WO2011085763A1

WO2011085763A1 - Method for measuring the switching time of an on-load tap changer and circuit for measuring switching time

Info

Publication number: WO2011085763A1
Application number: PCT/EP2010/007562
Authority: WO
Inventors: Alfred Bieringer
Original assignee: Maschinenfabrik Reinhausen Gmbh
Priority date: 2010-01-16
Filing date: 2010-12-11
Publication date: 2011-07-21
Also published as: EP2524385A1; ES2443155T3; EP2524385B1

Abstract

The invention relates to a method for measuring the switching time of an on-load tap changer and to a measuring circuit suitable therefor. In said method, the on-load tap changer is switched over, specific courses of measurement voltages are determined and the edges thereof detected. By comparing the real measured edges with target values stored in advance in nonvolatile memory, it can be determined if the switching sequence of the tested on-load tap changer corresponds to the target values.

Description

Method for switching time measurement on an on-load tap-changer and circuit for switching time measurement

The invention relates to a method for measuring the chronological order of during the

Actuation of an on-load tap changer successively running individual circuits of different contact and switching elements. The invention further relates to a suitable circuit for such a method.

A method and a circuit of the aforementioned type are already known from DE 10 2004 052 316 B3.

In the known method, non-volatile storage of the switch-specific sequence of the switching sequence takes place when the on-load tap-changer is switched over, subsequently a measuring circuit is connected between the respective sides of the electrical switches facing the movable switching elements. Subsequently, a switch of the

Made on-load tap-changer and at the same time made a measurement of the voltage curve via a measuring resistor of the measuring circuit. From this course, finally, the actual switching sequence can be determined by making an assignment of the respective times of the occurrence of measuring edges with the previously stored switching sequence. The measuring circuit used consists of a series connection of a voltage source and the already mentioned measuring resistor as well as means for measuring the voltage which drops across this measuring resistor.

This known method and the associated measuring circuit are in principle for a

On-load tap-changer of the type of a load selector suitable and designed, as is also explained with reference to the figures 1 to 4 in the above-mentioned document.

In addition, there are also on-load tap-changer, which has a separate selector for powerless preselection of the winding tap to be switched to, and, separately, a diverter switch for the actual uninterrupted switching of the load between the winding taps. The circuit of such an on-load tap-changer, as manufactured and sold by the Applicant under the type designation VACUTAP® VR, is known from DE 10 2005 048 308 B3 and described in detail there in FIG. 8: The two sides of the diverter switch A and B are shown, between which the uninterrupted switching takes place. Contacts MCA and MCB are the respective permanent main contacts, one of which is closed in stationary operation and thus carries current. MSV designates a vacuum switching cell in the main switching branch, TTV a vacuum switching cell in the resistance branch, which has the additional switching resistance R. The acting as a main switching contact mechanical switching contact II is referred to as MTF, acting as a resistance switching contact mechanical switching contact I is referred to as TTF. Y denotes the load derivation. Even with such on-load tap changers, there is likewise the need to ensure that the individual times during load switching have a normalized switch-specific time sequence within the overall switching sequence. It is therefore important even with the last-mentioned on-load tap-changers with separate selector and diverter switch to be able to reliably make corresponding switching-time measurements with simple means on site.

However, the method known from the aforementioned DE 10 2004 052 316 B3 and the associated measuring circuit are not suitable for such load changeover switches; other methods and / or circuits are not known.

The object of the invention is therefore also for on-load tap-changers of the type VACUTAP® VR and comparable devices specify a method that allows on site with simple means to make a switching time measurement during operation of the on-load tap-changer and to decide in the result, if this on-load tap-changer fully functional is. The object of the invention is, in turn, to provide a circuit with which such a method can be carried out in a simple manner.

This object is achieved by a method having the features of the first claim and a circuit having the features of the second claim.

With the invention it is now possible for the first time, directly on site, d. H. with an on-load tap-changer installed in the corresponding tap-changer to measure the switching time and the switching sequence and thus to achieve the same advantages for on-load tap-changers of the type VACUTAP® VR with separate selector and diverter switch, which the state of the art previously only permitted for load selectors.

The invention will be explained in more detail by way of example with reference to drawings.

