KR101926010B1 - A power converter system using new-renewable energy - Google Patents

Abstract

The present invention relates to a power conversion system using renewable energy, which receives renewable energy from a renewable energy generation unit and power from a commercial power source and supplies the renewable energy and the power to at least two water electrolysis devices configuring a DC link unit in common and connected in parallel to each other so as to control the water electrolysis devices to generate hydrogen. The system comprises: an AC/DC PWM rectifier converting the commercial power source to a DC power source and controlling a supply voltage of the DC power source; a DC/DC converter following a maximum power point with respect to the power of the renewable energy and controlling a supply current based on the supply voltage controlled by the AC/DC PWM rectifier; a switch unit having a switch on each of the at least two water electrolysis devices so as to turn on/off the power supply to the water electrolysis devices by on/off operations of the switch; and a control unit controlling the AC/DC PWM rectifier, the DC/DC converter, and the switch unit. With the above system, the steps of a conventional P&O method are subdivided to improve the response of the power converter even when generated power fluctuation is very large, and the water electrolysis devices connected in parallel to each other are selectively turned on/off according to the generated power of the renewable energy so as to maximize the use of the generated power, prevent deterioration due to overvoltage, and maximize the use of surplus power.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power conversion system using renewable energy,

The present invention provides a water electrolysis apparatus for producing hydrogen by electrolyzing raw water (water) for drinking water, industrial water, seawater desalination, etc., and is provided with an output of a DC / DC PWM rectifier with AC / DC PWM rectifier output connected in parallel, AC / DC PWM rectifier with voltage control, DC / DC converter with current control, To a power conversion system using renewable energy to supply power to the device.

We are establishing and implementing greenhouse gas reduction targets through climate agreements so that the global average temperature does not rise above 2 ℃ due to environmental problems caused by global warming. To this end, we are making efforts to reduce greenhouse gas emissions by reducing the use of chemical raw materials and expanding renewable energy sources.

Solar power and wind power are typical renewable energy, and the generated power is used in connection with power system through DC / AC inverter, which is a power converter, and it occupies a large part in utilization of renewable energy. However, due to the limitation of the operating voltage range of the inverter, which is a power converter, and irregular power generation, the amount of power generation is limited. In addition, since there is a minimum operating voltage range of the inverter which is a power converter, there is a disadvantage that surplus power exists when the voltage is lower than this voltage, and a large installation area is required according to the required power generation amount.

Therefore, various complex systems are being developed as a way to utilize this surplus power. In particular, as a substitute energy source that can replace fossil fuels that can produce the most energy, the importance of technology for producing hydrogen as a clean energy is highlighted, and many developments have been made.

Currently, hydrogen production is largely based on fossil raw materials such as coal, natural gas and petroleum, and renewable energy such as bio, solar and wind power, and nuclear power. From an economic point of view, it is most appropriate to produce hydrogen through a reformer, a natural gas that is a fossil raw material. However, since natural gas can be used as a direct energy source, it does not meet the purpose of using renewable energy. Therefore, a method using a renewable energy source having a direct current output is needed.

In order to produce hydrogen, electric energy is essentially used. The technology to produce hydrogen by using this is divided into Alkaline Electrolysis (AE) water electrolysis and Polymer Electrolyte Membrane (PEM) water electrolysis. Also, it is classified into High Temperature Electrolysis (HTE) technology using a solid oxide.

The power-receiving technique has advantages and disadvantages depending on the method. The alkaline method has a disadvantage in that it requires a lot of electric energy because the current density is lower than that of the polymer electrolyte method, and the polymer electrolyte method has a disadvantage in that an expensive catalyst such as platinum or iridium is used. However, it is predicted that the polymer electrolyte method will be advantageous in the price and performance competition in the future, and the technology using the polymer electrolyte method is being developed.

Therefore, there is a need for a technique for obtaining the energy source hydrogen while using less commercial electric energy. In particular, considering the cost of simple installation, considering the social cost, it is possible to use renewable energy with inconsistent generation output and AC / DC PWM rectifier, which is a commercial power source, as an auxiliary means, There is a need for a technique that can control the DC / DC converter to supply power to the load electrolysis unit and maximize the production of hydrogen.

That is, two converters must be used, two DC power converters are connected to form a DC link unit, and two power converters have to control the output voltage of each other. However, since the power converters control each other, the DC link portion is raised. Therefore, the use of renewable energy with inconsistent generation power can cause a larger number of such symptoms.

In order to prevent this, an additional controller for the output voltage of each other is required or a separate control circuit is required to control the DC output voltage of each power converter separately. For this purpose, a method of calculating the error value of the power converter and compensating the control value of the converter with this error value is widely used [Patent Document 1].

In addition, a technique of storing hydrogen by electrolyzing water with various non-continuous energy sources has been proposed [Patent Document 2]. However, if hydrogen is produced by using a non-continuous energy source such as sunlight, wind power, etc., it is necessary to control the power converter according to the generated power fluctuation. Therefore, deterioration due to overvoltage must be solved.

In addition, a technology has been proposed in which electric energy is generated through sunlight to supply electric power, hydrogen and oxygen are generated by supplying electric power to a power receiver with surplus electric power, and high pressure is compressed and stored through a control unit [ ]. The prior art is a system for distributing power according to generated power, which is transmitted as commercial power using sunlight. However, the prior art does not disclose any details of controlling the power supply to the power receiver using surplus power of the sunlight.

Therefore, there is a need for a technique capable of solving the above problems, effectively using surplus electric power of sunlight, and solving the deterioration problem of the water electrolytic solution.

Korean Published Patent Application No. 10-2012-0073989 (published on July 1, 2012) Korean Registered Patent No. 10-1321839 (issued October 23, 2013) Korean Registered Patent No. 10-1679003 (issued on November 24, 2016)

It is an object of the present invention to solve the above-mentioned problems and to provide a power supply system and a power supply control method thereof, in which, in order to obtain hydrogen for energy while using less commercial electric energy, The AC / DC PWM rectifier is used as an auxiliary means and the DC / DC converter is controlled according to the generation output of renewable energy to supply renewable energy to the load water electrolytic unit and maximize the production of hydrogen. And to provide a power conversion system using the same.

In addition, the object of the present invention is to provide a polymer electrolyte capable of producing hydrogen after a few minutes by supplying electric energy above a certain voltage at which the electrode can react, in order to produce hydrogen using a discontinuous energy source such as sunlight, PEM) type electrolytic water electrolysis device is introduced to provide a power conversion system using renewable energy.

Particularly, an object of the present invention is to set a minimum voltage required by each of the water electrolytic apparatuses and a maximum voltage not exceeding an overvoltage by parallelly connecting a plurality of electrolytic water electrolysis apparatuses, And to provide a power conversion system using renewable energy, which supplies power to the power receiving device within the power conversion system.

