JP5707071B2 - Tap switching method under load - Google Patents

Description

  The present invention relates to a tap switching method in a one-resistor one-valve tap switching device, and a sequence of switching operation from an even tap to an odd tap and switching operation from an odd tap to an even tap is varied depending on the switching direction. Thus, the present invention relates to a tap switching method capable of reliably preventing arcing at a contact.

  2. Description of the Related Art Conventionally, a load tap switching device is known in which a plurality of taps are provided in a transformer winding, the taps are switched without turning off the transformer load, the transformation ratio is constantly adjusted, and the supply voltage is kept constant. .

  In recent years, a vacuum valve has been used instead of the conventional mechanical type as a shut-off element of the on-load tap switching device. A vacuum valve is superior to an air contact or oil contact in terms of current interruption capability, and is also advantageous compared to a mechanical contact in that it can be downsized.

  There are several types of on-load tap changers depending on the number of vacuum valves and current limiting resistors used for one phase. For example, a load tap changer composed of two vacuum valves and one current limiting resistor is described in Patent Document 1 below.

  Moreover, the on-load tap switching device including two vacuum valves and two current limiting resistors is described in Patent Document 2 below. Further, a load tap switching device comprising three vacuum valves and one current limiting resistor is described in the following Patent Document 3, and a load tap switching device comprising four vacuum valves and two current limiting resistors is described in the following patent. Document 4 describes.

JP-A-5-82365 JP-B 61-18331 JP-A-5-82366 JP-B 62-16004 JP-A-60-94709

  However, as described above, the vacuum valve has an advantage that the current interruption capability and the contact itself can be reduced in size, but is generally expensive, so when used as an interruption element of the on-load tap switching device, It is required to use as few vacuum valves as possible. And by reducing the number of vacuum valves used per phase, in addition to miniaturization of the contacts themselves by using the vacuum valves, it is possible to realize miniaturization of the switching switch as the number of use decreases. It becomes possible.

  In addition, a so-called 1-resistor 1-valve type on-load tap switching device that has only one vacuum valve and can realize cost reduction and downsizing of a switching switch has been known. The on-load tap changer described in Patent Document 5 is mentioned.

  By the way, as a configuration of the 1-resistor 1-valve type tap changer at load, there is a circuit diagram shown in Patent Document 5, for example, a switching circuit L2 having a configuration shown in FIG. 3A is also known. .

  FIG. 3A shows the switching operation of the tap winding TW from the even-numbered tap T2 to the odd-numbered tap T3 in order from the left, where TW is a tap winding, and T1, T2, T3,. A plurality of taps provided in the winding is shown. M2 and M3 are tap selectors, R is a current limiting resistor, and V is a vacuum valve. Further, C1 and C2 are mechanical contacts of a current limiting resistor circuit. Hereinafter, C1 is referred to as a first switch and C2 is referred to as a second switch.

  FIG. 3B is a switching sequence diagram showing the switching order of the switching circuit L2 shown in FIG. 3A (showing the switching order and switching timing of the vacuum valve V and the switching switches C1 and C2). As shown in FIG. 3 (b), the switching circuit L2 in FIG. 3 (a) first opens the vacuum valve V that is closed during operation in switching from the even-numbered tap T2 to the odd-numbered tap T3. Next, the first switch C1 is switched from C1-1 to C1-2, and then the vacuum valve V is closed to allow a current to flow to the vacuum valve V side. In this state, the second switch C2 is switched from C2-1 to C2-2 to shift to the odd tap T3.

  FIG. 4A is a diagram illustrating the switching operation from the odd tap T3 to the even tap T2 of the tap winding TW in the switching circuit L2 in order from the right. FIG. 4B is a switching sequence diagram showing the switching order of the switching circuit L2 shown in FIG.

  As shown in FIG. 4B, when switching from the odd tap T3 of the tap winding TW to the even tap T2 in the switching circuit L2, the vacuum valve V in the open state is closed and the second switch C2 is switched to C2. -2 to C2-1. Then, the vacuum valve V is opened, the first switch C1 is switched from C1-2 to C1-1, and then the vacuum valve V is closed to shift to the even tap T2.

