JP3917092B2 - Power supply system and program for maintaining high reliability of DC distribution network - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a power supply system that generates power to be supplied to a plurality of power loads, and a program that causes the power supply system to function.
[0002]
[Prior art]
  2. Description of the Related Art Conventionally, there is a distributed power supply system in which power sources are distributed to generate power to be supplied to a plurality of power loads. In such a distributed power supply system, power is supplied to a plurality of power loads via a common power supply network.
[Patent Document 1]
JP-A-9-135541
[Patent Document 2]
JP-A-4-54621
[Non-Patent Document 1]
"From AC to DC. DC power supply that supports evolving IT business by realizing high reliability and low cost", Business Communication, Vol. 39, No. 7, Business Communication Co., Ltd. (2002.07.01), No. 36 From page 40
[0003]
[Problems to be solved by the invention]
The reliability of the power required for each of the plurality of loads varies depending on the electrical specifications and applications of the loads. In particular, there are many devices that require highly reliable power supply in a DC load driven by DC power. However, in the conventional distributed power supply system, power is supplied to a plurality of power loads through a common power supply network, so that when a part of the power supply stops due to a failure or the like, the power supply is stable with respect to the DC load. There was a problem that electric power could not be supplied.
[0004]
Then, an object of this invention is to provide the program which makes a power supply system which can solve said subject and a power supply system function. This object is achieved by a combination of features described in the independent claims. The dependent claims define further advantageous specific examples of the present invention.
[0005]
[Means for Solving the Problems]
In order to solve the above problem, in the first embodiment of the present invention, a power supply system that supplies power to a plurality of power loads provides AC power to an AC load among the plurality of power loads. DC power is supplied to an AC power distribution network and a DC load among multiple power loads.providePower distribution to the DC distribution network and AC distribution networkprovide,Providing power to the AC fuel cell unit and the DC distribution network,DC fuel cell unit andWithEach of the AC fuel cell unit and the DC fuel cell unit has a plurality of fuel cells, and each of the plurality of fuel cells is switched between the AC fuel cell unit and the DC fuel cell unit. When the reliability of any fuel cell included in the network changeover switch and the DC fuel cell unit is lower than the reliability of any fuel cell included in the AC fuel cell unit, the DC fuel cell unit is A fuel cell switching unit that switches a network switch so that the fuel cell is a fuel cell of an AC fuel cell unit, and the fuel cell of the AC fuel cell unit is a fuel cell of a DC fuel cell unit; The fuel cell switching unit measures the response time of each fuel cell as reliability.
[0006]
The surplus power amount in the direct current fuel cell unit may be larger than the surplus power in the alternating current fuel cell unit. In this case, each of the AC fuel cell unit and the DC fuel cell unit has a plurality of fuel cells, and the number of fuel cells included in the DC fuel cell unit is greater than the number of fuel cells included in the AC fuel cell unit. There may be many. Moreover, you may further provide the bypass circuit which supplies at least one part of the electric power which an AC fuel cell unit generates to a DC distribution network. Fuel that causes the bypass circuit to supply at least part of the power generated by the AC fuel cell unit to the DC distribution network when the power generated by the DC fuel cell unit is not sufficient for the power required by the DC load A battery switching unit may be further provided.
[0007]
Further, a DC / AC converter that converts the DC power generated by the AC fuel cell unit into AC is further provided, and the fuel cell switching unit converts the power generated by the DC fuel cell unit into the power required by the DC load. In contrast, when the operation of the DC / AC converter is stopped when it is not sufficient, at least a part of the electric power generated by the AC fuel cell unit may be supplied to the DC distribution network. Alternatively, the fuel cell switching unit further includes an AC load switch that disconnects at least a part of the AC load from the AC distribution network, and the fuel cell switching unit has insufficient power generated by the DC fuel cell unit for the power required by the DC load. In this case, at least a part of the power generated by the AC fuel cell unit may be supplied to the DC distribution network by releasing the AC load switch.
