JP5830311B2 - Power supply system, output end switch control device, and power supply method - Google Patents

Description

  The present invention relates to a power supply system that supplies power to a load, an output terminal switch control device, and a power supply method.

Conventionally, a power supply device used in a power feeding system is configured to be able to output an output capacity corresponding to the maximum load capacity of a load that supplies power (for example, Patent Document 1).
In addition, as shown in FIG. 10, when the load is an information communication (ICT) device, for each load (or a plurality of load groups) in order to improve the stability of the power supply system, that is, in consideration of a failure of the power supply device, etc. A power supply device is provided.
The DC power supply 100 (200, 300) generates DC power from AC power and supplies DC power to the load 102 (202, 302) via the switchboard 101 (201, 301).
Further, the DC power supply 100 (200, 300) is connected to a battery with respect to the output of DC power.
With this configuration, when a DC power supply fails, the operation of the load connected to the failed DC power supply is limited, and the operation of the load connected to another DC power supply that is not in failure is limited. Never happen.

International Publication No. 2002/061917

  However, in the above-described method of providing a DC power supply for each load, if the load capacity of the load changes, for example, if the load capacity of the DC power supply is significantly reduced, the load factor of the DC power supply is reduced. There is a disadvantage that loss in power conversion from AC power to DC power in the rectifier increases, and wasteful power is consumed.

  The present invention has been made in view of such circumstances, and can stably supply power to a load and suppress wasteful power consumption in a DC power source even when the load capacity of the load changes. It is an object of the present invention to provide a power supply system, an output end switch control device, and a power supply method.

The power supply system of the present invention is a power supply system that supplies DC power to a plurality of loads, and is connected to a plurality of DC power sources that convert AC power into DC power and output terminals of the DC power sources. An output end switch; a first wiring provided for each of the output end switches; one end connected to the output end switch; a connection line provided between the other ends of the first wiring; and the first A second wiring having one end connected to the intersection of the wiring and the connection line and the other end connected to the load; a detection unit for detecting an operating state of the load; and a resistance of the first wiring An operating DC power supply that selects an operating DC power supply group that is a combination of the DC power supply or the DC power supplies that minimizes the total loss, which is the sum of the resistance loss due to power conversion and the conversion loss in the power conversion, from the plurality of DC power supplies A loop selecting unit, the DC power from the DC power source included in the operating DC power supply group, the output-end switch is turned on, the operation control unit for supplying to the connected the load to the output-end switch And a control table in which load capacity combinations that are combinations of load capacities supplied to each of the loads and the operating DC power supply groups that can supply all the supplied power with a minimum total loss are stored. Bei example a storage unit, was, for the operating DC power supply group selection unit, a total of the calculated total power supplied is of the load capacitance is the power supplied to the load, supplying the total feed power A DC power supply group that is the DC power supply or a combination of the DC power supplies that supplies the necessary power is extracted, and the minimum loss total in the DC power supply group is extracted. When selecting the operating DC power supply group as the active DC power supply group, the load capacity combination corresponding to the load capacity of the load detected by each of the detection units is extracted, and the minimum loss for the load capacity combination is extracted. The operating DC power supply group having a total is selected from the control table, and the operation control unit is configured to output the output terminal of the DC power supply included in the operating DC power supply group selected by the operating DC power supply group selecting unit. and wherein a call to operate the switch as an on-state.

  The power supply system according to the present invention includes a rectification unit that converts a plurality of the DC power supplies into a DC power, the DC power supply being connected in parallel to the output end, and the DC power supply includes the rectification unit. The operation information indicating the number of operations is output to the operation DC power supply group selection unit, and the operation DC power supply group selection unit uses the output power of the DC power supply at the operation number of the rectification unit as the output power of the DC power supply. Calculating, extracting the DC power supply group by the output power, obtaining the conversion loss of the DC power supply from the output power of the DC power supply at the number of operating rectifier units for each of the extracted DC power supply groups, The total loss is calculated from the conversion loss and the resistance loss, and the DC power supply group having the minimum total loss is calculated from the DC power supply group. And selecting as the dynamic DC power supply group.

In the power supply system of the present invention, the operating DC power supply group selection unit calculates the total supply power at regular intervals, and the absolute value of the difference between the calculated total supply power and the total supply power obtained immediately before is calculated as follows: If it exceeds a preset threshold, the operating DC power supply group corresponding to Kimake load capacity combined before calculated, and selects anew from the control table.

  In the power supply system of the present invention, the detection unit is provided between the load and the other end of the second wiring, detects a current value supplied to the load according to an operating state of the load, The operating DC power supply group selection unit calculates the load capacity for each load from the current value and a voltage at which the DC power supply supplies DC power to the load.

  The power supply system according to the present invention is characterized in that the operating DC power supply group selection unit calculates the resistance loss using a resistance of the first wiring and a resistance of the connection line.

The output terminal switch control device of the present invention is an output terminal switch control device that controls the supply of DC power to a plurality of loads via wires from a plurality of DC power supplies, and each output terminal of the DC power supply , An output end switch interposed between the wiring connected to the load, a detection unit for detecting an operating state of the load, a resistance loss due to resistance of the wiring in each operating state of the load, and an alternating current Operating DC that selects from the plurality of DC power supplies an operating DC power supply group that is the DC power supply or a combination of the DC power supplies that minimizes the total loss that is the sum of conversion losses in power conversion for converting power into DC power A power supply group selection unit; and an operation control unit that operates the DC power supply included in the operating DC power supply group by turning on the output terminal switch. Stored is a control table in which load capacity combinations, which are combinations of load capacities supplied to each of the loads, and the operating DC power supply group capable of supplying all supply power with a minimum total loss are stored. A storage unit, and the operating DC power supply group selection unit obtains the total supply power that is the total of the load capacity, which is the power supplied to the load, and is necessary for supplying the total supply power When extracting the DC power supply group that is the combination of the DC power supply or the DC power supply that supplies power, and selecting the DC power supply group having the smallest total loss among the DC power supply groups as the operating DC power supply group, The load capacity combination corresponding to the load capacity of the load detected by each of the detection units is extracted, and the minimum loss for the load capacity combination is extracted. The operating DC power supply group having a total is selected from the control table, and the operation control unit is configured to output the output terminal of the DC power supply included in the operating DC power supply group selected by the operating DC power supply group selecting unit. It is characterized by operating with the switch turned on.

The power supply method of the present invention is a method of operating an output end switch control device that controls supply of DC power to a plurality of loads via wirings from a plurality of DC power supplies, and each output terminal of the DC power supply is operated. And an output end switch interposed between the load and the wiring connected to the load, a process in which the detecting unit detects an operating state of the load, and an operating DC power supply group selecting unit operates each of the loads. Operating DC power supply group that is the DC power supply or a combination of the DC power supplies that minimizes the total loss that is the sum of the resistance loss due to the resistance of the wiring in the state and the conversion loss in power conversion for converting AC power to DC power And selecting an output terminal switch inserted between the output terminal of each of the DC power supplies and the wiring connected to the load. As on-state, and a process to operate the DC power source included in the operating DC power supply group, the operating DC power supply group selection unit, the sum of the load capacity Ru power der supplied to the load calculated on the total power supplied Ru Oh, extracts the DC power supply or DC power supply group is a combination of the DC power source for supplying power necessary to supply the entire power supply, among the DC power source group, the minimum A combination of load capacities supplied to each of the loads corresponding to the load capacities of the loads detected by each of the detection units when selecting a DC power group having a total loss of is supplied to extract a certain load capacity combined, the operating DC power supply group having the minimum total loss of respect to the load capacity combined, to each of the load A load capacity combination that is a combination of load capacities, and the operating DC power supply group that can supply all the supplied power with a minimum total loss is selected from the corresponding control table, and the operation control unit The output DC switch included in the selected operating DC power supply group selected by the operating DC power supply group selection unit is operated while being turned on.

According to this invention, in order to increase the power conversion efficiency of the operating DC power supply in response to the load capacity change, the power loss of the operating DC power supply and the resistance of the wiring between the DC power supply and the load are increased. The operating DC power supply group that minimizes the total loss, which is the sum of the resistance loss due to the power, is selected.
For this reason, according to the present invention, power can be stably supplied to the load, and even when the load capacity of the load changes, the power consumption when converting power from AC power to DC power in the DC power supply ( Conversion loss) can be reduced, and wasteful power consumption can be suppressed.

