KR102423142B1 - Power conversion system using vanadium radox flow battery stack and method of performing thereof - Google Patents

Abstract

A power conversion system using a vanadium redox flow battery stack according to an embodiment of the present invention includes an electrolyte tank for storing an electrolyte, a pump for pumping the electrolyte stored in the electrolyte tank, and a chemical reaction by receiving the electrolyte from the pump A vanadium redox flow battery stack composed of a stack for generating A power conversion device comprising a plurality of converter modules each connected to a plurality of converters for secondary boosting to a high voltage, and a plurality of inverter modules for generating the secondary boosted voltage into a system voltage, and output from the power converter and an energy storage device for storing energy.

Description

POWER CONVERSION SYSTEM USING VANADIUM RADOX FLOW BATTERY STACK AND METHOD OF PERFORMING THEREOF

The present invention relates to a power conversion system using a vanadium redox flow battery stack and a method for implementing the same, and more particularly, to reduce the risk of failure by boosting the energy output from the high output vanadium redox flow battery stack in two steps. It relates to a power conversion system using a vanadium redox flow battery stack that enables the same, and a method for implementing the same.

Recently, efforts are being made to reduce greenhouse gases worldwide due to environmental pollution and global warming. Various efforts are being attempted.

Most power supply systems are mainly thermal power generation, but thermal power generation emits a huge amount of CO2 gas due to the use of fossil fuels, and the environmental pollution problem is very serious. , solar energy, tidal power, etc.) is a situation in which the development of power supply systems is rapidly increasing.

Most of the renewable energy uses clean energy that occurs in nature, so it is attractive because there is no emission of exhaust gas related to environmental pollution. has a situation.

Power storage technology is an important technology for efficient use of all energy, such as efficient use of electricity, improvement of power supply system capability and reliability, and expansion of the introduction of new and renewable energy with large fluctuations over time. There is a growing demand for it. In particular, expectations for the utility of secondary batteries in these fields are increasing.

Vanadium Radox Flow Battery (VRFB) has the advantage of being able to easily change the energy capacity and output by variably changing the tank capacity and the number of battery stacks, and it can be used semi-permanently, so high-capacity and high-efficiency secondary batteries are applied It is a secondary battery that has been in the spotlight for large-capacity power storage that should be.

A vanadium redox flow battery refers to a battery that charges and discharges using a redox reaction of metal ions with a changing oxidation number dissolved in an electrolyte.

An object of the present invention is to provide a power conversion system using a vanadium redox flow battery stack capable of reducing the risk of failure by boosting the energy output from the high-output vanadium redox flow battery stack in two stages, and a method for implementing the same do it with

In addition, the present invention reduces the input current ripple by configuring the converters that perform the primary boosting of the energy output from the vanadium redox flow battery stack in parallel and operating with a phase difference, thereby reducing the current flowing in the vanadium redox flow battery stack. An object of the present invention is to provide a power conversion system using a vanadium redox flow battery stack capable of stabilizing and a method for implementing the same.

In addition, the present invention provides a power conversion system using a vanadium redox flow battery stack capable of increasing the step-up ratio of the converter by serially configuring a converter that proceeds with a secondary voltage with respect to the primary boosted voltage, and a method for implementing the same. intended to provide

The objects of the present invention are not limited to the above-mentioned objects, and other objects and advantages of the present invention not mentioned may be understood by the following description, and will be more clearly understood by the examples of the present invention. It will also be readily apparent that the objects and advantages of the present invention may be realized by the means and combinations thereof indicated in the appended claims.

A power conversion system using a vanadium redox flow battery stack for achieving this purpose is an electrolyte tank for storing an electrolyte, a pump for pumping the electrolyte stored in the electrolyte tank, and a chemical reaction by receiving the electrolyte from the pump to generate energy A vanadium redox flow battery stack consisting of a stack that is designed to perform a first step-up of a voltage of energy output through the vanadium redox flow battery stack to a specific voltage, and then the first boosted specific voltage is applied to a voltage higher than the specific voltage. A power conversion device consisting of a plurality of converter modules each connected to a plurality of converters for secondary boosting to a voltage, and a plurality of inverter modules for generating the secondary boosted voltage into a system voltage, and the energy output from the power converter energy storage device to store it.

