JP2018046656A - Adjusting device and adjustment method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an adjusting device capable of reliably maintaining the voltage at installation point of a load in a desired range.SOLUTION: The adjusting device includes: series transformers the primary side of which is connected to each other in series between a power source and a power source output terminal; a voltage adjustment part connected to the secondary side of the series transformers, for adjusting the output voltage on the power source output terminal via the series transformers; and a control unit that changes at least one of the lower limit value of the output voltage and the upper limit value of the target voltage based on a supply direction of the electric power on the power source output terminal.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an adjustment device and an adjustment method.

Conventionally, various techniques for stabilizing power supplied from a distribution line have been proposed (see, for example, Patent Documents 1 and 2). Among these, in the technique of Patent Document 2, voltage control is performed in consideration of the wiring impedance so that the voltage at the installation point of the load is within a specified range.
Patent Document 1 JP 2005-341668 A Patent Document 2 JP 2012-231628 A

  However, there is a demand from customers to maintain the voltage at the installation point of the load within a desired range more reliably.

  In the first aspect of the present invention, a series transformer having a primary side connected in series between a power source and a power source output terminal, and a secondary side of the series transformer, the power source output via the series transformer. An adjustment device comprising: a voltage adjustment unit that adjusts an output voltage of a terminal; and a control unit that changes at least one of a target voltage lower limit value and a target voltage upper limit value of the output voltage based on a power supply direction at the power output terminal. Is provided.

  In the second aspect of the present invention, the step of changing at least one of the target voltage lower limit value and the target voltage upper limit value of the output voltage of the power output terminal based on the direction of power supply at the power output terminal, And adjusting the output voltage via the series transformer by a voltage regulator connected to the secondary side of the series transformer, the primary side of which is connected in series with the output terminal. The

  The above summary of the present invention does not enumerate all of the features of the present invention. A sub-combination of these feature groups can also be an invention.

The adjustment apparatus which concerns on this embodiment is shown. The operation of the adjusting device is shown. Indicates the changed target voltage upper limit value. Indicates the changed target voltage lower limit value. Indicates the adjusted voltage. 2 shows an exemplary configuration of a computer according to the present embodiment.

  Hereinafter, the present invention will be described through embodiments of the invention, but the following embodiments do not limit the invention according to the claims. In addition, not all the combinations of features described in the embodiments are essential for the solving means of the invention.

  FIG. 1 shows an adjusting device 1 according to this embodiment. The adjusting device 1 adjusts the power of the input voltage Vi input from the power supply 10 to the power of the output voltage Vo and outputs the power from a plurality of power supply output terminals 11. The adjustment device 1 includes one or more series transformers 12, a voltage adjustment unit 13, and a control unit 14. The adjusting device 1 may further include one or more bypass switches 15 and a measurement unit 16.

  The power supply 10 may be an AC power supply. In the present embodiment, as an example, a high-voltage distribution system of 6600 V and 60 Hz (or 50 Hz) is changed to a single-phase three-wire low-voltage distribution system of about 100 V and 60 Hz (or 50 Hz). It is a transformer (columnar transformer as an example) that converts and supplies voltage. The power supply 10 may have three output terminals, u-phase, v-phase, and o-phase, and may supply power of the input voltage Vi to the adjustment device 1.

  In the present embodiment, the plurality of power output terminals 11 are, for example, three power output terminals 11 (a), 11 (b), and 11 (n), and may output single-phase AC power. The voltage between at least one of the power output terminals 11 (a) and 11 (b) as the output terminal of the voltage line and the power output terminal 11 (n) as the output terminal of the neutral line is adjusted by the adjustment device 1. May be adjusted by The power output terminals 11 (a), 11 (b), and 11 (n) are connected to the u phase, the v phase, and the o of the power source 10 through the low piezoelectric lines 110 (a), 110 (b), and 110 (n), respectively. It may be connected to the phase output terminal. The low piezoelectric line 110 (n) connecting the power output terminal 11 (n) and the power source 10 may be grounded.

  Here, at least one load 20 such as an electric product and at least one generator 21 such as a solar panel may be connected to the plurality of power output terminals 11. For example, the load 20 and the generator 21 that each of about 10 customers may have may be connected to the plurality of power output terminals 11. A wiring impedance 200 may exist between the load 20 and the generator 21 and the plurality of power supply output terminals 11, so that the voltage VL at the installation point of the load 20 and the generator 21 is the power supply output terminal. 11 output voltages Vo may be different. For example, when the power consumption of the load 20 is larger than the power generated by the generator 21, the voltage VL at the installation point may be lower than the output voltage Vo. When the power consumption of the load 20 is smaller than the power generated by the generator 21, the voltage VL at the installation point may be higher than the output voltage Vo.