It is also an object of the present invention to provide a power conversion system using renewable energy that controls operation of each of the water electrolytic water electrolysis apparatuses so as to perform cross operation of the water electrolytic water electrolysis apparatus

In order to achieve the above object, according to the present invention, there is provided a power generation system for generating renewable energy of a renewable energy generation unit and generating power by supplying power to a commercial power source, supplying a power source to at least two power- The AC / DC PWM rectifier converts the commercial power to DC power and controls the supply voltage of the DC power. A DC / DC converter for following a maximum power point with respect to the power of the renewable energy and controlling a supply current based on a supply voltage controlled by the AC / DC PWM rectifier; A switch unit having a switch in each of the at least two water electrolytic dissolution apparatuses and turning on / off the power supply to the water electrolytic dissolution apparatus by on / off of the switch; And a control unit for controlling the AC / DC PWM rectifier, the DC / DC converter, and the switch unit.

According to another aspect of the present invention, there is provided a power conversion system using renewable energy, wherein the controller controls the DC / DC converter such that the power point state is a fourth power point when the power increment is negative and the voltage increment is negative. Set the power point state to a third state when the voltage increment is negative and the voltage increment is positive and if the power increment is positive and the voltage increment is negative initially set the power point state Sets the power point state to a first state at the beginning if the power increment is positive and the voltage increment is positive and sets the power point state to a first state when the power increment is positive and the power increment when the voltage increment is negative Thereafter, the power point state is set to the sixth state if the power point state is the first, fourth, and sixth states, otherwise, the power point state is set to the second state, The power point state is set to the fifth state if the power point state is the second, third, and fifth states after the first time when the power increment is positive and the voltage increment is positive, To the first state, and increases the reference current when the power point state is set to the first, fourth, and sixth states, and when the power point state is set to the second, third, and fifth states Thereby reducing the reference current.

Further, in the power conversion system using renewable energy, the control unit sets the output current limit so as to be output only to a value lower than or equal to a predetermined current value for the AC / DC PWM rectifier, And the power is supplied by selecting a part of the plurality of power receiving devices according to the decrease.

Further, in the power conversion system using renewable energy, the control unit controls the switch unit so that the power supplied to the power receiving unit (hereinafter referred to as " supply power ") is divided by the number of current- If the divided power is greater than a preset maximum power, one of the powered off devices that are turned off is selected and turned on. If the divided power is smaller than the preset minimum power, and selectively turning off one of the on-channel water-electrolysis devices.

Further, the present invention provides a power conversion system using renewable energy, wherein the system includes: a fuel cell for charging electric power using hydrogen produced by the electrolytic water electrolysis device; and a DC power source for the fuel cell, And an output of the DC / AC converter is supplied instead of the commercial power or is supplied together with the commercial power.

As described above, according to the power conversion system using renewable energy according to the present invention, the current is controlled by the power converter that receives the renewable energy as input while simultaneously controlling the voltage by the power converter that receives the commercial power source, The power can be minimized, the burden on the controller can be reduced, and the system can be stably operated.

Further, according to the power conversion system using the renewable energy according to the present invention, by refinement of the steps of the conventional maximum power point tracking method, the response of the power converter is improved even when the generated power fluctuation is very large, The effect of preventing occurrence of a phenomenon or severely lowering the output voltage is obtained.

Further, according to the power conversion system using renewable energy according to the present invention, a plurality of water electrolysis apparatuses are connected in parallel, selectively turned on / off, and power is supplied to each of the water electrolysis apparatuses between a minimum voltage and a maximum voltage , The deterioration of the electrode due to the overvoltage and the electrochemical deterioration of the electrolyte membrane can be prevented, and the surplus electric power which can not be used when the electric power is less than a certain power generation amount can be utilized at the maximum.

1 is a block diagram illustrating a configuration of a power conversion system using renewable energy according to a first embodiment of the present invention.
2 is a block diagram of a configuration of an AC / DC PWM rectifier according to a first embodiment of the present invention;
3 is an equivalent circuit of a DC / DC buck converter of a DC / DC converter according to the first embodiment of the present invention.
4 is a flowchart illustrating a method of controlling a power conversion system using renewable energy according to a first embodiment of the present invention.
5 is a diagram illustrating a step of controlling output voltage and output current by the AC / DC PWM rectifier and the DC / DC converter according to the first embodiment of the present invention.
6 is a graph showing a VP characteristic curve of a photovoltaic power generation to cope with in the present invention.
7 is a flowchart illustrating a step of calculating a reference current following a maximum power point according to the first embodiment of the present invention.
FIG. 8 is a graph of a section according to power fluctuation for applying the improved P & O algorithm according to the first embodiment of the present invention.
9 is a diagram for explaining a method of estimating a maximum power point according to the first embodiment of the present invention.
10 is a flowchart showing the operation of a power supply switch section for maintaining the operation time of the water electrolytic apparatus according to the first embodiment of the present invention.
11 is a flowchart for explaining on / off control of the water electrolytic apparatus according to the second embodiment of the present invention.
12 is a block diagram of a configuration of a power conversion system using renewable energy according to a second embodiment of the present invention;

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the drawings.

In the description of the present invention, the same parts are denoted by the same reference numerals, and repetitive description thereof will be omitted.

First, a power conversion system 100 using renewable energy according to a first embodiment of the present invention will be described with reference to FIG.

1, a power conversion system 100 using renewable energy according to the present invention includes a renewable energy generation unit 10 that generates electricity using renewable energy, a DC that converts power generated by renewable energy, An AC / DC PWM rectifier 90 for performing voltage control on a commercial power source, a switch unit 30 for turning on / off the power supply, a control unit 40 for controlling power conversion, (50) for decomposing and producing hydrogen, and a storage device (60) for storing the produced hydrogen.

First, the renewable energy generation unit 10 is a device for generating electricity by generating new and renewable energy such as a solar power, a wind power, or a direct current power generation device. Preferably, the renewable energy generation unit 10 may be a solar power generation device. In this case, the renewable energy generating unit 10 is constituted by a plurality of solar cell arrays, and is used for collecting sunlight incident from the outside to generate electricity, and usually silicon and a composite material are mainly used.

Next, the water electrolytic solution 50 is a device for producing hydrogen by electrolyzing water. It is the most economical, reliable and easy to mass-produce the method of purifying water obtained from nature to produce hydrogen and electrolyzing it.

Preferably, the water electrolytic dissolution apparatus 50 is composed of at least two or more water electrolytic dissolution apparatuses (or unit devices), and the plurality of water electrolytic dissolution apparatuses are connected in parallel to each other.

Each water electrolyzer must be supplied with a power supply of at least the minimum voltage in order to produce hydrogen for energy. However, renewable energy alone is limited to the production of hydrogen, the energy source.

Therefore, the water electrolyzer 50 is configured to generate hydrogen by receiving both the renewable energy output and the output of the commercial power source. That is, the renewable energy output is supplied by current control and the output of the commercial power supply is supplied by voltage control to a plurality of power receiving units 50 connected in parallel.

