KR20050072329A - Power controlling method of fuel cell power generation system associated with electric power system - Google Patents

Abstract

The present invention provides a fuel cell power supply unit comprising an oxygen supply unit, a fuel gas supply unit, a fuel cell, and a power conversion unit; The present invention relates to a power control method of a grid-connected fuel cell power generation system having a grid power supply. In accordance with another aspect of the present invention, there is provided a power control method comprising the steps of: providing a secondary power supply unit in which a DC current generated in the fuel cell is charged or discharged; Detecting a load voltage and a load current of the load; Detecting an output voltage and an output current of the fuel cell having a maximum output power value; Calculating load power and fuel cell power based on the detected load voltage and load current, and fuel cell output voltage and fuel cell output current, respectively; By comparing the load power and the fuel cell power, if the fuel cell power is greater than the load power, at least one of the fuel gas supply unit and the oxygen supply unit is controlled to reduce an oxygen supply amount or a fuel gas supply amount, and the secondary power supply And controlling the secondary power supply unit to be additionally charged. As a result, it is possible to conserve power lost to the grid power side of the fuel cell to improve the efficiency of the system.

Description

Power Controlling Method of Fuel Cell Power Generation System Associated with Electric Power System

The present invention relates to a power control method of a grid-connected fuel cell power generation system having a fuel cell power supply unit and a grid power supply unit, and more particularly, it is possible to conserve power lost to the grid power side in a fuel cell, The present invention relates to a power control method of a grid-connected fuel cell power generation system capable of achieving a power supply.

1 is a control block diagram of a grid-connected fuel cell power generation system according to the prior art. As shown in the figure, the grid-connected fuel cell power generation system of the prior art, the oxygen supply unit 1, the fuel gas supply unit 2, the oxygen and fuel gas supply unit 2 supplied from the oxygen supply unit 1 The fuel cell 3 for generating a direct current by reacting the fuel gas supplied from the fuel cell 3 and the power converter 4 for converting the direct current generated in the fuel cell 3 into an alternating current and supplying the load 30 to the load 30. It includes a fuel cell power supply unit 10 and a grid power supply unit 20 for supplying commercial power to the load (30).

By the power generation system, the fuel cell 3 reacts the oxygen supplied from the oxygen supply unit 1 with the fuel gas supplied from the fuel gas supply unit 2 to generate a DC current, which is then transferred to the power conversion unit 4. The power converter 4 boosts the DC current, converts the DC current into an AC voltage, and outputs the same to the load 30.

Here, the control unit 7 receives the load voltage and the load current detected by the load power detection unit 5 and the fuel cell output voltage and the fuel cell output current detected by the fuel cell power detection unit 6, respectively. Calculate the power. After the calculation, the load power is compared with the fuel cell power, and the fuel cell power is adjusted according to the comparison result. That is, one of the oxygen supply unit 1 and the fuel gas supply unit 2 is controlled to remove an over / under state of fuel cell power with respect to the load power.

At this time, the fuel cell power is gradually increased or decreased compared to the load power, as shown in Figure 2, when the shortage is supplemented with the shortage in the system power supply unit 20, the surplus in the surplus state the system power Supply to the supply unit 20.

In the case described above, when the fuel cell power to the load power is in a surplus state, it corresponds to the loss power when viewed from the fuel cell side, thereby acting as a factor that lowers the power generation efficiency of the entire system.

Accordingly, an object of the present invention is to provide a power control method of a grid-connected fuel cell power generation system which can improve the efficiency of a system by conserving power lost from a fuel cell to a power system side.

Other aspects or advantages of the invention will be apparent in part from the following detailed description, and in part will be apparent from the practical application of the invention.

The object is, according to the present invention, an oxygen supply unit, a fuel gas supply unit, a fuel cell for generating a DC current by reacting the oxygen supplied from the oxygen supply unit and the fuel gas supplied from the fuel gas supply unit, and the fuel cell A fuel cell power supply unit having a power conversion unit converting a DC current generated by the AC current into an AC current and supplying the load to the load; In the power control method of a grid-connected fuel cell power generation system having a grid power supply for supplying commercial power to the load, the DC current generated in the fuel cell interposed between the fuel cell and the power converter is charged or discharged Providing a secondary power supply unit; Detecting a load voltage and a load current of the load; Detecting an output voltage and an output current of the fuel cell having a maximum output power value; Calculating load power and fuel cell power based on the detected load voltage and load current, and fuel cell output voltage and fuel cell output current, respectively; By comparing the load power and the fuel cell power, if the fuel cell power is greater than the load power, at least one of the fuel gas supply unit and the oxygen supply unit is controlled to reduce an oxygen supply amount or a fuel gas supply amount, and the secondary power supply Controlling the secondary power supply to be charged additionally.

