KR20120107233A - Rapid charging system for a battery base on a photovoltaic generation system - Google Patents

Abstract

PURPOSE: A rapid charging system for a battery based on a photovoltaic generation system is provided to reduce charging time for the battery using a constant voltage and constant current concurrent charging control method. CONSTITUTION: A three phase bidirectional PWM(Pulse Width Modulation) convertor part(300) changes a DC voltage outputted from a DC link part(200) into a three phase AC voltage. The three phase bidirectional PWM convertor part supplies the changed three phase AC voltage to a system. The three phase bidirectional PWM convertor part stores a predetermined DC output voltage to the DC link part and a battery. An insulation type DC/DC convertor part(400) controls energy saved in the DC link part and the battery in a preset constant voltage and constant current mode. The insulation type DC/DC convertor part transfers power to the battery. [Reference numerals] (AA) Three phase system; (BB) Solar cell

Description

 Battery Rapid Charging System through Linkage with Photovoltaic System {RAPID CHARGING SYSTEM FOR A BATTERY BASE ON A PHOTOVOLTAIC GENERATION SYSTEM}

The present invention relates to a fast charging system for a battery through linkage with a photovoltaic power generation system, and more particularly, through the current control of a three-phase pulse width modulation (PWM) converter, as well as from a commercial power source, MPPT (Maximum Power) of a photovoltaic system. Point tracking) control, and the maximum power is supplied through this, and the fast charging system of the battery through linkage with the photovoltaic system that controls the fast charging of the battery using the constant voltage / constant current parallel control of the fast charging system .

Global economic and industrial flows are struggling with extreme weather and energy costs due to the depletion of fossil fuels and global warming due to their use. It is natural to turn attention to alternative energy during this revolution and the world is competitively engaged in renewable energy development.

 The automobile industry is an industry that causes high pollution and consumes a lot of energy, and is devoted to developing electric vehicles as part of a renewable energy development project. Electric vehicles are powered by a secondary battery to drive electric motors, and thus, secondary batteries are an indispensable product of renewable energy. Secondary batteries are applied to all products moving in addition to the automotive industry, and solve environmental pollution, realize low cost, and add simplicity and convenience.

In order to use such a secondary battery, a charger is indispensable, and recently, a new charger for a rechargeable secondary battery having a high capacity is required. However, at present, there is no new technology or environment related to a new rechargeable secondary battery charger, and since the power for charging a large capacity battery is supplied from the system, energy consumption is severe and the utilization rate of the charging station site is low.

The present invention has been made in view of the above problems, by inducing rapid charging using a constant voltage / constant current parallel charge control technique for a high-capacity inverter type charging topology and super-fast charging, reducing the long charging time of the battery In connection with the photovoltaic system is to provide a battery rapid charging system.

In addition, the present invention provides a rapid charging system for a battery through a linkage with a solar power generation system that reduces the consumption of commercial power and increases the use of charging sites through linkage with the solar power generation system.

According to the present invention for achieving the technical problem, the step-up DC / boosting the DC voltage input from the solar cell to the preset DC output voltage by following the output of the solar cell changes in accordance with the amount of solar radiation and temperature at all times the maximum power point A DC converter unit; The power input from the solar cell through the boosting DC / DC converter unit, the power input or output from the system through the three-phase bidirectional PWM converter unit and the power to charge the battery through the isolated DC / DC converter unit is balanced DC link portion that acts as a buffer to achieve; Inverting the DC voltage output from the DC link unit into a three-phase AC voltage and supplying it to the system, and converting the DC link unit and the battery to store a constant DC output voltage in the battery by receiving power from the system. A three-phase bidirectional PWM converter unit; And an isolated type DC / DC converter for controlling power stored in the DC link unit and the battery in a predetermined constant voltage / constant current mode to transfer power to the battery. It includes.

According to the present invention as described above, by inducing rapid charging by using a constant voltage / constant current parallel charge control technique for a high-speed inverter charging topology and super-fast charging, SOC (State Of Charge) in relation to the charging time Up to 80% can be controlled in about 20 minutes.

In addition, by linking with the solar power generation system, it is possible to reduce the consumption of power used than the battery charging system through the existing system, and to integrate the solar cell power generation in the charging station site, the utilization rate of the renewable energy and the utilization of the site. Can increase.

1 is an exemplary view illustrating a basic concept of a battery rapid charging system through linkage with a solar power generation system according to an embodiment of the present invention.
Figure 2 is a circuit diagram of a battery rapid charging system through linkage with the solar power generation system according to an embodiment of the present invention.
3 is a power flow diagram of a three-phase bidirectional PWM converter according to an embodiment of the present invention, a slow charge mode power flow diagram (mode 1, FIG. 3a), a fast charge mode power flow diagram (mode 2, FIG. 3b), a power generation mode power flow diagram (Mode 3, Fig. 3c), Low-illumination mode power flow diagram (Mode 4, Fig. 3d).
Figure 4 is a graph of the rapid charging profile of the isolated DC / DC converter unit according to an embodiment of the present invention.

