JP2017073857A - Power supply system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To allow for stable power supply to a load according to the situation where a distributed power supply device is stopped, in a power supply system where the distributed power supply device is a main power supply.SOLUTION: A power supply system is constituted of a distributed power supply device, and a power switching unit connected with a first power path for supplying the power outputted from the distributed power supply device to a first type load, and a second power path for supplying the power outputted from a commercial power supply to the first type load, and supplying power from the first power path to the first type load, when power is outputted from the distributed power supply device, and supplying power from the second power path to the first type load, when power is not outputted from the distributed power supply device.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a power supply system.

  A power supply system including a fuel cell is known as one of distributed power supply devices. As such an electric power supply system, a configuration for achieving independent operation as described below is known. That is, the power supply system shuts off the commercial power supply from the power supply system when the commercial power supply stops. In addition, the power supply system supplies the power of one storage battery to the power supply system, and supplies the power generated by a distributed power supply device such as a fuel cell or a solar battery to the power supply system so as to be interconnected with the power of the storage battery. And the electric power supplied from a power supply system is stored in another storage battery (for example, refer patent document 1).

In addition, a power supply system is known in which power consumed by a data center is supplied by a fuel cell in consideration of the environment and the like (see, for example, Patent Document 2).
In addition, a fuel cell system is known in which hydrogen used for power generation by a fuel cell is extracted from gas supplied by a gas supply facility (gas infrastructure) (see, for example, Patent Document 3).

JP2013-162686A JP 2010-181063 A JP 2012-79605 A

Based on the techniques of Patent Document 2 and Patent Document 3, it is conceivable to construct a power supply system that uses a fuel cell that generates power upon receiving gas supply from a gas supply facility as a power source of a data center. In this case, the power generated by the fuel cell is the main power source for the data center.
In this way, in the power supply system in which the fuel cell is used as the main power source, even if the power generation of the fuel cell is stopped due to, for example, a failure of the fuel cell itself or a failure of the gas supply facility, power is supplied to the data center. It is necessary to make it.
However, for example, Patent Document 1 is a configuration in which a power source is backed up in response to a commercial power source being stopped in a power supply system using the commercial power source as a main power source. For this reason, according to Patent Document 1, when a distributed power supply device such as a fuel cell is the main power supply, it is difficult to stably supply power to a load in accordance with the stoppage of the distributed power supply device. It is.

  The present invention has been made in view of such circumstances, and in a power supply system in which a distributed power supply device is a main power supply, power can be stably supplied to a load according to the situation in which the distributed power supply device is stopped. The purpose is to be able to supply.

  One aspect of the present invention for solving the above-described problems is a distributed power supply device, a first power path that supplies power output from the distributed power supply device to a first type load, and a commercial power supply. Is connected to the second power path for supplying the first type load to the first type load, and the power is supplied from the first power path to the first type load. The power supply system includes a power switching device configured to supply power to the first type load from the second power path when power is not output from the distributed power supply device.

  As described above, according to the present invention, in the power supply system in which the distributed power supply is the main power supply, power can be stably supplied to the load according to the situation where the distributed power supply is stopped. The effect of becoming is obtained.

It is a figure which shows the structural example of the electric power supply system in 1st Embodiment. It is a figure which shows the structural example regarding switching of the gas supply to the fuel cell in 2nd Embodiment.

Hereinafter, a power supply system according to an embodiment of the present invention will be described with reference to the drawings.
[First Embodiment]
FIG. 1 is a diagram illustrating a configuration example of a power supply system according to the present embodiment. The power supply system in the present embodiment supplies power to a data center including a server group.
The power supply system of FIG. 1 includes a fuel cell 10, a gas supply facility 20, a commercial power supply 30, a server group 40 (an example of a first type load), a power switching device 50, and general loads 60-1 to 60-n (second An example of a seed load), a switch 70 and a power supply control device 100 are provided.

