Embodiments described herein relate generally to a magnetizing inrush current suppressing device for suppressing a magnetizing inrush current to be generated when powering on a transformer.
It is generally known that a large magnetizing inrush current flows when non-load magnetizing is performed by power-on while a transformer core has a residual magnetic flux. The magnitude of this magnetizing inrush current is several times as large as the rated load current of the transformer. The system voltage fluctuates if a large magnetizing inrush current like this flows. If this voltage fluctuation is large, it may have an influence on users.
As a method of suppressing this magnetizing inrush current, a method is known in which when turning on a directly grounded three-phase transformer by using three single-phase circuit-breakers, one arbitrary phase is first closed, and then two remaining phases are closed, thereby suppressing a magnetizing inrush current.
There is also a known method in which a circuit-breaker of a reference phase is closed at a timing at which a prospective magnetic flux and residual magnetic flux of the reference phase match, and then two remaining circuit-breakers are closed with a delay so as to minimize the difference between a prospective magnetic flux and residual magnetic flux of each of other phases.
There is, however, a circuit-breaker in which a capacitor is connected in parallel between the poles in order to facilitate current interruption. When shutting down a transformer by this circuit-breaker in which the capacitor is connected between the poles, it is difficult for the above-described methods to suppress a magnetizing inrush current for the following reason.
When shutting down a transformer by the circuit-breaker in which a capacitor is connected between the poles, an AC voltage having a small amplitude appears at a transformer terminal after shutdown due to the inter-pole capacitor. This AC voltage is a power supply voltage divided by the inter-pole capacitor and the stray capacitance of the transformer. In this state, the residual magnetic flux of the transformer is obtained by superposing a component of this small-amplitude AC voltage on a DC component.
When the residual magnetic flux is thus obtained by superposing the AC component on the DC component, it is difficult to obtain the intersection of the residual magnetic flux and prospective magnetic flux as described above. This is so because the DC component of the residual magnetic flux changes in accordance with the breaking phase of the circuit-breaker, and the magnitude of the AC component changes in accordance with the capacitance of the inter-pole capacitor.
Under the circumstances, it is desired to provide a magnetizing inrush current suppressing device capable of suppressing a transformer magnetizing inrush current to be generated when powering on a transformer by using a circuit-breaker in which a capacitor is connected between the poles.
Embodiments will be described with reference to the drawings.
In general, according to one embodiment, there is provided a magnetizing inrush current suppressing device for controlling a circuit-breaker which opens and closes a connection between a three-phase transformer and a three-phase AC power supply and in which a capacitor is connected between poles, to suppress a magnetizing inrush current. The magnetizing inrush current suppressing device includes: a transformer-side voltage measurement unit configured to measure a three-phase AC voltage on the three-phase transformer side of the circuit-breaker; a residual magnetic flux DC component calculation unit configured to calculate DC components of residual magnetic fluxes of three phases of the three-phase transformer after the three-phase transformer is shut down, based on the three-phase AC voltage measured by the transformer-side voltage measurement unit; a notable phase detection unit configured to detect, as a notable phase, a phase having one of a maximum absolute value and a minimum absolute value from among the DC components of the residual magnetic fluxes of the three phases calculated by the residual magnetic flux DC component calculation unit; a power-supply-side voltage measurement unit configured to measure a three-phase AC voltage on the power supply side of the circuit-breaker; a first-phase determination unit configured to determine a first phase at which the notable phase detected by the notable phase detection unit from the three-phase AC voltage measured by the power-supply-side voltage measurement unit takes a peak value having a polarity opposite to a polarity of the DC component of the notable phase of the residual magnetic flux calculated by the residual magnetic flux DC component calculation unit; a first closing unit configured to close the circuit-breaker at the notable phase by the first phase determined by the first-phase determination unit; a second-phase determination unit configured to determine a second phase at which the notable phase detected by the notable phase detection unit from the three-phase AC voltage measured by the power-supply-side voltage measurement unit becomes a zero point after the first phase determined by the first-phase determination unit; and a second closing unit configured to close the circuit-breaker at two phases other than the notable phase by the second phase determined by the second-phase determination unit.
Embodiments of the present invention will be explained below with reference to the accompanying drawings.
The power system according to this embodiment includes a power supply bus 1, a three-phase circuit-breaker 2, a transformer 3, power supply voltage detectors 4U, 4V, and 4W of three phases, transformer terminal voltage detectors 5U, 5V, and 5W of three phases, and a magnetizing inrush current suppressing device 6.
