KR20130088210A - High efficiency solar charging system - Google Patents

Abstract

PURPOSE: A high efficiency sunlight charging system is provided to protect an electric double layer capacitor (EDLC) by connecting to a solar battery through a high-capacity switch. CONSTITUTION: A high-capacity controls the connection state of a solar battery. The high-capacity switch controls the EDLC connection state of a sub-battery. A resistor controls charging current. The resistor charges the EDLC of the sub-battery. The high-capacity switch blocks or conducts charging currents. [Reference numerals] (AA) Vehicle battery; (BB) Surge voltage protection unit; (CC) Resistor; (DD) Main power supply switch control unit; (EE) Auxiliary power supply switch control unit; (FF) Overheating temperature sensing unit; (GG) Overvoltage sensing unit; (HH) Back voltage sensing unit; (II) Cell voltage sensing unit; (JJ) D.C. voltage smoothing circuit

Description

High Efficiency Solar Charging System {HIGH EFFICIENCY SOLAR CHARGING SYSTEM}

The present invention relates to a high efficiency solar charging device, and more particularly, it is connected in parallel through a solar charging battery and a control circuit using a high capacity EDLC (EDLC; Electric Double Layer Capacitor) with a very fast charge and discharge time. By supplying electricity to the electric device smoothly and when a lot of electric energy is charged in the solar rechargeable battery at the moment, it uses the fast charging characteristic of the EDLC to store the electric energy in the EDLC and supply it to the solar rechargeable battery. The purpose is to improve charging performance.

[Document 1] Korean Patent Registration No. 326815 "Voltage Enhancing Device for Complete Combustion of Internal Combustion Engine"

[Patent 2] Korean Patent Publication No. 2004-21707 "Voltage stabilization device of an alternator"

Many studies have been made to improve solar charging efficiency. Among the methods for smoothly charging and supplying electric energy, a method of applying a high capacity battery capable of charging a large amount of solar charging energy is common. However, the above method has a limitation in improving the charging efficiency of solar energy because its purpose is to improve the charging capacity. Therefore, EDLC is connected to the high capacity battery in parallel through the control circuit to maximize the instantaneous charging efficiency of the electric energy and to supply the electric energy to the battery to minimize the loss of electric energy to maximize the charging efficiency. In addition, the conventional method using the EDLC is a direct parallel connection between the solar rechargeable battery and the EDLC, when the parallel connection with the solar rechargeable battery gave an electric shock to the solar rechargeable battery due to the instantaneous charge phenomenon of the EDLC and overvoltage, overheating Due to such problems, EDLC could not be protected.

The present invention maximizes the instantaneous charging efficiency of electrical energy by connecting EDLC in parallel to the solar rechargeable battery to charge and supply electricity, thereby degrading the charging efficiency according to the momentary change of electrical energy generated by photovoltaic power generation. In order to solve the problem, the EDLC is connected to the solar rechargeable battery to control the charging time by controlling the charging current so that the instantaneous charging phenomenon does not occur and the electrical charge of the solar rechargeable battery is not controlled. It is connected through the control of a high capacity switch to protect the solar rechargeable battery and EDLC in response to problems such as overvoltage and overheating conditions, thereby realizing a high efficiency charging system and improving the lifetime and performance of the solar rechargeable battery and EDLC. It is characteristic.

The present invention uses the conventional EDLC directly connected to the solar rechargeable battery and unlike the products that improve the performance of solar charging efficiency through the overvoltage because it is connected through a high capacity switch without a direct connection with the solar rechargeable battery It protects the EDLC according to the problem of overheating and prevents the instantaneous charging phenomenon when connected to the solar rechargeable battery, thereby improving the performance and life of the solar rechargeable battery.

1 is a configuration diagram connecting a secondary battery manufactured using a conventional EDLC in parallel with a solar rechargeable battery
2 is an operation configuration diagram of a high efficiency solar charging system according to the present invention
3 is a circuit diagram illustrating an embodiment of a high efficiency solar charging system according to the present invention.
4 is a graph comparing electrical phenomena occurring when the high efficiency solar charging system according to the present invention is connected in parallel with a solar charging battery.
5 is an operation configuration diagram of a graph comparing the voltage drop phenomenon of the high efficiency solar charging system according to the charging of EDLC

The present invention relates to a high efficiency solar charging system for improving the charging efficiency by maximizing the charging efficiency of the electric energy by connecting the EDLC in parallel to the solar charging battery.