  The fuel cell 10 is a power generator that generates power using hydrogen extracted from a gas (an example of a medium) supplied from a gas supply facility 20 and oxygen taken from the air. In the present embodiment, the fuel cell 10 is provided in a data center including the server group 40 and supplies power. That is, the fuel cell 10 is one of distributed power supply devices. The fuel cell 10 outputs AC power.

  The gas supply facility 20 is an infrastructure that supplies medium-pressure gas or low-pressure gas, for example.

A path for outputting electric power obtained by the power generation of the fuel cell 10 is connected to one of the two inputs in the power switching device 50. Further, another path for outputting electric power obtained by the power generation of the fuel cell 10 is connected to the commercial power source 30.
The other input of the power switching device 50 is connected to a path through which power from the commercial power supply 30 is output.
The output of the power switching device 50 is connected to the server group 40.

  The server group 40 collectively indicates one or more servers provided in a server room in a data center, for example. Therefore, the output of the power switching device 50 is connected to each of the devices as servers included in the server group 40.

The path of power output from the commercial power supply 30 is connected to one input of the power switching device 50 as described above. The path of power output from the commercial power supply 30 is connected to the general load 60-1 via the switch 70 and connected to the general loads 60-n to 60-n without passing through the switch 70. Has been.
Here, the general loads 60-1 to 60-n are loads other than the server in the data center, for example, and are lighting, an air conditioner, and the like in the data center, for example. In the following description, the general loads 60-1 to 60-n are referred to as general loads 60 unless otherwise distinguished.

  The switch 70 opens and closes according to the control of the power supply control device 100. When the switch 70 is closed, the power output from the commercial power supply 30 is supplied to the general load 60-1, and when the switch 70 is open, the general load 60-1 of the power output from the commercial power supply 30 is supplied. The supply to is cut off.

  The power supply control device 100 controls the opening / closing of the switch 70 according to the switching state of the power path of the power switching device 50.

Next, the operation of the power supply system configured as described above will be described.
As understood from the above description, the power switching device 50 includes a path for supplying power output from the fuel cell 10 to the server group 40 (first power path) and power output from the commercial power supply 30. A path (second power path) supplied to the server group 40 is connected. That is, the power switching device 50 receives the power output from the fuel cell 10 and the power output from the commercial power supply 30.
In addition, when the power is output from the fuel cell 10, the power switching device 50 supplies power to the server group 40 from the first power path. That is, the power switching device 50 forms a power path so that the power output from the fuel cell 10 is supplied to the server group 40 when the fuel cell 10 is operating normally and generating power.

As described above, the power switching device 50 is configured so that the power output from the fuel cell 10 is supplied to the server group 40 in a normal state. At this time, the power supply control device 100 detects that the power switching device 50 is in a state of forming a power path so as to supply the power of the fuel cell 10 to the server group 40. That is, it detects that it is in a normal state.
The power supply control device 100 controls the switch 70 to be closed when it is detected that the switch is in a normal state.
Thereby, in the normal state, the power of the fuel cell 10 is supplied to the server group 40, and the power of the commercial power supply 30 is supplied to each of the general loads 60-1 to 60-n. It is done.

  Further, it is generally preferable that the fuel cell 10 stably outputs the rated output power instead of causing the operation to follow the load power. Therefore, when power is stably output from the fuel cell 10 according to the rating, when the load power of the server group 40 is small, surplus is generated in the power output from the fuel cell 10. Therefore, in the present embodiment, when surplus power is generated from the fuel cell 10, the surplus power can be supplied to the commercial power supply 30 through grid interconnection. Thereby, the surplus of the electric power output from the fuel cell 10 can be used effectively, for example, by using it for selling electricity.

  Thus, in the data center according to the present embodiment, in the normal state, the power of the fuel cell 10 is constantly supplied to the server group 40, and the power of the commercial power supply 30 is supplied to the general load 60 other than the server. Is done. That is, in the power supply system in the present embodiment, the fuel cell 10 is a main power source, and the commercial power source 30 is an auxiliary power source.