It is a block diagram which shows the structural example of the electric power feeding system by one Embodiment of this invention. It is a graph which shows a response | compatibility with the output power as each DC power of DC power supply RF1, RF2, and RF3, and the power loss consumed in order to obtain this DC power. It is a figure which shows the structure of the resistance value table which shows each resistance value of wiring S11, S22, S33, SN1N2, SN2N3. It is a figure which shows the connection relation of each wiring and node between each of direct-current power supply RF1, RF2, RF3 of electric power feeding system, and load L1, L2, and L3. Control table configuration corresponding to the total supply power division range in which the total supply power is divided equally from the minimum to the maximum and the operating DC power supply group that minimizes the total loss in the supply system in the case of the total supply power division range FIG. It is a flowchart which shows the operation example of the operation control of DC power supply which makes the total loss of the electric power feeding system of the output terminal switch control part 1 in a electric power feeding system the minimum. It is a figure of the table which shows a response | compatibility with the combination of the numerical value of each load capacity | capacitance of load L1, L2, and L3, and the output terminal switch name connected to the output terminal of the DC power supply which the working DC power supply group operates in the combination. It is a flowchart which shows the operation example of the operation control of DC power supply which makes the total loss of the electric power feeding system of the output terminal switch control part 1 in a electric power feeding system the minimum. It is a figure which shows the structural example of DC power supply RF1 in FIG. It is a figure which shows the structure of the conventional electric power feeding system.

<First Embodiment>
Hereinafter, a first embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a schematic block diagram showing a configuration example of a power feeding system according to an embodiment of the present invention.
In FIG. 1, the power supply system includes an output end switch control unit 1, DC power supplies RF1, RF2, RF3, output end switches RFSW1, RFSW2, RFSF3, batteries BAT1, BAT2, BAT3, wirings S1, S2, S3, SN1N2, SN2N3, It consists of detectors D1, D2, and D3.
The output end switch RFSW1 is inserted between the output end of the DC power supply RF1 and the connection point P1, and outputs DC power from the DC power supply RF1 to the wiring S11 when on, while it is off. In this case, DC power is not output from the DC power supply RF1 to the wiring S11. That is, the output end switch RFSW1 operates the DC power supply RF1 when in the on state, and does not operate the DC power supply RF1 when in the off state.
The DC power supply RF1 converts commercial AC power into DC power, and supplies the converted DC power to the loads L1, L2, and L3, which are information communication devices, for example, via the wiring S11 and the output end switch RFSW1.

When the battery BAT1 is connected to the connection point P1 and the DC power supply is operating normally, the battery BAT1 is charged by any one or combination of the DC power supplies RF1, RF2, and RF3, while when the output voltage of the DC power supply decreases, Discharging is performed to supply DC power to the loads L1, L2, and L3.
The wiring S11 is a wiring that connects between the connection point P1 and the connection point N1, and has a resistance R1N1 (resistance value is the same as the resistance name) that is a parasitic resistance.
The wiring S1 is a wiring that connects the connection point N1 and the load L1, and has a resistance R1 that is a parasitic resistance.
The detection unit D1 measures the voltage value V of the voltage applied to the load L1 and the current value I of the current supplied to the load L1, and outputs the measured voltage value V and current value I to the output end switch. Output to the control unit 1.

The output end switch RFSW2 is inserted between the output end of the DC power supply RF2 and the connection point P2, and outputs DC power from the DC power supply RF2 to the wiring S22 when on, while it is off. In this case, DC power is not output from the DC power supply RF2 to the wiring S22. That is, the output end switch RFSW2 operates the DC power supply RF2 when it is on, and does not operate the DC power supply RF2 when it is off.
The DC power supply RF2 converts commercial AC power into DC power, and supplies the converted DC power to the loads L1, L2, and L3 via the wiring S22 and the output end switch RFSW2.

When the battery BAT2 is connected to the connection point P2 and the DC power supply is operating normally, the battery BAT2 is charged by any one or combination of the DC power supplies RF1, RF2, and RF3, while when the output voltage of the DC power supply decreases, Discharging is performed to supply DC power to the loads L1, L2, and L3.
The wiring S22 is a wiring that connects between the connection point P2 and the connection point N2, and has a resistance R2N2 that is a parasitic resistance.
The wiring S2 is a wiring that connects between the connection point N2 and the load L2, and has a resistance R2 that is a parasitic resistance.
The detection unit D2 measures the voltage value V of the voltage applied to the load L2 and the current value I of the current supplied to the load L2, and outputs the measured voltage value V and current value I to the output end switch. Output to the control unit 1.

The output end switch RFSW3 is interposed between the output end of the DC power supply RF3 and the connection point P3, and outputs DC power from the DC power supply RF3 to the wiring S33 when on, while it is off. In this case, DC power is not output from the DC power supply RF3 to the wiring S33. That is, the output end switch RFSW3 operates the DC power supply RF3 when in the on state, and does not operate the DC power supply RF3 when in the off state.
The DC power supply RF3 converts commercial AC power into DC power, and supplies the converted DC power to the loads L1, L2, and L3 via the wiring S33 and the output end switch RFSW3.

When the battery BAT3 is connected to the connection point P3 and the DC power supply is operating normally, the battery BAT3 is charged by any one or combination of the DC power supplies RF1, RF2 and RF3, while when the output voltage of the DC power supply decreases, Discharging is performed to supply DC power to the loads L1, L2, and L3.
The wiring S33 is a wiring that connects between the connection point P3 and the connection point N3, and has a resistance R3N3 that is a parasitic resistance.
The wiring S3 is a wiring that connects the connection point N3 and the load L3, and has a resistance R3 that is a parasitic resistance.
The detection unit D3 measures the voltage value V of the voltage applied to the load L3 and the current value I of the current supplied to the load L3, and outputs the measured voltage value V and current value I to the output end switch. Output to the control unit 1.
The wiring SN1N2 is a wiring that connects the node N1 and the node N2, and includes a resistor RN1N2 that is a parasitic resistance.
Further, the wiring SN2N3 is a wiring that connects the node N2 and the node N3, and includes a resistor RN2N3 that is a parasitic resistance.

The output end switch controller 1 performs on / off control to turn on or off each of the output end switches RFSW1, RFSW2, and RFSW3. That is, the output end switch control unit 1 performs operation control of whether to operate or stop each of the DC power sources RF1, RF2, and RF3.
The output terminal switch control unit 1 includes an operating DC power supply group selection unit 11, an operation control unit 12, and a storage unit 13.

  In the present embodiment, each of the DC power sources RF1, RF2, and RF3 supplies power to each load with a DC voltage of, for example, 400 V (a constant voltage value V). Thereby, compared with the case where electric power is supplied with a lower DC voltage, the current value can be reduced when supplying DC electric power, and the electric energy consumed in the parasitic resistance of each wiring described above is reduced. And the efficiency of power supply can be improved.

Next, the operating DC power supply group selection unit 11 has the least conversion loss in the DC power supplies RF1, RF2, and RF3 corresponding to the load capacity combination that is a combination of the load capacities (supply power) of the loads L1, L2, and L3. An operating DC power supply group that is any one or combination of DC power supplies RF1, RF2, and RF3 is selected.
Here, each of the DC power sources RF1, RF2, and RF3 has a power loss in power conversion when converting commercial AC power into DC power. This power loss is different depending on the DC power source, and has a different value depending on the power at the time of conversion. The difference between the input AC power and the output DC power is measured as a power loss for each DC power source.
FIG. 2 is a graph showing, as an example, the correspondence between output power as DC power of each of the DC power sources RF1, RF2 and RF3 and power loss consumed to obtain this DC power. In the graph of FIG. 2, the horizontal axis represents output power, and the vertical axis represents loss in power conversion. As shown in FIG. 2, the loss in power conversion differs depending on the DC power source and the value of output power.

  The operating DC power supply group selection unit 11 corresponds to the operating states of the loads L1, L2, and L3, and is the sum of the resistance loss due to the parasitic resistance of the wirings S11, S22, S33, S1N2N, and DN2N3 and the conversion loss in power conversion. The active DC power supply group that is a DC power supply or a combination of DC power supplies that minimizes the total loss is selected from a plurality of DC power supplies, that is, DC power supplies RF1, RF2, and RF3. Here, the operating DC power supply group is any one of the DC power supplies RF1, RF2, and RF3, or a combination of two or more DC power supplies RF1, RF2, and RF3.

The operating DC power supply group selection unit 11 calculates the load capacities PW1, PW2, and PW3 of the loads L1, L2, and L3 from the voltage value V and the current value I that are output from the detection units D1, D2, and D3, respectively. Further, the operating DC power supply group selection unit 11 stores the voltage value V as a constant value in the internal storage unit, and determines each of the current value I from the detection unit and the voltage value V stored in the internal storage unit. The load capacity of the load may be calculated. Hereinafter, the description will be made assuming that the voltage value is a constant value.
Further, the operating DC power supply group selection unit 11 integrates each of the load capacities PW1, PW2, and PW3, and calculates the total supply power that is power consumption in the entire power feeding system.
The operating DC power supply group selection unit 11 selects an operating DC power supply group that can supply all the obtained supply powers from the DC power supplies RF1, RF2, and RF3.
The operation control unit 12 turns on the output terminal switch connected to the output terminal of the DC power supply included in the operating DC power supply group, and turns off the output terminal switch connected to the output terminal of the DC power supply not included. Control the operation of the DC power supply.