[0008]
Each of the AC fuel cell unit and the DC fuel cell unit has one or more fuel cells, and the reliability of the fuel cell included in the DC fuel cell unit is the reliability of the fuel cell included in the AC fuel cell unit. A fuel cell switching unit that switches between a fuel cell included in the direct current fuel cell unit and a fuel cell included in the alternating current fuel cell unit may be further provided.
[0009]
Each of the direct current fuel cell unit and the alternating current fuel cell unit further includes a power generation amount measuring unit that measures a cumulative power generation amount of the power generated by each of the fuel cells, and the fuel cell switching unit includes the direct current fuel cell unit. A fuel cell having a DC fuel cell unit and a fuel cell having an AC fuel cell unit when the accumulated power generation amount of the fuel cell is greater than a cumulative power generation amount of the fuel cell of the AC fuel cell unit; May be switched.
[0010]
The fuel cell unit further includes an operation time measuring unit that measures the accumulated operation time of each of the fuel cells included in each of the AC fuel cell unit and the DC fuel cell unit, and the fuel cell switching unit is a fuel included in the DC fuel cell unit. When the cumulative operating time of the battery is longer than the cumulative operating time of the fuel cell included in the AC fuel cell unit, the fuel cell included in the DC fuel cell unit and the fuel cell included in the AC fuel cell unit are switched. May be.
[0011]
The fuel cell unit further includes a maximum power generation amount measuring unit that measures the maximum power generation amount of each fuel cell included in each of the AC fuel cell unit and the DC fuel cell unit, and the fuel cell switching unit is a fuel cell included in the DC fuel cell unit. When the maximum power generation amount is smaller than the maximum power generation amount of the fuel cell included in the AC fuel cell unit, the fuel cell included in the DC fuel cell unit and the fuel cell included in the AC fuel cell unit are switched. Also good.
[0012]
According to the second aspect of the present invention, a program for a power supply system that generates power to be supplied to a plurality of power loads is provided as follows:The fuel cell switching unit of the power supply system measures the response time of each fuel cell as reliability, and the reliability of any fuel cell that the direct current fuel cell unit has is either that the alternating current fuel cell unit has. The fuel cell of the direct current fuel cell unit is used as the fuel cell of the alternating current fuel cell unit when the reliability of the fuel cell is lower than the reliability of the fuel cell of the direct current fuel cell unit. To change the fuel cell, the network changeover switch is changed.
[0013]
The above summary of the invention does not enumerate all the necessary features of the present invention, and sub-combinations of these feature groups can also be the invention.
[0014]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, the present invention will be described through embodiments of the invention. However, the following embodiments do not limit the invention according to the claims, and all combinations of features described in the embodiments are included. It is not necessarily essential for the solution of the invention.
[0015]
FIG. 1 shows a configuration of a power supply system 100 according to an embodiment of the present invention. The power supply system 100 aims to supply highly reliable power to the DC load 14 among the plurality of power loads (12, 14). The plurality of power loads (12, 14) are provided, for example, in a plurality of households in an apartment house.
[0016]
The power supply system 100 includes an AC distribution network 10 that provides AC power to the AC load 12 in the plurality of power loads (12, 14), and a DC load 14 in the plurality of power loads (12, 14). DC power distribution network 20 that provides direct current power to AC, AC fuel cell unit 30 that provides power to AC power distribution network 10, and AC fuel cell unit that provides power to DC power distribution network 20 And a direct-current fuel cell unit 40 having higher reliability than 30. The DC fuel cell unit 40 is more reliable than the AC fuel cell unit 30 and the DC power distribution network 20 is provided independently of the AC power distribution network 10. And reliable power supply.
