TWM571618U - Power generation efficiency booster - Google Patents

Abstract

A power generation efficiency riser for solving the problem of the overall power loss of a power generation array by a conventional power optimization technique. The system includes: a conversion module having four switching switches and a storage inductor, each of the switching switches electrically connecting the energy storage inductor to form a full bridge circuit, the conversion module having an input end and an output end; a detection module, the detection module is electrically connected to the input end and the output end of the conversion module; a control module has a receiving unit and a processing unit, and the receiving unit is electrically connected to the a detection module and the processing unit; and a driving circuit electrically connected to the processing unit and the four switching switches respectively.

Description

Power generation efficiency booster

This creation is about a power generation efficiency riser, especially a power generation efficiency riser that converts power through energy storage to reduce energy loss.

The energy conversion efficiency of solar panels is related to the amount of sunlight shining on the panel. When unforeseen factors such as changes in sunshine conditions, dirty panels, and aging failure of a single panel occur, the power generation of solar panels fluctuates. In addition, the energy conversion efficiency of wind power generation is related to the ambient wind and wind direction. When unforeseen factors such as wind or windward surface changes and mechanical parts aging occur, the wind power generation fluctuates. Moreover, solar or wind power plants usually combine several power generating components (solar panels or wind turbines) in series and parallel to form a power generating array to provide sufficient power generation power, but when the power generation of each power generating component When the height is not high, the total output power after series and parallel connection is less than the sum of the power generation of a single power generation component, that is, the loss of electrical energy during transmission, affecting the actual power generation of the overall power station, and even causing damage to the power generation component or reducing the service life.

The conventional power control system uses a plurality of variable resistors in series or in parallel to each of the power generating components, and can adjust the output voltage and current slightly, and then find the maximum power point by measuring the power, but each can The variable resistance system converts electrical energy into thermal energy to balance the power generation of each of the power generating components, resulting in additional energy loss, reducing energy conversion efficiency, and generating thermal energy causing temperature rise, affecting the performance of the power generating component, and even causing the system damage. In addition, the conventional power control system must adjust the configuration according to different forms of power generation components, resulting in inconvenience of integration and use.

In view of this, the conventional power control system does have the need to improve.

In order to solve the above problems, the purpose of the present invention is to provide a power generation efficiency booster that is converted by energy storage to reduce energy loss.

The second purpose of this creation is to provide a power generation efficiency booster that integrates monitoring and buck-boost functions and can be used for various energy sources with varying power.

The power generation efficiency enhancer of the present invention comprises: a conversion module having four switch switches and a storage inductor, each of the switch switches electrically connecting the energy storage inductor to form a full bridge circuit, and the conversion module has a An input terminal and an output terminal; the detection module is electrically connected to the input end and the output end of the conversion module respectively; a control module having a receiving unit and a processing unit, The receiving unit is electrically connected to the detecting module and the processing unit respectively; and a driving circuit is electrically connected to the processing unit and the four switching switches respectively.

Accordingly, the power generation efficiency booster of the present invention forms a boost converter and a buck converter by the energy storage component and the switching component, and analyzes and controls the voltage and current of the input and output through the control module to achieve power. Maximize the effect, so that it does not need to balance the energy through the resistor, which can reduce energy waste and avoid the influence of components on the heat. In addition, the power generation efficiency enhancer of this creation integrates monitoring and conversion functions, and can be applied to various powers. Power generation components.

The conversion module has an input capacitor connected in parallel to the input end, and an output capacitor is connected in parallel to the output end. In this way, the input capacitor and the output capacitor can be used as filters to reduce voltage chopping.

The detection module has an input voltage sensor connected in parallel with the input end, an input current sensor is connected in series with the input end, an output voltage sensor is connected in parallel with the output end, and an output current sensor is connected in series. Output. In this way, it is possible to measure the voltage and current of the power generation, and the voltage and current after the conversion, which has the effect of detecting the conversion efficiency.