  FIG. 5A shows the switching operation from the even-numbered tap T2 to the odd-numbered tap T3 in order from the left in the switching circuit L3 of the one-resistance one-valve type tap switching apparatus with load of another configuration. FIG. 7B is a switching sequence diagram showing the switching order.

  In the switching from the even-numbered tap T2 to the odd-numbered tap T3, the switching circuit L3 shown in FIG. 5A first changes the second switch C2 from C2-1 to C2-2 as shown in FIG. Switch. Next, the vacuum valve V in the closed state is opened, and the first switch is switched from C1-1 to C1-2. Thereafter, the vacuum valve V is closed and a current is supplied to the vacuum valve V side, and the process proceeds to the odd-numbered tap T3.

  FIG. 6A shows the switching operation from the odd-numbered tap T3 to the even-numbered tap T2 in the switching circuit L3 in order from the right, and FIG. 6B is a switching sequence diagram showing the switching order. In the switching circuit L3 shown in FIG. 6A, when switching from the odd tap T3 to the even tap T2, the second switch C2 is switched from C2-2 to C2-1 as shown in FIG. Then, the vacuum valve V is opened, the first switch C1 is switched from C1-2 to C1-1, and then the vacuum valve V is closed to complete the transition to the even tap T2.

  However, in the switching circuit L2 having the configuration shown in FIGS. 3A and 4A, when switching from the even tap T2 to the odd tap T3, the second switch C2 is switched from C2-1 to C2-2. At the time of switching, since the vacuum valve V is in a closed state, a switching operation in an energized state (switching while energizing) occurs, and there is a problem that an arc is generated.

  Further, since the switching order from the odd tap T3 to the even tap T2 is a so-called reciprocal operation in which the switching order from the even tap T2 to the odd tap T3 is reversed, the switching from the even tap T2 to the odd tap T3 is performed. Similarly, an arc is generated when the second switch C2 is switched from C2-2 to C2-1.

  Further, as shown in FIGS. 3 (a) and 4 (a), the odd-numbered tap T3 is operated with the vacuum valve V opened, so the vacuum valve V having a high withstand voltage performance must be used. I must.

  Further, in the switching circuit L3 configured as shown in FIGS. 5A and 6A, no arc is generated when switching from the even-numbered tap T2 to the odd-numbered tap T3, but when switching from the odd-numbered tap T3 to the even-numbered tap T2. There is a problem that an arc is generated when the second switch C2 is switched from C2-2 to C2-1. In the switching circuit L3 shown in FIGS. 5A and 6A, the switching order from the even-numbered tap T2 to the odd-numbered tap T3 and the switching order from the odd-numbered tap T3 to the even-numbered tap T2 are reversed, so-called reciprocation. Similar to the switching circuit L2 shown in FIGS. 3A and 4A, the operation is repeated.

  As described above, in the conventional switching circuits L2 and L3, an arc is generated when the first and second switches C1 and C2 are switched. Therefore, the insulating oil for immersing the first and second switches C1 and C2 is used. As a result, there is a problem that the insulating oil needs to be periodically replaced, and the contact is consumed due to the occurrence of an arc.

  Therefore, the present invention is a 1-resistor 1-valve type switching switch which is advantageous in terms of cost and miniaturization, and can switch contacts without generating an arc and has a high withstand voltage performance. The present invention provides a tap switching method when a switching switch is not required.

  The invention according to claim 1 is provided with one current limiting resistor and one vacuum valve, and is connected in series to each of the current limiting resistor and the vacuum valve, and is one of a plurality of taps of the tap winding. In the tap switching method of the 1-resistor 1-valve type on-load tap switching device configured to include a changeover switch for selecting the even-numbered tap to the odd-numbered tap, the switching to the current limiting resistance is performed with the vacuum valve closed. Switch the switch to be connected, then open the vacuum valve and switch the switch connected to the vacuum valve, then close the vacuum valve, the switch from odd tap to even tap is to close the vacuum valve In this state, the switch connected to the current limiting resistor is switched, then the vacuum valve is opened, the switch connected to the vacuum valve is switched, and then the vacuum valve is closed. To.