  One or a plurality of series transformers 12 have a primary side, that is, a primary coil connected in series to a low piezoelectric line 110 between the power supply 10 and the power supply output terminal 11, and a secondary side, that is, a secondary coil, connected to the voltage regulator 13. Is a connected transformer. The transformation ratio of the series transformer 12 may be configured such that the primary side is higher than the secondary side, and may be, for example, primary side: secondary side = 10: 1 (or 5: 1). In the present embodiment, as an example, two series transformers 12 (a) and 12 (b) are provided in the low piezoelectric lines 110 (a) and 110 (b), but only one of them may be provided. Good.

  The voltage adjustment unit 13 adjusts the output voltage Vo of the power supply output terminal 11 via each series transformer 12 so that it falls within the target voltage range as an example. Here, the target voltage range is a range defined by the target voltage lower limit value and the target voltage upper limit value. The target voltage range may be equal to a reference voltage range expected for the voltage VL at the installation point (for example, 101 ± 6 V), or may be a partial range within this reference voltage range. . The target voltage range may be a range that partially overlaps the reference voltage range, or may be a completely different range from the reference voltage range. The voltage adjustment unit 13 may include an inverter 131, one or more reactors 133, and a power supply unit 135.

  The inverter 131 outputs a current flowing to the secondary side of each series transformer 12, thereby adding a voltage from the primary coil of the series transformer 12 to the input voltage Vi to the adjustment device 1 and outputting between the power output terminals 11. Adjust the voltage Vo. The inverter 131 has three output terminals of u-phase, v-phase, and o-phase, of which u-phase and o-phase output terminals are connected to the series transformer 12 (a), and v-phase and o-phase outputs. A terminal may be connected to the series transformer 12 (b). The inverter 131 may be supplied with DC power from a power supply unit 135 described later. As an example, the switching frequency of the inverter 131 may be 20 kHz.

  One or more reactors 133 smooth the current output from inverter 131. In this embodiment, as an example, two reactors 133 (u) and 131 (v) are provided between the u-phase and v-phase output terminals of the inverter 131 and the series transformers 12 (a) and 12 (b). It has been. Instead of / in addition to the reactor 133, another smoothing circuit may be provided at the output terminal of the inverter 131.

  The power supply unit 135 supplies power to the inverter 131. In the present embodiment, as an example, the power supply unit 135 converts AC power from the power supply 10 into DC power and supplies the DC power to the inverter 131. The power supply unit 135 may include a converter 1351, a smoothing capacitor 1352, and a reactor 1353.

  Converter 1351 converts AC power into DC power. The converter 1351 has an input side (AC side) terminal connected to the low piezoelectric lines 110 (a) and 110 (b) on the upstream side of the series transformer 12, and an output side (DC side) terminal connected to the inverter 131. It's okay. For example, the converter 1351 may supply DC power of about 400 to 500 V to the inverter 131.

  Smoothing capacitor 1352 is connected between the output terminals of converter 1351 and smoothes the DC power output from converter 1351.

  Reactor 1353 is provided between low piezoelectric line 110 (a) and converter 1351, smoothes the current, and boosts the input side terminals of converter 1351. In addition, from the viewpoint of smoothing the current, instead of / in addition to the reactor 1353, the leakage inductance of the power supply 10 that is a transformer may be used.

  The power supply unit 135 may supply the inverter 131 with power supplied from another power source different from the power source 10 (for example, a private power generation facility).

  The control unit 14 controls each unit in the adjustment device 1. For example, the control unit 14 determines at least one of the target voltage lower limit value and the target voltage upper limit value of the output voltage Vo based on the supply direction of power at the power output terminal 11, preferably further based on the amount of power supplied at the power output terminal 11. , The output voltage Vo is adjusted by the voltage adjustment unit 13 within the changed target voltage range.

  Here, the supply direction of power may be changed according to the power consumption of the load 20 and the power generated by the generator 21. For example, when the power consumption of the load 20 is larger than the power generated by the generator 21, the voltage VL at the installation point of the load 20 and the generator 21 is lower than the output voltage Vo, and the supply direction is a series transformer. The direction may be from 12 to the power output terminal 11. When the power consumption of the load 20 is smaller than the power generated by the generator 21, the voltage VL at the installation point is higher than the output voltage Vo, and the supply direction is from the power output terminal 11 to the series transformer 12. It may be the direction to.

  The supplied power amount may be an integrated value [Wh] for a reference time (for example, one or a plurality of cycles) of the power [W]. In this case, the power supply direction may be expressed by the positive or negative power supply amount. For example, if the supplied power amount is positive, the power supply direction may be from the series transformer 12 to the power output terminal 11, and if the supplied power amount is negative, the supply direction is changed from the power output terminal 11 to the series transformer. The orientation may be toward the vessel 12.