The receiving unit is electrically connected to the input voltage sensor, the input current sensor, the output voltage sensor, and the output current sensor. As such, it has the effect of receiving detected data for subsequent analysis.

Wherein, the receiving unit is an analog digital converter. In this way, the continuous signal can be converted into a discrete signal, which has the function of receiving the detected data in a timed and fixed interval.

The processing unit includes a maximum power point tracking technique. In this way, the output power can be monitored and the maximum output power can be maintained, which has the effect of improving energy conversion efficiency.

The control module has a communication unit, and the communication unit is electrically connected to the processing unit, and the communication unit is a universal asynchronous transceiver. In this way, the communication unit can transmit the detection data and the processing flow to the cloud database for storage or notification to the administrator, and has the functions of warning and management.

The control module has a recording unit electrically connected to the processing unit, and the recording unit is a random access memory. In this way, the recording unit can access various data for execution and operation of the processing unit, and has the effect of improving the processing speed.

Wherein, the control module is a microcontroller. In this way, the input, output, and processing functions can be integrated into a single wafer, which is small in size and convenient to use.

The control module and the driving circuit are microcontrollers. In this way, the arithmetic processing and the switching control interface can be integrated into a single wafer, which has the advantages of small size and convenient use.

The power generation efficiency booster of the present invention may further comprise a power supply unit, wherein the power supply unit is electrically connected to the control module and the driving circuit, and the power supply unit is connected in parallel with the input end of the conversion module. In this way, the power supply unit can provide the control module and the power required for the operation of the drive circuit through the energy source, and has the effect of not requiring an additional power supply source.

In order to make the above and other objects, features and advantages of the present invention more comprehensible, the preferred embodiments of the present invention are described in detail below with reference to the accompanying drawings.

Referring to FIG. 1 , a preferred embodiment of the present power generation efficiency booster O includes a conversion module 1 , a detection module 2 , a control module 3 , a drive circuit 4 , and a The power supply unit 5, the input end of the conversion module 1 is electrically connected to a power generating component S, and the power generating component S can be an energy source that changes power generation power such as a solar panel or a wind power generator, and the detecting module 2 The control module 3 is electrically connected to the detection module 2 and the driving circuit 4, and the driving circuit 4 is electrically connected to the conversion module 1 The power supply unit 5 is electrically connected to the control module 3 and the drive circuit 4 .

The conversion module 1 is formed by four switching switches 11a, 11b, 11c, 11d and a storage inductor 12, wherein one end of a first switching switch 11a is electrically connected to the conversion module 1 An input end, and the other end of the first switch 11a is electrically connected to the first end of the energy storage inductor 12; one end of a second switch 11b is electrically connected to the output end of the conversion module 1, and the second The other end of the switch 11b is electrically connected to the second end of the energy storage inductor 12; one end of the third switch 11c is grounded, and the other end of the third switch 11c is electrically connected to the first of the energy storage inductor 12 One end of the fourth switch 11d is grounded, and the other end of the fourth switch 11d is electrically connected to the second end of the energy storage inductor 12. Moreover, an input capacitor 13 can be connected in parallel with the input end of the conversion module 1, and an output capacitor 14 can be connected in parallel with the output end of the conversion module 1. In this way, the conversion module 1 can receive the electric energy generated by the power generating component S from the input end, and then store or use the electric energy by the output terminal after the power conversion processing.

The detection module 2 can be connected to the input end of the conversion module 1 by an input voltage sensor 21, and an input current sensor 22 is connected in series with the input end of the conversion module 1, and an output voltage sensor is used. 23 is connected in parallel with the output end of the conversion module 1, and an output current sensor 24 is connected in series with the output end of the conversion module 1. Thus, the input voltage sensor 21 to measure the generated voltage V _S S of the power-generating element, the input current sensor 22 for measuring the generated current I _S of the power-generating element S, the output voltage sensor 23 with To measure the conversion voltage V _{L of} the conversion module 1 , the output current sensor 24 is used to measure the conversion current I _{L of} the conversion module 1 .