In addition, the power conversion method using the vanadium redox flow battery stack for achieving this object is a step of generating energy by a chemical reaction to the electrolyte when the vanadium redox flow battery stack is supplied by pumping the electrolyte stored in the electrolyte tank. , the first converter group of the plurality of converter modules step-up the voltage of the energy output through the vanadium redox flow battery stack to a specific voltage, the second converter group of the plurality of converter modules is the first converter Second step of step-up of the specific voltage that is primarily boosted by the group to a voltage higher than the specific voltage, the step of an inverter module generating the voltage of the second boosted energy into the voltage of the system, and the energy storage device is the inverter module and storing the energy output by the

According to the present invention as described above, there is an advantage that the risk of failure can be reduced by boosting the energy output from the high-output vanadium redox flow battery stack over two stages.

In addition, according to the present invention, the input current ripple is reduced by configuring the converters that perform the primary boosting of the energy output from the vanadium redox flow battery stack in parallel and operating with a phase difference, thereby reducing the flow in the vanadium redox flow battery stack. It has the advantage of stabilizing the current.

In addition, according to the present invention, there is an advantage in that the step-up ratio of the converter can be increased by configuring the converters that proceed with the secondary voltage to the primary boosted voltage in series.

1 is a view for explaining a power conversion system using a vanadium redox flow battery stack according to an embodiment of the present invention.
2 is a block diagram illustrating the internal structure of a vanadium redox flow battery stack according to an embodiment of the present invention.
3 and 4 are circuit diagrams for explaining a plurality of converter modules according to an embodiment of the present invention.
5 is a circuit diagram illustrating a power conversion system using a vanadium redox flow battery stack according to an embodiment of the present invention.
6 is a flowchart illustrating an embodiment of a power conversion method using a vanadium redox flow battery stack according to the present invention.

The above-described objects, features and advantages will be described below in detail with reference to the accompanying drawings, and accordingly, those skilled in the art to which the present invention pertains will be able to easily implement the technical idea of the present invention. In describing the present invention, if it is determined that a detailed description of a known technology related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description will be omitted. Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used to indicate the same or similar components.

1 is a view for explaining a power conversion system using a vanadium redox flow battery stack according to an embodiment of the present invention.

Referring to FIG. 1 , a power conversion system using a vanadium redox flow battery stack includes a plurality of vanadium redox flow battery stacks 100_1 to 100_N, a plurality of power conversion devices 200_1 to 200_N, and an energy storage device 300 . And, the power conversion device 200 includes a plurality of converter modules (210_1 to 210_N) and a plurality of inverter modules (220_1 to 220_N).

When the vanadium redox flow battery stacks 100_1 to 100_N are supplied by pumping the electrolyte stored in the electrolyte tank, energy is generated by a chemical reaction using the electrolyte. These vanadium redox flow battery stacks 100_1 to 100_N will be described in more detail with reference to FIG. 2 below.

Each of the plurality of converter modules 210_1 to 210_N primarily boosts the voltage of energy output through the vanadium redox flow battery stack 100_1 to 100_N to a specific voltage, and then sets the first boosted specific voltage to the specific voltage. It consists of a plurality of converters that step-up the secondary voltage to a voltage higher than the voltage.

That is, each of the plurality of converter modules 210_1 to 210_N includes a first converter group 211_1 to 211_N and a second converter group 212_1 to 212_N, and the first converter group 211_1 to 211_N is a vanadium redox flow. The voltage of energy output through the battery stacks 100_1 to 100_N is first boosted to a specific voltage, and the second converter group 212_1 to 212_N further increases the specific voltage boosted by the first converter group 211_1 to 211_N. Second step-up with high voltage.

In the first converter group 211_1 to 211_N, a plurality of converters are configured in parallel with each other and operate with a different phase difference to perform primary boosting. In this case, the plurality of converters may be implemented as bidirectional converters, and four bidirectional converters are respectively connected in parallel to form first converter groups 211_1 to 211_N. At this time, each of the four bidirectional converters of the first converter group 211_1 to 211_N operates with a phase difference.

In this way, after connecting four bidirectional converters in parallel, each of the four bidirectional converters operates with a different phase difference from each other, thereby reducing the input current ripple and stabilizing the current flowing in the vanadium redox flow battery stack 100_1 to 100_N. have.