Further, when a large number of power receiving and electrolyzing apparatuses 50 are connected in parallel and each of them is turned on / off by the switch unit 30 to supply power less than the power required by the load, The input power switch 30 is cut off, and the remaining power receiving device 50 is continuously supplied with power. If the output of the commercial power source is limited and the output of the renewable energy is small, the power that is required by the load can be supplied with a power lower than that required by the load.

That is, the power supplied by combining the output of the renewable energy and the output of the commercial power supply can be adjusted, and the overall load of the water electrolytic unit 50 can be adjusted by the switch unit 30. Therefore, it is possible to minimize surplus power of new renewable energy, and it is suitable for system construction for mass production of hydrogen.

Next, the AC / DC PWM rectifier 90 is an AC / DC converter, which is a power converter that receives a commercial power supply and supplies a DC output voltage. The AC / DC PWM rectifier 90 converts AC power of an input commercial power supply into DC power and performs voltage control by a PWM control signal.

Next, the DC / DC converter 20 is a power converter that converts the power input from the renewable energy generating unit 10 and supplies the converted power to the power receiving unit 50. The DC / DC converter 20 receives input of the renewable energy that is generated by the DC power supply, and takes into consideration the characteristics of the water electrolytic apparatus 50 that requires a voltage. The buck type DC / Configure transducer.

On the other hand, the DC / DC converter 20 and the AC / DC PWM rectifier 90 are controlled by the controller 40.

Next, the switch section 30 is constituted by a plurality of load switches, and each switch is connected to each of the plurality of the water electrolytic apparatuses 50. [ The output of the DC / DC converter 20 is supplied to or blocked from each of the power receiving units 50 in accordance with the on / off of each switch of the switch unit 30. [

The switch unit 30 is turned on / off under the control of the control unit 40.

Next, the control unit 40 is a device for controlling the DC / DC converter 20, the AC / DC PWM rectifier 90, the switch unit 30, and the like.

That is, the control unit 40 controls the DC / DC PWM rectifier 90 that receives the commercial power as the input, and outputs the AC / DC PWM to the DC / DC converter 20, The current control is performed with the main control based on the output voltage of the rectifier 90. This makes it possible to stably operate the power converter without having a compensation circuit for the control error that each power converter has.

First, the control unit 40 controls the AC / DC PWM rectifier 90, and controls the DC output voltage with respect to the input commercial power. At this time, preferably, the current limit setting value is adjusted by the user. That is, when the user sets the current limit setting value (current limit value), the control unit 40 controls the output current of the commercial power supply in the AC / DC PWM rectifier 90 so that the output current does not exceed the current limit setting value . This makes it possible to make the most of renewable energy while minimizing utility power.

In addition, when renewable energy is used as sunlight, the amount of electricity generated is very small if there is no sunshine. However, when the water electrolytic solution 50 is to be operated even during such a time, the control unit 40 increases the output current of the AC / DC PWM rectifier 90 to control the water electrolytic device 50 to continuously produce hydrogen can do. Preferably, the capacitance of the AC / DC PWM rectifier 90 is also set to the same capacitance required by the load.

The controller 50 controls the DC / DC converter 20 so that the output voltage controlled by the AC / DC PWM rectifier 90 is used as a reference voltage to perform current control according to the maximum power estimation do.

That is, in the conventional maximum power follow-up system, the output voltage is controlled by the amount of power generated by the renewable energy. However, in the system according to the present invention, since the control unit 50 controls the output voltage to the AC / DC PWM rectifier 90, the DC / DC converter 20 controls the power generation amount of the renewable energy, The current control is performed in accordance with the maximum power estimation using the output voltage controlled by the AC / DC PWM rectifier 90 as a reference voltage.

The control unit 50 controls the voltage duty ratio in the buck converter of the DC / DC converter 20 in accordance with the maximum current required in the water electrolytic unit 50, which is a load, in a period in which the power fluctuation is rising. Thus, the DC / DC converter 20 is controlled to the maximum current according to the fluctuation of the power generation amount to supply the current to the load.

Next, the storage device 60 is a device for storing generated hydrogen.

Next, the configuration of the AC / DC PWM rectifier 90 according to the first embodiment of the present invention will be described in detail with reference to FIG.

AC / DC PWM rectifier 90, which converts AC to DC, uses voltage source PWM to control input harmonics, power factor, and so on. The PWM rectifier of the AC / DC PWM rectifier 90 has a bidirectional power conversion characteristic and has a function of controlling harmonic elimination and power factor. For this reason, PWM rectifiers are widely used in the industrial field.

As shown in FIG. 2, the operation block of the PWM rectifier shows the relationship between the input / output voltage and current of the rectifier and the existence function of the switch which is a control variable. Input currents are determined when input power supply voltages (V _sa , V _sb , V _sc ) and converter output voltages (V _oa , V _ob , V _oc ) are applied across the resistor and inductor. When the input current of the rectifier is generated, the direct current is determined according to a function for controlling the switching element. Then, given the DC current in the DC circuit, the DC voltage is determined and the rectifier output voltage (V _oa , V _ob , V _oc ) is determined by the control of the switching device. That is, in a three-phase PWM rectifier, the voltage and current of the associated circuit are coupled to each other, and thus control is performed.

In case of 3-phase PWM rectifier, the switching function of the system is defined as follows. That is, the following equation defines the averaging switching function for the AC input side and the DC output side for the three-phase PWM rectifier.

[Equation 1]

Here, S _a , S _b , and S _c represent the sources of the three-phase power source, and d represents the DC voltage magnitude ratio to the input voltage. In addition, w and t represent angular frequency and time of the input power source, and? Represents a phase angle.

As shown in Fig. 2, in an operation block of the AC / DC power converter or AC / DC PWM rectifier 90, a voltage applied to the reactor at the input of the switching element and a voltage generated at the PWM rectifier are distinguished. These are defined as follows.

&Quot; (2) "

Here, voltage and frequency disturbances of the grid power must be controlled. That is, dq conversion is required for phase synchronization such as harmonic elimination and power factor control.

The d-q conversion of the circuit parameters for the input is defined as follows.

&Quot; (3) "

In addition, the current limit value of the AC / DC PWM rectifier 90 can be set. Considering the characteristics of the water electrolytic apparatus 50, which is a load like this, the use of the commercial power supply can be minimized.

Next, the configuration of the DC / DC converter 20 according to the first embodiment of the present invention will be described in detail with reference to FIG.

As described above, the DC / DC converter 20 is configured as a power converter in the present invention. The DC / DC converter 20 may be configured in the form of a buck converter that reduces the output of the DC / DC converter 20 in consideration of the power configuration of the renewable energy and the load characteristics of the power receiver.

That is, in order to utilize the renewable energy to the maximum, the variation range of the duty ratio with respect to the voltage is widened. However, the efficiency of the buck converter is not affected by the duty ratio, and the efficiency of the boost converter boosting the voltage is influenced by the voltage-dependent duty ratio. Therefore, the buck converter is advantageous in terms of efficiency and advantageous in utilizing surplus power of renewable energy such as solar light.