  The one or more bypass switches 15 are connected to be able to switch whether to bypass the primary side of the series transformer 12. For example, each bypass switch 15 is connected in parallel to the primary coil of the corresponding series transformer 12 with respect to the low piezoelectric line 110 between the power supply 10 and the power supply output terminal 11, so that the primary coil can be short-circuited. Yes. In the present embodiment, as an example, two bypass switches 15 (a) and 14 (b) are connected in parallel with the primary coils of the two series transformers 12 (a) and 12 (b).

  The measuring unit 16 measures the supply direction of power between the series transformer 12 and the power supply output terminal 11, and preferably further measures the amount of supplied power. The measurement unit 16 may include a voltage measurement unit 161, a current measurement unit 163, and a calculation unit 165.

  The voltage measuring unit 161 measures the output voltage Vo between the power supply output terminals 11. The voltage measurement unit 161 may supply the measurement result to the calculation unit 165.

  The current measuring unit 163 measures the output current from the power output terminal 11. The current measurement unit 163 may supply the measurement result to the calculation unit 165.

  The calculation unit 165 calculates the supply direction, and preferably further calculates the supply power amount. The calculation unit 165 may supply the control unit 14 with the power supply amount and the supply direction.

  According to the adjusting device 1 described above, the control unit 14 sets the target voltage of the output voltage Vo based on the power supply direction indicating the magnitude relationship between the voltage VL at the installation point of the load 20 and the generator 21 and the output voltage Vo. At least one of the lower limit value and the target voltage upper limit value is changed. Therefore, in order to change the target voltage range of the output voltage Vo according to whether the voltage VL at the installation point is larger or smaller than the output voltage Vo, the voltage VL at the installation point is set to a desired range (for example, 101 ± 6 V). Can be maintained within.

  Further, the control unit 14 further changes at least one of the target voltage lower limit value and the target voltage upper limit value based on the supplied power amount. Here, since (supply power amount) × (wiring impedance 200) / (output voltage Vo) = (voltage VL at the installation point) − (output voltage Vo), the supply power amount is the voltage VL at the installation point. And the voltage difference between the output voltage Vo. Therefore, since the target voltage range of the output voltage Vo is changed according to the voltage difference between the voltage VL and the output voltage Vo at the installation point, the voltage VL at the installation point can be more reliably maintained within a desired range. it can.

  FIG. 2 shows the operation of the adjusting device 1. Note that each bypass switch 15 is turned on at the start of the operation. The inverter 131 and the converter 1351 may be disabled by the control unit 14.

  When the adjustment device 1 starts operation, the measurement unit 16 measures the power supply direction and the power supply amount (step S11). For example, the voltage measuring unit 161 of the measuring unit 16 measures the voltage between the low piezoelectric lines 110 (a) and 110 (n) and the voltage between the low piezoelectric lines 110 (b) and 110 (n). It's okay. Further, the current measuring unit 163 uses the current sensor 1630 (see FIG. 1) provided in the low piezoelectric lines 110 (a) and 110 (b) between the series transformer 12 and the power supply output terminal 11. You may measure the electric current which flows into the low piezoelectric track 110 (a), 110 (b). Then, the calculation unit 165 calculates a multiplication value of the voltage value between the low piezoelectric lines 110 (a) and 110 (n) and the current value of the low piezoelectric line 110 (a) within a reference time (one cycle as an example). May be used to calculate the amount of power supplied by the low piezoelectric lines 110 (a) and 110 (n). Similarly, the calculation unit 165 integrates the product of the voltage value between the low piezoelectric lines 110 (b) and 110 (n) and the current value of the low piezoelectric line 110 (b) within the reference time. The amount of power supplied by the low piezoelectric lines 110 (b) and 110 (n) may be calculated. Moreover, the calculating part 165 may calculate the supply direction of electric power from the positive / negative of supplied electric energy. However, instead of calculating the supply direction from the sign of the supplied power amount, the measuring unit 16 can measure the supplied power amount by another conventionally known method such as the method disclosed in Japanese Patent Application Laid-Open No. 2013-169066. Instead, only the supply direction may be measured.

  Next, the control unit 14 changes at least one of the target voltage lower limit value and the target voltage upper limit value of the output voltage based on the power supply direction, preferably the supply direction and the supplied power amount (step S13). Details of the change of the target voltage lower limit value and the target voltage upper limit value will be described later with reference to FIGS. 3 and 4.

  Next, the control unit 14 determines whether or not the output voltage Vo between the power supply output terminals 11 is out of the target voltage range (step S15). For example, the control unit 14 determines the effective value of the voltage between the low piezoelectric lines 110 (a) and 110 (n) measured by the voltage measuring unit 161 and the low piezoelectric lines 110 (b) and 110 (n). It may be determined whether or not the effective value of the voltage is outside the target voltage range.

