JP6719077B2 - Power supply system and its wiring resistance measuring method - Google Patents

Description

The present invention relates to a power supply system in which a plurality of power supply devices cooperate to supply power to a load, and a wiring resistance measuring method thereof.

In recent years, a power supply system in which a plurality of power supply devices including storage batteries (hereinafter also appropriately referred to as power storage devices) are connected in parallel to supply power to a load has become widespread (see, for example, Patent Document 1). A configuration in which a plurality of power storage devices are connected in parallel is a configuration that occurs when a new power storage device is retrofitted to an existing power storage device, or when power storage devices are respectively installed at distant locations.

When a plurality of power storage devices connected in parallel independently supply power to a load in a state of being disconnected from a commercial power system, all of the plurality of power storage devices are often operated by voltage control. At that time, if the wiring length from each power storage device to the load is different, the output currents of the respective power storage devices become unbalanced due to variations in wiring resistance.

JP, 2013-55826, A

In order to equalize the output currents of the plurality of power storage devices, it is conceivable to insert a correction resistor in at least one wiring between the plurality of power storage devices and the load. As a premise, it is necessary to accurately measure each wiring resistance between the plurality of power storage devices and the load.

When a plurality of power storage devices are installed in different places (for example, different floors), the final wiring length cannot be determined unless the power storage devices are actually installed and laid out. In addition to the length, the wiring resistance is affected by the environment such as temperature. Therefore, it is preferable to actually measure the wiring resistance after installation in order to obtain a more accurate wiring resistance.

The present invention has been made in view of such circumstances, and an object thereof is to provide a power supply system capable of accurately obtaining each wiring resistance in a power supply system in which a plurality of power supply devices are arbitrarily connected, and a wiring resistance measurement thereof. To provide a method.

In order to solve the above problems, a power supply system according to an aspect of the present invention includes a first power supply device, a second power supply device, and a third power supply device, and an output current of the first power supply device, A power supply system for merging an output current of a second power supply device and an output current of the third power supply device for output to the outside, the output wiring of the first power supply device and the output wiring of the second power supply device. Are connected at a first node, the output wiring of the third power supply device is connected to the first node, and a potential difference is generated between the output of the first power supply device and the output of the second power supply device. A current detection unit that detects a current flowing between the first power supply device and the second power supply device; and an output wiring of the first power supply device and the second wiring based on the detected current and the potential difference. And a calculation unit that calculates a combined resistance of the output wirings of the power supply device. The current detection unit sets the output of the first power supply device and the output of the second power supply device to the same potential, and in a state where a current flows from the third power supply device to the first power supply device and the second power supply device. A current flowing through the first power supply device and a current flowing through the second power supply device are detected, and the arithmetic unit detects the detected current flowing through the first power supply device and the detected current flowing through the second power supply device. The wiring resistance between the output terminal of the first power supply device and the first node and the wiring resistance between the output terminal of the second power supply device and the first node are calculated based on the ratio and the combined resistance.

According to the present invention, it is possible to accurately obtain each wiring resistance in a power supply system in which a plurality of power supply devices are arbitrarily connected.

It is a figure showing an example of a power supply system provided with a plurality of power supply units arbitrarily connected. It is a figure for demonstrating the basic procedure of the wiring resistance measuring method in the power supply system which concerns on embodiment of this invention. It is a figure for demonstrating the specific example 1 (state 1) of the wiring resistance measuring method in the power supply system which concerns on embodiment of this invention. It is a figure for demonstrating the specific example 1 (state 2) of the wiring resistance measuring method in the power supply system which concerns on embodiment of this invention. It is a figure for demonstrating the specific example 1 (state 3) of the wiring resistance measuring method in the power supply system which concerns on embodiment of this invention. It is a figure for demonstrating the specific example 1 (state 4) of the wiring resistance measuring method in the power supply system which concerns on embodiment of this invention. It is a figure for demonstrating the specific example 1 (state 5) of the wiring resistance measuring method in the power supply system which concerns on embodiment of this invention. It is a figure for demonstrating the modification of FIG. It is a figure for demonstrating the specific example 2 of the wiring resistance measuring method in the electric power supply system which concerns on embodiment of this invention. It is a figure for demonstrating the specific example 3 of the wiring resistance measuring method in the electric power supply system which concerns on embodiment of this invention. It is the figure which generalized the resistance measuring method using the basic procedure shown in FIG. It is a figure which shows the structural example of each power supply device. It is a figure for demonstrating the correction method of the offset error of a voltage detection circuit, and a gain error (the 1). It is a figure for demonstrating the offset error of a voltage detection circuit, and the correction method of a gain error (the 2). It is a figure which shows the structural example of the voltage detection part for improving the measurement precision of wiring resistance.

FIG. 1 is a diagram illustrating an example of a power supply system 1 including a plurality of power supply devices 10 that are arbitrarily connected. In the example shown in FIG. 1, the first power supply device 10a, the second power supply device 10b, and the third power supply device 10c are connected in parallel, and the output wirings of the first power supply device 10a, the second power supply device 10b, and the third power supply device 10c are merged. Then, the sum of these currents is supplied to the actual load 2. Although a configuration example of the power supply device 10 will be described later, the power supply device 10 includes a power storage unit and has a function of controlling output current and output voltage. Further, the power supply device 10 has a function of detecting current and voltage of its own output wiring.

In the example shown in FIG. 1, the distances from the first power supply device 10a, the second power supply device 10b, and the third power supply device 10c to the actual load 2 are different, and the wiring resistances are different. When the output voltages of the first power supply device 10a, the second power supply device 10b, and the third power supply device 10c are the same, the output current of the third power supply device 10c closest to the actual load 2 is the largest. The output current of the first power supply device 10a farthest from the actual load 2 becomes the smallest. This imbalance of the output current can be eliminated by inserting a correction resistor in the output wiring of the third power supply device 10c and the output wiring of the second power supply device 10b. As a premise, it is necessary to accurately measure the resistance value of each output wiring of the plurality of power supply devices 10a-10c.