In contrast to the above normal state, for example, when a malfunction of the fuel cell 10 itself or a malfunction of the gas supply facility 20 occurs, there is an abnormal state in which power is not output from the fuel cell 10 because the fuel cell 10 stops generating power. Occur.
When an abnormal state occurs in this way, the power switching device 50 supplies power to the server group 40 from the second power path. That is, when the power from the fuel cell 10 is no longer input, the power switching device 50 switches the power path so that the power output from the commercial power supply 30 is supplied to the server group 40.

As described above, the power switching device 50 is configured to perform switching without causing an instantaneous interruption in the server group 40 when switching power from the fuel cell 10 to the commercial power supply 30. In other words, the power switching device 50 according to the present embodiment is configured to be able to perform high-speed power switching without instantaneous interruption.
As described above, the power switching device 50 according to the present embodiment is provided between the first power path and the second power path so that the operation of the server (an example of the device as the first type load) in the server group 40 does not stop. Switch. Thereby, when the power is switched between the fuel cell 10 and the commercial power supply 30, the server operation in the server group 40 does not stop, so that the normal operation of the server can be maintained.
The power switching device 50 is configured to switch from the commercial power source 30 to the fuel cell 10 in order to obtain a normal state in response to the fuel cell 10 returning to a normal operation and outputting power. In addition, power switching is performed without interruption.

  Here, the data center of the present embodiment has a demand contract with an electric power company that is a supplier of the commercial power supply 30. In the demand contract, the maximum demand power (demand) is determined in advance between the consumer and the power company, and the power usage fee is determined according to the demand. When the power used exceeds the demand, payment of the excess contract amount or increase in the contract fee occurs. And a consumer uses electric power so that a demand may not be exceeded.

However, when an abnormal state occurs and the power of the commercial power supply 30 is supplied to the server group 40 as described above, the power supplied from the commercial power supply 30 to the data center is supplied to the server group 40. It increases according to the power to be used.
When the power of the commercial power supply 30 is supplied to the server group 40 in response to the abnormal state, the power used by the commercial power supply 30 may exceed the demand. Therefore, in the present embodiment, the supply of power to the general load 60-1 is stopped in response to the state in which the power of the commercial power supply 30 is supplied to the server group 40 according to the abnormal state. To be.

  The supply of power to the general load 60-1 is stopped by the power supply control device 100 controlling the switch 70. That is, when the power supply control device 100 detects that the state of the power switching device 50 is switched from the state of outputting the power of the fuel cell 10 to the state of outputting the power of the commercial power source 30, an abnormal state has occurred. Detect as. When the occurrence of an abnormal state is detected, the power supply control device 100 controls the switch 70 that has been closed so far to be in an open state. Thereby, the electric power supply of the commercial power supply 30 to the general load 60-1 is stopped according to the state where the electric power of the commercial power supply 30 is supplied to the server group 40 due to the abnormal state.

As the general load 60-1, when the operation is stopped in response to the state where the power of the commercial power supply 30 is supplied to the server group 40 in the general load 60, excess demand is reliably avoided. Those having load power corresponding to the amount of power reduction that can be performed are selected. In this case, it is preferable that the general load 60-1 has a load power that minimizes the amount of power reduction in order to ensure that an excess of demand is avoided. Furthermore, even if the general load 60-1 is stopped, it is preferable that the general load 60-1 has as little influence as possible on the deterioration of the data center environment.
Further, there may be a plurality of devices as the general load 60-1 in which the power supply is stopped in the abnormal state, and accordingly, the switch 70 also corresponds to each of the plurality of devices as the general load 60-1. A plurality may be provided.
With this configuration, in this embodiment, it is possible to prevent the power consumption of the commercial power supply 30 from exceeding the demand while preventing a significant environmental degradation in the data center.