Comparing the load power with the maximum output power of the fuel cell if the load power is not less than the fuel cell power as a result of the comparison of the load power and the fuel cell power; When the maximum output power value of the fuel cell is greater than the load power, at least one of the fuel gas supply unit and the oxygen supply unit is controlled such that an oxygen supply amount or a fuel gas supply amount is increased, and the secondary power supply unit is discharged. The method may further include controlling the supply unit.

Further, when the load power is not less than the maximum output power value of the fuel cell as a result of the comparison between the load power and the maximum output power value of the fuel cell, the difference between the maximum output power value of the fuel cell and the fuel cell output is 2; The method may further include controlling the secondary power supply to discharge the differential power supply and controlling the secondary power supply to receive power from the power system.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

3 is a control block diagram of a grid-connected fuel cell power generation system according to the present invention. As shown in the figure, the grid-connected fuel cell power generation system according to the present invention, the oxygen supply unit 51, the fuel gas supply unit 52, the oxygen and fuel gas supply unit supplied from the oxygen supply unit ( A fuel cell 53 for generating a direct current by reacting the fuel gas supplied from 52, and a power converter 54 for converting the direct current generated in the fuel cell 53 into an alternating current and supplying the load 70 to the load 70. ), A load power detector 55 for detecting a load voltage and a load current of a load, a fuel cell power detector 56 for detecting an output voltage and an output current of the fuel cell 53 having a maximum output power value, Power supply is controlled by controlling the secondary power supply unit 58 in which the DC current generated by the fuel cell 53 is charged or discharged, the oxygen supply unit 51, the fuel gas supply unit 52, and the secondary power supply unit 58. The fuel cell power supply unit 50 having the control unit 57 to be described later and the load 70 And a system power supply 60 for supplying power.

The oxygen supply unit 51, the fuel gas supply unit 52, the fuel cell 53, the power conversion unit 54, the load power detection unit 55, and the fuel cell power detection unit 56 are conventional grid-connected fuel cells. What is used in a power generation system can be employ | adopted as it is.

Similarly to the prior art, by the configuration of the fuel cell power supply unit 50 as described above, the fuel cell 53 reacts the oxygen gas supplied from the oxygen supply unit 51 with the fuel gas supplied from the fuel gas supply unit 52. The DC current is generated and then transferred to the power conversion unit 54, and the power conversion unit 54 boosts the DC current to convert it into an AC voltage and outputs the load to the load 70.

Here, the control unit 57 receives the load voltage and load current detected by the load power detection unit 55 and the fuel cell output voltage and the fuel cell output current detected by the fuel cell power detection unit 56, respectively, and load power and fuel cell, respectively. Calculate the power.

In addition, the control unit 57 controls any one of the oxygen supply unit 51 and the fuel gas supply unit 52 to compare the load power and the fuel cell power after calculation and adjust the fuel cell power according to the comparison result. The secondary power supply unit 58 is controlled to compensate for the shortage / surplus of the fuel cell power with respect to the load power, and the power is also supplied from the system power supply unit 60 as necessary. A detailed control process of the controller 57 will be described below with reference to FIGS. 4 and 5.

The secondary power supply unit 58 includes battery means interposed between the fuel cell 53 and the power converter 54 to charge or discharge the DC current generated in the fuel cell.

Here, the secondary power supply unit 58 can sufficiently achieve the object of the present invention to preserve the power lost to the power system even with a relatively small charging capacity compared to the maximum output power value of the fuel cell.

4 is a flowchart illustrating a method of controlling power in a grid-connected fuel cell power generation system according to the present invention, and FIG. 5 is a graph illustrating a power control example of the grid-connected fuel cell power generation system according to the present invention. to be.

First, referring to FIG. 4, the secondary power supply unit 58 is provided between the fuel cell 53 and the power conversion unit 54 (S100), and the load voltage and the load current are periodically generated after starting the power generation system. The fuel cell output voltage and the fuel cell output current are detected (S150 and 200). In the drawing, step S150 and step S200 are divided into separate steps, but they may be detected simultaneously or in reverse order.

The load power and the fuel cell power are respectively calculated based on the detected load voltage, the load current, the fuel cell output voltage, and the fuel cell output current (S250).

Comparing the calculated load power and the fuel cell power (S300), when the fuel cell power is greater than the load power, the oxygen supply unit 51 and the fuel gas may reduce the supply amount of oxygen or fuel gas to reduce fuel cell power. The control unit 52 controls the supply unit 52 (S350), and controls the secondary power supply unit 58 so that the surplus fuel cell power not supplied to the load 70 is charged to the secondary power supply unit 58 (S400).

As a result, it is possible to preserve the power previously lost to the system power supply unit 60.