The control module 3 has a receiving unit 31 electrically connected to the input voltage sensor 21 of the detecting module 2, the input current sensor 22, the output voltage sensor 23, and the The output current sensor 24 can be an Analog-to-Digital Converter (A/D), and the control module 3 can receive the detection through the receiving unit 31 in a timed and fixed interval. The supply voltage V _{S of the} module 2, the supply current I _S , the conversion voltage V _L and the conversion current I _L ; the control module 3 further has a processing unit 32 electrically connected to the receiving unit 31, and the processing unit 32 can pass The receiving unit 31 reads the detection data, converts the power generation of the power generating component S according to the power generation voltage V _S and the power generation current I _S , and converts the conversion module according to the conversion voltage V _L and the conversion current I _L 1 Optimized output power, and then through the Maximum Power Point Tracking (MPPT) technology, determine whether the power is abnormal (weather changes, component failures, etc.), and generate a control signal C to make the output power Maximum.

The control module 3 can also have a communication unit 33. The communication unit 33 can be a Universal Asynchronous Receiver Transmitter (UART). The communication unit 33 can transmit the detection data and processing flow to the cloud. The database is stored or notified to the manager. The control module 3 can also have a recording unit 34. The recording unit 34 can be a random access memory (RAM). The recording unit 34 can access various data and can be used by the processing unit. 32 execution and application, with the effect of improving processing speed. The receiving unit 31, the processing unit 32, the communication unit 33 and the recording unit 34 of the control module 3 can be integrated into a Micro Control Unit (MCU).

The driving circuit 4 is electrically connected to the four switching switches 11a, 11b, 11c, and 11d of the conversion module 1, and the driving circuit 4 can control the four switching switches 11a according to the control signal C generated by the processing unit 32. Turning on and off of 11b, 11c, and 11d, and further, the driving circuit 4 can respectively control the four switching switches 11a, 11b, 11c, and 11d by using different Pulse Width Modulation (PWM) signals. By adjusting the duty ratio of the pulse width modulation signal, the operation mode and the duty cycle of the conversion module 1 can be switched. The driving circuit 4 can also be integrated with the control module 3 in the microcontroller.

The power supply unit 5 provides the power required for the operation of the control module 3 and the driving circuit 4, and the power supply unit 5 can also connect the input end of the conversion module 1 to cause the power supply unit 5 to generate the power generating element S. The electrical energy is converted to supply the control module 3 and the drive circuit 4, thus eliminating the need to use an additional power supply to maintain operation.

According to the foregoing structure, when the power generation power of the power generating component S decreases, the control module 3 can immediately measure through the detecting module 2, and according to the basic circuit and the calculus theory, the change trend of the power generation power is known. The control module 3 switches the conversion module 1 to a boost converter or a buck converter through the drive circuit 4, wherein the first switch 11a and the second switch When the switch 11b is turned on, and the third switch 11c is turned off, the fourth switch 11d is controlled by a pulse width modulation signal, and the power generation voltage V _S of the power generating element S can be boosted and converted; When the switch 11b and the third switch 11c are turned on, and the fourth switch 11d is turned off, the first switch 11a is controlled by a pulse width modulation signal, and the power generation voltage V _S of the power generating element S can be lowered. Pressure conversion. In this manner, the control module 3 calculates the maximum value of the output power by adding or subtracting the generated voltage V _S and operating with the processing unit 32.

Referring to FIG. 2, the power generation efficiency riser O of the present invention can electrically connect the power generating element S one-to-one, and then combine and connect a load L by the plurality of power generation efficiency risers O in series or in parallel. The load L may be a battery, an inverter, or a power transmission line. Therefore, each of the power generating elements S may output maximum power and collect the power into the load L for power distribution processing such as energy storage and inverter.