FIG. 2 is a diagram for explaining the basic procedure of the wiring resistance measuring method in the power supply system 1 according to the embodiment of the present invention. The output wiring of the first power supply device 10a and the output wiring of the second power supply device 10b are connected at the first node N1. The wiring merged at the first node N1 is connected to the output wiring of the third power supply device 10c at the second node N2. The actual load 2 is connected to the second node N2. Hereinafter, in this configuration, a method for measuring the first wiring resistance R1 between the output terminal of the first power supply device 10a and the first node N1 and the second wiring resistance R2 between the output terminal of the second power supply device 10b and the first node N1. Will be explained.

First, the actual load 2 is set to a high impedance state, and a current flows from the first power supply device 10a (second power supply device 10b) to the second power supply device 10b (first power supply device 10a). The combined resistance (first wiring resistance R1+second wiring resistance R2) is calculated based on the current flowing at this time and the potential difference between the output of the first power supply apparatus 10a and the output of the second power supply apparatus 10b at this time. ..

Next, the output of the first power supply device 10a and the output of the second power supply device 10b are kept at the same potential, and a current is supplied from the third power supply device 10c. The current is prevented from flowing from the third power supply device 10c to the actual load 2. The actual load 2 may be separated from the second node N2. The ratio between the first wiring resistance R1 and the second wiring resistance R2 is calculated from the ratio of the current flowing from the first node N1 to the first power supply apparatus 10a and the current flowing from the first node N1 to the second power supply apparatus 10b.

Finally, the first wiring resistance R1 and the second wiring resistance R2 are calculated from the combined resistance (first wiring resistance R1+second wiring resistance R2) and the ratio of the first wiring resistance R1 and the second wiring resistance R2. By repeating these three procedures, each wiring resistance of the power supply system 1 to which a plurality of power supply devices 10 are arbitrarily connected can be measured.

FIG. 3 is a diagram for explaining a specific example 1 (state 1) of the wiring resistance measuring method in the power supply system 1 according to the embodiment of the present invention. In Specific Example 1, a wiring resistance measuring method of a power supply system 1 in which four power supply devices 10 are connected in parallel will be described. In the specific example 1, the output wiring of the first power supply device 10a and the output wiring of the second power supply device 10b are connected at the first node N1. The wiring merged at the first node N1 is connected to the output wiring of the third power supply device 10c at the second node N2. The wiring merged at the second node N2 is connected to the output wiring of the fourth power supply device 10d at the third node N3. The actual load 2 is connected to the third node N3.

First, the first wiring resistance R1 between the output terminal of the first power supply device 10a and the first node N1 and the second wiring resistance R2 between the output terminal of the second power supply device 10b and the first node N1 that are farthest from the actual load 2 are set. Ask. A potential difference is generated between the output of the first power supply device 10a and the output of the second power supply device 10b while the outputs of the third power supply device 10c and the fourth power supply device 10d and the actual load 2 are set to high impedance. As a result, a current flows between the first power supply device 10a and the second power supply device 10b. The combined resistance (first wiring resistance R1+second wiring resistance R2) is calculated based on the current flowing at this time and the potential difference between the output of the first power supply apparatus 10a and the output of the second power supply apparatus 10b at this time. ..

FIG. 4 is a diagram for explaining a specific example 1 (state 2) of the wiring resistance measuring method in the power supply system 1 according to the embodiment of the present invention. Next, the output of the first power supply device 10a and the output of the second power supply device 10b are controlled to the same potential, and the output of the third power supply device 10c or the fourth power supply device 10d is controlled to a potential different from the potential. In the example shown in FIG. 4, the output potential of the third power supply device 10c is controlled to be higher than the output potentials of the first power supply device 10a and the second power supply device 10b.

The ratio between the first wiring resistance R1 and the second wiring resistance R2 is calculated from the ratio of the current flowing from the first node N1 to the first power supply device 10a and the current flowing from the first node N1 to the second power supply device 10b. Since the voltages applied to the first wiring resistance R1 and the second wiring resistance R2 are the same, the resistance ratio can be obtained if the ratio of the currents flowing through the two is known. Even if the third wiring resistance R3 and the fourth wiring resistance R4 are unknown, the ratio between the first wiring resistance R1 and the second wiring resistance R2 can be obtained. Finally, the first wiring resistance R1 and the second wiring resistance R2 are calculated from the combined resistance (first wiring resistance R1+second wiring resistance R2) and the ratio of the first wiring resistance R1 and the second wiring resistance R2. To do.

FIG. 5 is a diagram for explaining a specific example 1 (state 3) of the wiring resistance measuring method in the power supply system 1 according to the embodiment of the present invention. Next, the third wiring resistance R3 between the output terminal of the third power supply device 10c and the second node N2 and the fifth wiring resistance R5 between the first node N1 and the second node N2, which are the furthest from the actual load 2, are obtained. .. A potential difference is generated between the output of the second power supply device 10b and the output of the third power supply device 10c in a state where the outputs of the first power supply device 10a and the fourth power supply device 10d and the actual load 2 are in high impedance. As a result, a current flows between the second power supply device 10b and the third power supply device 10c. Based on the current flowing at this time and the potential difference between the output of the second power supply device 10b and the output of the third power supply device 10c at this time, the combined resistance (combined resistance (fifth wiring resistance R5+second wiring resistance R2)). +third wiring resistance R3) is calculated.

FIG. 6 is a diagram for explaining a specific example 1 (state 4) of the wiring resistance measuring method in the power supply system 1 according to the embodiment of the present invention. Next, the output of the second power supply device 10b and the output of the third power supply device 10c are controlled to the same potential, and the output of the first power supply device 10a or the fourth power supply device 10d is controlled to a potential different from the potential. In the example shown in FIG. 6, the output potential of the fourth power supply device 10d is controlled to be higher than the output potentials of the second power supply device 10b and the third power supply device 10c.