Referring to the DC equivalent circuit of the buck converter as shown in FIG. 3, the secondary voltage V _PV and the output voltage V _out can be expressed by the following equations.

&Quot; (4) "

Where D is the duty ratio and R ₀ is the load resistance. Also, R _L is the inductor resistance inside the DC / DC converter. This results in conduction losses in the inductor.

The voltage gain G _V according to this equation is as follows.

&Quot; (5) "

The efficiency? Is expressed by Equation (3).

&Quot; (6) "

을 적용한다.here,

Is applied.

The efficiency of the buck converter is independent of the duty ratio D in Equation (6), and it can be confirmed that the larger the load resistance R ₀ is, the better the efficiency is.

Since the generated power of the renewable energy fluctuates greatly, when the generated power is lowered, the load power also decreases. Therefore, the efficiency is inevitably deteriorated. In addition, since the duty ratio fluctuates depending on the voltage fluctuation, the buck converter system independent of the duty ratio is advantageous in terms of efficiency.

In addition, the load output voltage V _out should be controlled by the AC / DC PWM rectifier V _AC and the DC / DC converter 20 should be controlled to set its output voltage to the load output voltage V _out . Therefore, it is preferable that the DC / DC converter 20 is configured by a buck converter method.

Next, the construction of the water electrolytic solution 50 according to the first embodiment of the present invention will be described more specifically.

As described above, the water electrolytic solution 50 is a device for producing hydrogen by electrolyzing water.

Preferably, a PEM (Polymer Electrolyte Membrane) method with good electrolysis efficiency is applied. In addition, an alkaline electrolysis (AE) method can be applied. The solid polymer electrolyte (PEM) method has fast chemical response and high current density with respect to power fluctuation. On the other hand, the alkali water electrolysis (AE) method has a slow chemical response and low current density with respect to power fluctuation.

In PEM type PEM electrolysis, each electrode reacts as follows.

[Chemical Formula 7]

Basically, a certain voltage is applied to the electrode for the electrolysis reaction, so that the electrode reacts to generate hydrogen. The reaction energy in the above reaction formula is as follows.

[Formula 8]

As shown in Formula (5), theoretically, the hydrothermal reaction proceeds at 1.228 V or higher. It is known that, under actual conditions, depending on the electrolytic solution, hydrogen is generated at 1.7 V or more due to the internal resistance. In addition, it is known that as the voltage increases, the paradigm current used for the hydrogen generation reaction increases and the hydrogen production rate increases.

If 20 water-electrolytic electrodes with a voltage of 1.7 V capable of producing hydrogen are connected in series, the minimum voltage for producing hydrogen should be 34V. Even if the amount of power supplied from the power conversion unit is present, if it is smaller than the minimum voltage of 34 V, hydrogen for energy can not be produced. For example, when the current limit of the commercial power source is set and the power generation amount in the renewable energy generation unit is small, the amount of power supplied to the power receiving unit 50 as the load may be small.

It is also assumed that the water electrolytic solution 50 has 18 2V cells (CELL) connected in series. At this time, the operation characteristics of the PEM water electrolytic device are as follows. When 38 VDC is supplied from the power source device, the voltage of the electrode of the water electrolytic device gradually increases. And as the voltage gradually increases, the amount of current increases as well. The production of hydrogen is proportional to the current.

That is, when 30VDC 1A is required, electrolysis of water starts to produce hydrogen. And consumes a current of 20A at 38V. This is the maximum current consumption. When the voltage and current are applied, the electrolyte membrane of the water electrolytic apparatus is deteriorated and the durability is reduced.

In addition, the starting voltage and the voltage after 2 hours are reduced from 38VDC to 35VDC. This is because the water electrolytic device itself drops in voltage due to internal deterioration. Therefore, when 18 electrodes (CELL) are used in series, the voltage range is 30 ~ 38V, 1 ~ 20A. In the water electrolytic apparatus, the amount of hydrogen production varies depending on the electric current.

Therefore, preferably, the water electrolytic dissolution apparatus 50 is composed of at least two or more water electrolytic dissolution apparatuses (or unit devices), and the plurality of water electrolytic dissolution apparatuses are connected in parallel to each other. When the load is supplied with power that is lower than the power required by the load, the power supply disconnecting unit 30 is turned off and the power supply 50 is continuously supplied.

That is, if the supplied voltage becomes the minimum voltage required by the water electrolytic apparatus 50, the hydrogen can not be produced in all three electrolytic electrolytic apparatuses 50 despite the supply amount of the new and renewable energy. At this time, when the power supply to one of the water electrolysis apparatuses 50 is stopped, the remaining two water electrolysis apparatuses 50 can continuously produce hydrogen because they are within the voltage range capable of producing hydrogen.

At this time, when the amount of electric power supplied is reduced, the load is calculated to stop another water receiving apparatus. And the remaining one can produce hydrogen up to the voltage range required by the water electrolytic solution 50.

On the contrary, when all of the power receiving and electrolyzing apparatuses 50 are operated at the time when the power generation amount of new and renewable energy such as solar power is increased, the PWM rectifier, which is a commercial power source, In such a case, the effect of utilizing the development of renewable energy such as sunlight is reduced. Therefore, only one power receiving apparatus 50 is operated, and power is supplied to the power receiving apparatus 50 one by one while confirming the power generating amount. By doing so, it is possible to maximize the amount of power generated by renewable energy such as sunlight.

In order to maximize the generation amount of renewable energy such as solar power as described above, several water electrolysis apparatuses 50 are installed and connected in parallel.

Next, a method of calculating the installed capacity of the renewable energy generating unit 10 according to the first embodiment of the present invention will be described.

As described above, when the voltage range of the electrolytic electrolysis electrode capable of producing hydrogen is 1.7 to 2.0 VDC, when one electrolytic electrolysis unit 50 uses 20 electrodes, it produces hydrogen in the range of 34 to 40 VDC . If a current of 20A is required at a maximum of 40V, 800W of electric power is required.

When three power receiving devices are used as in the example of Fig. 1, a power of 2400 W is required. Here, the power capacity for the control power source for driving the power converter and the efficiency of the power converter must be further calculated. In addition, when the solar cell I-V characteristic is observed, the voltage of the solar cell decreases rather than the solar power when the amount of sunshine is the maximum. Therefore, the maximum power standard is calculated as about 80% of the solar photovoltaic capacity, and the capacity of the renewable energy is installed.

In addition, the capacity of the PWM rectifier should be considered separately to calculate the installed capacity of new and renewable energy, and to meet the load capacity to produce hydrogen by commercial power when the renewable energy generation is insufficient. It also has the ability to set the output current limit of the PWM rectifier to minimize utility power.

Next, a control method of the power conversion system using the renewable energy according to the first embodiment of the present invention will be described with reference to FIG.

As shown in FIG. 4, the control method of the power conversion system using renewable energy according to the present invention includes a step of controlling the output voltage by converting the commercial power to DC power by the AC / DC PWM rectifier 90 (S20) of following the maximum power point by the DC / DC converter (20) and controlling the output current based on the output voltage, and selecting the power take-off unit (50) (Step S30).