The power supply bus 1 is the bus of a power system including a three-phase AC power supply having U, V, and W phases.
The primary side of the transformer 3 is connected to the power supply bus 1 via the circuit-breaker 2. The transformer 3 is a three-winding, three-phase transformer for transforming a three-phase AC voltage. The transformer 3 includes primary, secondary, and tertiary windings 301, 302, and 303. The primary and secondary windings 301 and 302 are connected by a Y-connection. The tertiary winding 303 is connected by a Δ connection. The neutral point of the primary winding 301 and the secondary winding 302 is grounded.
The circuit-breaker 2 is installed between the power supply bus 1 and transformer 3. The circuit-breaker 2 is a single-phase operation type circuit-breaker which individually operates main contact points 21U, 21V, and 21W of the U, V, and W phases. Inter-pole capacitors 22U, 22V, and 22W are respectively connected in parallel to the main contact points 21U, 21V, and 21W of the circuit-breaker 2. The inter-pole capacitors 22U, 22V, and 22W are formed to facilitate current interruption by the circuit-breaker 2. When the circuit-breaker 2 is closed, the transformer 3 is powered on by the power supply bus 1. When the circuit-breaker 2 is opened, the transformer 3 is blocked from the power supply bus 1, but is electrically connected to the power supply bus 1 by the inter-pole capacitors 22U, 22V, and 22W.
The three power supply voltage detectors 4U, 4V, and 4W are installed for the individual phases (U, V, and W phases) of the power supply bus 1. The power supply voltage detectors 4U, 4V, and 4W are measurement devices for measuring the phase voltages (ground voltages) of the individual phases (U, V, and W phases) of the power supply bus 1. For example, the power supply voltage detectors 4U, 4V, and 4W are voltage dividers such as VTs (Voltage Transformers) or PDs (Potential Devices). The power supply voltage detectors 4U, 4V, and 4W are connected between ground and the individual phases of the power supply bus 1. The power supply voltage detectors 4U, 4V, and 4W output detected values as detection signals to the magnetizing inrush current suppressing device 6.
The three transformer terminal voltage detectors 5U, 5V, and 5W are measurement devices for measuring ground voltages (phase voltages) Vtu, Vtv, and Vtw of the terminals (U, V, and W phases) on the primary side of the transformer 3. For example, the transformer terminal voltage detectors 5U, 5V, and 5W are voltage dividers such as VTs (Voltage Transformers) or PDs (Potential Devices). The transformer terminal voltage detectors 5U, 5V, and 5W are formed for the individual phases of the primary terminals of the transformer 3. The transformer terminal voltage detectors 5U, 5V, and 5W output detected values as detection signals to the magnetizing inrush current suppressing device 6.
The magnetizing inrush current suppressing device 6 outputs a close command to the main contacts 21U to 21W of the phases of the circuit-breaker 2 based on the detection signals received from the power supply voltage detectors 4U, 4V, and 4W and transformer terminal voltage detectors 5U, 5V, and 5W. Consequently, the circuit-breaker 2 is closed.
The arrangement of the magnetizing inrush current suppressing device 6 will be explained with reference to
The magnetizing inrush current suppressing device 6 includes a power supply voltage measurement unit 601, transformer voltage measurement unit 602, residual magnetic flux calculation unit 603, DC component calculation unit 604, phase detection unit 605, and close command output unit 606.
The power supply voltage measurement unit 601 measures the individual phase voltages Vu, Vv, and Vw of the power supply bus 1 based on the detection signals detected by the power supply voltage detectors 4U, 4V, and 4W. The power supply voltage measurement unit 601 outputs the measured individual phase voltages Vu, Vv, and Vw to the phase detection unit 605.
The transformer voltage measurement unit 602 measures the phase voltages Vtu, Vtv, and Vtw on the primary side of the transformer 3 based on the detection signals detected by the transformer terminal voltage detectors 5U, 5V, and 5W. The transformer voltage measurement unit 602 outputs the measured phase voltages Vtu, Vtv, and Vtw on the primary side of the transformer 3 to the residual magnetic flux calculation unit 603.