[0017]
Each of the AC fuel cell unit 30 and the DC fuel cell unit 40 has a plurality of fuel cells (16a to 16c, 16d to 16e). Then, each of the plurality of fuel cells (16a to 16c) included in the direct current fuel cell unit 40 is connected to the DC distribution network 20 via each of the network changeover switches (94a to 94c) included in the bypass circuit 50. Each of the plurality of fuel cells (16d to 16e) included in the fuel cell unit 30 is connected to the AC power distribution network 10 via each of the network changeover switches (94d to 94e) included in the bypass circuit 50. The network change-over switches (94a to 94e) connect each of the plurality of fuel cells (16a to 16e) to the AC distribution network 10 or the DC distribution network 20, that is, the AC fuel cell unit 30 and the DC fuel cell. The unit 40 is switched to be incorporated. In addition, power is supplied to the AC power distribution network 10 via a DC / AC converter 70 that converts DC power generated by the AC fuel cell unit 30 into AC power.
[0018]
When each power generation capacity of the fuel cells (16a to 16e) is C and the number of installed fuel cells is N, the total power generation capacity of the plurality of fuel cells (16a to 16e) is given by C × N. When the failure probability of the fuel cells (16a to 16e) is R, and the total power consumption of the plurality of loads (12, 14) is ΣM (N), the probability of insufficient power supply is ΣM (N)> C × N It is the probability of x (1-R). In this example, the power generation capacity and the number of installed fuel cells (16a to 16e) are set such that the probability that the power supply is insufficient is smaller than the probability that a power system such as a commercial power source (hereinafter referred to as a system) will fail. It is preferable to provide it. Thereby, it can have the reliability of the electric power supply equivalent to or more than a system | strain.
[0019]
The surplus power amount in the direct current fuel cell unit 40 is larger than the surplus power in the alternating current fuel cell unit 30. Thereby, the probability that the power supplied to the DC distribution network 20 is insufficient is lower than that of the AC distribution network 10. That is, the reliability of the power supplied to the direct current fuel cell unit 40 is higher than the reliability of the power supplied to the alternating current fuel cell unit 30. The surplus power is a margin of power, for example, the difference between the maximum power generated by the fuel cell unit and the average power consumed by the power load, or the ratio of the difference in the maximum power generation.
[0020]
The number of fuel cells (16a to 16c) included in the DC fuel cell unit 40 may be greater than the number of fuel cells (16d to 16e) included in the AC fuel cell unit 30. Thereby, the reliability of the electric power supplied from the direct current fuel cell unit 40 is higher than the reliability of the electric power supplied from the alternating current fuel cell unit 30. For example, when one of the plurality of fuel cells 16 included in each of the AC fuel cell unit 30 and the DC fuel cell unit 40 stops operating due to a failure or the like, the DC fuel cell unit 40 is replaced with the AC fuel cell unit. Since there are more than 30 fuel cells, the reduction rate of the supplied power is smaller than that of the AC fuel cell unit 30. That is, the direct current fuel cell unit 40 has higher power supply reliability than the alternating current fuel cell unit 30.
[0021]
The bypass circuit 50 supplies at least part of the power generated by the AC fuel cell unit 30 when the power supplied to the DC load 14 is insufficient in accordance with control by the fuel cell switching unit 92. 20 is supplied. For example, when the power supplied to the DC load 14 is insufficient, the fuel cell switching unit 92 is connected to the network switch (94d, 16d) connected to the fuel cells (16d, 16e) included in the AC fuel cell unit 30. By switching at least a part of 94e) to the DC power distribution network 20 side, at least a part of the power generated by the AC fuel cell unit 30 is supplied to the DC power distribution network 20. As a result, the amount of power supplied to the DC load 14 can be increased.