When each of the DC power sources RF1, RF2, and RF3 is operated by a plurality of units in a combination of two or more units in the operating DC power source group, the output capacity of the output power of each DC power source is balanced.
That is, when two DC power supplies are operating, these two units output half (1/2) of the total power supply capacity, and when three DC power supplies are operating, these three units are Outputs 1/3 of the total power supply capacity.

Next, an operation performed by the operating DC power supply group selection unit 11 to select an operating DC power supply group from the DC power supplies RF1, RF2, and RF3 will be described.
The storage unit 13 stores a resistance value table indicating resistance values r1N1, r2N2, r3N3, rN1N2, and rN2N3 of the parasitic resistances of the wirings S11, S22, S33, SN1N2, and SN2N3 used by the operating DC power supply group selection unit 11 for calculation. Has been. In this resistance value table, as shown in FIG. 3, wiring names, resistance names, and resistance values are stored in association with each other. In addition, the wirings S1, S2 and S3 have the same loss power consumed as thermal energy, regardless of whether they are supplied from any DC power supply, and therefore need not be used for selecting an operating DC power supply group. It is not stored in the value table.
2 is stored as a conversion loss table in which the output power and the loss power (conversion loss) are paired for each DC power source.

The operating DC power supply group selection unit 11 selects any one of the DC power supplies or combinations of DC power supplies that can supply all the supplied power as candidates for the operating DC power supply group that supplies all the supplied power supplied to the loads L1, L2, and L3. Select.
Then, the operating DC power supply group selection unit 11 uses the resistance value table and the conversion loss table stored in the storage unit 13 to supply the conversion loss, which is the loss power in the power conversion in the operating DC power supply, and the power. The total loss is calculated by summing up the resistance loss, which is the loss power in the wirings S11, S22, S33, SN1N2 and SN2N3 which are the paths.

For example, when it is necessary to supply 20 kW of power to each of the loads L1, L2, and L3 (when 20 kW of power is consumed), the total supply power is 60 kW, and this 60 kW is used as an operating DC power supply group. Will supply. At this time, the operating DC power supply group selection unit 11 extracts the following seven DC power supply groups as candidates for the operating DC power supply group. Each of the DC power supplies RF1, RF2, and RF3 has, for example, a maximum rated DC power output capacity of 100 kW.
First candidate 60 kW: DC power supply RF1
2nd candidate 60kW: DC power supply RF2
3rd candidate 60kW: DC power supply RF3
4th candidate 30 kW: DC power supply RF1, DC power supply RF2
5th candidate 30 kW: DC power supply RF1, DC power supply RF3
Sixth candidate 30 kW: DC power supply RF2, DC power supply RF3
7th candidate 20 kW: DC power supply RF1, DC power supply RF2, DC power supply RF3

At this time, the operating DC power supply group selection unit 11 compares the total supply power and the maximum rating of the output capacity of the DC power supply. If the total supply power is less than or equal to the maximum rating of the output capacity of the DC power supply, any one of them is selected. Extract DC power as DC power group.
On the other hand, when the total supply power exceeds the maximum rating of the output capacity of the DC power supply, the operating DC power supply group selection unit 11 divides the split supply power obtained by dividing the total supply power below the maximum rating of the output capacity of the DC power supply. The number is obtained, and a combination of the DC power supplies of this division number is selected as a DC power supply group.

For example, when each of the loads L1, L2, and L3 needs to be supplied with 40 kW, the total supply power is 120 kW, and the operating DC power supply group supplies 120 kW. At this time, since the total supply power exceeds 100 kW, which is the maximum rating of the output capacity of each of the DC power supplies RF1, RF2, and RF3, the operating DC power supply group selection unit 11 is set as the following candidate for the operating DC power supply group. The four DC power supply groups shown are extracted.
First candidate 60 kW: DC power supply RF1, DC power supply RF2
Second candidate 60 kW: DC power supply RF1, DC power supply RF3
Third candidate 60 kW: DC power supply RF2, DC power supply RF3
4th candidate 40 kW: DC power supply RF1, DC power supply RF2, DC power supply RF3

Then, the operating DC power supply group selection unit 11 calculates the total loss of each of the extracted DC power supply groups as candidates as shown below. As an example, the process of calculating the total loss in four DC power supply groups when the total power supply is 120 kW will be described.
The operating DC power supply group selection unit 11 reads the conversion loss at 60 kW of each of the DC power supplies RF1 and RF2 in the first candidate from the conversion loss table of the storage unit 13. The conversion loss of the DC power supply RF1 at 60 kW is 2.6 kW, and the conversion loss of the DC power supply RF2 is 3.3 kW.

Further, the operating DC power supply group selection unit 11 generates a net list indicating the connection relationship between each wiring and node between each of the DC power supplies RF1, RF2, and RF3 and the loads L1, L2, and L3 of the power supply system of FIG. , Read from the storage unit 13, and extract current paths for the loads L1, L2, and L3 from the DC power supplies RF1 and RF2. FIG. 4 is a diagram illustrating a connection relationship between each wiring and node between each of the DC power sources RF1, RF2, and RF3 of the power feeding system and the loads L1, L2, and L3.
Here, the operating DC power supply group selection unit 11 extracts a current path from the DC power supply RF1 to the load L1 as a wiring S11, a node N1, and a wiring S1.

Further, the operating DC power supply group selection unit 11 extracts a current path from the DC power supply RF1 to the load L2 as a wiring S11, a node N1, a wiring SN1N2, a node N2, and a wiring S2.
The operating DC power supply group selection unit 11 extracts a current path from the DC power supply RF1 to the load L3 as a wiring S11, a node N1, a wiring SN1N2, a node N2, a wiring SN2N3, a node 3, and a wiring S3.
Here, the operating DC power supply group selection unit 11 extracts a current path from the DC power supply RF2 to the load L2 as a wiring S22, a node N2, and a wiring S2.

Further, the operating DC power supply group selection unit 11 extracts a current path from the DC power supply RF2 to the load L3 as a wiring S22, a node N2, a wiring SN2N3, a node N3, and a wiring S3.
At this time, since the power is supplied from the DC power supplies RF1 and RF2, the operating DC power supply group selection unit 11 does not extract the current path from the DC power supply RF2 to the load L1 because the current flows in the direction of the DC power supply RF3. .

Then, the operating DC power supply group selection unit 11 determines the wirings S11, S22, and S33 from the current values of the output power output from the DC power supplies RF1, RF2, and RF3 and the current values consumed by the loads L1, L2, and L3. , SN1N2 and SN2N3 are obtained.
That is, when the voltage value for supplying DC power is 400 V (a constant voltage value V), each of the loads L1, L2, and L3 has a load capacity of 40 kW, and each of the detection units D1, D2, and D3 Outputs a current value of 100 A (ampere) as 40 kW / 400 V as a detection result. As a result, the operating DC power supply group selection unit 11 calculates the load capacity of the loads L1, L2, and L3 by 100A × 400V and calculates each as 40 kW.
When the DC power supplies RF1 and RF2 are operated, the operating DC power supply group selection unit 11 calculates 60 kW, that is, the current output from each of the DC power supplies RF1 and RF2 is (60 kW / 400 V) = 150A.

Next, since 100 A is supplied to each of the loads L1, L2, and L3, the operating DC power supply group selection unit 11 has a current of 150 A flowing from the DC power supply RF1 to the wiring S11 and supplies 100 A to the load L1. Then, it is detected that 50A flows through the wiring SN1N2.
Further, the operating DC power supply group selection unit 11 detects that 150 A of current flows from the DC power supply RF2 to the wiring S22, 100 A is supplied to the load L2, and 100 A flows to the wiring SN2N3.
Further, the operating DC power supply group selection unit 11 detects that 100 A of current flows from the node N2 to the wiring S33 and 100 A is supplied to the load L3.

Next, the operating DC power supply group selection unit 11 selects the resistance value r11 of the wiring S11, the resistance value r22 of the wiring S22, the resistance value rN1N2 of the wiring SN1N2, and the resistance value of the wiring SN2N3 from the resistance value table of the storage unit 13. Read rN2N3.
Then, the operating DC power supply group selection unit 11 calculates the resistance loss Pr1 in the first candidate DC power supply group as follows.
Pr1 = r11 × 150 ² + r22 × 150 ² + rN1N2 × 50 ² + rN2N3 × 100 ²
The operating DC power supply group selection unit 11 adds 2.6 kW of the conversion loss of the DC power supply RF1 read out earlier and 3.3 kW of the conversion loss of the DC power supply RF2 to obtain 5.9 kW as the first candidate conversion loss Pf1. Is calculated.
Thereby, the operating DC power supply group selection unit 11 adds the resistance loss Pr1 and the conversion loss Pf1, and obtains the total loss PT1 of the first candidate DC power supply group as the addition result.