Based on the phase voltages Vtu, Vtv, and Vtw measured by the transformer voltage measurement unit 602, the residual magnetic flux calculation unit 603 integrates the phase voltage Vtu, Vtv, and Vtw of the U, V, and W phases after the transformer 3 is shut down by the circuit-breaker 2. The residual magnetic flux calculation unit 603 sets the integrated values as the residual magnetic fluxes (primary-side phase magnetic fluxes) φZu, φZv, and φZw of the core of the transformer 3. The residual magnetic flux calculation unit 603 outputs the calculated residual magnetic fluxes φZu, φZv, and φZw to the DC component calculation unit 604.
The DC component calculation unit 604 calculates the DC components φZdu, φZdv, and φZdw from the residual magnetic fluxes φZu, φZv, and φZw of the individual phases calculated by the residual magnetic flux calculation unit 603. The DC component calculation unit 604 outputs the calculated DC components φZdu, φZdv, and φZdw of the residual magnetic fluxes to the phase detection unit 605.
The phase detection unit 605 receives the DC components φZdu, φZdv, and φZdw of the residual magnetic fluxes of the individual phases calculated by the DC component calculation unit 604, and the individual phase voltages Vu, Vv, and Vw of the power supply bus 1 measured by the power supply voltage measurement unit 601. The phase detection unit 605 detects the U phase as a notable phase which is a phase having the largest absolute value among the DC components φZdu, φZdv, and φZdw of the residual magnetic fluxes of the individual phases. Note that a phase having the largest absolute value among the DC components φZdu, φZdv, and φZdw is the notable phase in this embodiment, but a phase having the smallest absolute value may be the notable phase. The phase detection unit 605 detects a phase at which the detected notable phase of the phase voltages Vu, Vv, and Vw of the power supply bus 1 has a peak value having a polarity opposite to that of the DC components φZdu, φZdv, and φZdw of the notable phase. The phase detection unit 605 outputs an indication of the detected notable phase and an amount of the phase to the close command output unit 606.
The close command output unit 606 sets the phase detected by the phase detection unit 605 as a target close phase θc1 in the notable phase of the circuit-breaker 2. As shown in
Based on the target close phases θc1 and θc2, the close command output unit 606 outputs a close command to an operation mechanism for driving the main contact point of the phase to be closed of the circuit-breaker 2. Consequently, the main contact point of the phase to be closed of the circuit-breaker 2 is closed. By closing the circuit-breaker 2 at the phases in the two stages as described above, as shown in
With reference to
The DC component calculation unit 604 detects a maximum magnetic flux (positive peak value) φmax and minimum magnetic flux (negative peak value) φmin during one period from the waveform of the residual magnetic flux φZ. The DC component calculation unit 604 calculates the DC component φZd by dividing the sum of the maximum magnetic flux φmax and minimum magnetic flux φmin by 2. In
In this embodiment, the target close phases θc1 and θc2 for closing the circuit-breaker 2 can be decided without detecting the intersection of the prospective magnetic flux and residual magnetic flux. Accordingly, even the circuit-breaker 2 in which the inter-pole capacitors 22U, 22V, and 22W are connected in parallel to the main contact points 21U, 21V, and 21W can suppress the magnetizing inrush current of the transformer 3, which is generated when powering on the transformer 3.
Note that in this embodiment, the various parameters in phase control by the magnetizing inrush current suppressing device 6 may also be corrected in order to, e.g., further increase the accuracy. For example, when the circuit-breaker 2 is closed, a preceding discharge called pre-arc occurs between the main contacts, or the close time varies due to, e.g., operation variations of the operation mechanisms. By pre-acquiring the characteristics of the close variation caused by the pre-arc and the variation when the circuit-breaker is closed, these variations can be corrected by using their characteristics when performing phase control. By performing this correction, a magnetizing inrush current can be suppressed more reliably even when these variations occur.
Also, the inter-pole capacitors 22U, 22V, and 22W have been explained as parts of the circuit-breaker 2 in this embodiment, but the present invention is not limited to this arrangement. These capacitors need only be connected in parallel to the main contact points of the circuit-breaker, and may also be parts separate from the circuit-breaker. In addition, the three phases need not be integrated in the circuit-breaker 2, and three circuit-breakers formed for the individual phases may also be used.