[0022]
The power supply system 100 further includes a measuring unit 96 that measures the reliability of each of the plurality of fuel cells (16a to 16e) and the reliability of any one of the fuel cells (16a to 16c) included in the DC fuel cell unit 40. Is lower than the reliability of any of the fuel cells (16d to 16e) of the AC fuel cell unit 30, the corresponding fuel cell of the DC fuel cell unit 40 and the corresponding fuel cell of the AC fuel cell unit 30 A fuel cell switching unit 92 is further provided. The measurement unit 96 is an example of a power generation amount measurement unit, an operation time measurement unit, and a maximum power generation amount measurement unit of the present invention. The fuel cell switching unit 92 switches each of the network switching switches (94a to 94e) included in the bypass circuit 50, and a DC fuel cell unit with a combination having the highest reliability among the plurality of fuel cells (16a to 16e). Organize 40. Details of operations of the bypass circuit 50, the measurement unit 96, and the fuel cell switching unit 92 will be described later with reference to FIG.
[0023]
According to the power supply system 100 configured as described above, when the power supplied to the DC load 14 is insufficient, the insufficient power can be supplied from the AC fuel cell unit 30. Further, when the reliability of the fuel cell 16 included in the DC fuel cell unit 40 is lower than the reliability of the fuel cell 16 included in the AC fuel cell unit 30, the fuel cell switching unit 92 switches the corresponding fuel cell 16. Thus, the direct current fuel cell unit 40 is formed by a combination having the highest reliability among the plurality of fuel cells (16a to 16e). Thereby, the power supply system 100 can perform highly reliable power supply to the DC load 14.
[0024]
FIG. 2 shows an example of an operation in which the power supply system 100 improves the reliability of the direct current fuel cell unit 40. First, the measurement part 96 acquires the operation performance of a fuel cell (16a-16e) (S200). For example, the measuring unit 96 acquires the accumulated power generation amount of the power generated by each of the fuel cells (16a to 16e) and the accumulated operation time during which each of the fuel cells (16a to 16e) is operated as the operation results of the fuel cell 16 (16a to 16e). Next, the measuring unit 96 measures the maximum power generation amount of each of the fuel cells (16a to 16e) (S202).
[0025]
Subsequently, the measurement unit 96 determines that the accumulated power generation amount of any of the fuel cells (16a to 16c) included in the DC fuel cell unit 40 is any of the fuel cells (16d to 16e) included in the AC fuel cell unit 30. It is determined whether or not it is greater than the accumulated power generation amount (S204). The accumulated power generation amount of any of the fuel cells (16a to 16c) included in the DC fuel cell unit 40 is greater than the accumulated power generation amount of any of the fuel cells (16d to 16e) included in the AC fuel cell unit 30. If the measurement unit 96 determines that there are many (S204: Yes), the fuel cell switching unit 92 switches between the corresponding fuel cell 16 of the DC fuel cell unit 40 and the corresponding fuel cell 16 of the AC fuel cell unit 30. (S210).
[0026]
For example, when it is determined in step 204 that the accumulated power generation amount of the fuel cell 16 a included in the DC fuel cell unit 40 is larger than the cumulative power generation amount of the fuel cell 16 e included in the AC fuel cell unit 30, the fuel cell is determined in step 210. The switching unit 92 switches the network changeover switch 94a to the AC power distribution network 10 side. Then, the network changeover switch 94e is switched to the DC power distribution network 20 side. Thereby, the fuel cell switching unit 92 incorporates the fuel cell 16e having a smaller total amount of power generation than the fuel cell 16a into the DC fuel cell unit 40, and converts the fuel cell 16a having a larger total amount of power generation than the fuel cell 16e to the AC fuel. The battery unit 30 is incorporated.
[0027]
In step 204, the accumulated power generation amount of all fuel cells (16a to 16c) included in the direct current fuel cell unit 40 is greater than the cumulative power generation amount of all fuel cells (16d to 16e) included in the AC fuel cell unit 30. If the measurement unit 96 determines that the number is less (S204: No), then the AC fuel cell unit 30 has the accumulated operating time of any of the fuel cells (16a to 16c) included in the DC fuel cell unit 40. It is determined whether or not the accumulated operating time is longer than any one of the fuel cells (16d to 16e) (S206). When the cumulative operating time of any of the fuel cells (16a to 16c) included in the direct current fuel cell unit 40 is greater than the cumulative operating time of any of the fuel cells (16d to 16e) included in the alternating current fuel cell unit 30 When it is determined by the measurement unit 96 (S206: Yes), the process proceeds to step 210, and the corresponding fuel cells 16 are switched. Details of step 210 are as described above.
