JPH021990B2 - - Google Patents

Description

[Detailed Description of the Invention] (Technical Field) The present invention relates to a control device for ocean thermal power generation, which improves followability and stability, makes it possible to set an output target value extremely close to the maximum output, and improves operating efficiency and This is designed to increase net output.

(Prior art) In general, an ocean temperature difference power generation device uses pumps to introduce warm seawater and cold seawater from the surface of the ocean into the device, and converts the temperature difference between the two seawaters into working fluid through a heat exchanger. Electric power is generated by converting thermal energy into electrical energy based on the gas-liquid state change of the working fluid. Conventionally, the control for making the power generation output of the power generation device match the target value has been manual control based on the amount of deviation from the target value, or PID control, that is, calculations such as proportional, integral, differential, etc. from the amount of deviation. A control method has been adopted in which a correction amount is calculated through processing, a throttle valve is operated based on the correction amount, and the amount of circulating fluid in the device is corrected to control the power generation output. However, this power generation device has large thermal inertia and inertia of the moving parts, and furthermore, the power generation output of this device depends on external factors that cannot be controlled artificially, such as the temperature of both hot and cold seawater and the outside air temperature. Therefore, the above-mentioned control has poor followability and stability with respect to the target value, and in order to carry out the above-mentioned control, it is necessary to perform the power generation equipment under the external factors for which it is installed. It is necessary to set a target value that is considerably lower than the maximum output that can be obtained, and furthermore, since this control is performed by operating a throttle valve, there is a loss of pump drive power, which reduces the operating efficiency and net output of the power generation equipment. The drawback was that it caused a decrease in output.

(Objective of the Invention) An object of the present invention is to eliminate the above-mentioned conventional drawbacks, and to improve the power generation output of the ocean temperature difference power generation device and the temperature of uncontrollable external factors such as the temperature of both hot and cold seawater and the outside air temperature.・Sensors are installed to quantitatively detect controllable internal factors such as the flow rate of cold seawater and the flow rate of working fluid, and the output of each sensor is processed by a microcomputer to determine the power generation output. We derive the functional relationship between the
By configuring the control device to control the pump drive power of cold seawater and working fluid to match the generated output to the target value, it is possible to improve followability and stability of output control and improve control accuracy. ,
A control device for ocean temperature difference power generation that enables the setting of an output target value that is extremely close to the maximum output under the external factors in which this power generation device is installed, thereby increasing the operating efficiency and net output of this power generation device. Our goal is to provide the following.

(Summary of the Invention) In other words, the control device of the present invention generates electricity through a turbine using the working fluid vapor formed by evaporating the working fluid using warm seawater pumped into the evaporator from the ocean surface layer by a warm seawater pump. The machine is driven to generate electricity, and the working fluid vapor that has passed through the turbine is condensed and liquefied by cold seawater pumped into a condenser from the deep ocean by a cold seawater pump, and the working fluid is supplied as a liquid. In the control device that controls the ocean temperature difference power generation device A configured to be pressurized into the evaporator again by a pump, there are sensors that quantitatively detect the temperature and flow rate of warm seawater, cold seawater, and working fluid, and the outside air temperature. An operating system that is equipped with sensors that detect the output of the generator and the generator, inputs the output of those sensors to a microcomputer via an analog/digital converter, and stores it in advance in a ROM attached to the microcomputer. It is configured to be able to output the results of memory read/write, numerical operations, logical operations, comparison judgments, and interrupt processing by
The system is characterized in that the drive power of each motor that drives each pump is controlled via a digital/analog converter and a power amplifier in accordance with the result of processing input from a digital converter. be.

(Example) The present invention will be described in detail below with reference to the drawings.

First, FIG. 1 shows an example of the configuration of an ocean temperature difference power generation device to be controlled by the present invention. In the illustrated configuration, the ocean temperature difference power generation device A includes a warm seawater pipe 1
The warm seawater pumped up from the ocean surface by the warm seawater pump 2 is supplied to the evaporator 3, and the working fluid is evaporated by heat exchange within the evaporator 3, and the steam of the working fluid is used to power the turbine. 4, a generator 5 is driven to obtain electric power.
Thus, the steam of the working fluid that has passed through the turbine 4 is condensed by heat exchange with cold seawater pumped into the condenser 8 by the cold seawater pump 7 from the deep ocean via the cold seawater pipe 6. The liquid working fluid is liquefied and further separated into gas and liquid by the liquid receiver 9, and the liquid working fluid is fed under pressure to the evaporator 3 by the liquid supply pump 10 and becomes vapor again. This cycle is repeated. Due to the temperature difference between the warm seawater and the cold seawater in the condenser 8, the thermal energy collected in the power generator A is converted into electrical energy based on the change in the gas-liquid state of the working fluid and extracted. . Therefore, the power generation output changes continuously and smoothly in response to changes in internal and external factors. In addition, a warm seawater pump motor 11, a cold seawater pump motor 12, and a liquid supply pump motor 13 are connected to and interlocked with each of the pumps 2, 7, and 10 for warm seawater, cold seawater, and working fluid, respectively. The driving power of the motors 11, 12, and 13 is controlled by the control device B of the present invention whose detailed configuration is shown in FIG.

