JP6095109B2 - Power supply system - Google Patents

Description

  The present invention relates to a power supply system that can be used as an independent microgrid system including a tidal current power generation device.

  Regarding tidal power generation using tidal currents, studies in Japan are described in, for example, Non-Patent Documents 1 and 2, and examples in Scotland and Korea are described in Non-Patent Documents 3-6, for example. In Scotland in particular, tidal current power generation is expected to grow into a powerful natural energy source, similar to solar and wind power generation.

  In tidal power generation, the speed and direction of the tidal current change at regular intervals due to tidal flow, making it easy to predict output fluctuations.However, in order to compensate for the difference in power supply and demand, installation of power storage devices and output control It is necessary to introduce a possible power supply and / or link with a power supply network including a commercial power supply.

  In addition, a power generation system that supplies power by combining tidal power generation and thermal power generation has been proposed (for example, Patent Document 1).

  The power generation system described in Patent Document 1 selects a turbine having the same capability as tidal power generation from thermal power generation, and controls the thermal power so that power corresponding to the shortage of tidal power generation can be output by a computer. It is configured to convert power into commercial power.

Kyozuka Y. An experimental study on the Darrieus-Savonius turbine for the tidal current power generation.JSME Journal of Fluid Science and Technology, 2008, 3 (3), 439-449. Deog H D, Suzuki K. Power generation characteristics of a novel horizontal tidal current power generation system installed in the Akashi Strait of Japan.Sustainable Energy Technologies (ICSET), 2010 IEEE International Conference, 2010, 1-6. Dolman S, Simmonds M, Towards best environmental practice for cetacean conservation in developing Scotland ’s marine renewable energy, 2010, 34 (5), 1021-1027. Johnson K, Kerr S, Side J, Accommodating wave and tidal energy-Control and decision in Scotland, Ocean & Coastal Management, 2012,65, 26-33. Bae Y H, Kim K O, Choi B H, Lake Sihwa tidal power plant project, Ocean Engineering, 2010, 37 (5-6), 454-463. Lee DS, Oh SH, Yi JY, Park W, Cho HS, Kim DG, Eom HM, Ahn SJ, Experimental investigation on the relationship between sluice caisson shape of tidal power plant and the water discharge capability, Renewable Energy, 2010, 35 ( 10), 2243-2256.

Japanese Utility Model Publication No. 6-8769

  However, the power generation system of Patent Document 1 described above controls thermal power so that power corresponding to the shortage of tidal power generation can be output, but does not consider the power load connected to the transmission line network, and is more stable. Could not supply the power.

  Moreover, in the power generation system of Patent Document 1 described above, thermal power generation itself is one of the factors that promote global warming, so that it has been difficult to spread.

  Accordingly, an object of the present invention is to provide a power supply system that includes a tidal current generator as a main power source and can supply more stable power.

  Another object of the present invention is to provide a power supply system that can be used as a stand-alone microgrid system that is not linked to another power system.

  According to the present invention, a fuel cell power generation device that generates power using fuel gas, a solar cell power generation device that includes a plurality of solar cell panels and generates power using sunlight, and a tidal current is used. A tidal power generation device that generates power, and a power transmission line that is connected to the fuel cell power generation device, the solar cell power generation device, and the tidal current power generation device, and transmits the output power of the fuel cell power generation device, the solar cell power generation device, and the tidal current power generation device to the customer Load detecting means for detecting the power load of the power transmission line network including at least the network, the power generation amount detecting means for detecting the power generation amount of the fuel cell power generation device, the solar cell power generation device and the tidal current power generation device, and the detected power A power supply system is provided that includes control means for controlling the power generation amount of the fuel cell power generation device based on the difference between the load and the detected power generation amount.

  Since the control means controls the power generation amount of the fuel cell power generation device based on the difference between the detected power load and the power generation amount in the power transmission line network, it can supply stable power and the conventional commercial power network. Can be used as a stand-alone microgrid system.

  The control means is preferably configured to control the power generation amount of the fuel cell power generation device so as to compensate for the shortage amount of the detected power generation amount with respect to the detected power load.

