KR101940069B1 - Parallel operation control apparatus of solar electric induction generator - Google Patents

Abstract

The present invention relates to a parallel operation control apparatus for a solar photovoltaic induction generator. The control system of the solar motor induction generator is composed of a solar cell module for converting sunlight into DC power, a plurality of DC motors for generating rotation force by receiving DC power from the solar cell module, and a plurality of DC motors And a plurality of AC induction generators including a plurality of AC induction generators for outputting an AC power, wherein one end is connected to the solar cell module and the other end is connected to the DC motor to interrupt the flow of DC power applied from the solar cell module to the DC motor An output switch module which is connected to the power system stage of which one end is connected to the AC induction generator and the other end is connected to at least one load to control the flow of AC power applied from the AC induction generator to the power system stage, Installed between the solar cell module and the DC motor, measures the power output from the solar cell module A first sensor module installed at one end of the AC induction generator for measuring the rotation of the AC induction generator, a first sensor module receiving DC power to control the operation of the DC motor, And a control module for controlling the operation of the input switch module and the output switch module.

Description

[0001] The present invention relates to a parallel operation control apparatus for a solar electric induction generator,

The present invention relates to a parallel operation control apparatus for a solar photovoltaic induction generator, and more particularly, to a parallel operation control apparatus for a solar photovoltaic induction power generator that drives a DC motor with DC power and rotates the AC induction generator with a DC motor, To a parallel operation control apparatus for a generator.

Air pollution and global warming are accelerating as energy is produced and used indiscriminately. Air pollution and global warming are leading to natural destruction and become a big problem in society.

At present, the development of eco-friendly energy generation capable of minimizing natural destruction and generating energy is being developed and research centered on developed countries. For example, research and development on a solar cell that directly generates electric power using solar light has been actively conducted.

The technology to produce electricity from the sunlight is becoming an alternative energy source in the future because it is pollution-free and an infinite energy source, and the solar power generation facility is rapidly spreading. Moreover, large-scale photovoltaic power generation facilities capable of producing large amounts of electricity are being produced nationwide.

In response to the above-mentioned development of a large-capacity photovoltaic power generation facility, researches on a power conversion device for converting DC power output from a large-capacity photovoltaic panel into AC power have been actively conducted.

Most of the power conversion apparatuses that have been researched and developed are inverter power converters in which a plurality of inverters are connected in series and in parallel to convert three-phase AC power into one phase.

Such a power conversion apparatus has a problem in that power loss due to the heat generated from the respective components and the flow of the cooling air occurs in the power conversion process.

Korean Patent Publication No. 10-2014-0009631 (2014.01.23)

SUMMARY OF THE INVENTION Accordingly, the present invention has been made in view of the above problems, and it is an object of the present invention to provide an electric induction generator for converting DC power received from a solar cell into AC power, And to provide a parallel operation control device for a solar photovoltaic induction generator which is capable of outputting electric power while still being capable of outputting electric power.

The technical problem of the present invention is not limited to the above-mentioned problems, and other technical problems which are not mentioned can be clearly understood by those skilled in the art from the following description.

According to an aspect of the present invention, there is provided a parallel operation control apparatus for a solar photovoltaic induction generator including a solar cell module for converting sunlight into DC power,

An electric induction generating module including a plurality of DC motors that generate DC power by receiving DC power from the solar cell module, and a plurality of AC induction generators that are connected to the plurality of DC motors and output AC power,

An input switch module having one end connected to the solar cell module and the other end connected to the DC motor to interrupt the flow of DC power applied from the solar cell module to the DC motor,

An output switch module for controlling the flow of the alternating-current power applied from the alternating-current induction generator to the power system stage, the output switch module being connected to the power system stage having one end connected to the alternating current induction generator and the other end connected to at least one load,

A first sensor module installed between the solar cell module and the DC motor for measuring power output from the solar cell module,

A rotational speed measuring module installed at one end of the alternating current induction generator for measuring a rotation of the alternating current induction generator,