On the other hand, the control device B shown in the second diagram includes a detection unit 14,
It is composed of a calculation section 15, an operation section 16, and front and rear interfaces 17 and 18. Of these, the detection unit 14 includes a warm seawater temperature sensor 19 and a warm seawater flow rate sensor 20 provided in the warm seawater pipe 1 , a cold seawater temperature sensor 21 and a cold seawater flow rate sensor 22 provided in the cold seawater pipe 6 , a condenser 3 and a turbine 4 . It is composed of a working fluid temperature sensor 23, a working fluid flow rate sensor 24, an outside air temperature sensor 25, and an output sensor 26 provided in the generator 5, and the output of each sensor 19-26 is , both are connected to the front interface 17 via the transmission line 27.
It is configured to input. Note that each sensor is provided with an amplifier for dealing with attenuation and noise intrusion during transmission.

On the other hand, the front interface 17
The inputs from 9 to 26 are amplified by an amplifier 28, noise that has entered during transmission is removed by a filter 29, and then multiplexed in time series by a multiplexer 30. The signals are sequentially sampled and held and output to the arithmetic unit 15 via the analog/digital converter 32. In addition, multiplexer 30 and analog/
The digital converter 32 operates in synchronization with the arithmetic unit 15 in response to a synchronization signal from the arithmetic unit 15 .

Furthermore, the following removal methods can be considered for the noise removal described above, depending on the nature of the mixed noise.

(i) Make the amplifier 28 a differential type.

(ii) The filter 29 is a Butterworth-type or Thievisiev-type low-pass filter, and its cutout frequency is set to 1/2 or more of the sampling frequency.

(iii) Make the multiplexer 30 a differential type.

(iv) The analog/digital converter 32 is of a double integration type and its sampling period is synchronized with the power supply frequency.

(v) A tracking and hold amplifier 33 is inserted at the output end of the analog/digital converter 32.

Note that each of the above-mentioned terms (i) to (v) can be used alone or in combination as appropriate to perform the required noise removal.

Furthermore, the calculation unit 15 includes a microcomputer (CPU) 34, a clock generator 35, and a ROM 36.
and RAM 37. Of these, the ROM 36 stores in advance an operating system and control language for operating the CPU 34 itself, and the RAM 37
A control program derived from a control algorithm to be described later is stored in advance, and is configured to operate in synchronization with a synchronizing signal from a clock generator 35. Note that the synchronization signal is also output to the rear interface 18.

Next, the CPU 34 processes the input data from the front interface 17 according to the control program read from the ROM 36, and then operates each pump motor 1 for both hot and cold seawater and water supply.
1, 12 and 13 are output to the rear interface 18 as signals to be controlled.

On the other hand, the rear interface 18 is a digital/
Analog converter 38, low pass filter 39, distributor 40 and hold amplifier 41
-1 to 41-3, CPU3
After converting the signal from 4 into an analog voltage value by the digital/analog converter 38, the signal is sent to each motor 11, 12, and 13 under control via a low-pass filter 39 and a distributor 40.
Hold amplifiers 41-1 to 41-4 connected to
1-3, and those amplifiers 41-1 to 41-4.
1-3, the analog voltage value is held until the next input.

In addition, the operation unit 16 controls each motor 11, 12, 1
The power to drive each motor is controlled via the power amplifiers 42-1 to 42-3 using the voltages held in the hold amplifiers 41-1 to 41-3, respectively, depending on the characteristics of each motor. , the power controllers 42-1 to 42-3 are constituted by power control equipment such as a reactor or an SCR inverter.

Therefore, the control algorithm described above applies to each pump 2, 7, 1 constituting the ocean temperature difference power generation device A.
0, evaporator 3, condenser 8, turbine 4, generator 5
A mathematical model indicating the characteristics of the entire power generation device A is derived from the characteristic values such as, and each sensor 19 of the mathematical model is
This is to control the driving power of each pump 2, 7, 10 based on the deviation with respect to the output of 26 to match the target value under optimal conditions.

