TWI452802B - Solar storage system and driving method using the same - Google Patents

Description

Solar energy storage system and driving method thereof

The invention relates to solar energy technology, in particular to a solar energy storage system and a driving method thereof.

As a new type of energy, solar energy is becoming more and more widely used. For example, solar lighting devices, the use of solar energy to power electronic products, and the use of solar energy to drive automobiles continue to emerge. The conversion of solar energy into an important part of energy-based solar applications requires the use of solar energy storage systems.

In the prior art, solar energy storage systems generally include solar panels, charge and discharge control devices, and energy storage devices. Solar panels are used to collect solar energy and convert solar energy into electrical energy. The charge and discharge control device is used to control the solar panel to charge the energy storage device and control the energy storage device to supply power to the load. When fast charging is required, the charging and discharging control device is generally used to convert the DC voltage outputted by the solar panel into a relatively high voltage pulse voltage to charge the energy storage device. Wherein, the positive pulse voltage of the pulse voltage charges the energy storage device, and the negative pulse voltage does not charge the energy storage device. The negative pulse voltage can play a snoring protection function when the energy storage device is rapidly charged, avoiding excessive accumulation of air bubbles on the electrode plate of the energy storage device, slowing the temperature rise of the energy storage device, and improving the service life of the energy storage device. However, the negative pulse voltage is consumed on the charge and discharge control device, so that the charge and discharge control device generates heat, thereby reducing the service life of the charge and discharge control device. Moreover, the negative pulse voltage consumed by the portion of the heat also causes waste of energy and reduces the utilization efficiency of the solar energy.

In view of this, it is necessary to provide a solar energy storage system and a driving method thereof that can effectively improve the service life of the charge and discharge control device and reduce solar waste.

A solar energy storage system and a driving method thereof will be described below by way of specific embodiments.

A solar energy storage system includes: a solar panel, a charge and discharge control device, a main energy storage device, a trigger unit, an inverter, and an auxiliary energy storage device. The solar panel is used to collect solar energy and convert solar energy into electrical energy. The charge and discharge control device is connected between the solar panel and the main energy storage device. The charge and discharge control device is configured to convert a DC voltage outputted by the solar panel into a positive and negative alternating pulse voltage and charge the energy storage device with a positive pulse voltage. The positive and negative alternating pulse voltages include a positive pulse voltage and a negative pulse voltage. The trigger unit is connected to the charge and discharge control device and the inverter, and the trigger unit is configured to turn on the inverter during a period of a negative pulse voltage. The inverter is coupled to the auxiliary energy storage device for converting the negative pulse voltage to a positive pulse voltage and charging the auxiliary energy storage device.

A driving method for the above solar energy storage system, comprising the steps of:

The charging and discharging control device converts the DC voltage outputted by the solar panel into a positive and negative alternating pulse voltage and uses the positive pulse voltage to charge the energy storage device;

Using a trigger unit to cause the charge and discharge control device to electrically turn on the inverter while outputting a negative pulse voltage;

The negative pulse voltage output from the charge and discharge control device is converted into a positive pulse voltage by the inverter and charges the auxiliary energy storage device.

Compared with the prior art, the solar energy storage system and the driving method thereof of the present technical solution convert the DC voltage outputted by the solar panel into positive and negative alternating pulse voltages by using a charge and discharge control device. The solar energy storage system uses the positive pulse voltage to charge the energy storage device on the one hand, and converts the negative pulse voltage outputted by the charge and discharge control device into a positive pulse voltage by using an inverter and charges the auxiliary energy storage device. Therefore, the solar energy storage system and the driving method thereof can effectively avoid negative pulse voltage consumption, cause overheating of the charging and discharging control device on the charging and discharging control device, improve the service life of the charging and discharging control device; and, the output of the charging and discharging control device is negative The pulse voltage can be effectively utilized to improve the solar energy utilization efficiency of the solar energy storage system.

The solar energy storage system of the present technical solution will be further described in detail below with reference to the accompanying drawings and embodiments.

Referring to FIG. 1 , a solar energy storage system 100 according to a first embodiment of the present invention includes a solar panel 10 , a charge and discharge control device 20 , a main energy storage device 30 , a trigger unit 40 , an inverter 50 , and an auxiliary energy storage device. 60.

The solar panel 10 is used to collect solar energy and convert the solar energy into electrical energy. The solar panel 10 outputs a direct current voltage.

The charge and discharge control device 20 is connected between the solar panel 10 and the main energy storage device 30. The charge and discharge control device 20 is for converting a direct current voltage output from the solar panel 10 into a positive and negative alternating pulse voltage. The positive and negative alternating pulse voltages include a positive pulse voltage and a negative pulse voltage. The duty cycle of the positive pulse voltage is greater than the duty cycle of the negative pulse voltage. In this embodiment, the duty cycle of the positive pulse voltage is 70%-98%. The positive pulse voltage can be used to charge the energy storage device 30. When the amount of power of the main energy storage device 30 is insufficient, the charge and discharge control device 20 charges the electric energy generated by the solar panel 10 to the main energy storage device 30; when the main energy storage device 30 has sufficient power, the charge and discharge control device 20 The solar panel 10 is controlled to stop charging the main energy storage device 30.