[0028]
On the other hand, if the cumulative operating time of all the fuel cells (16a to 16c) included in the direct current fuel cell unit 40 is less than the cumulative operating time of all the fuel cells (16d to 16e) included in the alternating current fuel cell unit 30. When it is determined by the measuring unit 96 (S206: No), the maximum power generation amount of any one of the fuel cells (16a to 16c) included in the DC fuel cell unit 40 is the fuel cell included in the AC fuel cell unit 30. It is determined whether or not it is smaller than any of the maximum power generation amounts (16d to 16e) (S208). When the maximum power generation amount of any one of the fuel cells (16a to 16c) included in the direct current fuel cell unit 40 is less than the maximum power generation amount of any of the fuel cells (16d to 16e) included in the AC fuel cell unit 30 When it is determined by the measurement unit 96 (S208: Yes), the process proceeds to step 210, and the corresponding fuel cells 16 are switched. Details of step 210 are as described above.
[0029]
On the other hand, in step 208, the maximum power generation amount of all the fuel cells (16a to 16c) included in the DC fuel cell unit 40 is the cumulative power generation amount of all the fuel cells (16d to 16e) included in the AC fuel cell unit 30. If it is determined by the measurement unit 96 that there are more than (S208: No), this flow ends.
[0030]
As a method of measuring the maximum power generation amount of the fuel cell, only a minimum number of fuel cells satisfying the power demand of the entire power supply system 100 in a situation where the balance between power demand and supply is stable and stable. Make it work. Then, one of them is fully operated, it is confirmed that the power supply to the power supply system 100 is stable, and the power generation amount at that time is measured as the maximum power generation amount. By carrying out this procedure for other fuel cells, the maximum power generation amount of all the fuel cells can be measured.
[0031]
Another method for determining the reliability of the fuel cell 16 is to control the power generation amount of the fuel cell 16 to increase to a predetermined value and then until the power generation amount of the fuel cell 16 actually increases to a predetermined value. The response time may be measured as reliability. In this case, the fuel cell switching unit 92 includes a bypass circuit so that the response time of the fuel cell 16 included in the DC fuel cell unit 40 is shorter than the response time of the fuel cell 16 included in the AC fuel cell unit 30. 50 is switched and the fuel cells 16 included in the AC fuel cell unit 30 and the DC fuel cell unit 40 are reorganized.
[0032]
As another method for determining the reliability of the fuel cell 16, the amount of heat generated by the fuel cell 16 when the power generation amount of the fuel cell 16 is controlled to be a predetermined value may be measured as reliability. Since the fuel cell 16 having a large calorific value has low conversion efficiency, it is determined that the reliability is low. In this case, the fuel cell switching unit 92 includes a bypass circuit so that the calorific value of the fuel cell 16 included in the DC fuel cell unit 40 is smaller than the calorific value of the fuel cell 16 included in the AC fuel cell unit 30. 50 is switched and the fuel cells 16 included in the AC fuel cell unit 30 and the DC fuel cell unit 40 are reorganized.
[0033]
According to the above operation flow, the power supply system 100 organizes the direct current fuel cell unit 40 with a combination having the highest reliability among the plurality of fuel cells (16a to 16e). As a result, the power supply system 100 can perform highly reliable power supply to the DC load 14.