  As described above, in the present embodiment, in the power supply system in which the fuel cell 10 that is the distributed power supply device is the main power source, power is stably supplied to the load according to the situation in which the fuel cell 10 stops. be able to.

  In the present embodiment, the opening / closing of the switch 70 may be directly controlled by the power switching device 50, for example. As an example, in the normal state in which the power of the fuel cell 10 is supplied to the server group 40, the power switching device 50 energizes the switch 70 and supplies the power of the commercial power supply 30 to the server group 40. In the state, the switch 70 is not energized. The switch 70 operates so as to be closed when energized and open when not energized. Even with such a configuration, the switch 70 can be appropriately opened and closed in conjunction with the state of the power switching device 50. In such a configuration, since the power switching device 50 has a function as a power supply control device, the power supply control device 100 may be omitted.

[Second Embodiment]
Next, the second embodiment will be described. In the previous first embodiment, the hydrogen used by the fuel cell 10 for power generation is extracted from the gas supplied from the gas supply facility 20. However, when the gas supply facility 20 cannot supply gas to the fuel cell 10 due to some trouble, the fuel cell 10 is in a state where power generation is impossible as it is.
Therefore, the present embodiment is configured such that the gas can be supplied to the fuel cell 10 even when the gas supply by the gas supply facility 20 is stopped.

  FIG. 2 shows a portion of a configuration relating to gas supply to the fuel cell 10 according to the present embodiment. In this figure, the same parts as those in FIG. Moreover, the commercial power source 30, the server group 40, the power switching device 50, the general loads 60-1 to 60-n, the switch 70, and the power supply control device which are not shown in the figure among the parts shown in FIG. About 100 etc., the structure similar to FIG. 1 may be sufficient.

In the figure, a gas storage tank 80 and a gas switching device 90 are further provided.
The gas storage tank 80 is a facility for storing gas, and is installed in the data center or in the vicinity of the data center.

The gas switching device 90 is a device that switches the gas supplied to the fuel cell 10 between the gas supplied from the gas supply facility 20 and the gas supplied from the gas storage tank 80.
The gas switching device 90 includes a first supply path for supplying gas from the gas supply facility 20 to the fuel cell 10 and a gas supply tank for storing gas (an example of a medium storage device) that supplies gas to the fuel cell 10. 2 supply paths are connected. The gas switching device 90 is configured to supply the fuel cell 10 from the first supply path when the gas is supplied from the first supply path, and when the medium is not supplied from the first supply path. (2) Gas is supplied to the fuel cell 10 from the supply path.
That is, the gas switching device 90 forms a gas supply path so that the gas is supplied from the gas supply facility 20 to the fuel cell 10 in a normal state where the gas is supplied from the gas supply facility 20. On the other hand, when an abnormal state occurs in which gas is not supplied from the gas supply facility 20 due to some trouble, the gas switching device 90 supplies the gas supply path so that the gas is supplied from the gas storage tank 80 to the fuel cell 10. Switch.

The configuration of the gas switching device 90 is not particularly limited. For example, the gas supply is performed using the pressure of the gas supplied from the gas supply facility 20 and the pressure of the gas supplied from the gas storage tank 80. It is possible to adopt a configuration in which routes are switched.
That is, the gas switching device 90 forms a path for supplying gas from the gas supply facility 20 to the fuel cell 10 in a state where the gas pressure is obtained by supplying the gas from the gas supply facility 20. On the other hand, when the gas supply from the gas supply facility 20 stops, the gas pressure from the gas supply facility 20 decreases, and the gas pressure from the gas storage tank 80 increases, the gas switching device 90 operates as a gas storage tank. A path is formed so that gas is supplied from 80 to the fuel cell 10.

  As described above, even when the gas supply path is switched from the gas supply device 20 to the situation where the gas supply apparatus 20 does not supply the gas, as long as the gas is stored in the gas storage tank 80, Gas can be stably supplied to the fuel cell 10. Thereby, the normal operation of the fuel cell 10 can be maintained more firmly.