First, steps S10 and S20 for controlling the output voltage and the output current to the DC / DC converter 20 of the renewable energy and the AC / DC PWM rectifier 90 of the commercial power source will be described.

If two DC converters control the DC voltage, DC voltage fluctuation occurs to control each other. This is caused by an error in each power converter control. For this output voltage error, each power converter must control the output voltage while compensating for voltage error in real time. Therefore, the burden on the controller also increases, so that it is difficult to secure reliability for long time use.

To ensure reliability, the controller can be used with the same reference output voltage. However, this method is only possible if the input power source is the same power source. The power conversion system according to the present invention uses a commercial power source and a renewable energy having a large power fluctuation, so that the implementation is complicated and difficult with such a control method.

Therefore, as shown in FIG. 5, the renewable energy generating unit 10 is provided in accordance with the capacity of the water electrolytic unit as a load, and the DC / DC converter 20 is adapted to the capacity. At this time, in terms of the efficiency of the DC / DC converter 20, the maximum generated power of renewable energy can not be used. In order to solve this problem, the output voltage of the AC / DC PWM rectifier 90 is controlled to maximize the generated power of the renewable energy while minimizing the commercial power source.

Specifically, the following mathematical expression as the sum of the load power (P _out) is a renewable energy such as solar power (P _PV) and power (P _AC) of the AC / DC PWM rectifier (90). The load output voltage (V _out ) is controlled by the AC / DC PWM rectifier (V _AC ). Here, the load current I _out is the sum of the generated current I _PV of the renewable energy such as solar light controlled by the DC / DC converter 20 and the current I _AC of the AC / DC PWM rectifier 90. At this time, the renewable energy generation current I _PV of the DC / DC converter 20 is the current (I _MPP ) due to the maximum power follow-up.

Therefore, the load current I _out is reduced through the current control of the DC / DC converter 20 when the amount of renewable energy generated increases and the commercial power source, which is the auxiliary power source, decreases.

&Quot; (10) "

The average output voltage for the buck converter's renewable energy input V _PV is:

&Quot; (11) "

Here, t _on denotes a time when the switching of the DC / DC converter 20 is on and supplies power, and D is a duty ratio.

The voltage transfer ratio G _V is given by the following equation.

&Quot; (12) "

Here, the duty ratio D is varied to adjust the output voltage.

That is, the control unit 40 controls the duty ratio D so that the voltage output from the buck converter of the DC / DC converter 20 is adjusted to be higher than the load output voltage V _out .

In other words, since the output voltage is controlled by the AC / DC PWM rectifier 90, the output voltage of the AC / DC PWM rectifier 90 is finely (0.01 V) while supplying current to the load through current control. Further, when the generated power of the renewable energy becomes insufficient, the AC / DC PWM rectifier 90 supplies the power required by the load.

Next, an example of adjusting the voltage when limiting the output current of the commercial power supply will be described.

Specifically, it is assumed that the output current of the AC / DC PWM rectifier 90 is set to be limited to 15A. It is also assumed that the load, that is, the power to be supplied to the water electrolytic apparatus 50 is 1200 W (40 V, 30 A).

However, in the early stage of solar power generation, when the generation power of solar light decreases and the generated power is 400W, the power supplied to the load is less than the power required by the load. That is, the power required by the load is insufficient. Thus, the output voltage of the AC / DC PWM rectifier 90 is reduced to meet the power required by the load.

That is, in the absence of an additional power source, the AC / DC PWM rectifier 90 will have a current of 15A, but the output voltage will continue to decrease because of the power needed for the load. The output voltage drops without being maintained at 40V. Therefore, since the current is maintained at 15 A, the power supplied from the AC / DC PWM rectifier 90 to the actual load also decreases.

However, the DC / DC converter 20 adjusts the output voltage by referring to the output voltage of the AC / DC PWM rectifier 90. At this time, in order to continuously supply the current from the DC / DC converter 20, the maximum current is controlled to be higher than the output voltage of the AC / DC PWM rectifier 90 (for example, . Therefore, the output voltage of the DC / DC converter 20 also decreases.

Thus, when the solar power fluctuates, the output of the DC / DC converter 20 is also changed accordingly, and the output voltage of the PWM rectifier 90 is also varied in accordance with the output power of the DC / DC converter 20.

However, when the voltage falls below a predetermined voltage (for example, 30 V), the electrolytic water electrolyzer 50 can not produce hydrogen. Further, when excessive voltage or excessive power is supplied, there is a problem that the electrode or the insulating film of the water electrolytic solution 50 deteriorates.

Therefore, in accordance with the sum of the photovoltaic power and the PWM rectifier power, the power switch 50 is selectively connected by turning on / off the output switch, Thereby adjusting the number of the devices 50. [

In this way, the current of the AC / DC PWM rectifier 90 can be limited and the commercial power supply can be minimized. In addition, if hydrogen production is required even without renewable energy generation power, the user can continuously produce hydrogen by adjusting the output current limit of the AC / DC PWM rectifier 90.

In addition, according to the power conversion system according to the present invention, continuous power supply is performed, so that hydrogen can be continuously produced in the water electrolytic apparatus 50. In addition, the AC / DC PWM rectifier 90 controls the voltage in accordance with the fluctuation of the renewable energy power to supply stable power to the load. Therefore, it is possible to more stably supply power to the water electrolytic solution apparatus 50 as a load.

In addition, when the system according to the present invention uses the power of solar light installed as an input to the DC / DC converter 20, it is possible to use a solar panel that produces more electric power than a load requires. At this time, when the current control is performed in the DC / DC converter 20, more current is supplied than the amount of current required in the water electrolytic apparatus 50 as a load. In this case, the DC output voltage is increased by accumulating electric energy in the DC output. In the case of an AC / DC PWM rectifier 90 using a switching semiconductor device that directly converts AC into direct current, the AC / DC PWM rectifier 90 converts the AC stored in the output to an alternating current in order to lower the stored energy, And a bidirectional converter that controls the DC output voltage.

In addition, the present invention is necessary for supplying power to the water electrolytic apparatus 50 for producing hydrogen energy using commercial power and renewable energy. However, the commercial power source and the renewable energy are fused, and the control method can be usefully applied to the loads of other uses.

Next, step S20 of controlling the output current by following the maximum power point in the DC / DC converter 20 will be described in detail.

As described above, the DC / DC converter 20 for controlling the renewable energy is constituted by a buck converter for reducing the voltage. The control unit 40 calculates and controls the maximum current value in the power generated according to the conventional maximum power follow-up scheme. Particularly, as shown in Fig. 7, the current control is controlled as a main function in a certain section according to the power generation amount. Thus, in a normal state, the DC / DC converter 20 is controlled so as to obtain a current region as shown in FIG.