From the ratio of the current flowing from the second node N2 to the second power supply device 10b and the current flowing from the second node N2 to the third power supply device 10c, the combined resistance (fifth wiring resistance R5+second wiring resistance R2) and the third wiring The ratio of the resistance R3 is calculated. Ratio of combined resistance (combined resistance (fifth wiring resistance R5+second wiring resistance R2)+third wiring resistance R3), combined resistance (fifth wiring resistance R5+second wiring resistance R2) and third wiring resistance R3 From this, the combined resistance (fifth wiring resistance R5+second wiring resistance R2) and third wiring resistance R3 are calculated. The fifth wiring resistance R5 is calculated by subtracting the second wiring resistance R2 (known) from the combined resistance (fifth wiring resistance R5+second wiring resistance R2).

FIG. 7: is a figure for demonstrating the specific example 1 (state 5) of the wiring resistance measuring method in the power supply system 1 which concerns on embodiment of this invention. Finally, the fourth wiring resistance R4 between the output terminal of the fourth power supply device 10d and the third node N3 and the sixth wiring resistance R6 between the second node N2 and the third node N3 are obtained. The third wiring resistance R3 and the sixth wiring resistance R6 cannot be measured by the methods described so far. This is because current cannot flow to the third node N3 from a path independent of the third wiring resistance R3 and the sixth wiring resistance R6. That is, the third node N3 does not function as a node in resistance measurement. Therefore, the third wiring resistance R3 and the sixth wiring resistance R6 are measured by another method.

When the actual load 2 is connected to the third node N3 and the first power supply device 10a, the second power supply device 10b, and the third power supply device 10c are in high impedance, the fourth power supply device 10d supplies a predetermined current at a predetermined voltage. Shed. In that state, any of the first power supply device 10a, the second power supply device 10b, and the third power supply device 10c detects the voltage of the third node N3. The fourth wiring resistance R4 is calculated based on the potential difference between the output of the fourth power supply device 10d and the third node N3 and the current passed by the fourth power supply device 10d.

Next, a potential difference is generated between the output of the third power supply device 10c and the output of the fourth power supply device 10d while the outputs of the first power supply device 10a and the second power supply device 10b and the actual load 2 are set to high impedance. As a result, a current flows between the third power supply device 10c and the fourth power supply device 10d. Based on the current flowing at this time and the potential difference between the output of the third power supply device 10c and the output of the fourth power supply device 10d at this time, the combined resistance (fourth wiring resistance R4+sixth wiring resistance R6+third wiring resistance) Calculate R3). The sixth wiring resistance R6 is calculated by subtracting the fourth wiring resistance R4 (known) and the third wiring resistance R3 (known) from the combined resistance (fourth wiring resistance R4+sixth wiring resistance R6+third wiring resistance R3). To do.

FIG. 8 is a diagram for explaining a modified example of FIG. 7. With the actual load 2 not connected to the third node N3, and with the outputs of the first power supply device 10a and the second power supply device 10b set to high impedance, the output of the third power supply device 10c and the fourth power supply device 10d. Generates a potential difference at the output of. As a result, a current flows between the third power supply device 10c and the fourth power supply device 10d. Based on the current flowing at this time and the potential difference between the output of the third power supply device 10c and the output of the fourth power supply device 10d at this time, the combined resistance (combined resistance (sixth wiring resistance R6+third wiring resistance R3)). +the fourth wiring resistance R4) is calculated.

Next, the dummy resistor 3 is connected to the third node N3. The outputs of the third power supply device 10c and the fourth power supply device 10d are controlled to have the same potential (other than the ground potential) in a state where the first power supply device 10a and the second power supply device 10b have high impedance. The combined resistance (sixth wiring resistance R6+third wiring resistance R3) and the fourth wiring are determined from the ratio of the current flowing from the third power supply apparatus 10c to the third node N3 and the current flowing from the fourth power supply apparatus 10d to the third node N3. The ratio of the resistance R4 is calculated.

From the combined resistance (combined resistance (sixth wiring resistance R6+third wiring resistance R3)+fourth wiring resistance R4) and the ratio of the combined resistance (sixth wiring resistance R6+third wiring resistance R3) and the fourth wiring resistance R4, The combined resistance (sixth wiring resistance R6+third wiring resistance R3) and the fourth wiring resistance R4 are calculated. The sixth wiring resistance R6 is calculated by subtracting the third wiring resistance R3 (known) from the combined resistance (sixth wiring resistance R6+third wiring resistance R3). This method requires the dummy resistor 3, but the fourth wiring resistance R4 and the sixth wiring resistance R6 can be measured using the basic procedure shown in FIG.

FIG. 9: is a figure for demonstrating the specific example 2 of the wiring resistance measuring method in the electric power supply system 1 which concerns on embodiment of this invention. When all the nodes (the first node N1 and the second node N2) function as nodes in resistance measurement as shown in FIG. 9, all the wiring resistances shown in FIG. 2 are used even if the dummy resistor 3 is not used. It can be measured by the procedure.

FIG. 10 is a diagram for explaining a specific example 3 of the wiring resistance measuring method in the power supply system 1 according to the embodiment of the present invention. The third specific example is a power supply system 1 in which two power supply devices 10 are connected in parallel, and the output wiring of the first power supply device 10a and the output wiring of the second power supply device 10b are connected at a first node N1. The actual load 2 is connected to N1. With the above configuration, the first wiring resistance R1 and the second wiring resistance R2 can be measured using the method described in FIG. The details will be described below.

In FIG. 10, a predetermined current is caused to flow from the second power supply device 10b at a predetermined voltage. In that state, the first power supply device 10 detects the voltage of the first node N1. The second wiring resistance R2 is calculated based on the potential difference between the output of the second power supply device 10b and the first node N1 and the current passed by the second power supply device 10b. Next, with the actual load 2 in a high impedance state, a potential difference is generated between the output of the first power supply device 10a and the output of the second power supply device 10b. As a result, a current flows between the first power supply device 10a and the second power supply device 10b. The combined resistance (first wiring resistance R1+second wiring resistance R2) is calculated based on the current flowing at this time and the potential difference between the output of the first power supply apparatus 10a and the output of the second power supply apparatus 10b at this time. .. The first wiring resistance R1 is calculated by subtracting the second wiring resistance R2 (known) from the combined resistance (first wiring resistance R1+second wiring resistance R2).

