JPH057928B2 - - Google Patents

Description

[Detailed Description of the Invention] [Technical Field of the Invention] The present invention is aimed at realizing highly efficient operation of the gas turbine generator, particularly in the power receiving and substation system of a building facility that uses the gas turbine generator as a private power generation device. The present invention relates to a margin power control device that performs load process control.

[Technical Background of the Invention] In recent years, when a private power generation device is regularly used in the power receiving and substation system of a building facility, it is configured so that the load can be switched between the power purchasing side and the private power generation side, and the overload of the private power generation device is avoided. Efforts are being made to prevent this.

FIG. 1 shows an example of the configuration of a power receiving and substation system equipped with this type of conventional private power generator.
In the figure, 10 is a load that can be switched between the power purchasing side and the private power generation side, and 20 is a load switching contactor as a switching device for switching this load 10. Also,
30 is a regular private power generator installed in the main power receiving and substation system, 40 is an AC switch and disconnector, 50 is a transformer, 6
0 indicates a transaction meter, and 70 indicates a power receiving point, which are constructed as shown in the figure.

In other words, when the private power generator 30 is used regularly in the power receiving and transforming system shown in Figure 1, its main purpose is to save energy, but for this purpose it is necessary to switch between the power purchasing side and the private generating side as shown in the figure. A load 10 is provided to maintain the load on the private power generation side at a constant level to ensure highly efficient operation of the private power generation. The load switching contactor 20 is for this purpose, and by switching the contactor 20, it is possible to supply power to the load 10 from both the power purchase side and the private power generation side. Although the figure shows only one set of load 10 and load switching contactor 20, in reality, a plurality of similar configurations are connected to the system.

[Problems with the background art] By the way, in such a system, the private power generation device 3
If a gas turbine generator is used as the load 10, it is particularly difficult to operate the gas turbine generator with high efficiency by switching the load 10.
The main reasons for this are that the output of the gas turbine generator itself varies depending on the intake air temperature, and that the load itself varies. As a result, in the past, it has been common practice to keep the total load on the relatively small side in order to avoid exceeding the rating, which is contradictory from the viewpoint of achieving high efficiency operation of the gas turbine generator.

[Object of the Invention] An object of the present invention is to operate the gas turbine generator with high efficiency in response to changes in the intake air temperature and load fluctuations of the gas turbine generator, which is a private power generation device, and to establish an efficient power receiving and substation system. It is an object of the present invention to provide a surplus power control device that can realize operation.

In order to achieve the above object, the present invention separately installs a plurality of switchers that can switch the load between the power purchase system and the private power generator, which is the gas turbine generator, between the power purchase system and the private power generation device. An intake air temperature measuring means for measuring the temperature of air (intake air) taken in by a gas turbine generator in a surplus power control device for a power receiving and substation system configured to supply power to each load provided correspondingly through the electric power receiving/transforming system; Calculating the rated output of the gas turbine generator from the intake air temperature measured by the power measuring means for measuring the electric power supplied from the gas turbine generator to the load and the intake air temperature measuring means, and using the rated output and the electric power measuring means. surplus power calculation processing means for calculating surplus power at which the power of the gas turbine generator exceeds a predetermined dead zone of the rated output based on the measured power; and surplus power calculated by the surplus power calculation processing means and substation. A control determination processing means that determines which load is to be controlled based on the operating state of the system, and outputs a switching control signal to a switching device corresponding to the load to be controlled determined by the control determination processing means. and control output processing means.

[Embodiment of the Invention] Hereinafter, an embodiment of the present invention shown in the drawings will be described.

Fig. 2 shows an example of the system configuration of a power receiving and substation system to which the surplus power control device of the present invention is applied. I will only describe the parts. In the figure, 80 is a margin power controller, 81 is a load 1
a power sensor that measures the power supplied from the private power generator 30 of the gas turbine out of the power consumed by the gas turbine through the instrument transformer PT and the current transformer CT, and inputs the measured power to the surplus power controller 80; Reference numeral 82 denotes an intake air temperature sensor that measures the temperature of the air used by the private power generation device 30 consisting of a gas turbine generator and inputs the temperature to the surplus power controller 80.