As shown in FIG. 4, the control unit 40 detects the voltage and current (V _pv , I _PV ) of renewable energy such as solar light (S21). From this, the power P _PV is calculated. Then, the reference current I _ref is calculated using the improved P & O algorithm (S22). The PWM control signal of the DC / DC converter 20 is generated through the proportional integral (PI) control according to the PWM rectifier output voltage reference and the reference current I _ref (S23).

5, the control unit 40 includes an MPPT (maximum power point tracking) algorithm unit for calculating and generating a reference current I _{ref as a} control target for controlling the current of the DC / DC converter 20 , And a PI controller for controlling the actual PV direct current (I _pv ) to a target value in accordance with the generated reference current (I _ref ). Particularly, in order to track the maximum power point MPP of the renewable energy generation unit 10, the control unit 40 controls the output voltage V _PV of the PV panel of the renewable energy generation unit 10 and the output current I _PV ) and feeds back the supply voltage (V _out ) and the supply current (I _out ) supplied to the load (water electrolytic solution, etc.). That is, the output voltage V _PV of the PV panel of the renewable energy generating unit 10 and the output voltage V _PV of the renewable energy generating unit 10 are controlled by an algorithm that tracks the maximum power point MPP of the renewable energy generating unit 10 by the control unit 40. [ The current I _PV is controlled. Particularly, the reference current I _ref is calculated and generated through the improved P & O algorithm. The difference between the reference current I _ref and the actual PV direct current I _pv becomes a reference control value of the current source. And generates a PWM control signal of the DC / DC converter 20 through a reference.

Specifically, the MPPT algorithm is required because the PV panel has a nonlinear voltage-current characteristic with a unique point at which the generated power is maximized. The maximum power point (MPP) depends on the temperature and solar radiation conditions of the panel. Both conditions change day by day and depend on the season. In addition, solar radiation can change rapidly because it changes with the state of the atmosphere, such as clouds. It is very important to accurately track the MPP under all possible conditions to always get the maximum power point.

Particularly, the present invention is intended not only to deal with solar power generation on a clear day and a cloudy day, but also to cope with solar power generation on a day when the generation amount fluctuates very much, such as a cloudy sunny day.

FIG. 6 shows a curve for the power (P) characteristic versus the voltage (V) of the photovoltaic power generation. In FIG. 6, the curve A represents the V-P characteristic curve of the sunlight optimal for a clear day, and the curve B represents the V-P characteristic curve of the cloudy day. Curve C is the V-P characteristic curve of solar power generation on a clear cloudy day.

The existing P & O algorithm is mainly a method corresponding to the case of the curves A and B in FIG. In this case, there is no problem in supplying power to the water electrolytic apparatus as a load even by using the conventional MPPT algorithm. However, as shown by the curve C, the power fluctuation is severe on a clear cloudy day. Therefore, the corresponding control operation may be delayed. This may cause problems when limiting the output current at the PWM rectifier 90. [ In other words, if the output current is limited, the output voltage fluctuates according to the photovoltaic power, which may fall below the voltage that can produce hydrogen in the electrolytic device. Therefore, since the voltage source of the PWM rectifier 90 is fast, it is required to improve the maximum power follow-up method for the current according to the voltage reference.

FIG. 7 illustrates an improved P & O control method according to an embodiment of the present invention.

As shown in FIG. 7, first, the current voltage V (n) and the current I (n) are measured, and the output power P (n) at this time is calculated as a product of the voltage and the current. (Difference between current power and previous power,? P = P (n) -P (n-1)) is positive or negative. When the power increment ΔP is 0, the reference current I _ref is not adjusted.

If the power increment ΔP is negative, the voltage increment ΔV = V (n) -V (n-1) is compared with zero. If △ V is negative, set the power point state to ④ (or 4). At this time, the reference current I _ref is decreased. When? V is positive, the power point state is set to? (Or 3). At this time, the reference current I _ref is increased.

Next, when the power increment ΔP is positive, the voltage increment ΔV = V (n) -V (n-1) is compared with zero. If △ V is negative, first set the power point state to ② (or 2) and increase the reference current. Thereafter, it is set differently according to the previous power point state. That is, if the power point state is ①, ④, ⑥, set the power point state to ⑥ (or 6) and reduce the reference current. Otherwise, set the power point state to 2 (or 2) and increase the reference current.

As shown in FIG. 8, the state where the power point state is 1, 4, or 6 is the left side at the maximum power point and the state where the power point state is 2, 3, .

When? V is positive, the power point state is first set to 1 (or 1) and the reference current is decreased. Thereafter, it is set differently according to the previous power point state. That is, if the power point state is ②, ③ or ⑤, set the power point state to ⑤ (or 5) and increase the reference current. Otherwise, set the power point state to 1 (or 1) and reduce the reference current.

If there is one power converter such as the DC / DC converter 20, the maximum power can be followed by the reference voltage as in the conventional case. However, since the present invention is composed of two power converters such as DC / DC converter 20 and PWM rectifier 90, the PWM rectifier 90 controls the basic voltage and adjusts the basic voltage in the DC / DC converter 20 Control. Thus, the DC / DC converter 20 only controls the current from the output voltage of the PWM rectifier 90 to a voltage reference as high as 0.01 V at the maximum power point watched. And the voltage of the DC / DC converter 20 must be higher than the voltage of the PWM rectifier 90 so that the current controlled by the DC / DC converter 20 can be supplied to the load side. If it is low, current is not supplied.

That is, as shown in FIG. 8, the P & O control algorithm according to the present invention is configured such that the step of the conventional algorithm is segmented and the current source, and the response of the power converter according to the generated power variation is improved. That is, the P & O control algorithm is improved by applying ⑤ and ⑥ sections in comparison with C in Fig. 6 where the generated power fluctuation is severe. This makes it possible to optimally respond to power fluctuations.

5, and 6 will be described in more detail with reference to FIG.

In FIG. 9, the maximum power follow-up time is divided into left and right based on red as a judgment of voltage fluctuation. When the voltage P rises, it is compared with the past value. If the voltage V rises, it is on the left side, and when the voltage V decreases, on the right side.

That is, when the voltage rises, the power is followed as shown in (1) in FIG. 9 (a), and when the voltage is decreased, the power is followed as judged in (2) in FIG. 9 (b). In Fig. 9 (c), ④ is a voltage decreasing period due to power generation fluctuation at the maximum power point, and ③ is a voltage rising period due to power generation fluctuation at the maximum power point.

The above ① ~ ④ are the same in the existing P & O algorithm to distinguish the left or right at the maximum power point and the voltage increase and decrease conditions according to the voltage judgment in order to cope with the fluctuation of the sunshine amount.

In the present invention, the control algorithm is added to the existing P & O algorithm to cope with the fluctuation in the amount of sunshine, as shown in (d) and (e) of FIG. As shown in (d) and (e) of FIG. 9, according to the voltage rise judgment, the left side and the right side are divided based on the maximum power point.