  When it is determined in step S15 that the output voltage Vo is not outside the target voltage range (step S15; No), the control unit 14 keeps the bypass switch 15 on (step S16). Thereby, the bypass switch 15 is turned on in response to the output voltage Vo being in the range from the state in which the bypass switch 15 is turned off in the process of step S17 described later, and the voltage control by the voltage adjustment unit 13 is performed. Is disabled. In addition to this, the control unit 14 may disable the inverter 131 and the converter 1351 by turning off a pulse signal of a control command applied to the inverter 131 and the converter 1351. Thereby, the loss which generate | occur | produces in these conversion parts can be reduced, the power supply to a low voltage | pressure distribution system can be made efficient, and the lifetime of the adjustment apparatus 1 can be extended.

  When the process in step S16 is completed, the adjustment device 1 shifts the process to step S11 described above. Thereby, the processing of steps S11 and S13 is repeated, and at least one of the target voltage lower limit value and the target voltage upper limit value is sequentially updated based on the measurement result of the measurement unit 16.

  On the other hand, if it is determined in step S15 that the output voltage Vo is outside the target voltage range (step S15; Yes), the control unit 14 keeps the bypass switch 15 off (step S17). As a result, the bypass switch 15 is turned off in response to the output voltage Vo falling outside the range from the target voltage lower limit value to the target voltage upper limit value in a state where the bypass switch 15 is on. As a result, the current from the power supply 10 flows through the primary side of each series transformer 12, and the voltage control by the voltage regulator 13 is enabled.

  In addition, the control unit 14 adjusts the output voltage Vo via the series transformer 12 by the voltage adjusting unit 13. For example, the control unit 14 controls the secondary current output from the voltage adjustment unit 13 to each series transformer 12 so that the output voltage Vo outside the target voltage range is within the target voltage range.

  As an example, the control unit 14 converts the voltage measurement value supplied from the voltage measurement unit 161 via the calculation unit 165 into a voltage effective value and a voltage phase. Further, the control unit 14 calculates the deviation of the effective value of the measured voltage with respect to the target voltage range as the voltage deviation to be adjusted. In addition, the control unit 14 controls the inverter 131 and the power supply unit 135 (converter 1351 as an example) so that the primary voltage of the series transformer 12 becomes a voltage corresponding to the voltage deviation. For example, if the transformation ratio of the series transformer 12 is primary: secondary = 1: m, the control unit 14 issues a control command to the inverter 131 and the converter 1351 so that the output voltage of the inverter 131 becomes a voltage deviation × m. give. The control unit 14 may give a control command so that the output voltage of the inverter 131 gradually approaches voltage deviation × m. The control unit 14 sets the voltage applied to the low piezoelectric line 110 (a) by the series transformer 12 to the same phase as the voltage phase between the low piezoelectric lines 110 (a) and 110 (n). Thus, the voltage applied to the low piezoelectric line 110 (b) may be a phase inverted by 180 °.

  As a result, a voltage deviation voltage is generated on the primary side of the series transformer 12. As a result, a series transformer is applied to the voltage supplied from the power source 10 between the low piezoelectric lines 110 (a) and 110 (n) and / or between the low piezoelectric lines 110 (a) and 110 (n). 12 is added, and the output voltage Vo between the power supply output terminals 11 falls within the target voltage range. As an example, when the input voltage Vi is 95% of the target voltage lower limit value, the output voltage Vo becomes the target voltage lower limit value by adding a voltage of 5% as a voltage deviation. Further, when the input voltage Vi is 103% of the target voltage upper limit value, the output voltage Vo becomes the target voltage upper limit value by adding a voltage of −3% as a voltage deviation.

  And if the process of the above step S17 is complete | finished, the adjustment apparatus 1 will transfer a process to above-mentioned step S11. Thereby, the processing of steps S11 and S13 is repeated, and at least one of the target voltage lower limit value and the target voltage upper limit value is sequentially updated based on the measurement result of the measurement unit 16.

  In the above operation, the control unit 14 has been described as sequentially updating at least one of the target voltage lower limit value and the target voltage upper limit value based on the measurement result by the measurement unit 16, but it is updated in another manner. Also good. For example, the adjustment device 1 may be provided with a storage unit (not shown) that stores a history of measurement results obtained by the measurement unit 16, and the control unit 14 sequentially predicts the amount of supplied power and the supply direction from the history of measurement results. Then, at least one of the target voltage lower limit value and the target voltage upper limit value may be sequentially updated based on the prediction result. As an example, the control unit 14 creates a variation pattern of the supply power amount and the supply direction within a unit period (for example, one day, one week, one year), and the supply power amount and the supply direction based on the variation pattern. May be predicted. In this case, the voltage VL at the installation point can be maintained within the reference voltage range without continuously performing the measurement by the measurement unit 16.