Similarly, the operating DC power supply group selection unit 11 calculates the total loss of each of the second candidate, the third candidate, and the fourth candidate by the same operation as the process described in the first candidate.
That is, the operating DC power supply group selection unit 11 reads the conversion loss 2.6 kW of the DC power supply RF1 from the conversion loss table in the storage unit 13 and the conversion loss 4.1 kW of the 60 kW of the DC power supply RF3 and adds the results. 6.7 kW is defined as the second candidate conversion loss Pf2.
Further, the operating DC power supply group selection unit 11 calculates the resistance value loss Pr2 in the second candidate DC power supply group as follows.
Pr2 = r11 × 150 ² + r33 × 150 ² + rN1N2 × 50 ² + rN2N3 × 50 ²
Thereby, the operating DC power supply group selection unit 11 adds the resistance loss Pr2 and the conversion loss Pf2, and obtains the total loss PT2 of the second candidate DC power supply group as the addition result.

Further, the operating DC power supply group selection unit 11 reads the conversion loss 3.3 kW of 60 kW of the DC power supply RF2 and the conversion loss 4.1 kW of 60 kW of the DC power supply RF3 from the conversion loss table in the storage unit 13, and the addition result 7.1 kW is the third candidate conversion loss Pf3.
Further, the operating DC power supply group selection unit 11 calculates the resistance loss Pr3 in the third candidate DC power supply group as follows.
Pr3 = r22 × 150 ² + r33 × 150 ² + rN1N2 × 100 ² + rN2N3 × 50 ²
Thereby, the operating DC power supply group selection unit 11 adds the resistance loss Pr3 and the conversion loss Pf3, and obtains the total loss PT3 of the third candidate DC power supply group as the addition result.

Further, the operating DC power supply group selection unit 11 determines from the conversion loss table in the storage unit 13 that the 40 kW conversion loss of the DC power supply RF1 is 2.2 kW, the 40 kW conversion loss of the DC power supply RF2 is 3.0 kW, and the DC power supply RF3. The conversion loss of 3.8 kW of 40 kW is read out, and the addition result of 9.0 kW is set as the fourth candidate conversion loss Pf4.
Further, the operating DC power supply group selection unit 11 calculates the resistance loss Pr4 in the fourth candidate DC power supply group as follows.
Pr4 = r22 × 100 ² + r22 × 100 ² + r33 × 100 ²
Thereby, the operating DC power supply group selection unit 11 adds the resistance loss Pr4 and the conversion loss Pf4, and obtains the total loss PT4 of the fourth candidate DC power supply group as the addition result.

Next, the operating DC power supply group selecting unit 11 extracts the first candidate loss total PT1 and the second candidate extracted as operating DC power supply group candidates for supplying the total supply power 120 kW to the loads L1, L2, and L3. A DC power group having the smallest total loss is selected from the total loss PT2, the third total loss PT3, and the fourth total loss PT4, and this DC power supply group is set as the active DC power supply group, and the operation control unit 12 is output.
Thereby, the operation control unit 12 sets the output terminal switch corresponding to the DC power source included in the operating DC power source group to the ON state, and sets the output terminal switch corresponding to the DC power source not included in the operating DC power source group to the OFF state. To do. As a result, the DC power supply is in an operating state when the connected output terminal switch is turned on.
The output end switch control unit 1 performs the above-described processing every predetermined period, for example, every 5 minutes, and the total loss of the entire power feeding system is minimized in real time in response to changes in the load capacities of the loads L1, L2, and L3. Thus, the operating DC power supply is controlled.

In the above description, the load capacity of the loads L1, L2, and L3 is calculated to be the same. However, even if the loads L1, L2, and L3 are different load capacities, only the current values are different, and the output end switch control unit 1 The operation process of the DC power supply that minimizes the total loss of the power feeding system is the same.
Further, the operating DC power supply group selection unit 11 multiplies the voltage value V for supplying power by the current value I read for each measurement cycle from the detection units D1, D2, and D3, and loads L1, L2, and The load capacities PL1, PL2, PL3 of L3 are compared with the load capacities PL1, PL2, PL3 in the previous measurement cycle stored in the internal storage unit.

That is, the operating DC power supply group selection unit 11 calculates the difference between the load capacity PL1 calculated by the load L1 and the load capacity PL1 of the load L1 stored in the storage unit, and calculates the load capacity PL2 calculated by the load L2. And the difference between the load capacity PL2 of the load L2 stored in the storage unit, and similarly, the difference between the load capacity PL3 calculated by the load L3 and the load capacity PL3 of the load L3 stored in the storage unit Is calculated.
Then, the operating DC power supply group selection unit 11 performs a process of newly selecting an operating DC power supply group when any one of the differences exceeds a preset threshold value, while all the differences are set in advance. When the value is equal to or less than the threshold value, a new selection process for the active DC power supply group may not be performed.
Further, when the operation DC power supply group selection unit 11 performs processing for newly selecting an operation DC power supply group, the load capacities PL1, PL2, and PL3 obtained in the measurement cycle are changed to the load capacities in the previous measurement cycle. Write to the storage unit as PL1, PL2, and PL3.

  As described above, according to the present embodiment, each of the conversion losses of the plurality of DC power sources RF1, RF2, and RF3, and the plurality of DC power sources according to the load capacities of the loads L1, L2, and L3 measured at a constant period. The total loss which is the sum of the resistance loss due to the parasitic resistance of the wiring (S11, S22, S33, SN1N2, SN2N3) between each of the RF1, RF2 and RF3 and each of the plurality of loads L1, L2 and L3 is minimized. Is selected, and power is supplied to the loads L1, L2, and L3 from the DC power supply included in the operating DC power supply group, so that power supply with a minimum loss in the power supply system can be performed at all times.

Conventionally, all installed information communication apparatuses are always operated in a form of operation. However, in recent years, an operation has been performed in which any of the information communication apparatuses having the same function is caused to function and other operations are stopped by virtualization of the server or clouding.
For this reason, when it is configured by server virtualization or cloud computing as in the prior art, not all installed information communication devices are necessarily operated.
For example, in FIG. 10, when the load 102 is operating but the loads 202 and 302 have only standby power, the DC power supplies 200 and 300 that supply power to each of the loads 202 and 302 are Therefore, operation is performed at a load factor with poor conversion efficiency, and wasteful power (conversion loss) is consumed in power conversion from AC power to DC power.
Even in such a case, the present embodiment that can perform power feeding that minimizes the total loss in the power feeding system corresponding to the load capacity is effective.

<Second Embodiment>
The second embodiment of the present invention will be described below with reference to the drawings. The configuration of the power supply system according to the second embodiment is the same as that of the first embodiment shown in FIG.
The second embodiment is different from the first embodiment in that when the load capacity changes of the loads L1, L2 and L3 are the same, the operation DC power supply group is selected in advance as follows. This is the configuration used.
With the configuration of the second embodiment, it is possible to perform the operation processing of the DC power supply that minimizes the total loss of the power feeding system at a higher speed than the first embodiment.
As already described, when the load capacities of the loads L1, L2 and L3 change the same, that is, when the load capacities of the loads L1, L2 and L3 change from 20 kW to 40 kW, the control table is changed as follows. create.

  The control table is, for example, from 0 to 30 kW, 31 kW to 60 kW, 61 kW to 90 kW, 91 kW to 90 kW, 91 kW to 120 kW. It is assumed that there are 10 divisions of 121 kW to 150 kW, 151 kW to 180 kW, 181 kW to 210 kW, 211 kW to 240 kW, 241 to 270, and 271 kW to 300 kW. Then, using the power values 15 kW, 45 kW, 75 kW, 105 kW, 135 kW, 165 kW, 195 kW, 225 kW, 255 kW, and 285 kW as the total supply power, the calculation method of the total loss used in the first embodiment is used. The total loss of the power supply system is calculated, and the operating DC power supply group that minimizes the total loss of the power supply system in the power values of all the supplied powers is obtained in advance. The calculation of the operating DC power supply group may be performed by the operating DC power supply group selection unit 11 or may be performed using an external computer. When using an external computer, the storage unit 13 does not need to store a resistance value table and a conversion loss table, and stores a control table described below in advance.

Next, FIG. 5 shows the total supply power division range obtained by dividing the total supply power from the minimum (0 kW) to the maximum (300 kW) equally, and the total loss in the supply system in the case of the total supply power division range. It is a figure which shows the structure of the control table by which the response | compatibility with the active DC power supply group used as the minimum was shown. Here, in the present embodiment, for example, the name of the output terminal switch (switch identification information) connected to the output terminal of the DC power supply included in the operating DC power supply group is stored. When the total supply power is obtained, 11 reads the DC power supply of the operating DC power supply group stored in correspondence with the obtained total supply power from the control table of the storage unit 13.
Then, the operation control unit 12 turns on the output terminal switch connected to the output terminal of the DC power supplied from the operating DC power supply group selection unit 11 and is connected to the output terminal of the other DC power supply. Switch control for turning off the output end switch is performed.