More details will be described with reference to the accompanying drawings.

1 is a block diagram for connecting a secondary battery manufactured using a conventional EDLC in parallel with a solar rechargeable battery. In order to make the EDLC's internal voltage higher than the solar charging battery voltage, a plurality of EDLCs were connected in series and the positive electrode and the GND of the EDLC were connected to the solar charging battery to maximize the charging efficiency of the electric energy. However, the conventional method has an electric shock on the solar rechargeable battery due to the instant charging phenomenon of the EDLC when the solar rechargeable battery is connected, adversely affect the performance and life of the solar rechargeable battery. In addition, when used outside the air exposure where the use environment is not very good, it is used unprotected against problems such as overvoltage or overheating condition, which adversely affects the performance and life of EDLC. In addition, when a problem occurs in the EDLC, the effect of the photovoltaic rechargeable battery is rapidly affected, resulting in a rapid deterioration of the state of the solar rechargeable battery.

2 is an operational configuration diagram of a high efficiency solar charging system according to the present invention. By connecting the solar rechargeable battery and EDLC through the high capacity switch of the main power switch controller, the protection circuit operates when the problem occurs during use to separate the connection state between the solar rechargeable battery and the EDLC to protect the EDLC. The configuration to protect EDLC is a surge voltage protection unit to protect against the surge voltage that occurs momentarily, and the secondary battery from the problem caused when the positive pole and GND are reversed due to inadvertent connection in parallel with the solar rechargeable battery. Reverse voltage detector to protect the circuit and EDLC of the circuit, overheat temperature detector to protect the ambient temperature or input voltage if it is higher than the standard, and EDLC connected in series with the overvoltage detector It consists of a cell voltage sensing unit for preventing electric shock and controlling an instant charging phenomenon, a resistor for controlling the charging current of the EDLC, and an auxiliary power switch control unit.

3 is a circuit diagram illustrating an embodiment of a high efficiency solar charging system according to the present invention. As a circuit diagram for operating this according to the configuration of the present invention described in FIG. 2, the solar charging battery and the EDLC are separated and controlled as the high capacity relays RL1 and RL2 of the main power switch controller. Designing TR application circuits as shown in Figure 3 to disconnect the solar cell and EDLC as a switch such as RL1 and RL2, but using program control or other switch elements that can be advantageous for cost reduction and function implementation. There is a method, but the driving principle is the same. This will be described by implementing a function as a typical TR application circuit.

When the user connects the solar rechargeable battery and the auxiliary battery in parallel, a reverse voltage is applied to the auxiliary battery when the positive pole and the GND are connected in reverse directions. At this time, the reverse voltage protection diodes D1, D3, D4, D5, D6, D7, and D8 prevent the reverse voltage from being supplied to the circuit to protect the circuit components and maintain the relay RL1 and RL2 disconnected circuits. Protects and EDLC.

Varistor RV1 protects the circuit and EDLC of the secondary battery by removing the surge voltage when the surge voltage is higher than the reference voltage is applied to the secondary battery.

In order to prevent the EDLC from charging instantaneously when the secondary battery is connected to the solar rechargeable battery in parallel, Q7 is turned on through the resistor R6 at the initial connection and drives the relay RL3 of the auxiliary power switch controller. When RL3 is driven, the relay contacts are attached and R11 controls the charging current to charge EDLC through the contacts of RL3. When the EDLC is charged above the reference voltage of the zener diode D9, D9 is turned on and Q3 is turned on. At this time, the collector of Q3 goes LOW and turns off Q4 and Q7. At this time, the collector of Q4 becomes HIGH by R7 and turns on Q5 and Q6. At this time, RL1 and RL2 of the main power switch control unit are driven to attach the contacts, and connect the solar rechargeable battery and the EDLC. Q7 turns OFF to stop the drive of relay RL3 and the contact drops.

Capacitors such as EDLC have a very long lifespan depending on the applied voltage or temperature used. Therefore, a device that protects against overheating and overvoltage conditions is essential.