  According to the first aspect of the present invention, since the arc is not generated when switching from the even tap to the odd tap, or when switching from the odd tap to the even tap, it is possible to prevent the insulating oil from being contaminated. Periodic replacement of the oil becomes unnecessary, and consumption of the contact can be suppressed.

  In addition, according to the first aspect of the present invention, a vacuum valve having a high withstand voltage performance is used because the operation is always performed with the vacuum valve closed regardless of whether the even tap or the odd tap is selected. There is no need.

  Furthermore, according to the first aspect of the present invention, since the potential between both electrodes of the vacuum valve does not change between the even tap and the odd tap, the insulating structure of the vacuum valve can be simplified.

It is the circuit diagram and sequence diagram explaining the switching operation | movement from the even number tap to the odd number tap by the switching circuit based on this invention. It is the circuit diagram and sequence diagram explaining the switching operation | movement from the odd tap to the even tap by the switching circuit based on this invention. It is the circuit diagram and sequence diagram explaining the switching operation | movement from the even number tap to the odd number tap by the conventional switching circuit. It is the circuit diagram and sequence diagram explaining the switching operation | movement from the odd tap by the conventional switching circuit to the even tap. It is the circuit diagram and sequence diagram explaining the switching operation from the even-numbered tap to the odd-numbered tap by the switching circuit of the other conventional structure. It is the circuit diagram and sequence diagram explaining the switching operation | movement from the odd number tap to the even number tap by the switching circuit of the other conventional structure.

  Hereinafter, embodiments of the present invention will be described with reference to FIGS. 1 and 2. 1A is a circuit diagram showing a switching circuit L1 of the on-load tap switching device according to the present invention. In FIG. 1A, TW is a tap winding, and T1, T2, T3,. It shows adjacent taps provided on the line. M2 and M3 are tap selectors connected to the taps T2 and T3. R represents a current limiting resistor, and V represents a vacuum valve.

  C1 is a mechanical contact (referred to as a first switch) connected in series with the vacuum valve V, and C2 is a mechanical contact (referred to as a second switch) connected in series to the current limiting resistor R. It is. One end of the vacuum valve V and the current limiting resistor R is connected to a neutral point of a transformer star connection (not shown).

  FIG. 1 (a) shows the state diagram of the switching process in the switching operation of the tap winding from the even-numbered tap T2 to the odd-numbered tap T3 in order from the left, and FIG. 1 (b) shows the switching order indicating the switching order. It is a sequence diagram. The on-load tap switching method of the present invention will be described below.

In an operating state in which the first switch C1 is connected to C1-1, the second switch C2 is connected to C2-1, and the vacuum valve V is closed, the load current I _L is as indicated by a dotted line. Flowing.

When the switching operation is started, the second switch C2 is switched from C2-1 to C2-2, and between the taps T2 and T3 through the vacuum valve V, the first switch C1, the current limiting resistor R, and the second switch C2. A short circuit is formed, and the circulating current I _C limited by the current limiting resistor R flows like a two-dot chain line.

Next, by opening the vacuum valve V, the first switch C1 is switched from C1-1 to C1-2 in a no-current state, and the load current I _L flows through the current limiting resistor R. Subsequently, by closing the vacuum valve V, the load current I _L flows through the vacuum valve V, and the transition from the even-numbered tap T2 to the odd-numbered tap T3 is completed. Thereby, it becomes possible to operate in the state where the vacuum valve V is closed at the odd-numbered tap T3.

  FIG. 2A shows a state diagram of the switching process in the switching operation of the tap winding from the odd-numbered tap T3 to the even-numbered tap T2 in order from the right, and FIG. 2B shows the switching showing the switching order. It is a sequence diagram.