The first sensor module receives the DC power and controls the operation of the DC motor. The rotation speed of the AC induction generator is set at a predetermined speed, and the operation of the input switch module and the output switch module is controlled A control module,
The electric induction generation module is formed by connecting a first electric motor induction generator, a second electric motor induction generator, and a third electric motor induction generator, which include the DC motor and the AC induction generator, in parallel,
The input switch module includes a first input switch connected to the first electric motor induction generator, a second input switch connected to the second electric motor induction generator, and a third input switch connected to the third electric motor induction generator,
Wherein the output switch module includes a first output switch connected to the first induction generator, a second output switch connected to the second induction generator, and a third output switch connected to the third induction generator,
Wherein the control module controls the first input switch to turn on when the DC power is received from the first sensor module and is greater than or equal to a reference DC power value, If the rated output of the generator is exceeded, the second input switch is turned on,
When the sum of the rated output of the first electric motor induction generator and the second electric motor induction generator exceeds the sum of the rated output of the first electric motor and the second electric motor, And the third electric induction generator is driven in parallel with the first electric induction generator and the second electric induction generator to turn on the switch so that the speed measurement value is matched to the reference speed value Turns on the first output switch, the second output switch and the third output switch,
Wherein the control module turns the first output switch, the second output switch and the third output switch when the speed measurement values of the first to third electric motor induction generators match the reference speed value - Turn it on,
The first output switch, the second output switch and the third output switch are turned off when the speed measurement values of the first to third electric motor induction generators do not match the reference speed value ,
Wherein the control module controls the third input switch to turn on when the DC power output from the solar cell module is smaller than the sum of the rated outputs of the first electric induction generator, the second electric induction generator and the third electric induction generator, Off,

When the DC power output from the solar cell module is smaller than the sum of the rated outputs of the first and second induction generators, the second input switch is turned off, and the DC output from the solar cell module When the power value is '0', the first input switch can be turned off.

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The apparatus for controlling parallel operation of a photovoltaic induction generator according to the present invention is characterized in that when the position of the sun is changed according to the change of the morning and noon and the season of summer and winter, So that AC power can be stably outputted without loss of DC power.

1 is a schematic view of a parallel operation control apparatus for a solar photovoltaic induction generator according to an embodiment of the present invention.
2 to 4 are operation diagrams of a parallel operation control apparatus of the solar photovoltaic induction generator of FIG.

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention and methods for achieving them will become apparent with reference to the embodiments described in detail below with reference to the accompanying drawings. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein.

It should be understood, however, that these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art to which the present invention pertains. It can only be.

Hereinafter, a parallel operation control apparatus for a solar photovoltaic induction generator according to an embodiment of the present invention will be described with reference to FIG.

1 is a schematic view of a parallel operation control apparatus for a solar-electric-powered induction generator according to an embodiment of the present invention.

The parallel operation control apparatus 1 for a solar photovoltaic induction generator according to an embodiment of the present invention is configured to sequentially control a plurality of electric motor induction generators 20 sequentially in accordance with a change in output of the solar cell module 10, To convert DC power into AC power with little loss. For example, a parallel operation control device (1) for a solar-powered induction generator is designed to control the operation of a solar-electric induction generator by changing the position of the sun in accordance with the change of the morning and noon and the seasons of the summer and winter, The DC power produced by the module 10 can be converted into AC power without loss and output.

Further, when the parallel operation control device 1 of the solar photovoltaic induction generator reaches the predetermined rotational speed, the parallel operation control device 1 supplies AC power to the ammeter terminal A and outputs the AC power to the power system stage A and the motor- (20) is not broken.

The parallel operation control device 1 of the solar photovoltaic induction generator includes a solar cell module 10, an electric motor induction generation module 20 for receiving AC power and outputting AC power, An output switch module 40 whose one end is connected to the electric induction generating module 20 and the other end is connected to the electric power system end A, A first sensor module 50 for measuring the power output to the solar cell module 10, a rotational speed measurement module 60 for measuring the rotation of the electric induction generator, an input switch module 30 and an output switch module 40 As a component, a control module 70 for controlling the operation of the vehicle.

The electric induction generation module 20 may include first electric induction generators 21a and 22a, second electric induction generators 21b and 22b and third electric induction generators 21c and 22c, The module 30 may include a first input switch 30a, a second input switch 30b, and a third input switch 30c. The output switch module 40 may include a first output switch 40a, a second output switch 40b, and a third output switch 40c.

Hereinafter, the components included in and included in the parallel operation control apparatus 1 of the photovoltaic induction generator will be described in detail.