Show it:

Figure 1 shows the circuit of a known on-load tap-changer VACUTAP® VR with

connected inventive measuring circuit

FIG. 2 shows again a schematic representation of the measuring circuit according to the invention, a (known) switching sequence of the on-load tap-changer to which the measuring circuit according to the invention is to be connected FIG. 4 shows an oscillogram of the measuring circuit determined by means of the measuring circuit according to the invention

Voltage curves during switching, d. H. Actuation of the diverter switch and including the assignment according to the invention of the voltage profiles to the operating sequence of the individual mechanical and vacuum switches involved

Figure 5 shows the inventive method in the overall overview.

Figure 1 shows the circuit of the known on-load tap changer described, more precisely, whose diverter switch, shown in bold lines. The connected invention

Measuring circuit, however, is shown with dashed lines.

The measuring circuit has four connection points C, D, E, Y and three separate resistors R2, R3, R4.

The first connection point C is between the mechanical switching element MTF and the

Vacuum switching cell MSV of the tap changer connected. It leads via a first resistor R2 to a first voltage source U1, furthermore via a series connection of two further resistors R4 and R3 to a further voltage source U2.

The connection point D is connected between the mechanical switch TTF and the vacuum switching cell TTV of the on-load tap-changer and leads to the other side of the second voltage source U2. The further connection point E is between the vacuum switching cell TTV and the

Switching resistor R of the on-load tap-changer is arranged and leads between the series connection of the two resistors R4 and R3.

Finally, the connection point Y is connected to the other side of the voltage source U1 and leads to the load derivation, i. H. the star point of the on-load tap-changer.

Between the connection points Y and E, a first measuring device U_R is provided. Via resistor R3, d. H. parallel thereto, a second measuring device U_R3 is provided. The two measuring devices U_R and U_R3 record the voltage curves over time.

Figure 2 shows the measuring circuit according to the invention again only in a schematic representation. The on-load tap-changer is symbolized here only by a cylinder, arranged on the left in the picture. Shown are the connection points C, D, E, Y, which are electrically connected to the already explained points in Lastumschaiter. The connection point C leads via the first resistor R2 to the voltage source U1.

The measuring point D leads to the positive pole of the voltage source U2, whose other side with the

Series connection of two further resistors R3, R4 is connected and leads to the first voltage source U1.

The connection point E leads to the point between the resistors R3 and R4.

The connection point Y, with the star point, d. H. the load derivation is connected leads to

Positive pole of the voltage source U1. In a particularly advantageous manner, the two voltage sources U1, U2 are DC voltage sources with 24 V DC.

Also shown are the already explained voltage measuring devices U_R and U_R3.

U_R is connected between the connection points E and Y.

U_R3 is connected in parallel to the resistor R3.

The resistors R2 and R3 are particularly advantageously adapted to the value of the override resistance R of the diverter switch.

Advantageously, a two-channel memory is used as an oscilloscope as a common voltage measuring device.

It is also advantageous, this memory oscilloscope still a separate evaluation, for example, to Sol-st comparison of the determined switching sequence nachzuschalten.

FIG. 3 shows the switching sequence of the known on-load tap-changer, which is to be measured or checked by the method according to the invention and by means of the measuring circuit according to the invention. The switching sequence can be seen when switching from level n to the adjacent level n + 1-d. H. a complete load switching. For the proper functioning of the

On-load tap-changer, it is imperative that both the mechanical switching elements MTF, TTF and the vacuum switching cells MSV, TTV exactly in the intended time sequence, d. H. the sequence of times t1 ... t8, open or close. This can be checked by the invention.

FIG. 4 shows a real recorded oscillogram of the measuring voltages recorded by means of the two measuring devices U_R and U_R3 in the case of a real load switching. It is shown here how the individual voltage edges of the recorded voltage curves the individual

Times t1 ... t8 be assigned to the switching sequence.

This assignment results in the real-time switching sequence shown in FIG

Bar display. It can be seen that in this case, especially the switching times of

Switching elements TTF and TTV deviate from the desired course shown in Figure 3.

From this deviation of the actual course of the switching sequence from the previously non-volatilely stored desired course of the switching sequence, valuable conclusions can be drawn on the operating state of the currently investigated on-load tap-changer.