  The fuel cell power generator includes a fuel cell inverter that converts generated DC power into AC power, and the control means includes frequency detection means for detecting the frequency of the AC power output from the fuel cell inverter of the fuel cell power generator. It is also preferable to have frequency control means for controlling the frequency of the output power of the solar battery power generation device and the tidal current power generation device so as to synchronize with the frequency detected by the frequency detection means. Thereby, a plurality of different types of power generation devices can be connected to the same power supply system to supply power, and the power quality can be improved.

  The solar cell power generation device includes a solar cell inverter that converts generated DC power into AC power, and the tidal current power generation device includes a tidal current inverter that converts generated DC power into AC power. Is more preferably configured to synchronize the frequency of the AC power output from the solar cell inverter of the solar cell power generator and the AC power of the tidal current power generator with the frequency detected by the frequency detection means.

  It is also preferable that a heat pump is connected to the power transmission line network, and the load detection means is configured to detect the power loads of both the demand destination and the heat pump. By connecting the heat pump, surplus power can be converted into heat and used as a heat source.

  In this case, it is preferable that the control means is configured to control the power generation amount of the fuel cell power generation device to the maximum value in winter and to supply surplus power to the heat pump.

  It is preferable to further include heat storage means for recovering at least the heat discharged from the fuel cell power generator. Thereby, the heat generated simultaneously with the power generation in the fuel cell power generator can be used as a heat source.

  According to the present invention, since the control means controls the power generation amount of the fuel cell power generation device based on the difference between the detected power load and the power generation amount in the transmission line network, stable power can be supplied. It can be used as a stand-alone microgrid system that does not require a conventional commercial power grid.

1 is a block diagram schematically showing an overall configuration of a power supply system according to an embodiment of the present invention. It is a block diagram which shows schematically the structure of the fuel cell power generator of the electric power supply system of FIG. It is a block diagram which shows roughly the structure of the solar cell power generation apparatus of the electric power supply system of FIG. It is a block diagram which shows roughly the structure of the tidal current power generator of the electric power supply system of FIG. It is a flowchart which shows the control method of the electric power supply system of FIG.

  FIG. 1 schematically shows the overall configuration of a power supply system according to an embodiment of the present invention, FIG. 2 schematically shows the configuration of a fuel cell power generator, and FIG. 3 shows the configuration of a solar cell power generator. 4 schematically shows the configuration, FIG. 4 schematically shows the configuration of the tidal current power generation apparatus, and FIG. 5 shows the control method of the power supply system of FIG.

  The power supply system 100 includes a fuel cell power generation device 10, a solar cell power generation device 20, a plurality of tidal power generation devices 30A and 30B, and the fuel cell power generation device 10, the solar cell power generation device 20, and the tidal current power generation devices 30A and 30B. Connected power transmission line network 40, demand customer 50 connected to power transmission line network 40, heat pump 60 connected to power transmission line network 40, control device 70 as control means, fuel cell power generation device 10 and heat pump 60, and a heat storage tank 80 as a heat storage means.

  The fuel cell power generator 10 is mainly composed of a solid oxide fuel cell (SOFC) that uses city gas. The fuel cell power generation device 10 can control the amount of power generation by controlling the flow rate of the fuel gas. The fuel cell power generator 10 is connected to a power transmission network 40 via a bus 11 and a three-phase circuit breaker 12.

  As shown in FIG. 2, the fuel cell power generation apparatus 10 includes a fuel cell stack 10a, a DC-DC converter 10b whose input is connected to an output of the fuel cell stack 10a, and an input which is a DC-DC converter 10b. An inverter 10c connected to the output, a harmonic filter 10d inserted and connected between the output of the inverter 10c and the bus 11, and a voltage whose control input is connected to the bus 11 and whose output is connected to the input of the control device 70 A regulator 10e, a PWM (Pulse Width Modulation) generator 10f whose input is connected to the output of the voltage regulator 10e and whose output is connected to the control input of the inverter 10c, and a flow rate regulator whose input is connected to the output of the fuel cell stack 10a 10g and one input is connected to the output of the flow regulator 10g, the other input Is connected to the control device 70, the switch 10i inserted between the output of the flow rate selector 10h and the limiter 10j, the input connected to the output of the switch 10i, and the output of the fuel cell stack 10a. And a limiter 10j connected to the control input. The electric power generated from the fuel cell stack 10a is boosted by the DC-DC converter 10b, then converted to AC power by the inverter 10c, and the harmonic component generated by the inverter 10c is removed by the harmonic filter 10d. Thereafter, it is supplied to the bus 11. The harmonic filter 10d can improve the power quality in real time.