In (d) of FIG. 9, in the determination of the voltage reduction period, when the amount of sunshine fluctuates, the voltage rise is determined to be?. In this case, the voltage is immediately raised and does not follow the maximum power point. Continuously increase the current to confirm the state of the sunshine fluctuation as described above. Then, it judges the fluctuation of the sunshine quantity by the voltage, and if it is the decrease period, it follows the maximum power point by decreasing the current as shown in ②. If the amount of sunshine is reduced here, it is judged as ④ and it operates.

In (e) of FIG. 9, in the voltage rising period judgment, it is judged as (6) if the voltage decreases due to the fluctuation of the sunshine amount. In this case, the voltage does not increase immediately because the voltage is reduced. Instead, the current is decreased to confirm the fluctuation of the sunshine quantity, and the sunshine fluctuation is judged as the voltage. In the increasing period, the current is increased to follow the maximum power point as shown in (1). If the amount of sunshine increases here, it is judged as ③ and it operates.

The left and right judgment criteria based on the maximum power point are determined by supplying power and following the maximum power according to the variation of the voltage.

On the other hand, the water electrolyzer has the minimum voltage that can produce hydrogen. Further, the maximum voltage is set for preventing deterioration of the electrode or the insulating film.

Between the minimum voltage and the maximum voltage as described above, PWM switching moves to step. For example, assume that P (n-1) = 1000W, V (n-1) = 39V, P (n) = 800W, and V (n) = 37V. At this time, if the voltage of the current value is decreased by 2V from the past value and the step is set to 100, the PWM switching is performed by reducing to 2/100 = 0.02A. In addition, when the voltage increases, PWM switching is performed to increase 0.02A.

The size of this step can be adjusted while checking the power fluctuation and the transient voltage of the water electrolytic device which is a load in a steady state. If the transient is bad, the step value is set to 200 and the current is increased or decreased to 0.01A. The step value fluctuates between the maximum voltage and the minimum voltage setting that can produce hydrogen.

When the power generation amount decreases and reaches the minimum voltage, the current continuously decreases from this point.

Next, a step S30 of selecting the water electrolytic solution apparatus 50 and supplying electric power will be described with reference to Fig.

First, as shown in FIG. 10A, when the generated power increases, the power receiving apparatus is further supplied with power. In other words, as shown in FIG. 10A, in a period in which the generated power of the renewable energy is increased, the switch n is turned on in a plurality of load output switches and the load output switches n Are sequentially turned on.

The solar power can not make the total power generation required at the same time of the sunrise (the power receiver). Therefore, the output switch of the power converter is turned on to one of the power receiving devices 50 connected in parallel to supply power to the power receiving device. At this time, as described above, the power with maximum power follow-up (MPPT) is supplied. In addition, since the water electrolytic solution 50 needs a minimum voltage capable of producing hydrogen as shown in Formula 5, the control unit 40 may supply power to the second or more water electrolysis devices 50 according to the generated electric power of the sunlight. Can be determined.

That is, when more electric power is produced by comparing the generated electric power, the output switch is further turned on to operate more of the water electrolytic apparatus 50. This process is repeated to supply power to the water electrolytic solution 50. In other words, the switch-on state can be sequentially set through the maximum power estimation of the renewable energy generation amount at the time when the amount of sunshine increases.

The concrete steps are as follows.

1) Operate the PWM rectifier operated by commercial power supply.

2) Verify that the developed voltage is increased for initial start-up.

3) Compare the cumulative operation time of the water electrolytic unit, and turn on the switch n (the first) with a small cumulative operation time.

4) The DC / DC converter powers the load while performing MPPT.

5) If load supply power is 90% based on the connected load, turn on switch n, which has less second operating time. For example, if the generated power is constant at 90% on a single load basis, the load is powered by 45%.

6) Supply power to the load while MPPT according to power generation variation. At this time, when the power generation amount is 90% based on two loads, the third output switch n is turned on. That is, the current generation amount is 90% × 2 = 180%. When three loads (power dissipation devices) are shared, 180% / 3 units = 60%. That is, the load by each water electrolytic device supplies power at the level of 60%.

7) Supply power to the load according to the increased power generation. In addition, when the generated power becomes the maximum, the load capacity can be increased due to the increase in efficiency. In this case, the bidirectional PWM rectifier controls the maximum output voltage of the load to power out the utility power supply to prevent durability degradation due to device overvoltage.

Next, as shown in FIG. 10B, when the generated power decreases, some of the power-receiving units to which power is supplied are selected and the power is cut off stepwise.

That is, when there is no generated power of the renewable energy and the output voltage of the AC / DC PWM rectifier 90 becomes lower than the operation voltage of the water electrolytic apparatus 50 as a load, all the load output switches are turned off, .

In addition, the control unit 40 compares the sum of the renewable energy generation power and the output power of the PWM rectifier in real time to calculate a new renewable energy generation If the sum of the power and the output power of the PWM rectifier is insufficient, one power converter output switch 30 is turned off and power is supplied to the remaining power converter loads. Further, when the generated power is insufficient, the output switch 30 is further turned off to minimize the surplus power of the renewable energy to produce hydrogen.

That is, the control unit 40 compares the sum of the output power of the photovoltaic power PWM rectifier with the power required by the power receiving unit 50 in the time zone where the generated power decreases, as opposed to the time when the generated power increases, And the converter output switch is turned off to supply power to the remaining water electrolytic device 50. By repeating this process, the output switch is further turned off according to the generated power to minimize the surplus power of the sunlight to produce hydrogen.

The concrete steps are as follows.

8) If the power generation amount is reduced to 50% of the total load, turn off the most used power switch unit n. For example, since three units are operating, 50% x 3 units = 150%. One of them is stopped and the rest is divided into two, so 150% / 2 = 75%. That is, power is supplied to two units at 75% of the load power consumption.

9) If the remaining two loads become 50% due to the decrease in power generation, turn off the most used water electrolyzer n.

10) The remaining one unit is operated at 100% load, and load power consumption also decreases as power generation power decreases.

11) Turn off the DC / DC converter and PWM rectifier when the voltage of the last one of the power take-off units becomes the minimum voltage.

On the other hand, the control unit 40 counts the operation time of each of the power receiving units 50, and controls the power receiving units 50 to operate in an intersecting manner. Accordingly, the operation time of the plurality of power receiving units 50 installed according to the amount of renewable energy generation is maintained in a similar manner. The durability of the water electrolysis apparatuses 50 can be uniformly provided through the above-described cross operation method.

Specifically, the water electrolytic apparatus 50 of the solid polymer electrolyte (PEM) type is composed of a positive electrode, a negative electrode, and an ion exchange membrane. The ion exchange membrane has an electrolyte function that separates hydrogen and oxygen and moves them from the anode to the cathode. Since the ion exchange membrane is a strong acid electrolyte, a platinum series which is an acid-resistant noble metal catalyst is widely used. Since the catalyst uses a precious metal material such as platinum or iridium, durability is important.