In an operating state at the odd-numbered tap T3 in which the vacuum valve V is closed, the load current I _L flows as indicated by a dotted line shown in FIG. When the switching operation from the odd tap T3 to the even tap T2 is started, the second switch C2 is switched from C2-2 to C2-1.

Thereby, a short circuit is formed between the taps T2 and T3 through the vacuum valve V, the first switch C1, the current limiting resistor R, and the second switch C2, and the circulating current I _C limited by the current limiting resistor R is formed. Flows like a two-dot chain line.

Subsequently, the load current I _L flows through the current limiting resistor R by opening the vacuum valve V and switching the first switch C1 from C1-2 to C1-1 in a no-current state. Thereafter, by closing the vacuum valve V, the load current I _L flows through the vacuum valve V, and the transition from the even-numbered tap T2 to the odd-numbered tap T3 is completed. As a result, the even tap T2 can be operated with the vacuum valve V closed.

That is, in the switching method of the switching circuit L1 according to the present invention, switching by the conventional switching circuits L2 and L3 shown in FIGS. 3 (a), 4 (a), 5 (a), and 6 (a). As in the method, the switching operation from the even-numbered tap T2 to the odd-numbered tap T3 and the switching operation from the odd-numbered tap T3 to the even-numbered tap T2 are not the reciprocating operation of the fixed sequence operation, but the sequence is changed according to the switching direction. Accordingly, the load current I _L is not cut off by the first and second switches C1 and C2, and the arc generation problem that has occurred when the taps of the conventional circuits L2 and L3 are switched can be reliably solved.

  Specifically, prior to the switching operation of the first switch C1 and the vacuum valve V in any switching direction of switching from the even tap T2 to the odd tap T3 and switching from the odd tap T3 to the even tap T2, The second switch C2 is switched.

  As a result, the insulating oil that immerses the first and second switches C1 and C2 is not contaminated by the occurrence of an arc, and it is possible to prevent periodic insulation oil replacement work and contact wear due to the arc. It becomes.

  Further, as described above, since both the even-numbered tap T2 and the odd-numbered tap T3 are operated with the vacuum valve V closed, it is not necessary to use a vacuum valve having excellent withstand voltage performance.

  Further, the switching circuit L1 according to the present invention shown in FIGS. 1 (a) and 2 (a) is different from the conventional switching circuit L2 shown in FIGS. 3 (a) and 4 (a), and has an even number of tap selectors. Since the potential between both electrodes of the vacuum valve V does not change between the state connected to the tap T2 and the state connected to the odd-numbered tap T3 (the voltage drop of the current limiting resistor R), the vacuum valve V There is an advantage that the insulating structure can be simplified.

  As described above, in the on-load tap switching device according to the present invention, the load current is cut off at the contact point of the current limiting resistance circuit while adopting the one-resistance one-valve type advantageous in cost merit and downsizing. It is possible to reliably prevent the insulating oil from being contaminated by the arc.

  It can be used for a switching switch of a load tap switching device.

TW Tap winding T1, T2, T3 Tap M2, M3 Tap selector C1 First switch C2 Second switch V Vacuum valve R Current limiting resistor L1, L2, L3 On-load tap switching device I _L Load current I _C Circulating current

Claims (1)

  A current limiting resistor and a vacuum valve are provided, and a changeover switch that is connected in series to each of the current limiting resistor and the vacuum valve and selects one of a plurality of taps of the tap winding is provided. In the tap switching method of the one-resistor one-valve type tap switching device configured as described above, the switching from the even-numbered tap to the odd-numbered tap is performed by switching the switch connected to the current limiting resistor in the state where the vacuum valve is closed, In addition, when the vacuum valve is opened and the switch connected to the vacuum valve is switched, the vacuum valve is closed, and the switching from the odd tap to the even tap is performed in the same manner when the vacuum valve is closed. The switch is connected to the vacuum valve, then the vacuum valve is opened, the switch connected to the vacuum valve is switched, and then the vacuum valve is closed. Switching method.

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