[0034]
FIG. 3 is another example of the configuration of the power supply system 100. In this embodiment, the power supply system 100 replaces the bypass circuit 50, the fuel cell switching unit 92, and the measurement unit 96 described in FIG. 1 with a bypass circuit 50, an AC load switching unit 80, and a fuel cell described below. A switching unit 92 is provided. Other configurations are the same as those of the embodiment described with reference to FIG. In the present embodiment, each of the plurality of fuel cells (16a to 16c) included in the direct current fuel cell unit 40 is connected to the direct current distribution network 20 via the bypass circuit 50, and the plurality of fuels included in the alternating current fuel cell unit 30. Each of the batteries (16d to 16e) is connected to the AC power distribution network 10 via the bypass circuit 50.
[0035]
The AC load switching unit 80 includes an AC load switch 82 that disconnects at least a part of the plurality of AC loads 12 from the AC distribution network 10. The fuel cell switching unit 92 controls the bypass circuit 50, the DC / AC conversion unit 70, and the AC load switching unit 80, so that at least part of the power generated by the AC fuel cell unit 30 is supplied to the DC distribution network 20. To supply. Details of control of the bypass circuit 50, the DC / AC converter 70, and the AC load switching unit 80 by the fuel cell switching unit 92 will be described later with reference to FIG.
[0036]
FIG. 4 shows an example of an operation in which the power supply system 100 solves the shortage of power supply to the DC load 14. First, the power supply system 100 constantly monitors whether the power generated by the DC fuel cell unit 40 is sufficient for the power required by the DC load 14 (S102). If it is determined in step 102 that the power is sufficient (S102: Yes), this flow ends. In Step 102, when it is determined that the power generated by the DC fuel cell unit 40 is not sufficient for the power required by the DC load 14 (S102: No), the fuel cell switching unit 92 controls the bypass circuit 50. Then, at least part of the electric power generated by the AC fuel cell unit 10 is supplied to the DC distribution network 20 (S104).
[0037]
As a result of step 104, the power supply system 100 determines whether or not the shortage of power supply to the DC load 14 has been resolved (S106). If it is determined in step 106 that the power shortage has been resolved (S106: Yes), this flow ends. If it is determined in step 106 that the power shortage has not been resolved (S106: No), the fuel cell switching unit 92 further releases at least a part of the AC load switch 82 included in the AC load switching unit 80. Thus, at least a part of the electric power generated by the AC fuel cell unit 30 is supplied to the DC distribution network 20 (S108). In step 108, the fuel cell switching unit 92 may supply at least a part of the power generated by the AC fuel cell unit 30 to the DC distribution network 20 by stopping the operation of the DC / AC conversion unit 70.
[0038]
According to the above operation flow, the power supply system 100 can supply sufficient power to the DC load 14 by controlling the amount of power supplied to the DC distribution network 20. That is, the power supply system 100 can supply highly reliable power to the DC load 14.
[0039]
Note that the management company of the power supply system 100 may be connected to the power supply system 100 via a network such as the Internet and constantly monitor the operation status of the fuel cell 16 and the power supply status to the DC load 14. The fuel cell switching unit 92 is remotely controlled to provide the DC distribution network 20 with at least part of the power generated by the AC fuel cell unit 30 when the power supplied to the DC load 14 is insufficient. The direct current fuel cell unit 40 is organized by a combination having the highest reliability among the plurality of fuel cells (16a to 16e). In this way, the management company can manage the power supply system 100 to supply highly reliable power to the DC load 14.
[0040]
FIG. 5 shows an example of the configuration of a computer 300 for controlling the power supply system 100. In this example, the computer 300 stores a program that causes the power supply system 100 to realize the functions described with reference to FIGS. The computer 300 includes a CPU 700, ROM 702, RAM 704, communication interface 706, hard disk drive 710, FD disk drive 712, and CD-ROM drive 716. The CPU 700 operates based on programs stored in the ROM 702, the RAM 704, the hard disk 710, the FD disk 714, and / or the CD-ROM 718.