Furthermore, in the embodiment, an example of the method of calculating the DC components φZdu, φZdv, and φZdw from the residual magnetic fluxes φZu, φZv, and φZw of the individual phases by the DC component calculation unit 604 has been explained. However, the present invention is not limited to this. The DC components φZdu, φZdv, and φZdw can be calculated from the residual magnetic fluxes φZu, φZv, and φZw by any method. Also, if the values of the DC components φZdu, φZdv, and φZdw can be determined to such an extent that the polarities and the relationship between the values of the individual phases are known, correct values of the DC components φZdu, φZdv, and φZdw need not be calculated.
For example, the DC component calculation unit 604 need not divide the sum of the maximum magnetic flux φmax and minimum magnetic flux φmin by 2. Even by using a value not divided by 2, the phase detection unit 605 can determine the notable phase and the polarity of the DC component of the residual magnetic flux of the notable phase. In addition, the DC component calculation unit 604 can obtain the maximum magnetic flux φmax and minimum magnetic flux φmin during two or more periods instead of one period. It is also possible to calculate the average of a plurality of positive peak values (or a plurality of negative peak values), instead of the maximum magnetic flux φmax (or minimum magnetic flux φmin). Furthermore, the DC component calculation unit 604 may also calculate the DC components φZdu, φZdv, and φZdw from the deviation of the polarities of the instantaneous values of the residual magnetic fluxes φZu, φZv, and φZw. More specifically, when the polarity is positive, the polarities of the instantaneous values of the residual magnetic fluxes φZu, φZv, and φZw are often positive; when the polarity is negative, the polarities of the instantaneous values of the residual magnetic fluxes φZu, φZv, and φZw are often negative. Also, when the DC components φZdu, φZdv, and φZdw are close to zero, the positive and negative polarities of the instantaneous values of the residual magnetic fluxes φZu, φZv, and φZw are almost even. Accordingly, the polarities and values of the DC components φZdu, φZdv, and φZdw can be determined by using these properties.
In the embodiment, the power supply voltage detectors 4U, 4V, and 4W measure the phase voltages Vu, Vv, and Vw of the power supply bus 1. However, it is also possible to measure the individual line voltages of the power supply bus 1, and convert the line voltages into the phase voltages Vu, Vv, and Vw. This similarly applies to the transformer terminal voltage detectors 5U, 5V, and 5W. Accordingly, the transformer terminal voltage detectors 5U, 5V, and 5W may also measure the line voltages of the tertiary winding 303 of a Δ-connection.
In addition, in the embodiment, the phase voltages Vu, Vv, and Vw of the power supply bus 1 are measured based on the detection signals detected by the power supply voltage detectors 4U, 4V, and 4W. However, the present invention is not limited to this. The phase voltages Vu, Vv, and Vw of the power supply bus 1 may also be measured based on the detection signals detected by the transformer terminal voltage detectors 5U, 5V, and 5W. More specifically, the phase voltages Vu, Vv, and Vw of the power supply bus 1 may also be measured based on small-amplitude AC voltages to be superposed on the transformer terminals by the inter-pole capacitors 22U, 22V, and 22W.
Also, in this embodiment, the transformer 3 can be any transformer as long as it is a three-phase transformer. The transformer 3 is not limited to a three-winding transformer and may also be a two-winding transformer or a transformer having four or more windings. In addition, the connection of each winding can be either a Y-connection or A connection, and it is possible to use any combination of these connections.
Furthermore, in this embodiment, the calculation order and the calculation locations (e.g., computers and various detectors, regardless of whether inside or outside of the magnetizing inrush current suppressing device 6) can be changed as needed, provided that the same results are obtained.
While certain embodiments according to the present invention have been described, these embodiments have been presented by way of example only, and are not intended to limit the scope of the invention. The novel embodiments described herein may be implemented in a variety of other forms, and various omissions, substitutions, and/or changes may be made therein without departing from the spirit of the inventions. The accompanying claims and their equivalents are intended to cover such forms or modifications as would fall within the scope and spirit of the inventions.
Number | Date | Country | Kind |
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2012-132382 | Jun 2012 | JP | national |
This application is a Continuation Application of PCT Application No. PCT/JP2013/062430, filed Apr. 26, 2013 and based upon and claiming the benefit of priority from Japanese Patent Application No. 2012-132382, filed Jun. 11, 2012, the entire contents of all of which are incorporated herein by reference.
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Number | Date | Country | |
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Number | Date | Country | |
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Parent | PCT/JP2013/062430 | Apr 2013 | US |
Child | 14559307 | US |