Hereinafter, the operation of the operation control of the DC power supply that minimizes the total loss of the power feeding system in the second embodiment will be described with reference to FIG. FIG. 6 is a flowchart illustrating an operation example of the operation control of the DC power supply that minimizes the total loss of the power supply system of the output-end switch control unit 1 in the power supply system.
Step S1:
When the power supply system is activated, the DC power sources RF1, RF2, and RF3 start power conversion from commercial AC power to DC power.
However, the DC power supplies RF1, RF2, and RF3 start the power conversion operation, but the output power is 0 because each of the output end switches RFSW1, RFSW2, and RFSW3 connected to the respective output ends is in an OFF state. And it is not in operation.

Step S2:
Next, when the output end switch control unit 1 is activated, the operation control unit 12 turns on all of the output end switches RFSW1, RFSW2, and RFSW3.
At this time, the operation control unit 12 writes and stores the output end switch name (or switch identification information) in the on state in the switch state table in the storage unit 13.
As a result, each of the DC power sources RF1, RF2, and RF3 enters an operating state in which output power is output to the wirings S11, S22, and S33, respectively, and balances all the supplied power to the loads L1, L2, and L3. Output.

Step S3:
It is notified that the power supply system is in a state in which power can be supplied, and each of the notified users activates the loads L1, L2, and L3.

Step S4:
The operating DC power supply group selection unit 11 reads the current value IL1 flowing through the input terminal of the load L1 output from the detection unit D1.
In addition, the operating DC power supply group selection unit 11 reads the current value IL2 output from the detection unit D2 and flowing through the input terminal of the load L2.
Similarly, the operating DC power supply group selection unit 11 reads the current value IL2 output from the detection unit D3 and flowing to the load L3 input terminal.
Since the operating DC power supply group selection unit 11 has read the detection results from all of the detection units D1, D2, and D3, the process proceeds to step S5.
Here, the voltage value V at the input ends of the loads L1, L2, and L3 is stored as 400 V in the storage unit inside the operating DC power supply group selection unit 11.

Step S5:
The operating DC power supply group selection unit 11 adds the current values IL1, IL2, and IL3 obtained as measurement results, multiplies the addition result by the voltage value V, and obtains (IL1 + IL2 + IL3) × V of the multiplication result as the total supply power (load Total capacity) P is written and stored in the internal storage unit.
Then, the operating DC power supply group selection unit 11 resets the internal timer and advances the process to step S6.

Step S6:
The operating DC power supply group selection unit 11 starts an internal timer and starts a counting operation.
Then, the operating DC power supply group selection unit 11 advances the process to step S7.

Step S7:
The operating DC power supply group selection unit 11 compares the count value of the timer with the set value stored in the internal storage unit, and determines whether or not the count value exceeds the set value. This set value is a measurement cycle for measuring changes in the total supply power due to load fluctuations of the loads L1, L2, and L3, and is appropriately set by actually measuring the load fluctuation periods of the loads L1, L2, and L3.
At this time, if the count value exceeds the set value, the operating DC power supply group selection unit 11 advances the process to step S8, and if the count value does not exceed the set value, advances the process to step S7.

Step S8:
Next, the operating DC power supply group selection unit 11 reads the current value IL1 flowing through the input terminal of the load L1 output from the detection unit D1.
In addition, the operating DC power supply group selection unit 11 reads the current value IL2 output from the detection unit D2 and flowing through the input terminal of the load L2.
Similarly, the operating DC power supply group selection unit 11 reads the current value IL2 output from the detection unit D3 and flowing to the load L3 input terminal.
Since the operating DC power supply group selection unit 11 has read the detection results from all of the detection units D1, D2, and D3, the process proceeds to step S9.

Step S9:
Next, the operating DC power supply group selection unit 11 adds the current values IL1, IL2, and IL3 obtained as measurement results, multiplies the addition result by the voltage value V, calculates (IL1 + IL2 + IL3) × V, and supplies all the supplied power. (Total load capacity) Pn.
Then, the operating DC power supply group selection unit 11 advances the process to step S10.

Step S10:
After calculating the total supply power Pn, the operating DC power supply group selection unit 11 multiplies the total supply power P by a predetermined first coefficient. This predetermined first coefficient is for detecting how much the total supply power Pn has changed and increased from the previously measured total supply power P, and experimentally measured the fluctuations of the loads L1, L2, and L3. However, it is set appropriately according to the accuracy of control.
Here, the operating DC power supply group selection unit 11 multiplies the total supply power P by the first coefficient 1.1, for example. That is, the operating DC power supply group selection unit 11 can detect whether or not the total supply power Pn has fluctuated from the previously measured total supply power P and increased by 10% or more.
Then, the operating DC power supply group selection unit 11 compares the total supply power Pn and the total supply power P × 1.1, and determines whether or not the total supply power Pn exceeds the total supply power P × 1.1. Make a decision.
At this time, if the total supply power Pn exceeds the total supply power P × 1.1, the operating DC power supply group selection unit 11 advances the process to step S13, while the total supply power Pn is the total supply power P ×. If 1.1 is not exceeded, the process proceeds to step S11.

Step S11:
Next, the operating DC power supply group selection unit 11 multiplies the total supply power P by a predetermined second coefficient. This predetermined second coefficient is used to detect how much the total supply power Pn has changed and decreased from the previously measured total supply power P, and the fluctuations of the loads L1, L2, and L3 are measured by experiments. However, it is set appropriately according to the accuracy of control.
Here, the operating DC power supply group selection unit 11 multiplies the total power supply P by the second coefficient 0.9, for example. That is, the operating DC power supply group selection unit 11 can detect whether or not the total supply power Pn has fluctuated from the total supply power P measured last time and has decreased by 10% or more.
Then, the operating DC power supply group selection unit 11 compares the total supply power Pn and the total supply power P × 0.9, and determines whether or not the total supply power Pn is less than the total supply power P × 0.9. Make a decision.
At this time, if the total supply power Pn is less than the total supply power P × 0.9, the operating DC power supply group selection unit 11 advances the process to step S13, while the total supply power Pn is the total supply power P × 0. If it is not less than 9, the process proceeds to step S12.

Step S12:
Since the total supply power Pn, which is the sum of the load capacities of the loads L1, L2, and L3, does not change to the total supply power P detected last time, the operation DC power supply group selection unit 11 In order to count a new measurement cycle, the internal timer is reset, and the process proceeds to step S6.

Step S13:
Next, the operating DC power supply group selection unit 11 searches the total supply power division range including the calculated total supply power Pn from the control table shown in FIG.
Then, the operating DC power supply group selection unit 11 stores the names of the output end switches connected to the DC power supplies included in the operating DC power supply group, which are stored in correspondence with the total supply power division range including the total supply power Pn. Are read from the control table shown in FIG.
After reading the output terminal switch name, the operating DC power supply group selection unit 11 advances the process to step S14.

Step S14:
Next, the operating DC power supply group selection unit 11 reads the current switch state, that is, the name of the output end switch that is currently turned on, from the switch state table of the storage unit 13.
Then, the operating DC power supply group selection unit 11 compares the output end switch name read from the switch state table with the output end switch name read from the control table, and the output end switch name read from the switch state table and the control It is determined whether or not all output terminal switch names read from the table match.
At this time, if the output terminal switch name read from the switch state table and the output terminal switch name read from the control table all match, the operating DC power supply group selection unit 11 advances the process to step S15.
On the other hand, if the output terminal switch name read from the switch state table and the output terminal switch name read from the control table do not match, the operating DC power supply group selection unit 11 advances the process to step S17.

Step S15:
Next, when the output terminal switch name read from the switch state table and the output terminal switch name read from the control table all match, the operating DC power supply group selection unit 11 needs to control the output terminal switch. Therefore, the control signal is not output to the operation control unit 12.
After the state of the output terminal switch and the current state are maintained, the operating DC power supply group selection unit 11 advances the process to step S16.

Step S16:
Next, the operating DC power supply group selection unit 11 resets an internal timer and proceeds to step S6 in order to count a new measurement cycle.

Step S17:
Next, the operating DC power supply group selection unit 11 outputs the output terminal switch name read from the control table to the operation control unit 12 together with the control information for turning on the output terminal switch, and the process proceeds to step S18.
As a result, the operation control unit 12 turns on the output end switch of the output end switch name read from the control table, and puts the DC power source connected to the output end into the operating state.

Step S18:
Next, the operating DC power supply group selection unit 11 outputs the output end switch name other than the output end switch name read from the control table to the operation control unit 12 together with the control information for turning off the output end switch. Advances to step S19.
As a result, the operation control unit 12 turns off the output end switches other than the output end switch name read from the control table, and sets the DC power source connected to the output end to the non-operating state (stopped state). ).

Step S19:
Next, the operating DC power supply group selection unit 11 newly sets the total supply power Pn as the total supply power P, writes and stores it in the internal storage unit, and advances the process to step S16.
That is, the operating DC power supply group selection unit 11 overwrites the data of the total supply power P with the total supply power Pn so as to correspond to the current switch state, and sets it as a new total supply power P.