[0041]
For example, a program for causing the power supply system 100 to function can cause the power supply system 100 to use the AC power distribution network 10, the AC load 12, the DC load 14, the fuel cell 16, the DC power distribution network 20, and the AC power supply described in FIGS. The functions of the fuel cell unit 30, the DC fuel cell unit 40, the bypass circuit 50, the DC / AC converter 70, the AC load switching unit 80, the fuel cell switching unit 92, the network switching switch 94, and the measuring unit 96 are realized.
[0042]
The communication interface 706 communicates with the power supply system 100, for example. A hard disk drive 710 as an example of a storage device stores a program for operating the CPU 700. The ROM 702, the RAM 704, and / or the hard disk drive 710 store a program for causing the power supply system 100 to realize the functions described with reference to FIGS. Further, the program may be stored in the flexible disk 720, the CD-ROM 722, the hard disk drive 710, and the like.
[0043]
The FD drive 712 reads a program from the flexible disk 714 and provides it to the CPU 700. The CD-ROM drive 716 reads a program from the CD-ROM 718 and provides it to the CPU 700.
[0044]
The program may be read from the recording medium directly into the RAM and executed, or may be once read into the RAM after being installed in the hard disk drive. Further, the program may be stored in a single recording medium or a plurality of recording media. The program stored in the recording medium may provide each function in cooperation with the operating system. For example, the program may request the operating system to perform a part or all of the function and provide the function based on a response from the operating system.
[0045]
As a recording medium for storing a program, in addition to a flexible disk and a CD-ROM, an optical recording medium such as a DVD and a PD, a magneto-optical recording medium such as an MD, a tape medium, a magnetic recording medium, an IC card, a miniature card, etc. A semiconductor memory or the like can be used. A storage device such as a hard disk or a RAM provided in a server system connected to a dedicated communication network or the Internet may be used as a recording medium.
[0046]
As mentioned above, although this invention was demonstrated using embodiment, the technical scope of this invention is not limited to the range as described in the said embodiment. It will be apparent to those skilled in the art that various modifications or improvements can be added to the above embodiment. It is apparent from the scope of the claims that the embodiments added with such changes or improvements can be included in the technical scope of the present invention.
[0047]
【The invention's effect】
As described above, according to the present invention, it is possible to provide a power supply system that supplies highly reliable power to a DC load among a plurality of power loads.
[Brief description of the drawings]
FIG. 1 is a diagram illustrating an example of a configuration of a power supply system 100 according to an embodiment of the present invention.
FIG. 2 is a flowchart showing an example of an operation in which the power supply system 100 improves the reliability of the direct current fuel cell unit 40;
FIG. 3 is a diagram showing another example of the configuration of the power supply system 100 according to the embodiment of the present invention.
FIG. 4 is a flowchart illustrating an example of an operation in which the power supply system 100 solves the shortage of power supply to the DC load.