  In this fuel cell power generator 10, the output characteristics of the fuel cell stack 10a are set in advance. The control device 70 receives a current power generation amount signal from the voltage regulator 10e. Actually, the frequency of the bus 11 is measured from the period of the voltage, and when this frequency exceeds a specified frequency (such as 50 Hz), it is determined that the power is excessively supplied, and when the frequency is lower than that, it is determined that the power is insufficiently supplied. The controller 70 determines the power supply / demand balance described above, and issues a start / operation (Start) and stop (Stop) command to the flow rate selector 10h. On the other hand, the power output amount of the fuel cell stack 10a is input to the flow rate regulator 10g, and this value is output to the flow rate selector 10h. The flow rate selector 10h receives a start / operation (Start) and stop (Stop) command signal from the control device 70 and a signal indicating the output amount of the fuel cell from the flow rate regulator 10g, and commands the fuel flow rate to the switch 10i. Thus, the amount of fuel supplied to the fuel cell stack 10a is controlled. Here, the switch 10i is an actuator that adjusts the flow rates of fuel gas and air supplied to the fuel cell stack 10a. Furthermore, the limiter 10j is an actuator that restricts the upper limits of the flow rates of fuel gas and air determined by the flow rate selector 10h, and is the maximum fuel gas supplied to the fuel cell stack 10a. Air is regulated for safety. The output of the fuel cell stack 10a is controlled by the DC-DC converter 10b and the inverter 10c so that the frequency and voltage thereof become a reference voltage and a reference frequency (for example, 50 Hz). The power specification of the bus 11 is, for example, 50 Hz three-phase alternating current, and the effective value of the voltage is, for example, 400V.

The solar cell power generation device 20 is a mega solar device (for example, a module area of about 5560 m ² and a maximum output of 1000 kW) that mainly includes a plurality of solar cell panels and generates power using sunlight. It is connected to the power transmission network 40 via the circuit breaker 22. The amount of power generated by the solar cell power generator 20 varies depending on the influence of the weather.

  As shown in FIG. 3, the solar battery power generation apparatus 20 includes a solar battery panel 20 a composed of a plurality of solar battery panels, a DC-DC converter 20 b whose input is connected to the solar battery panel 20 a, and an input that is DC− The inverter 20c connected to the DC converter 20b, the harmonic filter 20d inserted and connected between the output of the inverter 20c and the bus 21, the control input is connected to the bus 21 and the output is connected to the input of the PWM generator 20f. A voltage regulator 20e, a PWM generator 20f whose output is connected to the control input of the inverter 20c, and a PWM circuit 20g whose input is connected to the solar cell panel 20a and whose output is connected to the control input of the DC-DC converter 20b. I have. The frequency and voltage of the output of the solar cell panel 20a are controlled by the DC-DC converter 20b and the inverter 20c. The power specification of the bus 21 is, for example, a three-phase AC of 50 Hz, and the effective value of the voltage is, for example, 400V. The PWM circuit 20g is configured to perform charge / discharge control in cooperation with the DC-DC converter 20b so that the output of the solar battery power generation device 20 is constant at a predetermined ratio with respect to the open circuit voltage. An MPPT (Maximum Power Point Tracking) circuit is provided in place of the PWM circuit 20g or in addition to the PWM circuit 20g, and the output of the solar battery power generation device 20 is controlled to be the maximum output according to the installation location and the weather. May be. In the circuit configuration shown in FIG. 3, a snubber circuit 20h composed of a resistor and a capacitor is provided immediately after the solar cell panel 20a. The snubber circuit 20h can prevent the DC-DC converter 20b and the inverter 20c from being damaged due to a sudden change in the amount of solar radiation. The control signal from the control device 70 is input to the inverter 20c via the voltage regulator 20e and the PWM generator 20f, and the frequency of the output power of the solar cell power generation device 20 is the reference frequency of the output power of the fuel cell power generation device 10. (For example, 50 Hz).