In addition, by using four bidirectional converters, the size of the reactor used can be reduced compared to when using one bidirectional converter, and there is an advantage that the voltage can be boosted higher (eg, 2 to 4 times).

In the second converter groups 212_1 to 212_N, a plurality of converters are configured in series with each other, and a secondary boosting of a specific voltage that is primary boosted by the first converter group is performed. In this case, the plurality of converters may be implemented as an LLC topology, and two LLC topologies are respectively connected in series to form the second converter groups 212_1 to 212_N.

At this time, since the two LLC topologies are respectively connected in series, as the step-up ratio of the converters of the second converter group 212_1 to 212_N increases, the efficiency decrease increases, so that the step-up can be performed through two steps.

The plurality of inverter modules 220_1 to 220_N generate energy boosted by the plurality of converter modules 210_1 to 210_N into a system voltage. At this time, the plurality of inverter modules 220_1 to 220_N may be implemented with a system three-phase 380Vac. In order to generate energy into a system voltage using this system three-phase 380Vac, an input of energy of a voltage of 600V or higher is required. To this end, the voltage of the energy output through the vanadium redox flow battery stack 100_1 to 100_N is boosted to a high voltage of 7 to 8 times and then to be supplied to the plurality of inverter modules 220_1 to 220_N.

If, as in the prior art, when a single converter boosts the voltage of energy output through the vanadium redox flow battery stack 100_1 to 100_N to a high voltage of 7 to 8 times, efficiency reduction and a risk of failure occur.

In order to solve this problem, each of the plurality of converter modules 210_1 to 210_N is a vanadium redox flow battery stack ( By boosting the voltage of energy output through 100_1 to 100_N, a voltage of 700 Vdc may be input to the plurality of inverter modules 220_1 to 220_N.

That is, when a single converter boosts the voltage of energy output through the vanadium redox flow battery stack 100_1 to 100_N to a high voltage of 7 to 8 times, efficiency reduction and a risk of failure occur, so the present invention provides multiple Energy output through the vanadium redox flow battery stack 100_1 to 100_N through two steps through the first converter group 211_1 to 211_N and the second converter group 212_1 to 212_N of the converter module 210_1 to 210_N It is possible to increase the voltage of 700Vdc and reduce the risk of failure at the same time.

Although not shown in FIG. 1 , the power conversion system using the vanadium redox flow battery stack may further include a demonstration operation device. That is, the demonstration operation device demonstrates whether the power conversion system using the vanadium redox flow battery stack generates the same effect as the existing energy conversion system.

To this end, the demonstration operation device repeats charging and discharging of the energy storage device 300 for a predetermined time in a state in which the vanadium redox flow battery stack and the plurality of power conversion devices are connected, and the charging efficiency of the energy storage device 300 and The performance of the plurality of power conversion devices 200_1 to 200_N is evaluated using the discharge efficiency.

2 is a block diagram for explaining the internal structure of a vanadium redox flow battery stack according to an embodiment of the present invention.

Referring to FIG. 2 , the vanadium redox flow battery stack 100_1 to 100_N includes an electrolyte tank 110 , a pump 120 , and a stack 130 .

The vanadium redox flow battery system is generally configured with a known vanadium redox flow battery, and a charging device 0 is added to the configuration of the vanadium redox flow battery.

The electrolyte tank 110 is configured in plurality and serves to store the electrolyte.

In the electrolyte tank 110 , the weak electrode and the negative electrolyte are stored in each electrolyte tank 110 and circulated in the vanadium redox flow battery ( ) by a pump 120 to be described later.

In the electrolyte stored in the electrolyte tank 110, a vanadium ion active material is dissolved, and the active material exchanges electrons to be charged or discharged.

The pump 120 serves to pump the electrolyte stored in the electrolyte tank 110 . The pump 120 pumps the electrolyte of the weak electrode and the negative electrolyte tank 110 and sends it to the stack 130 to be described later. Here, the pump 120 is provided in plurality to send the electrolyte of the positive electrode and the negative electrode to the stack 130 to repeat the process of circulation.

The stack 130 serves to receive the electrolyte from the pump 120 and generate electricity through a chemical reaction. The stack 130 basically has a structure in which a plurality of cells and a separator are disposed between the cells and stacked.