The solar cell module 10 is a device in which at least one solar cell cell for converting sunlight into electric energy is assembled. Each cell of the solar cell module 10 is formed of a silicon semiconductor in which an N-electrode for forming an electron and a P-electrode for forming a hole are bonded to each other when the light is irradiated, Thereby generating DC power. The solar cell module 10 applies the generated direct current power to the input switch module 30 and the electric motor-driven power generation module 20.

The electric induction generation module 20 converts the DC power supplied from the solar cell module 10 via the input switch module 30 into AC power and outputs the AC power. The electric induction generation module (20) has a structure in which a plurality of electric induction generators are connected in parallel. For example, the electric induction generating power generation module 20 is configured such that the first electric motor induction generators 21a and 22a, the second electric motor induction generators 21b and 22b, and the third electric motor induction generators 21c and 22c are connected in parallel. .

The first electric induction generators 21a and 22a to the third electric motor induction generators 21c and 22c are connected to the DC motor 21 which generates DC voltage and generates a rotating force and is connected to the rotating force of the DC motor And an alternating current induction generator 22 which is operated by the alternating current induction generator 22 and outputs an alternating current power.

Therefore, each of the electric induction generators can receive AC power and output AC power.

Here, the electric induction generator makes the rotor operate through the DC motor while connecting the stator of the induction motor to the power source, and drives the motor slightly faster than the synchronous speed and produces the electric power stably.

In particular, the electric induction generator is designed so that when the rotor is rotated, the direction of the electromotive force induced in the secondary winding is opposite, and the direction of the secondary current is also opposite. In the primary winding, the current in the opposite direction to that of the motor is output so as to cancel the magnetomotive force of the secondary current. Such an electric induction generator is simpler in structure and easier to handle than a synchronous generator. Also, the input switch module 30 connected to the DC motor 21 of each of the electric induction generators may be composed of a plurality of power semiconductors.

The power semiconductor is connected to the solar cell module 10 at one end and connected to the DC motor 21 to efficiently control power applied from the solar cell module 10 to the DC motor 21, The DC power can be stably supplied from the AC power source 10 to the DC motor 21. [

The input switch module 30 may be formed of the same number of input switches 30a to 30c as the number of the electric induction generators constituting the electric induction generating module 20 described above. Here, the input switch module 30 includes a first input switch 30a, a second input switch 30b, and a second input switch 30b corresponding to the first electric motor-driven generators 21a and 22a to the third electric motor-driven generators 21c and 22c, 3 input switch 30c.

At this time, the first input switch 30a is connected to the first electric motor induction generators 21a and 22a, the second input switch 30b is connected to the second electric motor induction generators 21b and 22b, The input switches 30a to 30c are connected to the third electric induction generators 21c and 22c so that the electric power supplied to the electric induction generators 20 can be efficiently controlled.

The alternating-current induction generators 22a to 22c of the electric induction generators are connected to the power system stage A to which at least one load is connected, and can supply the alternating electric power to be outputted. At this time, the output switch module 40 is connected to one end of the AC induction generator, so that the flow of AC power output from the AC induction generator 22 to the power system stage A can be smoothly controlled.

The output switch module 40 may be composed of a plurality of power semiconductors in the same manner as the input switch module 30. In addition, the output switch module 40 may be formed of the same number of output switches 40a to 40c as the number of the plurality of ac induction generators 22 described above. That is, the output switch module 40 may be formed of a first output switch 40a, a second output switch 40b, and a third output switch 40c.

Here, the first output switch 40a is connected to the first AC induction generator 22a, the second output switch 40b is connected to the second AC induction generator 22b, and the third output switch 40c And is connected to the third AC induction generator 22c so that each of the output switches 40a to 40c can efficiently control power supplied to the AC induction generators 22a to 22c.

The first sensor module 50 is installed between the solar cell module 10 and the DC motor 21 to measure the electric power applied from the solar cell module 10 to the DC motor 21, . Here, the first sensor module 50 may include a direct current voltmeter that measures a direct current voltage and a direct current meter that measures a direct current, and may obtain a direct current voltage and a direct current, respectively.