  The tidal current power generation devices 30A and 30B are arranged at different locations but have the same capacity. Each of the tidal power generators 30A and 30B uses, for example, a Darrieus type water turbine having a height of 1.9 m and a rotation diameter of 1 m as a tidal power generator. Darius-type water turbines can cope with changes in the direction of tidal currents during low and high tides. In tidal current power generation using tidal currents, the speed and direction of the tidal currents change at a constant period due to the fullness of the tidal currents, so it is relatively easy to predict the output fluctuations of the tidal current power generation devices 30A and 30B.

  As shown in FIG. 4, each of the tidal power generators 30A and 30B includes a tidal power generator 30a, a rectifier 30b whose input is connected to the output of the tidal power generator 30a, and a smoothing circuit 30g that receives the output of the rectifier 30b. The inverter 30c connected via the inverter, the harmonic filter 30d inserted between the output of the inverter 30c and the bus 31, the control input connected to the bus 31 and the output connected to the input of the PWM generator 30f. A voltage regulator 30e and a PWM generator 30f whose output is connected to the control input of the inverter 30c are provided. The output of the tidal current generator 30a is controlled in frequency and voltage by the rectifier 30b and the inverter 30c. The power specification of the bus 31 is, for example, 50 Hz three-phase alternating current, and the effective value of the voltage is, for example, 400V. Further, the control signal from the control device 70 is input to the inverter 30c via the voltage regulator 30e and the PWM generator 30f, and the frequency of the output power of the tidal power generation devices 30A and 30B is a reference for the output power of the fuel cell power generation device 10. It is controlled to synchronize with a frequency (for example, 50 Hz).

  The power transmission line network 40 is a system that transmits electric power supplied from the fuel cell power generation device 10, the solar cell power generation device 20, and the tidal current power generation devices 30A and 30B to the customer 50 at the power demand point. In this embodiment, it is an independent microgrid system that is not connected to another commercial power network. In the configuration of FIG. 1, a heat pump 60 is connected to the power transmission line network 40 in addition to the customer 50 as a load.

  The customer 50 is a variety of power supply destinations and includes various loads such as a household power load and an industrial power load. Therefore, in addition to a case where the demand changes within a short time within a few seconds, Changes occur for one year (seasonal).

  In this embodiment, the heat pump 60 is a device that converts electric energy into heat energy using surplus power. The heat obtained from the heat pump 60 is supplied to various facilities that use heat, or is stored in the heat storage tank 80. Depending on the region, the heat load varies greatly between summer and winter, so the change between seasons is large.

  The control device 70 is a device for controlling the operation of the power supply system 100. First, the control device 70 receives a measurement signal from the measuring device 90a that detects the power consumption of the customer 50 and a measurement signal from the measuring device 90b that detects the power consumption of the heat pump 60, and receives the demand 50 and the heat pump 60. To obtain the total power load. Next, information on the total power generation amount of the fuel cell power generation device 10, the solar cell power generation device 20, and the tidal current power generation devices 30A and 30B is acquired, and based on the difference between the acquired total power generation amount and the total power load, the fuel cell power generation device 10 power generation amount is controlled. Further, surplus power is supplied to the heat pump 60. In particular, in the winter season when there is a great demand for heat, the fuel cell power generation device 10 is set to the maximum operating state, and all surplus power is supplied to the heat pump 60.

  Further, the control device 70 detects the frequency of the AC power converted and output by the inverter 10c of the fuel cell power generation device 10, the output power of the solar cell power generation device 20 and the tidal current power generation devices 30A and 30B. Frequency control means for controlling the frequency so as to be synchronized with the frequency detected by the above-described frequency detection means.