5 shows an exemplary configuration of a computer 300 for controlling the power supply system 100. FIG.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 10 ... AC distribution network, 12 ... AC load, 14 ... DC load, 16 ... Fuel cell, 20 ... DC distribution network, 30 ... Fuel cell unit for AC, 40 ... -DC fuel cell unit, 50 ... bypass circuit, 70 ... DC-AC conversion unit, 80 ... AC load switching unit, 82 ... AC load switch, 92 ... fuel cell switching unit, 94 ... Network selector switch, 96 ... Measuring unit, 100 ... Power supply system, 300 ... Computer, 700 ... CPU, 702 ... ROM, 704 ... RAM, 706 ... Communication I / F, 710: Hard disk drive, 712: FD drive, 714: CD-ROM drive, 720: Flexible disk, 722 ... CD-R M

Claims (8)

A power supply system for supplying power to a plurality of power loads,
An AC distribution network that provides AC power to an AC load among the plurality of power loads;
A DC distribution network for providing DC power to a DC load among the plurality of power loads;
An AC fuel cell unit that provides power to the AC distribution network;
A direct current fuel cell unit that provides power to the direct current distribution network; and
Each of the AC fuel cell unit and the DC fuel cell unit has a plurality of fuel cells,
A network selector switch for switching each of the plurality of fuel cells to be incorporated into either the AC fuel cell unit or the DC fuel cell unit;
When the reliability of any of the fuel cells included in the DC fuel cell unit is lower than the reliability of any of the fuel cells included in the AC fuel cell unit, the DC fuel cell unit includes A fuel cell switching unit for switching the network switch so that the fuel cell is a fuel cell of the AC fuel cell unit , and the fuel cell of the AC fuel cell unit is the fuel cell of the DC fuel cell unit ; In addition,
The fuel cell switching unit measures a response time of each of the fuel cells as the reliability. A power generation amount measuring unit for measuring a cumulative power generation amount of power generated by each of the fuel cells included in each of the direct current fuel cell unit and the alternating current fuel cell unit;
When the fuel cell switching unit has a cumulative power generation amount of the fuel cell included in the DC fuel cell unit larger than a cumulative power generation amount of the fuel cell included in the AC fuel cell unit, The network changeover switch is switched so that the fuel cell having the fuel cell of the AC fuel cell unit is the fuel cell of the AC fuel cell unit and the fuel cell of the AC fuel cell unit is the fuel cell of the DC fuel cell unit. The power supply system according to claim 1. An operating time measuring unit that measures the cumulative operating time during which each of the fuel cells included in each of the AC fuel cell unit and the DC fuel cell unit is operated;
The fuel cell switching unit is configured such that when the cumulative operating time of the fuel cell included in the DC fuel cell unit is longer than the cumulative operating time of the fuel cell included in the AC fuel cell unit, the DC fuel cell unit is The network changeover switch is switched so that the fuel cell having the fuel cell of the AC fuel cell unit is the fuel cell of the AC fuel cell unit and the fuel cell of the AC fuel cell unit is the fuel cell of the DC fuel cell unit. The power supply system according to claim 1. A maximum power generation amount measuring unit that measures the maximum power generation amount of each of the fuel cells included in each of the AC fuel cell unit and the DC fuel cell unit;
The fuel cell switching unit is configured such that when the maximum power generation amount of the fuel cell included in the DC fuel cell unit is smaller than the maximum power generation amount of the fuel cell included in the AC fuel cell unit, the DC fuel cell unit is The network changeover switch is switched so that the fuel cell having the fuel cell of the AC fuel cell unit is the fuel cell of the AC fuel cell unit and the fuel cell of the AC fuel cell unit is the fuel cell of the DC fuel cell unit. The power supply system according to claim 1. The fuel cell switching unit includes the fuel that the DC fuel cell unit has, rather than the amount of heat generated by the fuel cell when the power generation amount of the fuel cell that the AC fuel cell unit has is controlled to be a predetermined value. 2. The power supply system according to claim 1, wherein the network changeover switch is switched so that a heat generation amount of the fuel cell is smaller when a power generation amount of the battery is controlled to be the predetermined value.   2. The power supply system according to claim 1, wherein the DC fuel cell unit includes more fuel cells than the AC fuel cell unit. The fuel cell switching unit switches the network switch so that the DC fuel cell units are organized in a combination having the highest reliability among a plurality of fuel cells. The power supply system according to 1. A program for the power supply system according to claim 1 ,
The program is stored in the fuel cell switching unit.
The response time of each of the fuel cells is measured as the reliability,
When the reliability of any fuel cell included in the DC fuel cell unit is lower than the reliability of any fuel cell included in the AC fuel cell unit, the DC fuel cell unit includes The network changeover switch is switched so that the fuel cell is a fuel cell of the AC fuel cell unit , and the fuel cell of the AC fuel cell unit is the fuel cell of the DC fuel cell unit. A program characterized by that.

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