The main energy storage device 30 is used to store the electrical energy converted by the solar panel 10 and to supply electrical energy to a load (not shown).

The trigger unit 40 is connected to the charge and discharge control device 20 and the inverter 50. When the charge and discharge control device 20 outputs a negative pulse voltage to prevent the temperature of the main energy storage device 30 from rising, the trigger unit 40 is simultaneously triggered and operates. The trigger unit 40 turns on the inverter 50 and the charge and discharge control device 20 during the period of the negative pulse voltage. When the charge and discharge control device 20 outputs a positive pulse voltage, the trigger unit 40 stops operating and cuts off the electrical connection between the inverter 50 and the charge and discharge control device 20.

The inverter 50 is connected between the trigger unit 40 and the auxiliary energy storage device 60. The inverter 50 can delay the phase of the voltage or current by 180 degrees, thereby realizing mutual conversion of positive voltage and negative voltage, or mutual conversion of positive current and negative current. Here, the inverter 50 is for converting the negative pulse voltage output from the charge and discharge control device 20 into a positive pulse voltage to charge the auxiliary energy storage device 60.

Specifically, when the charge and discharge control device 20 outputs a positive pulse voltage, the positive pulse voltage charges the main energy storage device 30; when the charge and discharge control device 20 outputs a negative pulse voltage, the trigger unit 40 is triggered to be connected. The inverter 50 is coupled to the charge and discharge control device 20, which converts the negative pulse voltage into a positive pulse voltage and charges the auxiliary energy storage device 60. Since the negative pulse voltage is converted into a positive pulse voltage by the inverter 50 to charge the auxiliary energy storage device 60, the loss of the negative pulse voltage in the charge and discharge control device 20 is correspondingly reduced, and the solar energy utilization efficiency of the solar energy storage system 100 is improved. .

Referring to FIG. 2, the driving method of the solar energy storage system 100 in the first embodiment includes the following steps:

In step 110, the DC voltage output from the solar panel 10 is converted into a positive and negative alternating pulse voltage by the charge and discharge control device 20, and the positive energy storage device 30 is charged by the positive pulse voltage.

Specifically, the charge and discharge control device 20 converts the DC voltage output from the solar panel 10 into a pulse voltage of alternating positive and negative. The positive and negative alternating pulse voltages include a positive pulse voltage and a negative pulse voltage. The duty cycle of the positive pulse voltage is greater than the duty cycle of the negative pulse voltage. In this embodiment, the duty cycle of the positive pulse voltage is 70%-98%. Then, the positive energy storage device 30 is charged by the positive pulse voltage, so that the main energy storage device 30 can be quickly charged.

In step 120, the charging and discharging control device 20 is caused to electrically turn on the inverter 50 while outputting the negative pulse voltage by the trigger unit 40.

Specifically, when the charge and discharge control device 20 outputs a negative pulse voltage, the trigger unit 40 triggers the operation. After the trigger unit 40 is triggered, the inverter 50 is electrically turned on, so that the inverter 50 and the charge and discharge control device 20 are in electrical communication state. When the charge and discharge control device 20 outputs a positive pulse voltage, the trigger unit 40 stops the triggering operation. The trigger unit 40 is disconnected from the inverter 50, thereby causing the inverter 50 and the charge and discharge control device 20 to be in an off state.

In step 130, the negative pulse voltage output from the charge and discharge control device 20 is converted into a positive pulse voltage by the inverter 50 and the auxiliary energy storage device 60 is charged.

Specifically, the phase of the negative pulse voltage output from the charge and discharge control device 20 is delayed by 180 degrees by the inverter 50, so that the negative pulse voltage output from the charge and discharge control device 20 is converted into a positive pulse voltage. Then, the positive pulse voltage converted by the inverter 50 is utilized and the auxiliary energy storage device 60 is charged.

The driving method of the solar energy storage system 100 of the present technical solution can charge the positive energy storage device 30 by using the positive pulse voltage outputted by the charge and discharge control device 20, and convert the negative pulse voltage outputted by the charge and discharge control device 20 by the inverter 50. The positive pulse voltage charges the auxiliary energy storage device to improve solar energy utilization efficiency.

Referring to FIG. 3 , the solar energy storage system 200 of the second embodiment of the present invention is substantially the same as the solar energy storage system 100 provided by the first embodiment, except that the solar energy storage system 200 further includes a switching unit 270 . With an additional load of 280.