The stack 130 receives the electrolyte from the pump 120 to generate electricity while causing a chemical reaction. The electrolyte discharged through the stack 130 is sent back to the electrolyte tank 110 and the electrolyte is circulated.

3 and 4 are circuit diagrams for explaining a plurality of converter modules according to an embodiment of the present invention.

3 and 4 , each of the plurality of converter modules 210_1 to 210_N primarily boosts the voltage of energy output through the vanadium redox flow battery stack 100_1 to 100_N to a specific voltage, and then It consists of a plurality of converters that secondarily boost a specific voltage that has been primarily boosted to a voltage higher than the specific voltage.

That is, each of the plurality of converter modules 210_1 to 210_N includes a first converter group 211_1 to 211_N and a second converter group 212_1 to 212_N, and the first converter group 211_1 to 211_N is a vanadium redox flow. The voltage of energy output through the battery stacks 100_1 to 100_N is first boosted to a specific voltage, and the second converter group 212_1 to 212_N further increases the specific voltage boosted by the first converter group 211_1 to 211_N. Second step-up with high voltage.

In the first converter group 211_1 to 211_N, a plurality of converters are configured in parallel with each other and operate with a different phase difference to perform primary boosting. In this case, the plurality of converters may be implemented as bidirectional converters, and four bidirectional converters are respectively connected in parallel to form first converter groups 211_1 to 211_N. At this time, each of the four bidirectional converters of the first converter group 211_1 to 211_N operates with a phase difference.

In this way, after connecting four bidirectional converters in parallel, each of the four bidirectional converters operates with a different phase difference from each other, thereby reducing the input current ripple and stabilizing the current flowing in the vanadium redox flow battery stack 100_1 to 100_N. have.

In addition, by using four bidirectional converters, the size of the reactor used can be reduced compared to when using one bidirectional converter, and there is an advantage that the voltage can be boosted higher (eg, 2 to 4 times).

In the second converter groups 212_1 to 212_N, a plurality of converters are configured in series with each other, and a secondary boosting of a specific voltage that is primary boosted by the first converter group is performed. In this case, the plurality of converters may be implemented as an LLC topology, and two LLC topologies are respectively connected in series to form the second converter groups 212_1 to 212_N. At this time, since the two LLC topologies are respectively connected in series, as the step-up ratio of the converters of the second converter group 212_1 to 212_N increases, the efficiency decrease increases, so that the step-up can be performed through two steps.

5 is a circuit diagram illustrating a power conversion system using a vanadium redox flow battery stack according to an embodiment of the present invention.

Referring to FIG. 5 , a power conversion system using a vanadium redox flow battery stack includes a plurality of vanadium redox flow battery stacks 100_1 to 100_N, a plurality of power conversion devices 200_1 to 200_N, and an energy storage device 300 . And, the power conversion device 200 includes a plurality of converter modules (210_1 to 210_N) and a plurality of inverter modules (220_1 to 220_N).

Each of the plurality of converter modules 210_1 to 210_N is output through the vanadium redox flow battery stack 100_1 to 100_N through two steps through the first converter group 211_1 to 211_N and the second converter group 212_1 to 212_N A voltage of 700Vdc may be input to the plurality of inverter modules 220_1 to 220_N by boosting the voltage of the energy used.

That is, when a single converter boosts the voltage of energy output through the vanadium redox flow battery stack 100_1 to 100_N to a high voltage of 7 to 8 times, efficiency reduction and a risk of failure occur, so the present invention provides multiple Energy output through the vanadium redox flow battery stack 100_1 to 100_N through two steps through the first converter group 211_1 to 211_N and the second converter group 212_1 to 212_N of the converter module 210_1 to 210_N It is possible to increase the voltage of 700Vdc and reduce the risk of failure at the same time.

Since each of the plurality of power conversion devices 200_1 to 200_N can convert the energy of the vanadium redox flow battery stack corresponding to 25kW class, a plurality of power conversion devices 200_1 to 200_N as shown in FIG. 5 . By configuring in parallel, it is possible to implement a power conversion system using a vanadium redox flow battery stack capable of converting the energy of a vanadium redox flow battery stack corresponding to 250 kW.

6 is a flowchart illustrating an embodiment of a power conversion method using a vanadium redox flow battery stack according to the present invention.