FIG. 11 is a generalized diagram of the resistance measuring method using the basic procedure shown in FIG. First, a current is passed between the first power supply device 10a and the second power supply device 10b, and the path impedance between the first power supply device 10a and the second power supply device 10b is calculated based on the potential difference between the first power supply device 10a and the second power supply device 10b ( Step 1). Next, the first power supply device 10a and the second power supply device 10b are kept at the same potential, and a current is supplied from the third power supply device 10c. From the ratio of the current flowing through the first power supply device 10a and the current flowing through the second power supply device 10b, the ratio of the impedance between the first power supply device 10a and the first node N1 and the impedance between the second power supply device 10b and the first node N1 Is calculated (step 2). From step 1 and step 2, the impedance between the first power supply apparatus 10a and the first node N1 and the impedance between the second power supply apparatus 10b and the first node N1 are calculated (step 3). Finally, the known impedance is subtracted for each path to obtain the unknown impedance (step 4).

From the above, the following four laws are derived.
(1) A node may be included in “known” and “unknown”. That is, a form in which a plurality of wiring impedances are added may be used.
(2) “Known” and “Unknown” may be mixed. For practical purposes, it should be solid.
(3) “Known” does not have to be known. There is no “known” in the pattern for measuring the wiring impedance in the immediate vicinity of the power supply device 10.
(4) Two or more "third power supply device 10c" may be provided.

FIG. 12 is a diagram showing a configuration example of each of the power supply devices 10a-10c. The first power supply device 10a includes a first power storage unit 11a, a first power conversion unit 12a, a first current detection unit 13a, a first voltage detection unit 14a, a first communication unit 15a, and a first control unit 16a. The first power storage unit 11a includes a lithium ion storage battery, a nickel hydrogen storage battery, a lead storage battery, an electric double layer capacitor, a lithium ion capacitor, and the like.

The first power conversion unit 12a converts the DC power discharged from the first power storage unit 11a into AC power and outputs the AC power to the output wiring. In addition, the first power conversion unit 12a converts AC power input from the grid (not shown) via the output wiring into DC power, and charges the first power storage unit 11a with the DC power. Specifically, the first power conversion unit 12a includes a bidirectional inverter alone or a combination of a bidirectional inverter and a bidirectional DC-DC converter. The bidirectional DC-DC converter and/or the bidirectional inverter charges/discharges the first power storage unit 11a with a constant current (CC) based on the current command value designated by the first control unit 16a. In addition, the bidirectional DC-DC converter and/or the bidirectional inverter charges/discharges the first power storage unit 11a with a constant voltage (CV) based on the voltage command value designated by the first control unit 16a.

The first current detection unit 13a detects the current flowing through its own output wiring based on the output signal of the first current sensor CTa installed in its own output wiring. The first voltage detector 14a detects the voltage between its own positive output wiring and its negative output wiring.

The first communication unit 15a communicates with the communication unit 15 of another power supply device 10. The first communication unit 15a, the second communication unit 15b, and the third communication unit 15c are connected by a communication line 20. For example, they are connected by a cable compatible with the RS-485 standard, and serial communication is performed according to a communication system compliant with the standard.

The first controller 16a includes a first calculator 17a. The configuration of the first control unit 16a can be realized by cooperation of hardware resources and software resources, or only by hardware resources. As hardware resources, analog elements, microcomputers, DSPs, ROMs, RAMs, FPGAs, and other LSIs can be used. A program such as firmware can be used as a software resource.

The second power supply device 10b and the third power supply device 10c also have the same configuration as the first power supply device 10a. Hereinafter, a method of measuring the first wiring resistance R1, the second wiring resistance R2, the third wiring resistance R3, and the fourth wiring resistance R4 will be described with the first power supply device 10a as a master machine in resistance measurement.

The first control unit 16a instructs the third control unit 16c to stop the operation via the communication line 20, and notifies the second control unit 16b to output the first output voltage. The second control unit 16b controls the second power conversion unit 12b to cause the second power conversion unit 12b to output the first output voltage. The first controller 16a controls the first power converter 12a to cause the first power converter 12a to output the second output voltage. The second output voltage is set to a value lower than the first output voltage. As a result, a current flows from the second power supply device 10b to the first power supply device 10a.

The first current detector 13a detects the current flowing through its own output wiring and outputs it to the first calculator 17a. The first calculator 17a calculates a combined resistance (first wiring resistance R1+second wiring resistance R2) based on the detected current and the differential voltage between the first output voltage and the second output voltage.

Next, the first control unit 16a notifies the second control unit 16b via the communication line 20 to output the third output voltage. The second control unit 16b controls the second power conversion unit 12b to cause the second power conversion unit 12b to output the third output voltage. The first controller 16a controls the first power converter 12a to cause the first power converter 12a to output the third output voltage. The first controller 16a notifies the third controller 16c via the communication line 20 to output the fourth output voltage. The third control unit 16c controls the third power conversion unit 12c to cause the third power conversion unit 12c to output the fourth output voltage. The fourth output voltage is set to a value higher than the third output voltage. As a result, a current flows from the third power supply device 10c to the first power supply device 10a and the second power supply device 10b.

The second current detector 13b detects the current flowing through its own output wiring and outputs it to the second controller 16b. The second communication unit 15b notifies the detected current to the first communication unit 15a via the communication line 20. The first communication unit 15a outputs the acquired current to the first calculation unit 17a. The first current detector 13a detects the current flowing through its own output wiring and outputs it to the first calculator 17a. The first calculation unit 17a calculates the ratio of the first wiring resistance R1 and the second wiring resistance R2 from the ratio of the current detected by the first current detection unit 13a and the current detected by the second current detection unit 13b. To do. The first calculator 17a calculates the first wiring resistance R1 and the second wiring resistance R2 from the combined resistance (first wiring resistance R1+second wiring resistance R2) and the ratio of the first wiring resistance R1 and the second wiring resistance R2. Calculate each.