Specifically, the switching unit 270 is connected to the inverter 250, the auxiliary energy storage device 260, and the additional load 280. The switching unit 270 mainly functions as a switch. The additional load 280 is a powered device that can be powered by alternating current. For example, the additional load 280 can be an alternating current light emitting diode. The switching unit 270 is configured to switch between the auxiliary energy storage device 260 and the additional load 280 to cause the inverter 250 to be connected to the auxiliary energy storage device 260 or the additional load 280. When the inverter 250 is connected to the auxiliary energy storage device 260, the inverter 250 converts the negative pulse voltage outputted by the charge and discharge control device 220 into a positive pulse voltage to charge the auxiliary energy storage device 260; when the inverter 250 is attached When the load 280 is turned on, the inverter 250 converts the negative pulse voltage output from the charge and discharge control device 220 into a positive pulse voltage to supply the additional load 280, so that the additional load 280 can operate normally.

The solar energy storage system and the driving method thereof of the technical solution use the charging and discharging control device to convert the DC voltage outputted by the solar panel into positive and negative alternating pulse voltages and charge the main energy storage device by using the positive pulse voltage; then, using the inverter The negative pulse voltage outputted by the charge and discharge control device is converted into a positive pulse voltage and charges the auxiliary energy storage device. Therefore, the solar energy storage system and the driving method thereof can effectively avoid negative pulse voltage consumption, cause overheating of the charging and discharging control device on the charging and discharging control device, improve the service life of the charging and discharging control device; and, the output of the charging and discharging control device is negative The pulse voltage can be effectively utilized to improve the solar energy utilization efficiency of the solar energy storage system.

In summary, the present invention has indeed met the requirements of the invention patent, and has filed a patent application according to law. However, the above description is only a preferred embodiment of the present invention, and it is not possible to limit the scope of the patent application of the present invention. Equivalent modifications or variations made by persons skilled in the art in light of the spirit of the invention are intended to be included within the scope of the following claims.

100,200‧‧‧Solar energy storage system

10‧‧‧ solar panels

20,220‧‧‧Charge and discharge control device

30‧‧‧Main energy storage device

40‧‧‧Trigger unit

50, 250‧‧‧Inverter

60, 260‧‧‧ auxiliary energy storage device

270‧‧‧Switch unit

280‧‧‧Additional load

1 is a block diagram of a solar energy storage system provided by a first embodiment of the present technical solution.

2 is a flow chart of a driving method of a solar energy storage system according to a first embodiment of the present technical solution.

3 is a block diagram of a solar energy storage system provided by a second embodiment of the present technical solution.

100‧‧‧Solar energy storage system

10‧‧‧ solar panels

20‧‧‧Charge and discharge control device

30‧‧‧Main energy storage device

40‧‧‧Trigger unit

50‧‧‧Inverter

60‧‧‧Auxiliary energy storage device

Claims (8)

A solar energy storage system comprising:
Solar panel, charge and discharge control device and main energy storage device,
The solar panel is used to collect solar energy and convert solar energy into electrical energy.
The charge and discharge control device is connected between the solar panel and the main energy storage device, and the charge and discharge control device is configured to convert the DC voltage outputted by the solar panel into positive and negative alternating pulse voltages and charge the energy storage device with the positive pulse voltage. The positive and negative alternating pulse voltages include a positive pulse voltage and a negative pulse voltage;
The solar energy storage system further includes a trigger unit, an inverter and an auxiliary energy storage device, the trigger unit is connected to the charge and discharge control device and the inverter, and the trigger unit is configured to output a negative pulse voltage in the charge and discharge control device. The inverter is turned on for a period of time, the inverter being coupled to the auxiliary energy storage device for converting the negative pulse voltage to a positive pulse voltage and charging the auxiliary energy storage device. The solar energy storage system of claim 1, wherein the duty cycle of the positive pulse voltage is greater than the duty cycle of the negative pulse voltage. The solar energy storage system of claim 1, wherein the positive pulse voltage has a duty ratio of 70% to 98%. The solar energy storage system of claim 1, wherein the solar energy storage system further comprises a switching unit and an additional load, the switching unit is connected to the inverter, the auxiliary energy storage device and the additional load, and the switching unit is used. Switching between the auxiliary energy storage unit and the additional load causes the inverter to be connected to the auxiliary energy storage device or an additional load. A method for driving a solar energy storage system according to any one of claims 1-3, comprising the steps of:
The charging and discharging control device converts the DC voltage outputted by the solar panel into a positive and negative alternating pulse voltage and uses the positive pulse voltage to charge the energy storage device;
Using a trigger unit to cause the charge and discharge control device to electrically turn on the inverter while outputting a negative pulse voltage;
The negative pulse voltage output from the charge and discharge control device is converted into a positive pulse voltage by the inverter and charges the auxiliary energy storage device. The method for driving a solar energy storage system according to claim 5, wherein the inverter and the charge and discharge control device are in an electrical communication state only during a period of a negative pulse voltage. The driving method of the solar energy storage system according to claim 5, wherein the duty ratio of the positive pulse voltage is greater than the duty ratio of the negative pulse voltage. The driving method of the solar energy storage system according to claim 5, wherein the positive pulse voltage has a duty ratio of 70% to 98%.