  Next, the change of the target voltage lower limit value and / or the target voltage upper limit value by the control unit 14 will be described.

  When the supply direction is the direction from the series transformer 12 to the power output terminal 11 (for example, when the supply power amount is positive), the control unit 14 compares the target voltage with, for example, the case where the supply direction is opposite. The lower limit value may be increased. Further, the control unit 14 compares the supply direction with the opposite direction, for example, when the supply direction is the direction from the power output terminal 11 to the series transformer 12 (for example, when the supply power amount is negative). Thus, the target voltage upper limit value may be reduced.

  In addition, the control unit 14 compares the target voltage when the magnitude of the supplied power amount, that is, when the absolute value of the supplied power amount is the first supply amount, as compared with the second supply amount that is smaller than the first supply amount. One of the lower limit value and the target voltage upper limit value may be changed so as to approach the other, and preferably, one of the lower limit value and the target voltage upper limit value may be changed so as to gradually approach the other as the process of step S13 is repeated. For example, the control unit 14 may change so that one of the target voltage lower limit value and the target voltage upper limit value is closer to the other as the amount of supplied power is larger. In addition, the control unit 14 changes the target voltage upper limit value based on a value obtained by multiplying the magnitude of the supplied power amount by the first coefficient, and based on a value obtained by multiplying the magnitude of the supplied power amount by the second coefficient. The lower voltage limit may be changed. As an example, the control unit 14 may change at least one of the target voltage upper limit value and the target voltage lower limit value by the following equations (1) and (2).

Target voltage upper limit value V _1b = reference upper limit value V _{1 −first} coefficient k ₁ × | power supply amount P | (1)
Target voltage lower limit value V _2b = reference lower limit value V ₂ + second coefficient k ₂ × | power supply amount P | (2)

However, in the equation, the first coefficient k ₁ and the second coefficient k ₂ are positive values, and may be set according to the wiring impedance 200, the power consumption of the load 20, the number of consumers, etc., and updated as appropriate. May be. The first coefficient and the second coefficient may be the same value or different values.

Further, the target voltage upper limit value V _1b and the target voltage lower limit value V _2b may satisfy the following expressions (3) and (4).

Change lower limit value V _1a ≦ target voltage upper limit value V _1b ≦ reference upper limit value V ₁ (3)
Reference lower limit value V ₂ ≦ Target voltage lower limit value V _2b ≦ Change upper limit value V _2a (4)

However, in the formula, the change lower limit value V _1a and the change upper limit value V _2a are values indicating the changeable limit values of the target voltage upper limit value V _1b and the target voltage lower limit value V _2b . By setting the change lower limit value V _1a and the change upper limit value V _2a , it is possible to prevent the target voltage range from becoming too narrow. Therefore, the loss generated in the inverter 131 and the converter 1351 is reduced, and the low voltage distribution The power supply to the system can be made more efficient, and the adjustment device 1 can have a longer life. Note that the values of the change lower limit value V _1a and the change upper limit value V _2a may be set from the predicted power consumption of the load 20, the generated power of the generator 21, and the wiring impedance 200.

The target voltage upper limit value V _1b and the target voltage lower limit value V _2b changed as described above are shown in FIGS. Here, FIG. 3 shows the changed target voltage upper limit value, and FIG. 4 shows the changed target voltage lower limit value. In the figure, the horizontal axis represents the input voltage Vi, and the vertical axis represents the output voltage Vo.

As shown in FIG. 3, when the supplied power amount P is negative, the target voltage upper limit value V _1b is changed to a reference upper limit value V ₁ (107 V as an example) or less. Thereby, the relationship between the input voltage Vi and the output voltage Vo is changed from a two-dot chain line graph to a solid line graph in the figure.

Specifically, when the input voltage Vi is within the target voltage range of the target voltage lower limit value V ₂ (95 V as an example) to the target voltage upper limit value V _1b , the input voltage Vi is output as it is as the output voltage Vo. The input voltage Vi is at less than the target voltage lower limit value V ₂ is output the input voltage Vi is adjusted to the target voltage lower limit value V ₂ as the output voltage Vo. When the input voltage Vi is larger than the target voltage upper limit value V _1b , the input voltage Vi is adjusted to the target voltage upper limit value V _1b and output as the output voltage Vo.

Thus, when the supplied power amount P is negative, that is, the power consumption of the load 20 is smaller than the generated power of the generator 21, and the power supply direction is from the power output terminal 11 to the series transformer 12. In the case of the direction, the voltage compensation is performed by changing the target voltage upper limit value V _1b to the reference upper limit value V ₁ or less at the installation point of the load 20. Therefore, the voltage VL at the installation point can be maintained within the reference voltage range (101 ± 6 V as an example).