The first control unit 16a instructs the second control unit 16b to stop the operation via the communication line 20, and notifies the third control unit 16c to flow the first output current at the fifth output voltage. The third controller 16c controls the third power converter 12c so that the third power converter 12c outputs the first output current at the fifth output voltage. With the operation of the first power conversion unit 12a stopped, the first voltage detection unit 14a detects the voltage of the second node N2 and outputs it to the first calculation unit 17a. The first calculation unit 17a calculates the third wiring resistance R3 based on the differential voltage between the fifth output voltage and the voltage of the second node N and the first output current.

The first control unit 16a instructs the second control unit 16b to stop the operation via the communication line 20, and notifies the third control unit 16c to output the sixth output voltage. The third controller 16c controls the third power converter 12c to cause the third power converter 12c to output the sixth output voltage. The first controller 16a controls the first power converter 12a so that the first power converter 12a outputs the seventh output voltage. The seventh output voltage is set to a value lower than the sixth output voltage. As a result, a current flows from the third power supply device 10c to the first power supply device 10a.

The first current detector 13a detects the current flowing through its own output wiring and outputs it to the first calculator 17a. The first calculation unit 17a, based on the detected current and the difference voltage between the sixth output voltage and the seventh output voltage, the combined resistance (third wiring resistance R3+fourth wiring resistance R4+first wiring resistance R1). To calculate. The first calculation unit 17a subtracts the third wiring resistance R3 (known) and the first wiring resistance R1 (known) from the combined resistance (third wiring resistance R3+fourth wiring resistance R4+first wiring resistance R1), The fourth wiring resistance R4 is calculated.

Through the above processing, the first wiring resistance R1 to the fourth wiring resistance R4 can be measured. Normally, the wiring resistance R1 to the wiring resistance R4 are on the order of 10 mΩ, so that the potential difference generated between the power supply devices 10 is very small. When the voltage supplied to the actual load 2 is 100/200V, the potential difference is less than 1V. In this case, a detector on the order of 100V is used for each of the voltage detection units 14a-14c of the plurality of power supply devices 10a-10c, so that if the measurement accuracy is 1%, accurate measurement of the wiring resistance becomes difficult. ..

Therefore, before measuring the wiring resistance, calibration is performed between the voltage detection units 14a-14c of the plurality of power supply devices 10a-10c. A predetermined calibration voltage Vc is output without passing a current from the first power supply device 10a of the master machine (output current=0A). If the output current is 0 A, there is no influence of the wiring resistance, so that the calibration voltage Vc is accurately applied to the output wirings of the second power supply device 10b and the third power supply device 10c. The second voltage detection unit 14b of the second power supply device 10b and the third voltage detection unit 14c of the third power supply device 10c each detect the voltage of its own output wiring. The first controller 16a notifies the second controller 16b and the third controller 16c of the calibration voltage Vc via the communication line 20. The first control unit 16a, the second control unit 16b, and the third control unit 16c may hold the same calibration voltage Vc in advance.

The second controller 16b compares the voltage detected by the second voltage detector 14b with the calibration voltage Vc. If they match, it is not necessary to correct the detected voltage value. When the two are different, the difference is held as a correction voltage value, and the correction voltage value is added to the voltage value detected by the second voltage detection unit 14b at least during the wiring resistance measurement period and output. The same applies to the third controller 16c and the third voltage detector 14c. By the above calibration, the individual difference between the voltage detection units 14a-14c can be eliminated after the installation.

The measurement error of the voltage detection circuit includes an offset error and a gain error. Therefore, more accurate calibration may be performed as follows. The master machine outputs predetermined calibration voltages Vc1 and Vc2 (Vc1≠Vc2), and the second power supply device 10b and the third power supply device 10c (slave machine) measure Vc1 and Vc2. Let the measured values be Vc1' and Vc2', respectively. It is assumed that the detection voltage shown in FIG. 13 is obtained.

Hereinafter, a method of correcting the offset error and the gain error of the voltage detection circuit will be described with reference to FIG. The gain of the voltage detection circuit is corrected so that VC2'-Vc1'=Vc2-Vc1. By doing so, the gain has an ideal characteristic. Next, the offset is corrected so that Vc1″=Vc1 (or Vc2″=Vc2). As a result, the characteristics of the ideal detection circuit are obtained. The correction method is an example, and other correction methods may be adopted.

When the measurement of the wiring resistance is completed, the voltage detection units 14a-14c are returned to the state before calibration (=at the time of factory shipment). This is because it is usually not confirmed in the shipping inspection whether the device normally operates after the calibration. When the shipping inspection is performed on the operation after the calibration, the combination of the “correction range expected in the calibration” and the “current input/output in the wiring resistance measurement” is inspected.

Next, another method for improving the wiring resistance measurement accuracy will be described.
FIG. 15 is a diagram showing a configuration example of the voltage detection unit 14 for improving the measurement accuracy of the wiring resistance. The voltage detection unit 14 includes a first differential amplification circuit 141, a second differential amplification circuit 142, and an A/D conversion circuit 143. The first differential amplifier circuit 141 is a circuit used during normal operation, and the second differential amplifier circuit 142 is a circuit used during wiring resistance measurement. The first differential amplifier circuit 141 and the second differential amplifier circuit 142 are connected in parallel to the output wiring of the power supply device 10.

The first differential amplifier circuit 141 and the second differential amplifier circuit 142 each include an operational amplifier. The operating voltage range of the operational amplifier of the first differential amplifier circuit 141 is set to a normal voltage range. The operating voltage range of the operational amplifier of the second differential amplifier circuit 142 is set to a range around the voltage (for example, 100 V) used when measuring the wiring resistance. For example, it is set in the range of 99 to 101V. The A/D conversion circuit 143 converts the analog voltage input from the first differential amplification circuit 141 or the second differential amplification circuit 142 into a digital value and outputs the digital value to the calculation unit 17.

Note that the same control as that of the circuit of FIG. 12 is performed without providing the second differential amplifier circuit 142 and changing the first differential amplifier circuit 141 and the voltage source that supplies the operating voltage to the first differential amplifier circuit 141. Can be realized by For example, by changing the resistance constant of the resistance voltage divider circuit that generates the operating voltage of the first differential amplifier circuit 141, the operating voltage range of the operational amplifier at the time of measuring the wiring resistance can be changed.