The rotational speed measuring module 60 is installed at one end of the motor-driven power generation module, that is, at one end of the alternating current induction generator, and measures the rotation of the alternating current induction generator. And applies the measured speed measurement value to the control module 70. [ The rotational speed measuring module 60 may be formed of the same number of rotational speed measuring devices as the plurality of alternating current induction generators 22 described above.

The rotational speed measuring module 60 may be formed of a first rotational speed measuring device, a second rotational speed measuring device, and a third rotational speed measuring device.

The control module 70 receives the DC power from the first sensor module 50 and controls the operation of the electric induction generator. And controls the operation of the input switch module (30) and the output switch module (40) in preparation for the speed of rotation of the electric induction generator.

The control module 70 may include a calculation circuit and a control circuit, and may be formed as a micro processing unit capable of decoding a received value and performing a calculation operation and a control operation using the calculated value. In particular, the control module 70 calculates and receives the measured values from the first sensor module 50 and the rotational speed measurement module 60 to precisely control the operations of the input switch module 30 and the output switch module 40 Can be adjusted.

The operation of the input switch module 30 and the output switch module 40 of the control module 70 will be specifically described when the operation of the parallel operation control device of the solar motor induction generator is described.

Hereinafter, the operation of the parallel operation control apparatus of the solar photovoltaic induction generator of FIG. 1 will be described in detail with reference to FIGS. 2 to 4. FIG.

2 to 4 are operation diagrams of a parallel operation control apparatus of the solar photovoltaic induction generator of FIG.

When the output of the solar cell increases or decreases with the lapse of time, the parallel operation control apparatus 1 for the solar motor-driven induction generator outputs the first The electric induction generators 21a and 22a to the third electric induction generators 21c and 22c are sequentially turned on or off in the parallel operation so that the electric power is converted with high efficiency.

2, the parallel operation control apparatus 1 for a solar photovoltaic induction generator is configured such that power applied to the control module 70 through the first sensor module 50, which is output from the solar cell module 10, The first input switch 30a is turned on to drive the first electric motor induction generators 21a and 22a.

In addition, when the speed measurement value signal is received from the rotational speed measurement module 60 to the control module 70 and the speed measurement value reaches a reference speed value, that is, a speed somewhat higher than 60 Hz, the first output switch 40a are turned on to transmit AC power to the power system stage A.

That is, when the output of the solar cell module is weak, only the first electric motor induction generators 21a and 22a are operated to convert the DC electric power into AC electric power and supply it to the electric power system stage A.

Referring to FIG. 3, when the DC power output from the solar cell module 10 is increased to exceed the rated output of the first electric motor induction generator, the parallel operation control device 1 of the solar motor- 22b together with the first electric induction generators 21a, 22a by turning on the second input switch 30b together with the second electric motor 30a. In addition, when the speed measurement value signal is received from the rotation speed measurement module 60 to the control module 70 and the speed measurement value reaches the reference speed value, that is, 60Hz, the first output switch 40a is connected in parallel The connected second output switch 40b is also turned on to transmit AC power to the power system stage A.

Referring to FIG. 4, the parallel operation control apparatus 1 for a solar photovoltaic induction generator is configured such that the direct current power output from the solar cell module 10 is increased so that the first and second induction generators 21a and 22a, The third input switch 30c is turned on together with the first input switch 30a and the second input switch 30b to turn on the first electric induction generator 21a 22a and the second electric motor-driven induction generators 21b, 22b and the third electric motor-driven electric generators 21c, 22c in parallel. In addition, when the speed measurement value signal is received from the rotational speed measurement module 60 to the control module 70 and the speed measurement value reaches the reference speed value, that is, 60 Hz, the first output switch 40a, The third output switch 40c connected in parallel to the output switch 40b is also turned on to transmit AC power to the power system stage A. [

On the other hand, when the output of the solar cell panel becomes smaller than the sum of the rated outputs of the first electric motor induction generators 21a and 22a to the third electric motor induction generators 21c and 22c, The third input switch 30c is turned off to shut off the drive of the third electric induction generators 21c and 22c. When the output of the solar cell panel becomes smaller than the sum of the rated outputs of the first electric motor induction generators 21a and 22a and the second electric motor induction generators 21b and 22b, the second input switch 30b is turned off, And blocks the driving of the second electric motor induction generators 21b and 22b.