Negative Temperature Coefficient Thermistor (NTC) RT1 and R2 are distributed when the temperature rises to protect the EDLC. Q1, which is kept OFF due to voltage, has a low resistance value of RT1, drives Q1 to an ON state, and the collector of Q1 is turned LOW so that Q3 connected to the collector of Q1 is turned OFF. When Q3 is turned off, the collector of Q3 is turned high by R6, and accordingly, Q4 is turned on so that Q5 and Q6 are turned off. At this time, RL1 and RL2 stop driving and disconnect the EDLC from the car battery connected by the contact. Q7 turned on by Q3 and R6 drives RL3 to supply current through the contacts of the relay, but when the temperature and applied voltage rise, the resistance value increases to show the negative current characteristic. Positive Temperature Coefficient thermistor) RT2 blocks the current to EDLC.

Electric energy is generated by solar power generation and supplies electric energy through solar rechargeable batteries. At this time, if a problem occurs in the photovoltaic power generation or a problem in the controlling portion thereof, it is impossible to control the generated electrical energy, resulting in overcharging or a loss of charge of the solar rechargeable battery and a voltage increase. At this time, overvoltage due to overcharging is also applied to the auxiliary batteries connected in parallel. When the overvoltage is applied, Q2 is turned on by the zener diode D2 which becomes conductive when the voltage is higher than the reference voltage, and the collector of Q2 is turned LOW. Q3 is turned off by Q2. When Q3 is turned off, the collector of Q3 goes high and accordingly, Q4 turns on and turns off Q5 and Q6. At this time, RL1 and RL2 stop driving and disconnect the EDLC from the solar rechargeable battery connected by the contact point. Q7, which is turned on by Q3, drives RL3 to supply current to the EDLC through the relay contacts, but when the temperature and applied voltage increase, the resistance value increases to block the current supplied by the RT2, which is a negative current characteristic, to the EDLC. do.

4 is a graph comparing electrical phenomena occurring when the high efficiency solar charging system according to the present invention is connected in parallel to the solar charging battery. 4A is a graph illustrating a voltage drop phenomenon of a battery generated during solar charging, and consumes the most electric energy during charging. When a lot of electrical energy is generated and supplied at the moment, the voltage of the solar rechargeable battery rises rapidly.

5 is an operation configuration diagram of a graph comparing the voltage drop phenomenon of the high efficiency solar charging system according to the charging of EDLC. FIG. 5 is a graph illustrating an instantaneous charging phenomenon of EDLC and a voltage drop phenomenon of the solar rechargeable battery according to the EDLC installed in the solar rechargeable battery. Because EDLC is very fast, it instantly charges the electrical energy that EDLC can hold when it is connected to a solar rechargeable battery, causing severe electrical shock to the solar rechargeable battery and reducing the life and performance of the solar rechargeable battery. The phenomenon occurred. The present invention minimizes the electric shock to the solar rechargeable battery because it charges the EDLC by controlling the amount of charge current supplied to the EDLC when charging the EDLC.

Auxiliary battery according to the present invention can be used as a secondary battery of a power source for driving solar charging-related technology or wind power generation technology, other large-capacity power charging a lot of instantaneous electrical energy.

It is applicable to all products using large capacity batteries according to the external environment in power generation using natural energy such as solar power, wind power, tidal power, and the function shows the same performance as described above.

In addition, when the secondary battery of the present invention is used, the capacity of the battery is expanded, and thus it is possible to use for a long time, thereby supplying sufficient electric energy to the electric devices, thereby improving the performance and life of the electric device.

Claims (5)

High efficiency solar charging system, characterized in that the control of the EDLC connection state of the solar rechargeable battery and the secondary battery as a high capacity switch.
2. The high efficiency solar charging system of claim 1, wherein the charging current of the EDLC is controlled as a resistor capable of controlling the charging current and a switch for conducting and blocking the charging current to charge the EDLC of the auxiliary battery. . The high efficiency solar charging system of claim 1, wherein a connection state of the high capacity switch is controlled through an overvoltage detector to protect the EDLC of the auxiliary battery from overvoltage. The high efficiency solar charging system of claim 1, wherein a connection state of the high capacity switch is controlled through an overheat temperature detector to protect the EDLC of the auxiliary battery from overheating temperature. The high efficiency photovoltaic charging system according to claim 1, wherein a connection state of the high capacity switch is controlled through a reverse voltage sensing unit to protect the control circuit and the EDLC of the secondary battery from reverse voltage.

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