As described above, according to the present embodiment, each wiring resistance in the power supply system in which the plurality of power supply devices 10 are arbitrarily connected can be accurately measured after construction. At that time, it is possible to perform the measurement easily without the need for an external measuring instrument.

The present invention has been described above based on the embodiment. It is understood by those skilled in the art that the embodiments are exemplifications, that various modifications can be made to the combinations of the respective constituent elements and the respective processing processes, and that the modifications are within the scope of the present invention. ..

In the description of FIG. 12, an example has been described in which the first control unit 16a of the first power supply device 10a designated as the master machine comprehensively measures the wiring resistances R1 to R4. In this regard, the wiring resistances R1 to R4 may be measured by distributed processing in which the first control unit 16a, the second control unit 16b, and the third control unit 16c cooperate. Alternatively, a control device connected to the power supply devices 10a-10c by the communication line 40 may be provided separately from the power supply devices 10a-10c, and the control device may collectively measure the wiring resistances R1-R4.

Further, power supply devices 10a-10c are not limited to the configuration including power storage units 11a-11c, and may be configurations including a fuel cell. Further, the power supply device 10 including the power storage unit and the power supply device 10 including the fuel cell may coexist in the power supply system 1.

The embodiment may be specified by the following items.

[Item 1]
A first power supply device (10a), a second power supply device (10b), and a third power supply device (10c) are provided, and the output current of the first power supply device (10a) and the second power supply device (10b). A power supply system (1) for merging the output current of the third power supply device (10c) with the output current of the third power supply device (10c) and outputting the combined current to the outside.
The output wiring of the first power supply device (10a) and the output wiring of the second power supply device (10b) are connected at a first node (N1), and the first power supply device (10c) is connected to the first node (N1). The output wiring of is connected,
By generating a potential difference between the output of the first power supply device (10a) and the output of the second power supply device (10b), the first power supply device (10a) and the second power supply device (10b) are connected to each other. A current detection unit (13a, 13b) for detecting a current flowing between
An arithmetic unit (17a) for calculating a combined resistance (R1+R2) of the output wiring of the first power supply device (10a) and the output wiring of the second power supply device (10b) based on the detected current and the potential difference. ,,
The current detection unit (13a, 13b) sets the output of the first power supply device (10a) and the output of the second power supply device (10b) to the same potential, and causes the third power supply device (10c) to output the first power supply. Detecting a current flowing through the first power supply device (10a) and a current flowing through the second power supply device (10b) in a state where a current is supplied to the device (10a) and the second power supply device (10b),
The calculation unit (17a) is configured to calculate the ratio of the detected current flowing through the first power supply device (10a) to the current flowing through the second power supply device (10b) and the combined resistance (R1+R2). Wiring resistance (R1) between the output terminal of the first power supply device (10a) and the first node (N1), and wiring resistance between the output terminal of the second power supply device (10b) and the first node (N1). Calculate (R2),
A power supply system (1) characterized by the above.
According to this, after installing the power supply system (1) including the three power supply devices (10a-10c), each wiring resistance can be measured without using an external measuring device.
[Item 2]
The power supply system (1) further includes a fourth power supply device (10d),
A second node (N2) is formed on the output wiring of the third power supply device (10c), and the output wiring of the fourth power supply device (10d) is connected to the second node (N2).
The current detectors (13a, 13b, 13c) generate a potential difference between the output of the third power supply device (10c) and the output of the first or second power supply device (10a OR 10b), Detecting a current flowing between the third power supply device (10c) and the first or second power supply device (10a OR 10b),
The arithmetic unit (17a) synthesizes the output wiring of the third power supply device (10c) and the output wiring of the first or second power supply device (10a OR 10b) based on the detected current and the potential difference. Calculate the resistance (R3+R5+R2 OR R3+R5+R1),
The current detection unit (13a, 13b, 13c) sets the output of the third power supply device (10c) and the output of the first or second power supply device (10a OR 10b) to the same potential, and the fourth power supply device ( 10d) to the third power supply device (10c) and the first or second power supply device (10a OR 10b), the current flowing through the third power supply device (10c) and the first or the second power supply device (10a OR 10b). 2 The current flowing in the power supply device (10a OR 10b) is detected,
The calculation unit (17a) includes a ratio of the detected current flowing through the third power supply device (10c) to a current flowing through the first or second power supply device (10a OR 10b) and the combined resistance (R3+R5+R1 OR R3+R5+R2). ), the wiring resistance (R3) between the output terminal of the third power supply device (10c) and the second node (N2), and the output terminal of the first or second power supply device (10a OR 10b). And the wiring resistance (R5+R1 OR R5+R2) between the second node (N2) and
The calculation unit (17a) uses the wiring resistance (R5+R1 OR R5+R2) between the output terminal of the first or second power supply device (10a OR 10b) and the second node (N2) to determine the first or second power supply. A wiring resistance (R5) between the second node (N2) and the first node (N1) is obtained by subtracting a wiring resistance (R1 OR R2) between the first nodes from an output terminal of a device (10a OR 10b). To calculate,
Item 1. A power supply system (1) according to Item 1, characterized in that.
According to this, after installation of the power supply system (1) including four power supply devices (10a-10d), each wiring resistance can be measured without using an external measuring device.
[Item 3]
A third node (N3) is formed on the output wiring of the fourth power supply device (10d), and the load (2) is connected to the third node (N3).
A voltage detector (14a, 14b, 14c) for detecting the voltage of the third node (N3) in a state in which a predetermined current flows from the fourth power supply device (10d) to the load (2),
The arithmetic unit (17a) is configured to output the fourth power supply device (10d) based on a current flowing from the fourth power supply device (10d) and a potential difference between the output of the fourth power supply device (10d) and the third node (N3). The wiring resistance (R4) between the output terminal of the power supply device (10d) and the third node (N3) is calculated,
Item 2. The power supply system (1) according to Item 2, which is characterized in that.
According to this, even when the current cannot be supplied to the node on the wiring between the two power supply devices including the fourth power supply device (10d) from another path, each of the two power supply devices and each node between the nodes. Wiring resistance can be measured.