Referring to FIG. 6 , the power conversion system using the vanadium redox flow battery stack pumps and receives the electrolyte stored in the electrolyte tank through the vanadium redox flow battery stack, and generates energy by a chemical reaction with the electrolyte (step S610).

The power conversion system using the vanadium redox flow battery stack primarily boosts the voltage of energy output through the vanadium redox flow battery stack through the first converter group of a plurality of converter modules to a specific voltage (step S620).

A power conversion system using a vanadium redox flow battery stack boosts a specific voltage primarily boosted by the first converter group to a voltage higher than the specific voltage through a second converter group of a plurality of converter modules (step S630).

In the power conversion system using the vanadium redox flow battery stack, the inverter module generates the voltage of the secondary boosted energy into the system voltage (step S640).

In the power conversion system using the vanadium redox flow battery stack, the energy storage device stores the energy output by the inverter module (step S660).

Although it has been described with reference to the limited embodiments and drawings, the present invention is not limited to the above embodiments, and various modifications and variations are possible from these descriptions by those skilled in the art to which the present invention pertains. Accordingly, the spirit of the present invention should be understood only by the claims described below, and all equivalents or equivalent modifications thereof will fall within the scope of the spirit of the present invention.

100: vanadium redox flow cell stack,
110: electrolyte tank,
120: pump,
130: stack,
200: power converter,
210_1~210_N: a plurality of converter modules,
211_1 to 211_N: the first converter group;
212_1 to 212_N: second converter group;
220_1~220_N: multiple inverter modules,
300: energy storage device

Claims (10)

a vanadium redox flow battery stack comprising an electrolyte tank for storing an electrolyte, a pump for pumping the electrolyte stored in the electrolyte tank, and a stack for generating energy through a chemical reaction by receiving an electrolyte from the pump;
A plurality of converters for first boosting the voltage of energy output through the vanadium redox flow battery stack to a specific voltage, and then secondarily boosting the first boosted specific voltage to a voltage higher than the specific voltage are respectively connected a power conversion device comprising a plurality of converter modules and a plurality of inverter modules for generating the secondary boosted voltage into a system voltage; and
An energy storage device for storing the energy output from the power conversion device,
Each of the plurality of converter modules is
a first converter group in which four bidirectional converters are respectively connected in parallel and operate with a different phase difference to perform primary boosting of the voltage of energy output through the vanadium redox flow battery stack to a specific voltage; and
A second converter group connected to the first converter group, two LLC topologies are configured in series with each other, and performing secondary boosting of the specific voltage boosted by the first converter group to a higher voltage. characterized
A power conversion system using a vanadium redox flow cell stack.
delete delete delete According to claim 1,
Each of the plurality of converter modules is
Characterized in that the voltage of the energy output through the vanadium redox flow battery stack is boosted to a voltage higher than the voltage required by the power conversion system
A power conversion system using a vanadium redox flow cell stack.
When the vanadium redox flow battery stack is supplied by pumping the electrolyte stored in the electrolyte tank, generating energy by a chemical reaction with the electrolyte;
first step-up of a voltage of energy output through the vanadium redox flow battery stack by a first converter group of a plurality of converter modules to a specific voltage;
a second step-up step of a second converter group of the plurality of converter modules by a second voltage boosted by the first converter group to a voltage higher than the specific voltage;
generating, by an inverter module, the voltage of the secondary boosted energy into a system voltage; and
An energy storage device comprising the step of storing the energy output by the inverter module,
The step of first step-up to the specific voltage is
Step of performing the first step-up of the voltage of energy outputted through the vanadium redox flow battery stack to a specific voltage by operating the first converter group comprising four bidirectional converters connected in parallel to each other with a phase difference from each other including,
The step of second step-up to a voltage higher than the specific voltage is
The second converter group connected to the first converter group and having two LLC topologies configured in series with each other performs secondary boosting of the specific voltage boosted by the first converter group to a higher voltage. characterized by including
A method of power conversion using a vanadium redox flow cell stack.
delete delete delete 7. The method of claim 6,
It characterized in that it comprises the step of boosting the voltage of the energy output by the plurality of converter modules through the vanadium redox flow battery stack to a voltage higher than the voltage required by the power conversion system.
A method of power conversion using a vanadium redox flow cell stack.

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