Finally, when the output of the solar cell becomes smaller than the rated output of the first electric motor induction generators 21a and 22a, only the first electric motor induction generator is controlled to operate alone. When the output of the solar panel is '0' So that even the stand-alone operation of the induction generator is stopped.

 That is, the parallel operation control device 1 of the solar photovoltaic induction generator measures the amount of electric power output from the solar cell module 10 in the control module 70 in real time and then outputs the input switch module 30 and the output switch module 40), and each of the electric induction generators is operated so as to output the rated output, thereby converting the direct current power into the alternating electric power with high efficiency.

Further, when the speed measurement value output from the rotational speed measurement module 60 does not reach the reference speed value, that is, does not match, the parallel operation control apparatus 1 of the solar motor-driven induction generator outputs the output switch module 40 The AC power output from the first electric motor induction generators 21a and 22a to the third electric motor induction generators 21c and 22c is not applied to the electric power system stage A, And the plurality of electric induction generators can be protected.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, You will understand. It is therefore to be understood that the embodiments described above are in all respects illustrative and not restrictive.

1: Parallel operation control device of solar induction generator
10: solar cell module 20: electric induction generating module
21: DC motor 22: AC induction generator
21a: first DC motor 21b: second DC motor
21c: third direct current motor
22a: first AC induction generator 22b: second AC induction generator
22c: a third alternating current induction generator
30: Input Switch Module
30a: first input switch 30b: second input switch
30c: third input switch
40: Output switch module
40a: first output switch 40b: second output switch
40c: third output switch
50: first sensor module 60: rotational speed measuring module
70: Control module A: Power system stage

Claims (4)

A solar cell module for converting sunlight into DC power;
An electric induction generating module including a plurality of DC motors that generate DC power by receiving DC power from the solar cell module, and a plurality of AC induction generators that are connected to the plurality of DC motors and output AC power;
An input switch module having one end connected to the solar cell module and the other end connected to the DC motor to interrupt the flow of DC power applied from the solar cell module to the DC motor;
An output switch module which is connected to the AC power source of the AC induction generator, the other end of which is connected to at least one load, and which controls the flow of the AC power applied from the AC induction generator to the power system;
A first sensor module installed between the solar cell module and the DC motor for measuring power output from the solar cell module;
A rotational speed measuring module installed at one end of the alternating current induction generator for measuring a rotation of the alternating current induction generator,
The first sensor module receives the DC power and controls the operation of the DC motor. The rotation speed of the AC induction generator is set at a predetermined speed, and the operation of the input switch module and the output switch module is controlled Contains control module ,
The electric induction generation module is formed by connecting a first electric motor induction generator, a second electric motor induction generator, and a third electric motor induction generator, which include the DC motor and the AC induction generator, in parallel,
The input switch module includes a first input switch connected to the first electric motor induction generator, a second input switch connected to the second electric motor induction generator, and a third input switch connected to the third electric motor induction generator,
Wherein the output switch module includes a first output switch connected to the first induction generator, a second output switch connected to the second induction generator, and a third output switch connected to the third induction generator,
Wherein the control module controls the first input switch to turn on when the DC power is received from the first sensor module and is greater than or equal to a reference DC power value, If the rated output of the generator is exceeded, the second input switch is turned on,
When the sum of the rated output of the first electric motor induction generator and the second electric motor induction generator exceeds the sum of the rated output of the first electric motor and the second electric motor, And the third electric induction generator is driven in parallel with the first electric induction generator and the second electric induction generator to turn on the switch so that the speed measurement value is matched to the reference speed value Turns on the first output switch, the second output switch and the third output switch,
Wherein the control module turns the first output switch, the second output switch and the third output switch when the speed measurement values of the first to third electric motor induction generators match the reference speed value - Turn it on,
The first output switch, the second output switch and the third output switch are turned off when the speed measurement values of the first to third electric motor induction generators do not match the reference speed value ,
Wherein the control module controls the third input switch to turn on when the DC power output from the solar cell module is smaller than the sum of the rated outputs of the first electric induction generator, the second electric induction generator and the third electric induction generator, Off,
When the DC power output from the solar cell module is smaller than the sum of the rated outputs of the first and second induction generators, the second input switch is turned off, and the DC output from the solar cell module When the power value is '0', the first input switch is turned off, Parallel operation control of solar electric induction generator. delete delete delete

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