Specific features and advantages of the present invention will become more apparent from the following detailed description based on the accompanying drawings. It is to be noted that the detailed description of known functions and constructions related to the present invention is omitted when it is determined that the gist of the present invention may be unnecessarily blurred.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will now be described in detail with reference to the accompanying drawings.

Regarding the rapid charging system of the battery through connection with the photovoltaic power generation system of the present invention, it will be described with reference to FIGS.

1 is a basic concept of a rapid charging system for a battery through a connection with a photovoltaic power generation system according to an embodiment of the present invention, as shown in the boost DC / DC converter unit 100 and the DC link unit 200. , A three-phase bidirectional PWM converter 300, an isolated DC / DC converter 400, and a control unit for controlling the same.

Here, the control unit controls all the respective systems such as the boost DC / DC converter unit 100, the three-phase bidirectional PWM converter unit 300, the isolated DC / DC converter unit, and generates a PWM signal.

2 is a circuit diagram of a battery rapid charging system through linkage with a photovoltaic power generation system according to an embodiment of the present invention.

The step-up DC / DC converter 100 follows the output of the solar cell that changes according to the amount of insolation and temperature at all times to boost the DC voltage input from the solar cell to the preset DC output voltage.

The boost DC / DC converter unit 100 is a converter unit including a solar boost converter and a plurality of converters such as a buck boost converter, an axial converter, and an interleaved boost converter. In particular, the boost converter has a simple circuit configuration, a small number of elements, which is advantageous in terms of unit cost and easy to control, and is suitable for constructing the present circuit.

More specifically, the step-up DC / DC converter 100 functions to boost the input DC voltage to 330V or more and 380V or less by following the maximum power generated according to the solar radiation and temperature of the solar cell surface. In addition, it is possible to secure the maximum power at all times from the solar cell through Maximum Power Point Tracking (MPPT) control.

The DC link unit 200 is a power storage module for connecting the step-up DC / DC converter 100, the three-phase bidirectional PWM converter 300 and the isolated DC / DC converter 400 in the middle, By temporarily charging and discharging the input and output power of the three converter units described above, the input and output power of the system is controlled to be balanced.

Specifically, the power input from the solar cell through the step-up DC / DC converter unit 100, the power input to or from the system through the three-phase bidirectional PWM converter unit 300 and the isolated DC / The DC charging unit 400 serves as a buffer so that the power of charging the battery can be balanced.

The three-phase bidirectional PWM converter unit 300 converts the DC voltage output from the DC link unit 200 into a three-phase AC voltage and performs inverting to supply the system, and receives a power from the system, thereby providing a constant DC output voltage. The conversion is performed to store the DC link unit 200 and the battery.

The three-phase bidirectional PWM converter unit 300 controls the fast charging system of the battery by connecting with the photovoltaic system in largely four modes according to the relationship between the power supply of the solar cell and the battery charging power, inverting according to the mode Process and converting process.

Specifically, (a) When the power supply of the solar cell and the charging power of the battery are the same (slow charge mode, hereinafter Mode 1) (b) When the battery is rapidly charged and the power supply of the solar cell is smaller than the charge power of the battery (Quick charging mode, below mode 2) (C) When the power supply of solar cell is higher than the charging power of battery (below power generation mode, mode 3) The control is divided into Mode 4).

 (A) When the power supply of the solar cell and the charging power of the battery are the same (mode 1), the power flow of FIG. 3A may be referred to. Mode 1 is a case in which the power supply of the solar cell and the charging power of the battery are the same. The power generation of the solar cell is boosted by the voltage of the DC link unit 200 to 380V through the step-up DC / DC converter unit 100. The battery is charged through the boosted DC link unit 200 voltage through the insulated DC / DC converter unit 400. The charging method in a normal state is a slow charging mode.

(B) When the battery power is rapidly charged and the power supply of the solar cell is smaller than the battery charge power (hereinafter, Mode 2), the power flow of FIG. 3B may be referred to. Mode 2 is a case where the power supply of the solar cell is smaller than the charging power of the battery, and the power generation of the solar cell is converted into the boosted DC / DC converter unit 100, the DC link unit 200, and the insulated DC / DC. The battery is charged through the converter unit 400, and the insufficient power is supplied from the system through the three-phase bidirectional PWM converter unit 300 to charge the battery. As a fast charging method, even if the power supply of the solar cell is small, it is possible to charge the battery quickly by receiving power from the system.

(C) When the power supply of the solar cell is larger than the battery charging power (hereinafter, Mode 3), the power flow of FIG. 3C may be referred to. Mode 3 is a case where the power supply of the solar cell is greater than the battery charging power, and generates the remaining energy after charging the battery into the system through the three-phase bidirectional PWM converter unit 300. In this case, the insulated DC / DC converter 400 charges the battery, and the remaining energy is generated by the three-phase PWM converter 300 through the inverting process.

(D) If the supply power of the solar cell is very small (hereinafter, Mode 4), the power flow of FIG. 3D may be referred to. Mode 4 is a case of sunset or when there is a lot of clouds when the output of the solar cell does not occur, when the power supply of the solar cell is very small, converting all the charging power of the battery of the three-phase bi-directional PWM converter unit 300 The battery is charged through the DC link unit 200 and the insulated DC / DC converter unit 400 through the system.

