2 is switched off. If a voltage is applied, the electric drive 5 is actuated via the controller 6.

During this second phase (II), the second switching contact V2 is opened. This phase is to be regarded as a critical switching state, since it can come to a not completely open second switching contact V2 for non-extinction of the arc. The controller 7 monitors during this time the power supply of the electric drive 5. If it comes during this phase (II) to a voltage dip, ie a failure of the power supply, this is detected by the grain roller 7 and with the help of existing in the controller 6 energy, from the previously charged capacitors, compensated, ie the second switching contact V2 is fully opened.

When the opening is completed, in the third phase (III), the adjacent tap n + 1 is approached by the second selector contact W2. During the closing of the second switching contact V2, ie in phase four (IV), the power supply is monitored by the controller 7. This phase (IV) is also to be regarded as a critical switching state, since it can lead to pre-ignition and subsequent non-extinction of the arc at a not completely closed second switching contact V2. In the event of a voltage dip, that is to say a failure of the power supply, this is detected by the grain roller 7 and compensated by means of the energy present in the control 6, from the previously charged capacitors, i. the second switching contact V2 is completely closed. In the fifth phase (V), ie after the second switching contact V2 has been closed, the so-called circular current Ik arises. This switching state is not critical.

Before opening the first switching contact V1, ie phase six (VI), it is checked again whether a voltage is applied to the phase line 11, 12, 13 selected for the power supply is applied. If this is not the case, the switching process is not performed and the on-load tap-changer remains in this position or the entire tapped transformer is switched off. In phase seven (VII), the adjacent tap n + 1 is approached. In the eighth phase (VIII), the first switching contact V1 is closed. The controller 7 monitors during this time the power supply of the electric drive 5. If it comes during this phase to a voltage dip, ie a failure of the power supply, this is detected by the grain roller 7 and with the help of existing in the controller 6, already pre-charged capacitors compensated. In the last phase, the switching process is completed.

With the aid of the method according to the invention, it is always ensured that the first and the second switching contact V1 and V2 never assume a critical switching state during a switching operation of an on-load tap-changer 1, from a winding tap n to a next winding tap n + 1. This prevents the destruction of the switching contacts V1 and V2, of the on-load tap-changer 1 or even of the entire tapped transformer 2. This would have devastating effects on a power grid.

Phases of switching

I Initiation of a changeover

Checking the voltage of a selected phase line by means of SUV Carrying out the changeover when voltage is applied

Abort of the changeover when voltage is not present

II Actuation of the electric drive by means of control

Opening the second switching contact

Monitoring the voltage using a controller

Using the energy of the capacitors from the controller at

Voltage drop for complete opening of the second Schalkontaktes

III Approaching the adjacent winding tapping by the second

voter contact

IV Actuation of the electric drive by means of control

Close the second switching contact

Monitoring the voltage using a controller

Using the energy of the capacitors from the controller at

Voltage drop for complete closing of the second Schalkontaktes

V Stay with fully closed switch contacts

Origin of the circulating current

Abort of the changeover when voltage is not present

VI Actuation of the electric drive by means of control

Opening the first switching contact

Monitoring the voltage using a controller

Using the energy of the capacitors from the controller at Voltage drop for complete opening of the second contact contact

VII Approaching the adjacent winding tapping by the first

voter contact

VIII Actuation of the electric drive by means of control

Close the first switching contact

Monitoring the voltage using a controller

Using the energy of the capacitors from the controller at

Voltage drop for complete closing of the first contact contact

IX Termination of the changeover

Claims

claims

1 . Method for carrying out a changeover operation in an on-load tap-changer (1) between winding taps (n, n + 1) of a tapped transformer (2) by means of switching contacts (V1, V2),

characterized:

that the switching process is subdivided into several phases (I-IX),

that critical and uncritical switching states of each used

Switching contacts (V1, V2) are identified,

that each of these phases (I-IX) is monitored,

that at the beginning of an intended switching operation by means of a voltage monitoring device (8), as a function of a decision logic parameterized in a controller (7), a value of the supply voltage is detected as basis for decision and only in the presence of the voltage supply in the next defined phase (I - IX) of Switchover is switched,

that at a voltage dip of the mains or supply voltage, and thus in case of failure of the power supply of the electric drive (5) during a switching operation using the residual energy present in the capacitors of the controller (6) each identified for a switching sequence critical switching states of the respective Switch contacts (V1, V2) overcomes by the next, as uncritically identified phase of the switching states is switched.

2. The method according to claim 1,

characterized,

in that, after the initiation of the switching in the first phase (I), a voltage monitoring device (8) checks whether a voltage is applied to a selected phase line (11, 12, 13),

that switching is aborted when the voltage is not applied, and that switching is continued when the voltage is present.

3. The method according to claim 1,

characterized,

in that during the second phase (II) an electric drive (5) is actuated via a control (6) and thereby opens the second switching contact (V2), that during opening the power supply of the electric drive (5) by a controller (7) is monitored and

in the event of a voltage dip in the power supply of the electric drive (5), energy from capacitors of the control (6) is used to completely open the second switching contact (V2).

4. The method according to claim 1,

characterized,

during the third phase (III), an adjacent winding tap (n + 1) is approached by a second selector contact (W2).

5. The method according to claim 1,

characterized,

in that during the fourth phase (IV) the electric drive (5) is actuated via a control (6) and thereby closes the second switching contact (V2),

that during closing the power supply of the electric drive (5) is monitored by the controller (7) and

in the event of a voltage dip at the power supply of the electric drive (5), energy from capacitors of the control (6) is used to completely close the second switching contact (V2).

6. The method according to claim 1,

characterized,

in that during the fifth phase (V) a first selector contact (W1) is applied to one winding tap (n) and the second selector contact (W2) is applied to the adjacent winding tap (n + 1),

that the first and the second switching contact (V1, V2) are closed and that in doing so a circulating current Ik is produced.

7. The method according to claim 1,

characterized,

during the sixth phase (VI) before the continuation of the switch-over, the voltage monitoring device (8) checks whether a voltage is applied to a selected phase line (11, 12, 13),

8. The method according to claim 1,

characterized,

during the seventh phase (VIS), an adjacent winding tap (n + 1) is approached by the first selector contact (W1).

9. The method according to claim 1,

characterized,

in that during the eighth phase (VIII) the electric drive (5) is actuated via a control (6) and thereby closes the first switching contact (V1),

that during closing the power supply of the electric drive (5) by a controller (7) is monitored and

in the event of a voltage dip in the power supply of the electric drive (5), energy from capacitors of the control (6) is used to completely close the first switching contact (V1).

10. The method according to claim 1,

characterized,

that in the ninth phase (IX) the switching is completed.