Subsequently, when the load power is not less than the fuel cell power, the comparison result compares the load power and the maximum output power value of the fuel cell (S450). When the maximum output power value of the fuel cell is greater than the load power, the fuel cell power The oxygen supply unit 51 and the fuel gas supply unit 52 are controlled to increase the supply amount of oxygen or fuel gas in order to increase (S500), and the insufficient power required by the load, that is, the maximum output power value of the fuel cell. The electric power corresponding to the difference between the fuel cell output and the fuel cell output is controlled by the secondary power supply 58 so as to be supplied by the discharge of the secondary power supply 58 (S550).

On the other hand, as a result of comparison, if the load power is not smaller than the fuel cell power and the load power is not smaller than the maximum output power value of the fuel cell, the supply amount of oxygen or fuel gas is maintained so as not to reduce the fuel cell power. The oxygen supply unit 51 and the fuel gas supply unit 52 are controlled (S600), and the insufficient power required by the load is equal to the difference between the maximum output power value of the fuel cell and the fuel cell output, and the secondary power supply unit ( The secondary power supply unit 58 is controlled to be supplied by the discharge (58) (S650), and the remaining insufficient power is supplied from the power system (S700).

That is, as shown in FIG. 5, in the case where a shortage occurs because the load power is not smaller than the fuel cell power, the secondary power supply unit 58 is discharged from the secondary power supply unit 58 until the maximum output power value of the fuel cell is reached. Power is supplied to the load 70.

In addition, when a shortage occurs in excess of the maximum output power value of the fuel cell, similarly to the above, up to the maximum output power value of the fuel cell, the electric power discharged from the secondary power supply unit 58 is supplied to the load 70. And the shortage exceeding this is to supply the commercial power supplied from the grid power supply unit 60 to the load 70.

As a result, even if the secondary power supply unit 58 having a relatively small charging capacity is provided, it is possible to prevent the leakage of power sufficiently lost to the power system side, thereby improving the power generation efficiency of the system.

By the above configuration, it is possible to conserve power lost to the grid power side in the fuel cell to improve the efficiency of the system.

Although some embodiments of the present invention have been shown and described, it will be apparent to those skilled in the art that the present embodiments may be modified without departing from the spirit or spirit of the invention. It is intended that the scope of the invention be defined by the claims appended hereto and their equivalents.

As described above, according to the present invention, the efficiency of the system can be improved by preserving power lost to the grid power side in the fuel cell.

1 is a control block diagram of a grid-connected fuel cell power generation system according to the prior art;

2 is a graph showing a power control example of a grid-connected fuel cell power generation system according to the prior art;

3 is a control block diagram of a grid-connected fuel cell power generation system according to the present invention;

4 is a flowchart illustrating a method of controlling power in a grid-connected fuel cell power generation system according to the present invention;

5 is a graph illustrating a power control example of a grid-connected fuel cell power generation system according to the present invention.

* Explanation of symbols for the main parts of the drawings

50: fuel cell power supply unit 51: oxygen supply unit

52: fuel gas supply unit 53: fuel cell

54: power conversion unit 55: load power detection unit

56 fuel cell power detection unit 57 control unit

58: secondary power supply unit 60: grid power supply unit

70: load

Claims (3)

An oxygen supply unit, a fuel gas supply unit, a fuel cell for generating a direct current by reacting the oxygen supplied from the oxygen supply unit with the fuel gas supplied from the fuel gas supply unit, and the direct current generated in the fuel cell as an alternating current. A fuel cell power supply unit having a power conversion unit converting and supplying the load to the load; In the power control method of a grid-connected fuel cell power generation system having a grid power supply for supplying commercial power to a load, Providing a secondary power supply interposed between the fuel cell and the power converter to charge or discharge a DC current generated by the fuel cell; Detecting a load voltage and a load current of the load; Detecting an output voltage and an output current of the fuel cell having a maximum output power value; Calculating load power and fuel cell power based on the detected load voltage and load current, and fuel cell output voltage and fuel cell output current, respectively; By comparing the load power and the fuel cell power, if the fuel cell power is greater than the load power, at least one of the fuel gas supply unit and the oxygen supply unit is controlled to reduce an oxygen supply amount or a fuel gas supply amount, and the secondary power supply And controlling the secondary power supply unit so as to be additionally charged. The method of claim 1, Comparing the load power with a maximum output power value of the fuel cell if the load power is not less than the fuel cell power as a result of comparing the load power with the fuel cell power; When the maximum output power value of the fuel cell is greater than the load power, at least one of the fuel gas supply unit and the oxygen supply unit is controlled such that an oxygen supply amount or a fuel gas supply amount is increased, and the secondary power supply unit is discharged. The power control method of the grid-connected fuel cell power generation system characterized in that it further comprises the step of controlling the supply. The method of claim 2, As a result of comparing the load power with the maximum output power value of the fuel cell, if the load power is not less than the maximum output power value of the fuel cell, the secondary power is equal to the difference between the maximum output power value of the fuel cell and the fuel cell output. And controlling the secondary power supply unit to discharge the supply unit, and controlling the secondary power supply unit to receive power from the power system.