  According to the present embodiment, the change in the total supply power Pn obtained for each measurement cycle is compared with the total supply power P obtained in the previous measurement cycle, and the previous total supply exceeds the ratio set by the total supply power Pn. When it fluctuates with respect to the power P, the on / off state of the output terminal switch corresponding to the total supply power Pn is read from the control table showing the on / off state of the output terminal switch set for every total power supply, and the operation control unit 12 Since the output end switch is controlled, it is not necessary to perform calculation for minimizing the total loss in the power feeding system, and operation control of the DC power sources RF1, RF2, and RF3 can be performed at high speed.

<Third Embodiment>
The third embodiment of the present invention will be described below with reference to the drawings. The configuration of the power supply system according to the third embodiment is the same as that of the first embodiment shown in FIG.
As in the second embodiment described above, when the loads L1, L2, and L3 do not fluctuate in the same manner, but the fluctuations in the loads L1, L2, and L3 are different, the control table is changed to the load L1, L2, and L3. An operating DC power supply group is set for each combination of load capacities.
FIG. 7 shows a load capacity combination which is a combination of numerical values of the load capacities of the loads L1, L2 and L3, and names of output terminal switches connected to the output terminals of the DC power supply operated by the active DC power supply group in the load capacity combination. It is a figure of the table which shows a response | compatibility.

  In FIG. 7, the range between the minimum value and the maximum value of the load capacity of each of the loads L1, L2, and L3, that is, 0 kW to 100 kW is divided into 10 kW divided ranges. It is divided into 10 kW, 11 kW to 20 kW, 21 kW to 30 kW, 31 kW to 40 kW, 41 kW to 50 kW, 51 kW to 60 kW, 61 kW to 70 kW, 71 kW to 80 kW, 81 kW to 90 kW, 91 kW to 100 kW. The power values of the center of each division range are 5 kW, 15 kW, 25 kW, 35 kW, 45 kW, 55 kW, 65 kW, 75 kW, 85 kW, and 95 kW, and the load capacity combination of the loads L1, L2, and L3. The total loss is calculated, and for each load capacity combination of the loads L1, L2, and L3, an operating DC power supply group that minimizes the total loss of the power feeding system is obtained. The calculation of the operating DC power supply group may be performed by the operating DC power supply group selection unit 11 or may be performed using an external computer. When using an external computer, the storage unit 13 does not need to store a resistance value table and a conversion loss table, and stores a control table described below in advance.

Hereinafter, the operation of the operation control of the DC power supply that minimizes the total loss of the power feeding system in the third embodiment will be described with reference to FIG. FIG. 8 is a flowchart illustrating an operation example of the operation control of the DC power supply that minimizes the total loss of the power supply system of the output end switch control unit 1 in the power supply system.
Steps S1 to S4 are the same as those in the second embodiment, and a description thereof will be omitted. In step S4, the operating DC power supply group selection unit 11 advances the process to step S25 after the predetermined operation is completed.
Step S25:
The operating DC power supply group selection unit 11 multiplies the current values IL1, IL2, and IL3 obtained as measurement results by the voltage values V to calculate power values V × IL1, V × IL2, and V × IL3, and loads Assume that the load capacities (supply power) P1, P2, and P3 of L1, L2, and L3, respectively.
Then, the operating DC power supply group selection unit 11 advances the process to step S6.

Steps S6 to S8 are the same as those in the second embodiment, and a description thereof will be omitted. In step S8, the operating DC power supply group selection unit 11 advances the process to step S29 after the predetermined operation is completed.
Step S29:
The operating DC power supply group selection unit 11 multiplies the current values IL1, IL2, and IL3 obtained as measurement results by the voltage values V to calculate power values V × IL1, V × IL2, and V × IL3, and loads The load capacities (supply power) Pn1, Pn2, and Pn3 of L1, L2, and L3 are assumed.
Then, the operating DC power supply group selection unit 11 advances the process to step S20.

Step S20:
After calculating the load capacities Pn1, Pn2, and Pn3 of the loads L1, L2, and L3, the operating DC power supply group selection unit 11 sets a predetermined third coefficient for each of the load capacities P1, P2, and P3. Multiply. The predetermined third coefficient is for detecting how much the amount of electric power fluctuated and increased from the previously measured load capacities P1, P2, and P3 of the load capacities Pn1, Pn2, and Pn3. , L2 and L3 are measured by experiment, and are set as appropriate according to the accuracy of control.
Here, the operating DC power supply group selection unit 11 multiplies each of the load capacities P1, P2, and P3 by a third coefficient 1.1, for example. That is, the operating DC power supply group selection unit 11 detects whether each of the load capacities Pn1, Pn2, and Pn3 has fluctuated from the previously measured load capacities P1, P2, and P3 and increased by 10% or more. It can be performed.
Then, the operating DC power supply group selection unit 11 compares the load capacity Pn1 with the load capacity supply power P1 × 1.1, and determines whether or not the load capacity Pn1 exceeds the load capacity P1 × 1.1. Do.
Further, the operating DC power supply group selection unit 11 compares the load capacity Pn2 with the load capacity supply power P2 × 1.1, and determines whether or not the load capacity Pn2 exceeds the load capacity P2 × 1.1. Do.
Similarly, the operating DC power supply group selection unit 11 compares the load capacity Pn3 with the load capacity supply power P3 × 1.1, and determines whether or not the load capacity Pn3 exceeds the load capacity P3 × 1.1. I do.
At this time, if any one of Pn1> P1 × 1.1, Pn> Pn2 × 1.1, and Pn3> P3 × 1.1 holds, the operating DC power supply group selection unit 11 advances the process to step S23. On the other hand, if none of Pn1> P1 × 1.1, Pn> Pn2 × 1.1, and Pn3> P3 × 1.1 holds, the following processing is performed.

When none of Pn1> P1 × 1.1, Pn> Pn2 × 1.1, and Pn3> P3 × 1.1 holds, the operating DC power supply group selection unit 11 determines each of the load capacities P1, P2, and P3. And multiply each by a predetermined fourth coefficient. The predetermined fourth coefficient is for detecting how much the amount of electric power has fluctuated and decreased from the previously measured load capacities P1, P2, P3 of the load capacities Pn1, Pn2, Pn3, and the load L1 , L2 and L3 are measured by experiment, and are set as appropriate according to the accuracy of control.
Here, the operating DC power supply group selection unit 11 multiplies each of the load capacities P1, P2, and P3 by a fourth coefficient 0.9, for example. That is, the operating DC power supply group selection unit 11 detects whether or not each of the load capacities Pn1, Pn2, and Pn3 has fluctuated from the previously measured load capacities P1, P2, and P3 and decreased by 10% or more. It can be performed.
Then, the operating DC power supply group selection unit 11 compares the load capacity Pn1 with the load capacity supply power P1 × 0.9, and determines whether or not the load capacity Pn1 is less than the load capacity P1 × 0.9. Do.
Further, the operating DC power supply group selection unit 11 compares the load capacity Pn2 with the load capacity supply power P2 × 0.9, and determines whether or not the load capacity Pn2 is less than the load capacity P2 × 0.9. Do.
Similarly, the operating DC power supply group selection unit 11 compares the load capacity Pn3 with the load capacity supply power P3 × 0.9, and determines whether or not the load capacity Pn3 is less than the load capacity P3 × 0.9. I do.
At this time, if any one of Pn1 <P1 × 0.9, Pn <Pn2 × 0.9, and Pn3 <P3 × 0.9 holds, the operating DC power supply group selection unit 11 advances the process to step S23. On the other hand, if none of Pn1> P1 × 1.1, Pn> Pn2 × 1.1, and Pn3> P3 × 1.1 holds, the process proceeds to step S12.

Steps S6 to S8 are the same as those in the second embodiment, and a description thereof will be omitted.
Step S23:
Next, the operating DC power supply group selection unit 11 includes the load capacities Pn1, Pn2, and Pn3 in the calculated load capacity combination from the control table shown in FIG. 8 of the storage unit 13, and includes the loads L1, L2, and L3. The combination of each load capacity division range is searched.
The operating DC power supply group selection unit 11 stores the output end switches corresponding to the combinations of the load capacity division ranges of the loads L1, L2, and L3, including the load capacitors Pn1, Pn2, and Pn3. The name (name of the output terminal switch connected to the DC power supply included in the operating DC power supply group) is read from the control table shown in FIG.
After reading the output terminal switch name, the operating DC power supply group selection unit 11 advances the process to step S14.

Steps S14 to S18 are the same as those in the second embodiment, and a description thereof will be omitted. In step S18, the operating DC power supply group selection unit 11 advances the process to step S29 after the predetermined operation is completed.
Step S29:
Next, the operating DC power supply group selection unit 11 newly sets each of the load capacities Pn1, Pn2, and Pn3 as the load capacities P1, P2, and P3, writes them in the internal storage unit, and stores the processes, and the process goes to step S16. Proceed.
In other words, the operating DC power supply group selection unit 11 overwrites the data of the load capacities P1, P2, and P3 with the new load capacities P1, P2, P3 in order to make each of the load capacities Pn1, Pn2, Pn3 correspond to the current switch state. Set as P2 and P3.