In addition, if it is difficult to create a mathematical model because it is expected that errors will accumulate in parts assembled during on-site work such as piping, etc., each sensor 19 to 2
By inputting in advance into the calculation unit 15 a program that statistically processes the measured data obtained in step 6 using the least squares method, maximum likelihood method, etc. to derive an approximate model, the control can be carried out, and furthermore, for each predetermined period,
By sequentially updating the approximate model based on data accumulated during operation, it is also possible to cope with changes in the performance of the power generation device A, such as contamination of the heat transfer surface of the evaporator 3.

Further, from each sensor 19 to 26, the calculation unit 15
The data input to the CPU 34 is processed according to the control program, and then the driving power of the pump motors 11, 12, 13 for both hot and cold seawater and liquid supply is controlled, and the data is processed in accordance with the control program. The power generation device A can be controlled to the optimum state under the factors.

Therefore, the power generation output of power generation device A can be made to follow the target value set extremely close to the maximum output at high speed with high accuracy and stability. Since no pump is used, there is no loss of pump drive power and the net output can be increased. Furthermore, all control methods and control programs are stored in the ROM of the calculation unit 15.
36 and RAM 37, the control method and control program can be changed without changing the configurations of power generation device A and control device B.
It is easy to carry out, and the latest and most optimal control methods can be introduced in keeping pace with advances in control theory and control technology.

(Effects) As is clear from the above explanation, according to the present invention, sensors that quantitatively detect internal and external factors that affect the power generation output of the ocean temperature difference power generation device are arranged at various locations, and the output of each sensor is The results are input to a microcomputer via an analog/digital converter and processed based on pre-stored control algorithms and control programs. By configuring the control device to control the operation of the pump motor that drives the fluid, the control accuracy, followability, and stability of output control can be improved, and the ocean temperature difference power generation device can be This has the particular effect of increasing the efficiency and net output of the ocean temperature difference power generation device by making it possible to set a target output value that is very close to the original maximum output.

[Brief explanation of drawings]

FIG. 1 is a block diagram showing an example of the configuration of an ocean temperature difference power generation device controlled by the control device of the present invention, and FIG.
The figure is a block diagram showing an example of the configuration of the control device of the present invention. A... Ocean temperature difference power generation device, B... Control device, 2... Warm seawater pump, 3... Evaporator, 4...
Turbine, 5... Generator, 7... Cold seawater pump,
8...Condenser, 10...Liquid supply pump, 11...Warm seawater pump, 12...Cold seawater pump, 13...Liquid supply pump, 19...Warm seawater temperature sensor, 20...
Same flow rate sensor, 21...cold seawater temperature sensor, 22
... Same flow rate sensor, 23... Working fluid temperature sensor, 24... Same flow rate sensor, 25... Outside air temperature sensor, 26... Output sensor, 32... Analog/
Digital converter, 34...Microcomputer, 36...ROM, 37...RAM, 38...
Digital/analog converter, 42-1 to 3...power amplifier.

Claims (1)

[Claims] 1 Working fluid vapor is formed by evaporating the working fluid using warm seawater pumped into the evaporator from the ocean surface layer by a warm seawater pump, and the working fluid steam is used to drive a generator through a turbine to generate electricity, and the steam passes through the turbine. The working fluid vapor is condensed and liquefied by cold seawater pumped into the condenser from the deep ocean by a cold seawater pump, and the working fluid restored to a liquid state is again pressurized into the evaporator by a liquid supply pump. In the control device that controls the ocean temperature difference power generation device A, sensors 19 to 2 quantitatively detect the temperature and flow rate of warm seawater, cold seawater, and working fluid, respectively.
4, and sensors 25 and 26 for detecting the outside temperature and the output of the generator, respectively, are provided, and the outputs of these sensors 19 to 26 are input to the microcomputer 34 via the analog/digital converter 32. attached to the microcomputer 34
A control program that is configured to output the results of memory read/write, numerical operations, logical operations, comparison judgments, and interrupt processing performed by the operating system that is stored in advance in the ROM 36, and that is stored in the RAM 37 in advance. According to the result of processing the input from the analog/digital converter 32, the digital/analog converter 38 and the power amplifiers 42-1 to 42-3
1. A control device for ocean temperature difference power generation, characterized in that the control device is configured to control the driving power of each motor 11, 12, 13 that drives each pump 2, 7, 10, respectively.