  The heat storage tank 80 is a facility for storing a heat medium for heat storage. The heat storage tank 80 is connected to the fuel cell power generation apparatus 10 in addition to the heat pump 60, and is used as a heat storage means for recovering heat discharged from the heat pump 60 and the fuel cell power generation apparatus 10. The heat stored in the heat storage tank 80 is supplied to equipment that uses heat.

  Hereinafter, the operation control operation of the power supply system 100 in the present embodiment will be described. As shown in FIG. 5, when supplying power using the power supply system 100, the control device 70 first turns on the outputs of the tidal current power generation devices 30A and 30B (step S1). Next, the output of the solar battery power generation device 20 is turned on (step S2). Next, a control command for starting operation is sent to the fuel cell stack 10a of the fuel cell power generator 10, and the fuel cell power generator 10 is operated (step S3).

  Next, the output frequency of the fuel cell power generator 10 is detected (step S4). Thereafter, the detected output frequency of the fuel cell power generation device 10 is set as a reference frequency, the frequency of the output power of the solar cell power generation device 20 and the tidal current power generation devices 30A and 30B is controlled, and the set reference frequency (for example, 50 Hz). (Step S5).

  Next, power load information including power consumption of the customer 50 and the heat pump 60 is acquired (step S6). Here, the total power load is obtained by adding the load power of the customer 50 and the load power of the heat pump 60 from the acquired power load information. Next, the total power generation amount information including the total power generation amount that is the sum of the power generation amounts of the fuel cell power generation device 10, the solar cell power generation device 20, and the tidal current power generation devices 30A and 30B is acquired (step S7).

  Next, it is determined whether the total power generation amount is smaller than the total power load (step S8). Here, it may be determined whether the total power generation amount is smaller than the total power load by a predetermined value. When it is determined that the total power generation amount is not smaller than the total power load (that is, the total power generation amount is equal to or greater than the total power load) (in the case of NO), the process proceeds to step S9 and the output of the fuel cell power generation device 10 is decreased. Control is performed as follows (step S9). On the other hand, when it is determined that the total power generation amount is smaller than the total power load (in the case of YES), control is performed to increase the output of the fuel cell power generation device 10 (step S10).

  After reducing the output of the fuel cell power generation device 10 or increasing the output of the fuel cell power generation device 10, the power load information is acquired in the same manner as in step S6 (step S11). Then, the total power generation amount information is acquired in the same manner as in step S7 (step S12).

  Next, in step 13, it is determined whether or not an operation stop command has been issued. Here, when it is determined that there has been no operation stop command (in the case of NO), the process returns to step S8, and the processing operations of steps S8 to S12 are repeated to perform stable power supply.

  On the other hand, if it is determined in step 13 that there has been a command to stop operation, the process proceeds to step S14, and the output of the solar cell power generator 20 is turned OFF. Then, the outputs of the tidal power generation devices 30A and 30B are turned off (step S15), and the fuel cell power generation device 10 is stopped (step S16). Thereby, the operation control operation of the power supply system 100 is completed.

  As described above, in the present embodiment, the power supply system 100 includes the total power load in the transmission line network 40 of the customer 50 and the heat pump 60, the fuel cell power generation device 10, the solar cell power generation device 20 and the tidal current power generation device 30A. Since the total power generation amount in the 30B transmission line network 40 is detected and the power generation amount of the fuel cell power generation device is controlled based on the difference between the two, stable power can be supplied and conventional commercial power can be supplied. It can be used as a stand-alone microgrid system that does not require a power grid.

  Further, according to the present embodiment, the frequency detection means for detecting the frequency of the power output from the fuel cell power generation device 10 and the frequency of the output power of the solar cell power generation device 20 and the tidal current power generation devices 30A and 30B are detected by this frequency. Frequency control means for controlling to synchronize with the frequency detected by the means, so that a plurality of different types of power generation devices can be connected to the same power supply system to supply power, and power quality can be improved. Can be improved.

  Moreover, according to this embodiment, the heat pump 60 is connected to the power transmission line network 40 together with the customer 50, so that surplus power can be converted into heat and effectively used as a heat source.