FIG. 5 again shows a schematic representation of the complete method according to the invention. It begins with the non-volatile storage of the switch-specific order of the

Switching sequence of the respective tap changer to be checked, ie a switching sequence in which the switching times correspond to switch-specific setpoint values. It ends with the comparison, ie the assignment of the individual times of the actually measured switching sequence with these previously stored setpoints. In detail for the process according to the invention:

- First, a non-volatile storage of the switching-specific time sequence of the switching sequence, d. H. the mechanical switching contacts (MTF; TTF) and the vacuum switching cells (MSV; TTV) which open and close successively when the diverter switch is switched over;

- Subsequently, a changeover of the diverter switch is performed

the course of a first measurement voltage (U_R) applied before the switchover between the second vacuum switch cell (TTV) and the series-connected over-resistance (R) on the one hand and the load derivative (Y) on the other hand during load switching is measured,

- The course of a second, also applied before the switch measurement voltage (U_R3) via a parallel to the second vacuum switch cell (TTV) permanently or temporarily looped

Measuring resistor (R3) during load switching is measured, i. the concrete chronological course of the first and the second applied or falling voltage (flanks) is detected,

- The times (t1 ... t8) of the occurrence of edges on the course of the detected two

Measuring voltages (U_R; U_R3) are detected,

Finally, an assignment of the detected actual times (t1... t8) to the previously stored switch-specific sequence of the desired switching sequence takes place, ie. H. the actual values of the times (t1... t8) are compared with the step-switch-specific desired times and deviations are detected and signaled.

Claims

claims

1. A method for switching time measurement on an on-load tap-changer, which is a selector for

has powerless preselection of a winding tap (n + 1) and a diverter switch for the actual switchover from the previous winding tap (n) to the preselected winding tap (n + 1),

wherein the diverter switch comprises a first mechanical switching contact (MTF) and a second mechanical switching contact (TTF), through which either one of the two

Winding taps (n; n + 1) directly over a first branch with a first

Vacuum switching cell (MSV) or a second branch with a series circuit of a second vacuum switching cell (TTV) and a switching resistance (R) with a load dissipation (Y) is connectable,

characterized,

first, non-volatile storage of the shift-specific time order of the switching sequence, i. H. the mechanical switching contacts (MTF; TTF) opening and closing one after the other when the diverter switch is switched over and the vacuum switching cells (MSV; TTV),

that subsequently a changeover of the diverter switch is carried out,

that the course of a first applied measuring voltage (U_R) between the second

Vacuum switching cell (TTV) and the series-connected over-resistance (R) on the one hand and the load derivative (Y) on the other hand during load switching is measured, that continues the course of a second applied measuring voltage (U_R3) via a parallel to the second vacuum switching cell (TTV) looped measuring resistor (R3) during the

Load switching is measured,

that subsequently the times (t1... t8) of the occurrence of edges on the course of the detected two measuring voltages (U_R; U_R3) are detected

and finally that an assignment of the detected times (t1... t8) to the previously stored switch-specific sequence of the switching sequence takes place, d. H. the actual values of the times (t1... t8) are compared with their desired values and deviations are recorded.

2. A method for switching time measurement according to claim 1,

characterized,

that for generating the two measuring voltages (U_R; U_R3) two separate

DC voltage sources (U1, U2) are used.

3. Measuring circuit for switching time measurement on an on-load tap-changer, which has a selector for

has powerless preselection of a winding tap (n + 1) and a diverter switch for the actual switchover from the previous winding tap (n) to the preselected winding tap (n + 1), wherein the diverter switch comprises a first mechanical switching contact (MTF) and a second mechanical switching contact (TTF), through which either one of the two

Winding taps (n; n + 1) directly over a first branch with a first

characterized,

the measuring circuit has four connection points (C, D, E, Y) and three separate resistors (R2, R3, R4),

that the first connection point (C) via a first resistor (R2) to a first

Voltage source (U1), further via a series circuit of a second and a third resistor (R3, R4) leads to a second voltage source (U2),

the second connection point (D) leads to the other side of the second voltage source (U2), the third connection point (E) leads electrically between the series connection of the second and third resistance (R3, R4),

the fourth connection point (Y) is connected to the other side of the first voltage source (U1),

in that a first measuring device for voltage measurement (U_R) is provided between the third and the fourth connection point (E; Y)

and that a second measuring device for measuring a further voltage (U_R3) is provided parallel to the second resistor (R3).

Measuring circuit according to claim 3

characterized,

the two voltage sources (U1, U2) are DC voltage sources.

Measuring circuit according to claim 3 or 4,

characterized,

that both measuring devices are designed as a combined two-channel memory as oscilloscope.