  According to the present embodiment, the load capacities Pn1, Pn2, and Pn3 of the loads L1, L2, and L3 obtained at regular intervals are compared with the load capacities P1, P2, and P3 obtained at the previous measurement cycle, and the load capacities are compared. When any of Pn1, P2, and P3 fluctuates with respect to the previous load capacity P1, P2, and P3 over a set ratio, the ON / OFF state of the output end switch set for each combination of the load capacities Pn1, Pn2, and Pn3 Is read from the control table indicated by the load capacity Pn1, Pn2, and Pn3, and the operation control unit 12 controls the output end switch so that the total loss in the power feeding system is minimized. It is not necessary to perform the calculation to perform the operation control of the DC power sources RF1, RF2, and RF3 at high speed.

<Fourth Embodiment>
Hereinafter, a fourth embodiment of the present invention will be described with reference to the drawings. The configuration of the power supply system according to the fourth embodiment is the same as that of the first embodiment shown in FIG.
The fourth embodiment is different from the third embodiment in that the DC power sources RF1, RF2 that minimize the total loss of the power feeding system in consideration of the failure of the rectifying unit that constitutes each of the DC power sources RF1, RF2, and RF3. , The operation control of each of the RF3 is performed.

Next, FIG. 9 is a diagram showing a configuration example of the DC power supply RF1 in FIG. The DC power supplies RF2 and RF3 have the same configuration.
As shown in FIG. 9, the DC power supply RF1 includes a plurality of rectification units, for example, rectification units RF1_1, RF1_2,..., RF1_N (N is an integer of 1 or more).
When the power capacity of the DC power is PPW, each of the rectifying units RF1_1, RF1_2,..., RF1_N outputs PPW / N DC power.
The output of the rectifier unit RF1_1 is connected to the anode of the diode DI1_1, and the output is connected to the output terminal of the DC power supply RF1 via the diode DI1_1.
The diode DI1_1 has a cathode connected to the output terminal of the DC power supply RF1.
The output of the rectifying unit RF1_2 is connected to the anode of the diode DI1_2, and the output is connected to the output terminal of the DC power supply RF1 via the diode DI1_2.
The diode DI1_2 has a cathode connected to the output terminal of the DC power supply RF1.
The output of the rectifying unit RF1_N is connected to the anode of the diode DI1_N, and the output is connected to the output terminal of the DC power supply RF1 via the diode DI1_N.
The diode DI1_N has a cathode connected to the output terminal of the DC power supply RF1.

The control unit RF1C detects the operating state of each of the rectifying units RF1_1, RF1_2,..., RF1_N, that is, detects a rectifying unit that does not output DC power due to a failure or the like, and controls the number of rectifying units that are operating as output end switch control It transmits to the part 1 as drive information with the power supply identification information which is its own identification information.
Here, when M (an integer of 1 or more, N ≧ M) of the rectifying units RF1_1, RF1_2,..., RF1_N fails, the output capacity of the DC power supply RF1 is PPW × ((N−M) / N) Doubled.
Further, the DC power sources RF2 and RF3 have the same configuration as the DC power source RF1 described above.

  For example, it is assumed that each of the direct current power supply RF1 to the direct current power supply RF3 includes four rectification units. Assuming that one rectifier unit in the DC power supply RF1 has failed, when the output end switches RFSW1 and RFSW2 are in the ON state, the DC power supplies RF1 and RF2 operate in equilibrium, but the output power of the DC power supply RF2 is 60 kW. Then, the output power of the DC power supply RF1 is 3/4 of 45 kW of 60 kW. At this time, the conversion loss at each output power of the DC power supply RF1 is also 3/4.

Therefore, when the rectification unit fails in each of the DC power sources RF1, RF2, and RF3, the capacity of the output power of each of the DC power sources RF1, RF2, and RF3 changes. For this reason, it is necessary to create a control table in the second and third embodiments so as to cope with a failure of the rectification unit in the DC power sources RF1, RF2, and RF3.
That is, each of the DC power supply groups that can correspond to the output power and conversion loss when the rectifier unit fails, and that the total loss in the power feeding system can satisfy the total supply power for each combination of the total supply power or the load capacity of each load. Calculate against Then, the DC power supply group with the minimum calculated loss is selected as the operating DC power supply group, and the total supply power (second embodiment) or the combination of the load capacities of the loads (third embodiment) Then, a control table with the selected operating DC power supply group is created. Then, the control table is written and stored in the storage unit 13 in advance.
The calculation of the total loss in this creation may be executed by the operating DC power supply group selection unit 11 or may be performed by an external computer.

In addition, this control table is created for each combination of the number that can be driven without failure of the rectification unit in each DC power source. For example, when each of the DC power supplies RF1, RF2, and RF3 is composed of four rectification units, the number of driveable rectification units that are not broken down is five types of 0, 1, 2, 3, and 4. . For this reason, each of the DC power sources RF1, RF2, and RF3 has five types of output power capacity states, so that 5 × 5 × 5 = 125 control tables are generated.
Next, the operating DC power supply group selection unit 11 uses the drive information transmitted from each of the DC power supplies RF1, RF2, and RF3 to combine the number of faults of the rectification unit in each of the DC power supplies RF1, RF2, and RF3 (output power Based on the combination of capacity states, the control table stored in the storage unit 13 is detected.

The operating DC power supply group selection unit 11 is stored in correspondence with the total supply power (second embodiment) or the combination of load capacities of the loads (third embodiment) from the detected control table. The active DC power supply group is searched, and the search result is output to the operation control unit 12.
Since the operation other than using the control table corresponding to the number of failures of the rectification unit in the DC power supply is the same as that in the second or third embodiment, the description thereof is omitted.

Further, in the first embodiment, the conversion loss table shown in FIG. 2 is configured as a table indicating the correspondence between output power and loss (conversion loss) for each number of rectifier units that can be driven in a DC power supply unit. Thus, it is written and stored in the storage unit 13 in advance.
The operating DC power supply group selection unit 11 obtains the number of driveable rectifier units in each of the DC power supplies RF1, RF2, and RF3 based on the drive information transmitted from each of the DC power supplies RF1, RF2, and RF3.
Next, the operating DC power supply group selection unit 11 reads the current value I from each of the detection units D1, D2, and D3 for each measurement cycle, calculates the load capacity of each of the loads L1, L2, and L3. When extracting a DC power supply group corresponding to the capacity, output power corresponding to the number of driveable rectifier units of each DC power supply and conversion loss at that time are read from the conversion loss table.

Then, the operating DC power supply group selection unit 11 extracts from the DC power supplies RF1, RF2, and RF3 a DC power supply group consisting of a DC power supply or a combination of DC power supplies that makes up the total supply power.
Next, the operating DC power supply group selection unit 11 performs the same calculation as that in the first embodiment, calculates the total loss of each DC power supply group, and sets the DC power supply group having the minimum total loss as the operating DC power supply group. Select as.
After selecting the operating DC power supply group, the operating DC power supply group selection unit 11 outputs the selected operating DC power supply group to the operation control unit 12.
Thereby, the operation control unit 12 sets the output terminal switch corresponding to the DC power source included in the operating DC power source group to the ON state, and sets the output terminal switch corresponding to the DC power source not included in the operating DC power source group to the OFF state. To do. As a result, the DC power supply is in an operating state when the connected output terminal switch is turned on.

In each of the first to fourth embodiments of the present invention described above, a plurality of loads, that is, the loads L1, L2, and L3 are associated with the power value of the load capacity that is stably consumed for the longest time. DC power supply RF1, RF1, RF2, L2 Wiring (S11, S22, S33, SN1N2, SN2N3) for each of the loads L1, L2, and L3 is formed from RF2 and RF3.
With this configuration, in any of the first, second, third, and fourth embodiments, the calculation load is reduced by reducing the number of times of selecting the operating DC power supply group, and the output end switch control unit The power consumption in 1 can be reduced.

In each of the first to fourth embodiments, the power feeding system is configured by three DC power sources RF1, RF1, and RF3 and three loads L1, L2, and L3. However, the configuration is not limited thereto. In other words, it corresponds to the configuration from a plurality of DC power supplies and a plurality of loads. For example, in each of the first to fourth embodiments, one load is connected to each of the nodes N1, N2, and N3, but a plurality of loads may be connected to each node. Even in this case, the value of the current flowing through each node, that is, the calculation of the total loss due to the power supplied via each node is the same as the method already described. That is, a detection unit is provided for each of a plurality of loads connected to each node, and the active DC power supply group selection unit 11 receives a current value (or current value and voltage value) from the detection unit connected to each load. , The load capacity of each load is calculated, the load capacity is aggregated for each node, and the total loss is calculated on the assumption that one load is connected to each node.
In each of the first to fourth embodiments, the parasitic resistances of the wiring lines SN1N2 and SN2N3, which are connection lines, are ignored, and the wirings S11, S22, and S33 connected to the DC power sources RF1, RF2, and RF3, respectively. The resistance value loss may be calculated in consideration of only the parasitic resistance, and the total loss may be calculated.