The three-phase bidirectional PWM converter unit 300 recognizes the amount of power supply of the solar cell and changes the mode accordingly, while controlling the charging of the battery by appropriately using the solar cell power generation and the power generation of the system. If the solar cell has a large amount of power generated, only the solar cell can be used to charge the battery and the remaining power can be generated through the system.In addition, when the solar cell has little generated power, the battery can be charged by receiving power from the system. Rather than using only the system to charge the battery, the consumption of commercial power can be reduced, and the utilization of the site can be improved by integrating solar cell power generation at the charging station site.

The isolated DC / DC converter 400 controls the energy stored in the DC link unit 200 and the battery in a predetermined constant voltage / constant current mode to transfer power to the battery.

The isolated DC / DC converter 400 has a structure of a full-bridge converter. In addition, push-pull and half-bridge converters are generally available. The reason for using the isolated converter in this system is because of the isolation between the battery and the system, which is the standard of the fast charging device, and the fast charging is based on how the control sequence (system operation control) of the used topology is used rather than the type of topology used. It is determined whether or not charging. The present invention controls the fast charging through the control of the CC / CV method.

4 is a graph showing a rapid charging profile of the insulated DC / DC converter 400 according to an embodiment of the present invention. While charging the battery with a constant current (greater than 0A and less than 120A) of the energy stored in the DC link unit 200 (CC mode), the SOC (State Of Charge) is constant at a point where the state of charge becomes 90 to 95%. By controlling the battery to be charged at a voltage (300V or more and 500V or less) (CV mode), rapid charging is enabled.

While the present invention has been particularly shown and described with reference to preferred embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. It will be appreciated by those skilled in the art that numerous changes and modifications may be made without departing from the invention. And all such modifications and changes as fall within the scope of the present invention are therefore to be regarded as being within the scope of the present invention.

100; Step-up DC / DC Converter
200; DC link section
300; 3-phase bidirectional PWM converter section
400; Isolated DC / DC Converter

Claims (7)

A boosting DC / DC converter unit 100 for boosting the DC voltage input from the solar cell to a preset DC output voltage by following the output of the solar cell that changes according to the amount of solar radiation and the temperature at a maximum power point at all times;
Power input from the solar cell through the boosting DC / DC converter unit 100, power input from the system through the three-phase bidirectional PWM converter unit 300 or output to the system and the isolated DC / DC converter unit 400 DC link unit 200 that acts as a buffer so that the power to charge the battery through the balance);
Inverting the DC voltage output from the DC link unit 200 into a three-phase AC voltage and supplying it to the system, and receiving power from the system, outputs a constant DC output voltage to the DC link unit 200 and the battery. A three-phase bidirectional PWM converter unit 300 for storing and converting; And
An isolated DC / DC converter 400 for controlling power of the DC link unit 200 and the energy stored in the battery in a predetermined constant voltage / constant current mode to transfer power to the battery; Fast charging system of the battery through connection with the photovoltaic power generation system comprising a.
The method of claim 1,
The boost DC / DC converter unit 100,
Fast charging system of battery through linkage with photovoltaic power generation system which finds maximum output point of solar cell and sets preset DC output voltage to 330V or more and 380V or less.
The method of claim 1,
The three-phase bidirectional PWM converter unit 300,
When the power supply of the solar cell and the charging power of the battery are the same (mode 1), the power generation of the solar cell is boosted by the voltage of the DC link unit 200 to 380V through the step-up DC / DC converter unit 100. And a battery rapid charging system through linkage with the photovoltaic system for controlling the boosted DC link unit 200 to slowly charge the battery via the insulated DC / DC converter unit 400.
The method of claim 1,
The three-phase bidirectional PWM converter unit 300
When the power supply of the solar cell is smaller than the charging power of the battery due to rapid charging (mode 2), the power generation of the solar cell is converted into the boosted DC / DC converter unit 100, the DC link unit 200, and the insulation. The fast charging system of the battery through linkage with a photovoltaic system for charging the battery via the type DC / DC converter unit 400 and controlling the fast charging of the battery by supplying insufficient power from the system.
The method of claim 1,
The three-phase bidirectional PWM converter unit 300,
When the power supply of the solar cell is greater than the battery charging power (mode 3), the battery fast charging system through linkage with the solar power generation system that controls the battery to charge and generate the remaining energy to the grid.
The method of claim 1,
The three-phase bidirectional PWM converter unit 300,
When the supply power of the solar cell is very small (mode 4), all the charging power of the battery is supplied from the system to charge the battery via the DC link unit 200 and the insulated DC / DC converter unit 400. Fast charging system of battery through linkage with photovoltaic power generation system.
The method of claim 1,
The isolated DC / DC converter 400 is,
While charging the battery with a constant current greater than 0A and less than 120A of the energy stored in the DC link unit 200 (CC mode), the SOC is charged at a constant voltage of 300V or more and 500V or less at the moment 90-95% ( CV mode) Fast charging system of battery through linkage with photovoltaic power generation system.

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