[Item 4]
A second node (N2) is formed on the output wiring of the third power supply device (10c), and a load (2) is connected to the second node (N2).
A voltage detector (14a, 14b) for detecting the voltage of the second node (2) when a predetermined current is applied from the third power supply device (10c) to the load (2),
The arithmetic unit (17a) is configured to output the third power supply device (10c) based on a current flowing from the third power supply device (10c) and a potential difference between the output of the third power supply device (10c) and the second node (N2). The wiring resistance (R3) between the output terminal of the power supply device (10c) and the second node (N2) is calculated,
Item 2. The power supply system according to Item 1, which is characterized in that
According to this, even when the current cannot be supplied to the node on the wiring between the two power supply devices including the third power supply device (10c) from another path, each of the two power supply devices and each node between the nodes. Wiring resistance can be measured.
[Item 5]
A load (2) is provided that includes a first power supply device (10a) and a second power supply device (10b), and combines an output current of the first power supply device (10a) and an output current of the second power supply device (10b). ) Output power supply system (1),
The output wiring of the first power supply device (10a) and the output wiring of the second power supply device (10b) are connected at a first node (N1), and the load (2) is connected to the first node (N1). ,
Voltage detection included in the second power supply device (10b), which detects the voltage of the first node (N1) in a state where a predetermined current flows from the first power supply device (10a) to the load (2). Part (14b),
An output terminal of the first power supply device (10a) based on a current flowing from the first power supply device (10a) and a potential difference between the output of the first power supply device (10a) and the first node (N1). And an arithmetic unit (17a, 17b) for calculating a wiring resistance (R1) between the first node (N1),
A power supply system (1) comprising:
According to this, even when the current cannot be supplied to the first node (N1) on the wiring between the first power supply device (10a) and the second power supply device (10b) from another path, the first power supply device (10a) ) And each of the second power supply device (10b) and each wiring resistance (R1, R2) between the first node (N1) can be measured.
[Item 6]
Each power supply device (10a-10c) included in the power supply system (1) includes
It has a voltage detection unit (14a-14c) for detecting the voltage of its own output wiring,
One power supply device (10a) included in the power supply system (1) outputs a predetermined voltage when no current flows,
The voltage detection units (14b, 14c) of the remaining power supply devices (10b, 10c) included in the power supply system (1) detect the voltage of its own output wiring,
The operation units (17b, 17c) of the remaining power supply devices (10b, 10c) at least the above based on the difference between the voltage detected by its own voltage detection unit (14b, 14c) and the predetermined voltage. 6. The power supply system (1) according to any one of items 1 to 5, wherein the voltage detected by its own voltage detection unit (14b, 14c) is corrected in the wiring resistance measurement period.
According to this, the influence of the individual difference of the voltage detection units (14a-14c) can be removed, and the measurement accuracy of the wiring resistance can be improved.
[Item 7]
Each power supply device (10a-10c) included in the power supply system (1) includes
It has a voltage detection unit (14a-14c) for detecting the voltage of its own output wiring,
The voltage detectors (14a-14c) are
A voltage detection circuit (141) that is normally used,
A voltage detection circuit (142) used during the wiring resistance measurement period,
The power supply system (1) according to any one of items 1 to 5, characterized by including.
According to this, by providing the voltage detection circuit (142) for measuring the wiring resistance, it is possible to improve the measurement accuracy of the wiring resistance.
[Item 8]
A first power supply device (10a), a second power supply device (10b), and a third power supply device (10c) are provided, and the output current of the first power supply device (10a) and the second power supply device (10b). Is a wiring resistance measuring method in the power supply system (1) for merging the output current of the third power supply device (10c) with the output current of the third power supply device (10c) and outputting the combined current to the outside.
The output wiring of the first power supply device (10a) and the output wiring of the second power supply device (10b) are connected at a first node (N1), and the first power supply device (10c) is connected to the first node (N1). The output wiring of is connected,
By generating a potential difference between the output of the first power supply device (10a) and the output of the second power supply device (10b), the first power supply device (10a) and the second power supply device (10b) are connected to each other. A first step of detecting a current flowing between
A second step of calculating a combined resistance of the output wiring of the first power supply device (10a) and the output wiring of the second power supply device (10b) based on the current detected in the first step and the potential difference; ,
The output of the first power supply device (10a) and the output of the second power supply device (10b) are set to the same potential, and the third power supply device (10c) to the first power supply device (10a) and the second power supply device ( 10b), a third step of detecting a current flowing through the first power supply device (10a) and a current flowing through the second power supply device (10b) in a state where a current is supplied.
The first power supply device (10a) is based on the ratio of the current flowing through the first power supply device (10a) and the current flowing through the second power supply device (10b) detected in the third step and the combined resistance. ) And the wiring resistance (R1) between the output node and the first node (N1), and the wiring resistance (R2) between the output terminal of the second power supply device (10b) and the first node (N1). The fourth step,
A wiring resistance measuring method comprising:
According to this, after the installation of the power supply system (1) including the three power supply devices (10a-10c), each wiring resistance can be measured without using an external measuring device.

1 power supply system, 2 real load, 3 dummy resistance, 10a 1st power supply device, 10b 2nd power supply device, 10c 3rd power supply device, 10d 4th power supply device, R1 1st wiring resistance, R2 2nd wiring resistance, R3 3rd wiring resistance, R4 4th wiring resistance, R5 5th wiring resistance, R6 6th wiring resistance, 11a 1st electrical storage part, 12a 1st power conversion part, 13a 1st current detection part, 14a 1st voltage detection part, 15a 1st communication part, 16a 1st control part, 17a 1st calculation part, CTa 1st current sensor, 11b 2nd electrical storage part, 12b 2nd electric power conversion part, 13b 2nd current detection part, 14b 2nd voltage detection part , 15b 2nd communication part, 16b 2nd control part, 17b 2nd calculation part, CTb 2nd current sensor, 11c 3rd storage part, 12c 3rd power converter, 13c 3rd current detection part, 14c 3rd voltage detection Section, 15c third communication section, 16c third control section, 17c third calculation section, CTc third current sensor, 20 communication line.