FIG. 3 is a block diagram showing an example of the internal configuration of the surplus power controller 80. In the figure, 80a
80b is a power sensor processing means that calculates the electric power being supplied from the private power generation device 30 side to the load 10 side based on the output signal from the power sensor 81, and 80b is a power sensor processing means that calculates the electric power being supplied from the private power generation device 30 side to the load 10 side based on the output signal from the above power sensor 81. Intake air temperature sensor processing means 80c calculates the temperature of the intake air, and system operation state processing means 80c processes the operation state signals 41 of the shield disconnector 40, load switching contactor 20, etc. in the power receiving and substation system. Further, 80d calculates the rated output of the private power generation device 30 consisting of a gas turbine generator from the output signal from the intake air temperature sensor processing means 80b,
Also, based on this rated output and the output signal from the power sensor processing means 80a, a surplus power is calculated to calculate the surplus power by which the current power of the private power generation device 30 consisting of a gas turbine generator exceeds the predetermined dead zone of the rated output. Arithmetic processing means, 80e is a control determination processing means that determines which load 10 is to be controlled based on the current system operation state and the surplus power calculated above, and 80f is the control object determined thereby. It is a control output processing means that outputs a signal for switching and controlling the load switching contactor 20 corresponding to the load.

On the other hand, FIG. 4 shows an example of the transition of power by the present surplus power control device. In the figure,
T indicates the control period of the margin power control device, and A
indicates the transition of the electric power w supplied from the private power generator 30, B, C, D, and E indicate the time points when the load was switched by the surplus power control device, and F indicates the rated output of the private power generator 30. It shows the change in W, and Wd shows the dead zone of the power used for control.

Further, FIG. 5 is a flowchart showing the details of controlling the surplus power. In the figure, step S80-1 is a step for determining whether or not surplus power control can be performed automatically, and step S80-2
Step S80-3 is a step to determine whether or not the state of the disconnection or disconnection in the grid is in a state where surplus power control is possible. This is the step of calculating the rated output W. Further, step S80-4 is a dead zone in which the difference between w and W calculated in step S80-3 (margin power Y=W-w) is set in advance.
Step S80-5 is a step of determining whether or not it is larger than Wd, step S80-5 is a step of switching the load to the private power generator 30 as a result of the determination of step S80-4, and step S80-6 is a step of determining whether Y<0. Step, step S80-7 is step S80-6
As a result of the determination, step S80-8 is a step in which the load is switched to the power purchasing side, and step S80-8 is a step in which delay processing is performed until the next control point.

Next, the operation of the margin power control device of the present invention will be explained using FIGS. 2 to 5.

First, the surplus power Y is the difference between the rated output W of the private power generation device 30 and the electric power w actually supplied from the private power generation device 30 to the load 10, and is expressed as in the following formula (1).

Y=W−w (1) Here, W is expressed as a function of the intake air temperature t of the private power generator 30, and is most simply expressed as in equation (2).

W=W ₀ (t≦T ₀ ) W=W ₁ + (T ₁ −t) (W ₀ −W ₁ )/(T ₁ −T ₀ ) (T ₀ ≦t≦T ₁ )……(2) However, T ₀ and T ₁ are the lower and upper limits of the intake air temperature, respectively.
W ₀ and W ₁ are the rated outputs of the private power generator 30 when t=T ₀ and t=T ₁ , respectively.

Further, w is data measured by the power sensor 81 in FIG. 2, and varies depending on the usage status of the load 10 in the system. In other words, the above equation (2) shows that the rated output increases as the intake air temperature t decreases, and the characteristic is that the sixth
The result will be as shown in the figure. Therefore, the gas turbine generator is operated with high efficiency by switching the load amount connected to the private power generation device 30 consisting of the gas turbine generator so that the load amount matches the rated output.

To explain specifically, the purpose of margin power control is to
The purpose is to minimize the difference Y between the two quantities W and w,
For this purpose, the control period T and dead zone Wd as shown in FIG. 4 are set in advance by the operator's judgment. Step S80-4 and step in FIG.
As shown in S80-6, the difference Y is calculated for each control cycle, and if Y>Wd...(3), an appropriate load among the multiple loads is switched to the private power generator 30 side (the B and E in Figure 4
corresponds to this). In addition, the difference Y is calculated at intervals shorter than the control cycle, and if Y0... (4), there is an overload, so the load 10 is switched to the power purchasing side using the load switching contactor 20 to reduce w. (C and D in FIG. 4 correspond to this).