On the other hand, as shown in FIG. 4, when the power supply amount P is positive and the supply direction is the direction from the series transformer 12 to the power output terminal 11, the target voltage lower limit value _V2b is the reference lower limit value. It is changed to V ₂ (95V as an example) or more. Thereby, the relationship between the input voltage Vi and the output voltage Vo is changed from a two-dot chain line graph to a solid line graph in the figure.

Specifically, when the input voltage Vi is within the target voltage range of the target voltage lower limit value V _2b to the target voltage upper limit value V ₁ (107 V as an example), the input voltage Vi is output as it is as the output voltage Vo. Further, when the input voltage Vi is larger than the target voltage upper limit value V ₁ was, it is output the input voltage Vi is adjusted to the target voltage maximum value V ₁ as the output voltage Vo. When the input voltage Vi is smaller than the target voltage lower limit value V _2b , the input voltage Vi is adjusted to the target voltage lower limit value V _2b and output as the output voltage Vo.

Thus, when the power supply amount P is positive, that is, the power consumption of the load 20 is larger than the power generated by the generator 21, and the power supply direction is from the series transformer 12 to the power output terminal 11. In the case of the direction, the voltage compensation is performed by changing the target voltage lower limit value V _2b to a reference lower limit value V ₂ or more at the installation point of the load 20. Therefore, the voltage VL at the installation point can be maintained within the reference voltage range (101 ± 6 V as an example).

FIG. 5 shows the voltage adjusted when the power supply amount P is positive. In the figure, the vertical axis indicates the voltage value, and the horizontal axis indicates time. In this example, it increased and than the target voltage upper limit value _{V 1} between the input voltage Vi time t1 to t2, is smaller than the target voltage lower limit value _{V 2b} during time t3 to t4. In contrast, the output voltage Vo is maintained during the time t1~t2 the target voltage upper limit value _{V 1,} is maintained during the time t3~t4 the target voltage lower limit value _{V 2b.}

  It should be noted that various embodiments of the present invention may be described with reference to flowcharts and block diagrams, where a block is either (1) a stage in a process in which an operation is performed or (2) a role in performing an operation. It may represent a section of the device it has. Certain stages and sections are implemented by dedicated circuitry, programmable circuitry supplied with computer readable instructions stored on a computer readable medium, and / or processor supplied with computer readable instructions stored on a computer readable medium. It's okay. Dedicated circuitry may include digital and / or analog hardware circuitry and may include integrated circuits (ICs) and / or discrete circuits. Programmable circuits include memory elements such as logical AND, logical OR, logical XOR, logical NAND, logical NOR, and other logical operations, flip-flops, registers, field programmable gate arrays (FPGA), programmable logic arrays (PLA), etc. Reconfigurable hardware circuitry, including and the like.

  Computer readable media may include any tangible device capable of storing instructions to be executed by a suitable device, such that a computer readable medium having instructions stored thereon is specified in a flowchart or block diagram. A product including instructions that can be executed to create a means for performing the operation. Examples of computer readable media may include electronic storage media, magnetic storage media, optical storage media, electromagnetic storage media, semiconductor storage media, and the like. More specific examples of computer readable media include floppy disks, diskettes, hard disks, random access memory (RAM), read only memory (ROM), erasable programmable read only memory (EPROM or flash memory), Electrically erasable programmable read only memory (EEPROM), static random access memory (SRAM), compact disc read only memory (CD-ROM), digital versatile disc (DVD), Blu-ray (RTM) disc, memory stick, integrated A circuit card or the like may be included.

  Computer readable instructions can be assembler instructions, instruction set architecture (ISA) instructions, machine instructions, machine dependent instructions, microcode, firmware instructions, state setting data, or object oriented programming such as Smalltalk, JAVA, C ++, etc. Including any source code or object code written in any combination of one or more programming languages, including languages and conventional procedural programming languages such as "C" programming language or similar programming languages Good.

  Computer readable instructions may be directed to a general purpose computer, special purpose computer, or other programmable data processing device processor or programmable circuit locally or in a wide area network (WAN) such as a local area network (LAN), the Internet, etc. The computer-readable instructions may be executed to create a means for performing the operations provided via and specified in the flowchart or block diagram. Examples of processors include computer processors, processing units, microprocessors, digital signal processors, controllers, microcontrollers, and the like.

  FIG. 6 illustrates an example computer 2200 in which aspects of the present invention may be embodied in whole or in part. The program installed in the computer 2200 can cause the computer 2200 to function as an operation associated with the apparatus according to the embodiment of the present invention or one or more sections of the apparatus, or to perform the operation or the one or more sections. The section can be executed and / or the computer 2200 can execute a process according to an embodiment of the present invention or a stage of the process. Such a program may be executed by CPU 2212 to cause computer 2200 to perform certain operations associated with some or all of the blocks in the flowcharts and block diagrams described herein.