In summary, the power generation efficiency enhancer of the present invention forms a boost converter and a buck converter by using an energy storage component and a switching component, and analyzes and controls the voltage and current of the input and output through the judgment of the control module. To achieve the power maximization effect, thus, it is not necessary to balance the energy through the resistor, which can reduce energy waste and avoid the influence of components on the heat energy. Moreover, the power generation efficiency enhancer of the present invention integrates the monitoring and conversion functions, and can be applied to various power meetings. A power generation component that changes.

Although the present invention has been disclosed by the above-described preferred embodiments, it is not intended to limit the present invention, and it is still within the spirit and scope of the present invention to make various changes and modifications to the above embodiments. The technical scope of the protection is created, so the scope of protection of this creation is subject to the definition of the patent application scope attached.

1‧‧‧Transition module

11a‧‧‧First switch

11b‧‧‧Second switch

11c‧‧‧third switch

11d‧‧‧fourth switch

12‧‧‧ Storage inductance

13‧‧‧Input capacitance

14‧‧‧Output capacitor

2‧‧‧Detection module

21‧‧‧Input voltage sensor

22‧‧‧Input current sensor

23‧‧‧Output voltage sensor

24‧‧‧Output current sensor

3‧‧‧Control Module

31‧‧‧ receiving unit

32‧‧‧Processing unit

33‧‧‧Communication unit

34‧‧‧recording unit

4‧‧‧Drive circuit

5‧‧‧Power supply unit

O‧‧‧Power efficiency booster

S‧‧‧Power Generation Components

V _S ‧‧‧Power generation voltage

I _S ‧‧‧Generation current

V _L ‧‧‧Switching voltage

I _L ‧‧‧Switching current

C‧‧‧Control signal

L‧‧‧load

[FIG. 1] A circuit architecture diagram of a preferred embodiment of the present invention. [Fig. 2] A schematic diagram of the implementation of a preferred embodiment of the present invention.

Claims (11)

A power generation efficiency booster includes: a conversion module having four switch switches and a storage inductor, each switch switch electrically connecting the energy storage inductor to form a full bridge circuit, the conversion module having an input end And an output module; the detection module is electrically connected to the input end and the output end of the conversion module respectively; a control module having a receiving unit and a processing unit, the receiving unit The detection module and the processing unit are electrically connected to each other; and a driving circuit is electrically connected to the processing unit and the four switching switches respectively. The power generation efficiency riser of claim 1, wherein the conversion module has an input capacitor connected in parallel to the input terminal, and an output capacitor is connected in parallel to the output terminal. The power generation efficiency riser of claim 1, wherein the detection module has an input voltage sensor connected in parallel with the input end, an input current sensor connected in series with the input end, and an output voltage sensing The output is connected in parallel with an output current sensor in series with the output. The power generation efficiency riser of claim 3, wherein the receiving unit is electrically connected to the input voltage sensor, the input current sensor, the output voltage sensor, and the output current sensing Device. The power generation efficiency riser of claim 4, wherein the receiving unit is an analog digital converter. The power generation efficiency riser of claim 1, wherein the processing unit includes a maximum power point tracking technique. The power generation efficiency riser of claim 1, wherein the control module has a communication unit electrically connected to the processing unit, and the communication unit is a universal asynchronous transceiver. The power generation efficiency riser of claim 1, wherein the control module has a recording unit electrically connected to the processing unit, and the recording unit is a random access memory. The power generation efficiency riser according to any one of claims 1, 7, or 8, wherein the control module is a microcontroller. The power generation efficiency riser according to any one of claims 1, 7, or 8, wherein the control module and the drive circuit are microcontrollers. The power generation efficiency riser of claim 1, further comprising a power supply unit electrically connected to the control module and the drive circuit, wherein the power supply unit is connected in parallel with the input end of the conversion module.