Claims (8)

A first power supply device, a second power supply device, and a third power supply device are provided, and an output current of the first power supply device, an output current of the second power supply device, and an output current of the third power supply device are provided. A power supply system that merges and outputs to the outside,
The output wiring of the first power supply device and the output wiring of the second power supply device are connected at a first node, and the output wiring of the third power supply device is connected to the first node,
A current detector that detects a current flowing between the first power supply device and the second power supply device by generating a potential difference between the output of the first power supply device and the output of the second power supply device. ,
An arithmetic unit that calculates a combined resistance of the output wiring of the first power supply device and the output wiring of the second power supply device based on the detected current and the potential difference;
The current detection unit sets the output of the first power supply device and the output of the second power supply device to the same potential, and in a state where a current flows from the third power supply device to the first power supply device and the second power supply device. Detecting a current flowing through the first power supply device and a current flowing through the second power supply device,
The calculation unit is configured to output the output terminal of the first power supply device and the first node based on the ratio of the detected current flowing in the first power supply device to the detected current flowing in the second power supply device and the combined resistance. And a wiring resistance between the output terminal of the second power supply device and the first node,
A power supply system characterized by the above. The power supply system further comprises a fourth power supply device,
A second node is formed on the output wiring of the third power supply device, and the output wiring of the fourth power supply device is connected to the second node,
The current detection unit generates a potential difference between the output of the third power supply device and the output of the first or second power supply device, and thereby the third power supply device and the first or second power supply device. Detects the current flowing between
The arithmetic unit calculates a combined resistance of the output wiring of the third power supply device and the output wiring of the first or second power supply device based on the detected current and the potential difference,
The current detection unit sets the output of the third power supply device and the output of the first or second power supply device to the same potential, and changes from the fourth power supply device to the third power supply device and the first or second power supply device. Detecting a current flowing through the third power supply device and a current flowing through the first or second power supply device in a state where a current is applied,
The arithmetic unit calculates the output terminal of the third power supply device and the output terminal of the third power supply device based on the ratio of the detected current flowing in the third power supply device to the current flowing in the first or second power supply device and the combined resistance. The wiring resistance between the second nodes and the wiring resistance between the output terminal of the first or second power supply device and the second node are calculated,
The calculation unit subtracts a wiring resistance between the first node from the output terminal of the first or second power supply device from a wiring resistance between the output terminal of the first or second power supply device and the second node. And calculate a wiring resistance between the second node and the first node,
The power supply system according to claim 1, wherein: A third node is formed on the output wiring of the fourth power supply device, and a load is connected to the third node,
Further comprising a voltage detection unit that detects a voltage of the third node in a state where a predetermined current is supplied from the fourth power supply device to the load,
The arithmetic unit, based on the current flowing from the fourth power supply device and the potential difference between the output of the fourth power supply device and the third node, between the output terminal of the fourth power supply device and the third node. Calculate wiring resistance,
The power supply system according to claim 2, wherein: A second node is formed on the output wiring of the third power supply device, and a load is connected to the second node;
Further comprising a voltage detection unit that detects a voltage of the second node in a state where a predetermined current flows from the third power supply device to the load,
The arithmetic unit, based on the current flowing from the third power supply device and the potential difference between the output of the third power supply device and the second node, between the output terminal of the third power supply device and the second node. Calculate wiring resistance,
The power supply system according to claim 1, wherein: A power supply system comprising a first power supply device and a second power supply device, the output current of the first power supply device and the output current of the second power supply device being combined and output to a load,
The output wiring of the first power supply device and the output wiring of the second power supply device are connected at a first node, and the load is connected to the first node,
A voltage detection unit included in the second power supply device, which detects a voltage of the first node in a state where a predetermined current flows from the first power supply device to the load;
The wiring resistance between the output terminal of the first power supply device and the first node is calculated based on the current flowing from the first power supply device and the potential difference between the output of the first power supply device and the first node. An arithmetic unit,
An electric power supply system comprising: Each power supply device included in the power supply system,
It has a voltage detector that detects the voltage of its own output wiring,
One power supply device included in the power supply system outputs a predetermined voltage when current does not flow,
The voltage detection unit of the remaining power supply device included in the power supply system detects the voltage of its own output wiring,
Based on the difference between the voltage detected by its own voltage detection unit and the predetermined voltage, the operation unit of the remaining power supply device detects it by its own voltage detection unit at least during the measurement period of the wiring resistance. The power supply system according to claim 1, wherein the voltage is corrected. Each power supply device included in the power supply system,
It has a voltage detector that detects the voltage of its own output wiring,
The voltage detection unit,
A voltage detection circuit used at normal time,
A voltage detection circuit used during the measurement period of the wiring resistance,
The power supply system according to claim 1, further comprising: A first power supply device, a second power supply device, and a third power supply device are provided, and an output current of the first power supply device, an output current of the second power supply device, and an output current of the third power supply device are provided. A method for measuring wiring resistance in a power supply system that merges and outputs to the outside,
The output wiring of the first power supply device and the output wiring of the second power supply device are connected at a first node, and the output wiring of the third power supply device is connected to the first node,
A first step of detecting a current flowing between the first power supply device and the second power supply device by generating a potential difference between the output of the first power supply device and the output of the second power supply device; ,
A second step of calculating a combined resistance of the output wiring of the first power supply device and the output wiring of the second power supply device based on the current detected in the first step and the potential difference;
The first power supply device in a state where the output of the first power supply device and the output of the second power supply device are set to the same potential and a current flows from the third power supply device to the first power supply device and the second power supply device. And a third step of detecting a current flowing through the second power supply device,
An output terminal of the first power supply device and the first node based on the combined resistance and the ratio of the current flowing in the first power supply device to the current flowing in the second power supply device detected in the third step. A fourth step of calculating a wiring resistance between the first power supply device and an output terminal of the second power supply device, and the first node;
A method for measuring wiring resistance, comprising:

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