  In each of the above embodiments, the case where power is supplied to a data center including a server is taken as an example. However, the facility to which the power supply system according to the present embodiment supplies power is not limited to the data center. For example, the configuration of the power supply system of the present embodiment can be applied to other facilities such as a school and a hospital.

In the above embodiment, the general load 60-1 that stops the power supply when the power path is switched so as to supply the power of the commercial power supply 30 to the server group 40 is fixedly selected in advance. It was.
However, for example, each time the power path for supplying the power of the commercial power supply 30 to the server group 40 is switched, for example, the general load that stops the power supply according to the power usage status of each general load 60 at that time 60 may be selected.
For this purpose, for example, the power supply control device 100 is configured to monitor the power used in each of the general loads 60. In addition, when the power path is switched so that the power of the commercial power supply 30 is supplied to the server group 40, the power supply control device 100 supplies the demand within the minimum necessary range in the general load 60. A general load 60 that is in a state of power consumption that can be prevented from exceeding is selected. At this time, as the general load 60 for stopping the power supply, a plurality of general loads 60 may be selected as long as the demand is not exceeded within a necessary minimum range.
At this time, the power supply control device 100 uses the power used by each general load 60 after switching the power path so that the power of the commercial power supply 30 is supplied to the server group 40 based on the past results of the power used. The general load 60 may be selected based on the estimated power consumption.
In addition, when a plurality of candidates are selected as the general load 60 that is in a state of power consumption that can prevent the demand from being exceeded within the minimum necessary range, for example, the general load 60 is determined in advance. Based on the degree of importance, it may be selected from those having a low degree of importance.

  Moreover, said 2nd Embodiment was demonstrated as another example of the structure for the gas supply to the fuel cell 10 in the electric power supply system shown by FIG. However, the configuration of FIG. 2 as the second embodiment may be applied to all fuel cells that generate power by receiving gas supply, in addition to the fuel cell 10 provided in the power supply system of FIG. 1. In this case, the device as a load that receives the supply of power output from the fuel cell may be other than the server, and is not particularly limited.

  Moreover, although the case where the distributed power supply device is the fuel cell 10 is given as an example in each of the above embodiments, for example, if it is a power generation device that can generate power by taking in a medium supplied from the facility, It can be used as a distributed power supply device of this embodiment.

DESCRIPTION OF SYMBOLS 10 Fuel cell, 20 Gas supply equipment, 30 Commercial power supply, 40 Server group, 50 Power switching device, 60-1-60-n General load, 70 Switch, 80 Gas storage tank, 90 Gas switching device, 100 Power supply control apparatus

Claims (4)

A distributed power supply;
A first power path for supplying power output from the distributed power supply device to the first type load and a second power path for supplying power output from a commercial power source to the first type load are connected, and When power is output from the distributed power supply device, power is supplied from the first power path to the first type load, and when power is not output from the distributed power supply device, the second power supply is supplied. A power supply system comprising: a power switching device configured to supply power from the power path to the first type load. The power switching device is
The power supply system according to claim 1, wherein the power supply system is configured to perform switching between the first power path and the second power path so that operation of the device as the first type load does not stop. When the second power path is connected to the first type load by the power switching device, a predetermined second of the one or more second type loads receiving supply of power output from the commercial power source The power supply system according to claim 1, further comprising a power supply control device that controls the supply of power to the seed load to be stopped. A first supply path for supplying a medium from a supply facility for supplying a medium used for power generation by the distributed power supply to the distributed power supply; a medium from a storage device for storing the medium to the distributed power supply; A second supply path for supplying
When the medium is supplied from the first supply path, the medium is supplied from the first supply path to the distributed power supply device, and when the medium is not supplied from the first supply path, the second supply is performed. The power supply system according to any one of claims 1 to 3, further comprising a medium switching device that allows a medium to be supplied from a path to the distributed power supply device.

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