The surplus power control device of the present invention controls the surplus power Y to maintain it in the range of 0<YWd (5) by repeating the above operations. By controlling in this manner, the electric power w can be maintained as shown in FIG. 4. Therefore, in such a control device, the dead zone Wd is adjusted according to the capacity of the plurality of loads to be controlled, and the control period T is also adjusted, so that margin power control can be performed according to the receiving fluctuating system. can be done.

As mentioned above, the surplus power control device of the present invention has the following features:
The rated output W of the gas turbine generator is calculated from the output signal of an intake air temperature sensor 82 that measures the intake air temperature t of the gas turbine generator as the private power generation device 30, and is supplied from the gas turbine generator to the load 10. The configuration is such that the power w is measured as the actual power used from the output signal of the power sensor 8, and the load to be controlled is determined and controlled based on the system operation status and the surplus power Y (=W-w). Achieves high-efficiency operation of the gas turbine generator without imposing an overload on the gas turbine generator, saves energy in the operation of the gas turbine generator itself, and easily uses the exhaust heat of the gas turbine for heating and cooling of building facilities. This makes it possible to save energy in the entire building facility.

[Effects of the Invention] As explained above, according to the present invention, the rated output of the gas turbine generator is calculated from the temperature of the air (intake air) taken in by the gas turbine generator, which is a private power generation device, and the rated output and the Based on the power supplied from the gas turbine generator to the load, the margin power at which the power of the gas turbine generator exceeds a predetermined dead zone of the rated output is calculated, and this margin power is calculated based on the operating status of the receiving and substation system. Based on this, the load to be controlled is determined and the load is switched to adjust the load amount, so that the high-temperature control of the gas turbine generator can be adjusted in response to changes in the intake air temperature and load fluctuations of the gas turbine generator, which is a private power generation device. It is possible to provide a margin power control device that can perform efficient operation and realize efficient operation of a power receiving and substation system.

[Brief explanation of the drawing]

Fig. 1 is a block diagram showing an example of a substation system equipped with a conventional private power generation device, Fig. 2 is a block diagram showing a substation system to which the present invention is applied, and Fig. 3 is the surplus power in Fig. 2. FIG. 4 is a block diagram showing the internal configuration of the controller, FIG. 4 is a diagram showing the transition of power by the surplus power control device of the present invention, FIG. 5 is a flow diagram showing the details of surplus power control according to the present invention, and FIG. FIG. 2 is a characteristic diagram showing the relationship between the intake air temperature of a gas turbine generator and its rated output. 10... Power purchase side - private generation side switching load, 20...
Load switching contactor, 30...Private power generation device, 4
0...AC circuit breaker, 50...Transformer, 60...
Transaction instrument, 70... Power receiving point, 80... Surplus power controller, 81... Power sensor, 82... Intake air temperature sensor, 80a... Power sensor processing means, 80b
...Intake air temperature sensor processing means, 80c...System operation state processing means, 80d...Marginal power calculation processing means, 80e...Control determination processing means, 80f...Control output processing means.

Claims (1)

[Scope of Claims] 1. Electric power from a power purchase system and a gas turbine generator, which is a private power generation device, is handled separately through a plurality of switching devices that can switch loads between the power purchase system and the private power generation device. A surplus power control device for a power receiving and substation system configured to supply power to each load installed in the gas turbine generator includes an intake air temperature measuring means for measuring the temperature of the air (intake air) taken in by the gas turbine generator; a power measuring means for measuring the power supplied from the generator to the load; and calculating the rated output of the gas turbine generator from the intake air temperature measured by the intake air temperature measuring means, and calculating the rated output of the gas turbine generator from the rated output and the power measuring means. a surplus power calculation processing means for calculating, based on the measured power, a surplus power at which the power of the gas turbine generator exceeds a predetermined dead zone of the rated output; and a surplus power calculation processing means calculated by the surplus power calculation processing means. control determination processing means for determining which load is to be controlled based on the operating state of the power receiving and substation system; and a switching device corresponding to the load to be controlled determined by the control determination processing means. A margin power control device comprising: control output processing means for outputting a switching control signal;