  A computer 2200 according to this embodiment includes a CPU 2212, a RAM 2214, a graphic controller 2216, and a display device 2218, which are connected to each other by a host controller 2210. Computer 2200 also includes input / output units such as communication interface 2222, hard disk drive 2224, DVD-ROM drive 2226, and IC card drive, which are connected to host controller 2210 via input / output controller 2220. Yes. The computer also includes legacy input / output units, such as ROM 2230 and keyboard 2242, which are connected to input / output controller 2220 via input / output chip 2240.

  The CPU 2212 operates according to programs stored in the ROM 2230 and the RAM 2214, thereby controlling each unit. The graphic controller 2216 obtains the image data generated by the CPU 2212 in a frame buffer or the like provided in the RAM 2214 or itself so that the image data is displayed on the display device 2218.

  The communication interface 2222 communicates with other electronic devices via a network. The hard disk drive 2224 stores programs and data used by the CPU 2212 in the computer 2200. The DVD-ROM drive 2226 reads a program or data from the DVD-ROM 2201 and provides the program or data to the hard disk drive 2224 via the RAM 2214. The IC card drive reads programs and data from the IC card and / or writes programs and data to the IC card.

  The ROM 2230 stores therein a boot program executed by the computer 2200 at the time of activation and / or a program depending on the hardware of the computer 2200. The input / output chip 2240 may also connect various input / output units to the input / output controller 2220 via parallel ports, serial ports, keyboard ports, mouse ports, and the like.

  The program is provided by a computer-readable medium such as a DVD-ROM 2201 or an IC card. The program is read from a computer-readable medium, installed in the hard disk drive 2224, the RAM 2214, or the ROM 2230, which are also examples of the computer-readable medium, and executed by the CPU 2212. Information processing described in these programs is read by the computer 2200 to bring about cooperation between the programs and the various types of hardware resources. An apparatus or method may be configured by implementing information manipulation or processing in accordance with the use of computer 2200.

  For example, when communication is performed between the computer 2200 and an external device, the CPU 2212 executes a communication program loaded in the RAM 2214 and performs communication processing on the communication interface 2222 based on processing described in the communication program. You may order. The communication interface 2222 reads the transmission data stored in the transmission buffer processing area provided in the recording medium such as the RAM 2214, the hard disk drive 2224, the DVD-ROM 2201, or the IC card under the control of the CPU 2212, and the read transmission. Data is transmitted to the network, or received data received from the network is written in a reception buffer processing area provided on the recording medium.

  Further, the CPU 2212 allows the RAM 2214 to read all or a necessary part of a file or database stored in an external recording medium such as a hard disk drive 2224, a DVD-ROM drive 2226 (DVD-ROM 2201), an IC card, etc. Various types of processing may be performed on the data on the RAM 2214. Next, the CPU 2212 writes back the processed data to the external recording medium.

  Various types of information, such as various types of programs, data, tables, and databases, may be stored on a recording medium and subjected to information processing. The CPU 2212 describes various types of operations, information processing, conditional judgment, conditional branching, unconditional branching, information retrieval, which are described in various places in the present disclosure and specified by the instruction sequence of the program with respect to the data read from the RAM 2214. Various types of processing may be performed, including / replacement etc., and the result is written back to the RAM 2214. Further, the CPU 2212 may search for information in files, databases, etc. in the recording medium. For example, when a plurality of entries each having an attribute value of the first attribute associated with the attribute value of the second attribute are stored in the recording medium, the CPU 2212 specifies the attribute value of the first attribute. The entry that matches the condition is searched from the plurality of entries, the attribute value of the second attribute stored in the entry is read, and thereby the first attribute that satisfies the predetermined condition is associated. The attribute value of the obtained second attribute may be acquired.

  The programs or software modules described above may be stored on a computer readable medium on or near computer 2200. In addition, a recording medium such as a hard disk or a RAM provided in a server system connected to a dedicated communication network or the Internet can be used as a computer-readable medium, thereby providing a program to the computer 2200 via the network. To do.

  As mentioned above, although this invention was demonstrated using embodiment, the technical scope of this invention is not limited to the range as described in the said embodiment. It will be apparent to those skilled in the art that various modifications or improvements can be added to the above-described embodiment. It is apparent from the scope of the claims that the embodiments added with such changes or improvements can be included in the technical scope of the present invention.