In addition, deterioration of the electrode and insulating film due to overvoltage and overvoltage greatly influences the hydrogen yield, and in the durability, the oxygen generating anode catalyst technology directly influences performance. Thus, by restricting the overvoltage through control over the DC / DC converter 20, deterioration due to the overvoltage can be prevented.

However, the durability of ion exchange membranes and precious metal catalysts due to the use of water electrolytic devices can not be protected by the power converter. Therefore, in order to protect the chemical safety due to durability and to maintain the yield, the power is supplied according to the total operation time (or cumulative operation time) of the water electrolysis apparatus 50 through the output switch 30 connected to the water electrolysis apparatus 50 And controls the selection of the device 50.

That is, in the time zone where the generated power increases due to the increase in the amount of sunshine, the power-receiving device 50 having a small cumulative operation time is preferentially selected and the power is supplied. On the contrary, in the time period during which the generated power decreases, the power receiving device 50 having a large cumulative operation time is preferentially selected and the power supply is stopped. That is, the cumulative operation time of the water electrolytic solution 50 is checked according to the generated power amount, and the durability is controlled to be maintained.

In summary, each switch on time for power supply to the water electrolytic apparatus 50 as a load is cumulatively counted. Therefore, the total cumulative operation time of each water electrolytic apparatus 50 is monitored, and the cumulative operation time is selected as described above when selecting the electrolytic apparatus 50 to supply or block the electric power.

Next, a power conversion system using renewable energy according to a second embodiment of the present invention will be described with reference to FIG.

The second embodiment of the present invention is the same as the first embodiment. However, the second embodiment differs in the step S20 of turning on / off the water electrolytic solution 50. Only the different parts are described below. Unless explained, the description of the first embodiment described above is referred to.

11, the control unit 40 divides the power P _out supplied to the power receiving unit 50 by the number n of the power receiving units currently connected, and then divides the divided power (that is, power shared in parallel) Is greater than the power P ₁ (S21). That is, it is determined whether the following expression (7) is satisfied.

&Quot; (7) "

If Equation (7) is satisfied, one of the water electrolytic solution apparatus 50 is selected (S22), and the selected water electrolytic apparatus 50 is added (S23). At this time, the water electrolytic water treatment apparatus 50 having the smallest cumulative operation time is selected.

Here, P ₁ represents the maximum power applied to one of the water electrolytic devices 50. As described above, when too large voltage and current are supplied to the water electrolytic solution 50, durability due to deterioration is reduced. Therefore, the appropriate power at which deterioration is minimized is set to the maximum power.

n is the number of the water electrolysis devices 50 connected in parallel. Therefore, dividing the supply power P _out by n is the power supplied to one of the power receiving units connected in parallel. If this power is greater than the maximum power P ₁ , there is room for degradation to proceed, thus adding one more power receiver to lower the power supply.

If the equation (7) is not satisfied, the control unit 40 divides the power P _out by the number n of the power receiving apparatuses currently connected and determines whether the divided power sharing is less than the minimum power P ₀ (S24). That is, it is determined whether the following expression (8) is satisfied.

&Quot; (8) "

If Equation (8) is satisfied, one of the water electrolytic dissolution apparatus 50 is selected (S25), and the selected water electrolytic dissolution apparatus 50 is shut off (S26). At this time, the water electrolytic water treatment apparatus 50 in which the accumulated operation time is the maximum is selected.

Here, P ₀ is set in advance as the minimum power to be applied to one of the water electrolysis apparatuses 50. As described above, when too little power (or voltage) is applied to the water electrolytic solution 50, no chemical reaction occurs and hydrogen is not produced. Therefore, the power required for hydrogen production is preset to the minimum power P ₀ .

n is the number of the water electrolysis devices 50 connected in parallel. Therefore, dividing the supply power P _out by n is the power supplied to one of the power receiving units connected in parallel. If this power is less than the minimum power P ₀ , the hydrogen production may be interrupted, thereby turning off at least one of the power receiving devices in operation to increase the power supply of the remaining power receiving devices.

Next, a power conversion system using renewable energy according to a third embodiment of the present invention will be described with reference to FIG.

12, the third embodiment of the present invention is the same as the first embodiment described above, and further differs in that it further comprises the fuel cell 70 and the DC / AC inverter 80 . Only the different parts are described below. Unless explained, the description of the first embodiment described above is referred to.

The present invention is a system for mass production of hydrogen. A commercial power source used as an auxiliary power source supplies a certain amount of produced hydrogen to the fuel cell 70 to generate DC power. The direct current power source is configured to transmit power to the commercial power source through the DC / AC inverter 80 so that the circuit can be configured in the form of an energy circulating structure.

Although the invention made by the present inventors has been specifically described according to the above embodiments, the present invention is not limited to the above embodiments, and it goes without saying that the present invention can be modified in various ways without departing from the gist of the present invention.

10: Renewable Energy Generation Section 20: DC / DC Converter
30: Switching unit 40:
50: water electrolytic device 60: storage device

Claims (5)

A new and renewable energy source for supplying renewable energy of a renewable energy generation unit and a commercial power source to generate hydrogen by supplying electric power to at least two or more power receiving units connected in parallel and having a DC link unit commonly, 1. A power conversion system comprising:
An AC / DC PWM rectifier for converting the commercial power to a DC power and outputting the DC power to the power receiving units, and controlling an output voltage (hereinafter referred to as a load output voltage);
Wherein the AC / DC PWM rectifier follows the maximum power point with respect to the power of the renewable energy and outputs the power of the renewable energy to the power receiving devices, A DC / DC converter for controlling the voltage to be adjusted;
A switch unit having a switch in each of the at least two water electrolytic dissolution apparatuses and turning on / off the power supply to the water electrolytic dissolution apparatus by on / off of the switch; And
And a control unit for controlling the AC / DC PWM rectifier, the DC / DC converter, and the switch unit,
Wherein the controller controls the output voltage of the DC / DC converter to be higher than the load output voltage.
The method according to claim 1,
Wherein the DC / DC converter includes a buck converter, and performs voltage conversion to adjust the generated power of renewable energy following the maximum power point to the load output voltage.
The method according to claim 1,
The control unit sets an output current limit for the AC / DC PWM rectifier so as to be output only to a predetermined current value or less, selects a part of the plurality of power receiving units according to an increase or decrease in the amount of renewable energy generation, Power conversion system using renewable energy.
The method of claim 3,
The control unit controls the switch unit to divide the power supplied to the power receiving unit by the number of the power receiving units currently connected and then, if the divided power is greater than a predetermined maximum power, If the divided electric power is smaller than the preset minimum electric power, one of the on-going electric power receiving devices is selected and turned off Power conversion system using renewable energy.
The method according to claim 1,
The system further includes a fuel cell that generates electric power using hydrogen produced by the electrolytic water dissipating device and a DC / AC inverter that converts the DC power of the fuel cell into an AC power,
Wherein the output of the DC / AC inverter is supplied to the AC / DC PWM rectifier instead of the commercial power, or is supplied to the AC / DC PWM rectifier together with the commercial power.

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