  Furthermore, according to the present embodiment, the heat storage tank 80 is further provided as a heat storage means for recovering at least the heat discharged from the fuel cell power generator 10, so that it is generated simultaneously with the power generation in the fuel cell power generator 10. Heat can be effectively used as a heat source.

  In the above-described embodiment, the power supply system 100 has been described as an example including the three types of power generation devices of the fuel cell power generation device 10, the solar cell power generation device 20, and the tidal current power generation devices 30A and 30B. Is not limited to this. For example, you may make it further provide a wind power generator. Further, instead of the solar battery power generation apparatus 20, a wind power generation apparatus or a geothermal power generation apparatus can be used.

  In the above-described embodiment, the power supply system 100 may be provided with a power storage device.

  The embodiments described above are illustrative of the present invention and are not intended to be limiting, and the present invention can be implemented in various other modifications and changes. Therefore, the scope of the present invention is defined only by the claims and their equivalents.

  The power supply system of the present invention can be used for the purpose of configuring an independent power supply network mainly based on local energy that does not require an external power supply.

DESCRIPTION OF SYMBOLS 10 Fuel cell power generation device 10a Fuel cell stack 10b, 20b DC-DC converter 10c, 20c, 30c Inverter 10d, 20d, 30d Harmonic filter 10e, 20e, 30e Voltage regulator 10f, 20f, 30f PWM generator 10g Flow regulator 10h Flow rate Selector 10i Switch 10j Limiter 11, 21, 31A, 31B Busbar 12, 22, 32A, 32B Three-phase circuit breaker 20 Solar cell power generator 20g PWM circuit 20h Snubber circuit 30A, 30B Tidal power generator 30b Rectifier 30g Smoothing circuit 40 Transmission line network 50 customer 60 heat pump 70 control device 80 heat storage tank 90a, 90b measuring instrument 100 power supply system

Claims (6)

A fuel cell power generator that generates power using fuel gas; and
A solar cell power generation device that is composed of a plurality of solar cell panels and generates power using sunlight; and
A tidal power generation device that generates power using tidal currents, and
A power transmission line network connected to the fuel cell power generation device, the solar cell power generation device, and the tidal current power generation device and transmitting output power of the fuel cell power generation device, the solar cell power generation device, and the tidal current power generation device to a demand destination When,
Load detecting means for detecting an electric load of the transmission line network including at least the demand destination;
A power generation amount detecting means for detecting a power generation amount of the fuel cell power generation device, the solar cell power generation device and the tidal current power generation device;
Control means for controlling the power generation amount of the fuel cell power generation device based on the difference between the detected power load and the detected power generation amount ,
The fuel cell power generator includes a fuel cell inverter that converts generated DC power into AC power, and the control means detects the frequency of the AC power output from the fuel cell inverter of the fuel cell power generator. Power supply comprising: frequency detection means; and frequency control means for controlling the frequency of output power of the solar cell power generation device and the tidal current power generation device so as to be synchronized with the frequency detected by the frequency detection means. system.   The control means is configured to control the power generation amount of the fuel cell power generation device so as to compensate for the shortage amount in which the detected power generation amount is insufficient with respect to the detected power load. The power supply system according to claim 1. The solar cell power generation device includes a solar cell inverter that converts generated DC power into AC power, and the tidal current power generation device includes a tidal current inverter that converts generated DC power into AC power. The frequency control means is configured to synchronize the frequency of the alternating current power output from the solar battery inverter of the solar battery power generation apparatus and the alternating current power of the tidal current power generation apparatus with the frequency detected by the frequency detection means. The power supply system according to claim 1 , wherein the power supply system is a power supply system. Wherein and heat pump is connected to the grid, the load detecting means, any of claims 1 to 3, characterized in that it is configured to detect the power load of both the demand end and said heat pump power supply system according to any one of claims. 5. The power supply according to claim 4 , wherein the control unit is configured to control a power generation amount of the fuel cell power generation device to a maximum value in winter and supply surplus power to the heat pump. system. The power supply system according to any one of claims 1 to 5 , further comprising heat storage means for recovering at least heat discharged from the fuel cell power generator.

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