  The order of execution of each process such as operations, procedures, steps, and stages in the apparatus, system, program, and method shown in the claims, the description, and the drawings is particularly “before” or “prior to”. It should be noted that the output can be realized in any order unless the output of the previous process is used in the subsequent process. Regarding the operation flow in the claims, the description, and the drawings, even if it is described using “first”, “next”, etc. for convenience, it means that it is essential to carry out in this order. It is not a thing.

DESCRIPTION OF SYMBOLS 1 Adjustment apparatus, 10 power supply, 11 power supply output terminal, 12 series transformer, 13 voltage adjustment part, 14 control part, 15 bypass switch, 16 measurement part, 20 load, 21 generator, 110 low piezoelectric track, 131 inverter, 133 Reactor, 135 Power supply unit, 161 Voltage measurement unit, 163 Current measurement unit, 165 Calculation unit, 200 Wiring impedance, 1351 Converter, 1352 Smoothing capacitor, 1353 Reactor, 1630 Current sensor, 2200 Computer, 2201 DVD-ROM, 2210 Host controller 2212 CPU, 2214 RAM, 2216 Graphic controller, 2218 Display device, 2220 Input / output controller, 2222 Communication interface, 2224 Hard disk Live, 2226 DVD-ROM drive, 2230 ROM, 2240 input / output chip, 2242 keyboard

Claims (17)

A series transformer in which the primary side is connected in series between the power source and the power output terminal;
A voltage adjusting unit that is connected to the secondary side of the series transformer and adjusts the output voltage of the power supply output terminal via the series transformer;
A control unit that changes at least one of a target voltage lower limit value and a target voltage upper limit value of the output voltage based on a power supply direction at the power output terminal;
An adjustment device comprising: The controller is
The adjustment device according to claim 1, wherein the lower limit value of the target voltage is increased when the supply direction is a direction from the series transformer to the power output terminal. The controller is
The adjustment device according to claim 1 or 2, wherein the upper limit value of the target voltage is reduced when the supply direction is a direction from the power supply output terminal to the series transformer.   4. The control unit according to claim 1, wherein the control unit changes at least one of the target voltage lower limit value and the target voltage upper limit value based on a power supply amount supplied at the power output terminal. 5. Adjustment device.   The control unit is configured to reduce the target voltage lower limit value and the target voltage upper limit when the magnitude of the supplied power amount is the first supply amount, compared to the second supply amount that is smaller than the first supply amount. The adjustment device according to claim 4, wherein one of the values is changed so as to approach the other. The controller is
The target voltage upper limit value is changed based on a value obtained by multiplying the magnitude of the supplied power amount by a first coefficient,
6. The adjustment device according to claim 4, wherein the target voltage lower limit value is changed based on a value obtained by multiplying a magnitude of the supplied power amount by a second coefficient.   The adjusting device according to any one of claims 4 to 6, further comprising a measuring unit that measures the amount of supplied power and the supply direction between the series transformer and the power supply output terminal.   The adjustment device according to claim 7, wherein the control unit sequentially updates at least one of the target voltage lower limit value and the target voltage upper limit value based on a measurement result by the measurement unit. A storage unit for storing a history of measurement results by the measurement unit;
The control unit sequentially predicts the power supply amount and the supply direction from the history of the measurement results, and sequentially updates at least one of the target voltage lower limit value and the target voltage upper limit value based on a prediction result. 8. The adjusting device according to 7. Further comprising a bypass switch capable of switching whether to bypass the primary side of the series transformer;
The control unit switches off the bypass switch in response to the output voltage being out of a range from the target voltage lower limit value to the target voltage upper limit value in a state where the bypass switch is on. The adjusting device according to any one of 1 to 9.   The adjustment device according to claim 10, wherein the control unit switches the bypass switch on in response to the output voltage being in the range in a state where the bypass switch is off.   The supply direction varies according to power consumption of at least one load connected to the power output terminal and generated power of at least one generator connected to the power output terminal. The adjustment device according to any one of the above. The power source is an AC power source,
The voltage regulator is
An inverter that outputs a current that flows to the secondary side of the series transformer;
A power supply unit for supplying power to the inverter;
The adjusting device according to claim 1, comprising:   The adjustment device according to claim 13, wherein the power supply unit converts AC power from the power source into DC power and supplies the DC power to the inverter.   The adjustment device according to claim 13, wherein the power supply unit supplies power from another power source different from the power source to the inverter.   The adjusting device according to any one of claims 1 to 15, wherein the power source is a transformer that converts a voltage from a high-voltage distribution system to a low-voltage distribution system. Changing at least one of the target voltage lower limit value and the target voltage upper limit value of the output voltage of the power output terminal based on the direction of power supply at the power output terminal;
Adjusting the output voltage via the series transformer by a voltage regulator connected to the secondary side of a series transformer whose primary side is connected in series between a power source and the power output terminal;
An adjustment method comprising:

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