In the first embodiment, when adding a load for providing a new load, when adding a DC power supply for providing a new DC power source, when removing a load for removing a current load, and for a DC power source for removing a current DC power source At the time of removal, the resistance value table and the conversion loss table stored in the storage unit 13 are rewritten in correspondence with the new wiring and the DC power supply.
On the other hand, in the second to fourth embodiments, when adding a load that provides a new load, when adding a DC power source that provides a new DC power source, when removing a load that removes an existing load, When the DC power source is removed, a new control table is created.
The creation of this control table is based on the configuration of the power supply system and calculates the total loss already described by the operating DC power supply group selection unit 11 from the load capacity and the output power capacity of the DC power supply, and the operating status of each load. On the other hand, it may be automatically generated by selecting an operating DC power supply group that minimizes the total loss.
Then, the operating DC power supply group selection unit 11 writes and stores the created control table in the storage unit 13.

  Further, a program for realizing the function of the output terminal switch control unit 1 in FIG. 1 is recorded on a computer-readable recording medium, and the program recorded on the recording medium is read into a computer system and executed. Operation control of the DC power supply may be performed. Here, the “computer system” includes an OS and hardware such as peripheral devices.

Further, the “computer system” includes a homepage providing environment (or display environment) if a WWW system is used.
The “computer-readable recording medium” refers to a storage device such as a flexible medium, a magneto-optical disk, a portable medium such as a ROM and a CD-ROM, and a hard disk incorporated in a computer system. Furthermore, the “computer-readable recording medium” dynamically holds a program for a short time like a communication line when transmitting a program via a network such as the Internet or a communication line such as a telephone line. In this case, a volatile memory in a computer system serving as a server or a client in that case, and a program that holds a program for a certain period of time are also included. The program may be a program for realizing a part of the functions described above, and may be a program capable of realizing the functions described above in combination with a program already recorded in a computer system.

  The embodiment of the present invention has been described in detail with reference to the drawings. However, the specific configuration is not limited to this embodiment, and includes design and the like within a scope not departing from the gist of the present invention.

DESCRIPTION OF SYMBOLS 1 ... Output end switch control part 11 ... Active DC power supply group selection part 12 ... Operation control part 13 ... Memory | storage part BAT1, BAT2, BAT3 ... Battery D1, D2, D3 ... Detection part L1, L2, L3 ... Load R1N1, R2N2, R3N3, RN1N2, Rn2N3, R1, R2, R3 ... Resistance RF1, RF2, RF3 ... DC power supply RFSW1, RFSW2, RFSW3 ... Output end switch S1, S2, S3, S11, S22, S33, SN1N2, SN2N3 ... Wiring

Claims (7)

A power supply system that supplies DC power to a plurality of loads,
A plurality of DC power sources for converting AC power to DC power;
An output end switch connected to each output end of the DC power supply;
A first wiring provided for each of the output end switches and having one end connected to the output end switch;
A connection line provided between the other ends of the first wiring;
A second wiring having one end connected to an intersection of the first wiring and the connection line and the other end connected to the load;
A detection unit for detecting an operating state of the load;
An operating DC power supply group that is a combination of the DC power supply or a combination of the DC power supplies that minimizes the total loss that is the sum of the resistance loss due to the resistance of the first wiring and the conversion loss in the power conversion is the plurality of DC power supplies. An operating DC power supply group selection unit to select from,
An operation control unit configured to supply the DC power from the DC power source included in the operating DC power supply group to the load connected to the output end switch by turning on the output end switch;
Stored is a control table in which load capacity combinations, which are combinations of load capacities supplied to each of the loads, and the operating DC power supply group capable of supplying all supply power with a minimum total loss are stored. A storage unit;
With
The operating DC power supply group selection unit is
A direct current that is a combination of the direct current power supply or the direct current power supply that obtains the total supply power that is the sum of the load capacities that are the power supplied to the load and supplies the power necessary to supply the total supply power When a power supply group is extracted and a DC power supply group having the smallest total loss among the DC power supply groups is selected as the operating DC power supply group, it corresponds to the load capacity of the load detected by each of the detection units. Extracting the load capacity combination to be selected, and selecting the operating DC power supply group having the minimum total loss for the load capacity combination from the control table;
The operation control unit is
The power supply system, wherein the output terminal switch of the DC power source included in the operating DC power source group selected by the operating DC power source group selection unit is turned on. The DC power supply is composed of a rectification unit that is connected in parallel to the output end and converts AC power into DC power,
The DC power supply outputs operation information indicating the number of operations of the rectification unit to the operating DC power supply group selection unit,
The operating DC power supply group selection unit calculates output power of the DC power supply at the number of operating rectifier units as output power of the DC power supply, extracts the DC power supply group based on the output power, and extracts the extracted DC power supply For each group, the conversion loss of the DC power supply is obtained from the output power of the DC power supply at the number of operating rectifier units, the total loss is calculated from the conversion loss and the resistance loss, and the DC power supply group The power supply system according to claim 1, wherein a DC power supply group having a minimum total loss is selected as the active DC power supply group. The operating DC power supply group selection unit is
At fixed intervals, the calculated total power supplied, the absolute value of the difference between the calculated total feed power required for full power supply and immediately prior is, if it exceeds a preset threshold, the calculated pre Kimake load The power supply system according to claim 1 or 2, wherein the operating DC power supply group corresponding to a capacity combination is newly selected from the control table. The detection unit is provided between the load and the other end of the second wiring, and detects a current value supplied to the load according to an operating state of the load,
The operating DC power supply group selection unit calculates the load capacity for each load from the current value and a voltage at which the DC power supply supplies DC power to the load. The power feeding system according to claim 3 . The operating DC power supply group selection unit, according to any one of claims 1 to 4, characterized in that to calculate the resistance losses using the resistance of the resistor and the connecting line of the first wiring Power supply system. An output end switch control device that controls supply of DC power to a plurality of loads via wiring from a plurality of DC power supplies,
An output end switch interposed between each output end of the DC power supply and a wiring connected to the load;
A detection unit for detecting an operating state of the load;
The DC power source or a combination of the DC power sources that minimizes the total loss, which is the sum of the resistance loss due to the resistance of the wiring in each operating state of the load and the conversion loss in power conversion for converting AC power into DC power An operating DC power supply group selection unit that selects an operating DC power supply group that is the plurality of DC power supplies,
An operation control unit that operates the DC power source included in the operating DC power source group by turning on the output end switch; a load capacity combination that is a combination of load capacities supplied to each of the loads; A storage unit storing a control table in which the operating DC power supply group capable of supplying supply power with a minimum total loss is shown correspondingly;
With
The operating DC power supply group selection unit is
A direct current that is a combination of the direct current power supply or the direct current power supply that obtains the total supply power that is the sum of the load capacities that are the power supplied to the load and supplies the power necessary to supply the total supply power When a power supply group is extracted and a DC power supply group having the smallest total loss among the DC power supply groups is selected as the operating DC power supply group, it corresponds to the load capacity of the load detected by each of the detection units. Extracting the load capacity combination to be selected, and selecting the operating DC power supply group having the minimum total loss for the load capacity combination from the control table;
The operation control unit is
The output terminal switch control device, wherein the output terminal switch of the DC power source included in the operating DC power source group selected by the operating DC power source group selecting unit is operated while being on. It is a method of operating an output end switch control device that controls the supply of DC power to a plurality of loads via wires from a plurality of DC power sources,
An output end switch interposed between each output end of the DC power supply and a wiring connected to the load;
A process in which the detection unit detects an operating state of the load;
The operating DC power supply group selection unit minimizes the total loss that is the sum of the resistance loss due to the resistance of the wiring in each operating state of the load and the conversion loss in power conversion for converting AC power into DC power. Selecting a DC power source or an operating DC power source group that is a combination of the DC power sources from the plurality of DC power sources;
The operation control unit operates the DC power supply included in the operating DC power supply group by turning on an output terminal switch inserted between each output terminal of the DC power supply and the wiring connected to the load. And a process of making
The operating DC power supply group selection unit is
Calculated on the total power supplied Ru total der the load capacitance Ru power der supplied to the load, are the DC power supply or a combination of the DC power source for supplying power necessary to supply the entire power supply When a DC power supply group is extracted and a DC power supply group having the smallest total loss among the DC power supply groups is selected as the operating DC power supply group, the load capacity of the load detected by each of the detection units is selected. A corresponding load capacity combination that is a combination of load capacities supplied to each of the loads is extracted, and the operating DC power supply group having the minimum total loss for the load capacity combination is supplied to each of the loads. The load capacity combination, which is a combination of load capacities, and the operating DC power supply group that can supply all the supplied power with the minimum total loss are shown correspondingly. Select from the control table,
The operation control unit is
The power supply method, wherein the output terminal switch of the DC power supply included in the operating DC power supply group selected by the operating DC power supply group selection unit is turned on.

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