KR20200035685A - Energy harvesting system using multiple ambient energy sources - Google Patents

Abstract

The present invention relates to an energy harvesting system using multiple peripheral energy sources. According to the present invention, the energy harvesting system includes: a plurality of energy converters connected to multiple peripheral energy sources respectively, and receiving energy from the multiple peripheral energy sources to convert the energy into electric energy; an electric energy buffer receiving and collecting the electric energy from the plurality of energy converters and adding the collected electric energy to a set electric power level; a constant voltage converter receiving the electric energy from the electric energy buffer to convert the energy into driving power of a power level which can be used by a load; and an electric energy storage receiving and storing the driving power from the constant voltage converter and providing the stored driving power to the load. If internal power for a specific energy converter occurs in accordance with the intensity of a peripheral energy source, the plurality of energy converters selectively use the internal power as external power for the other energy converters. The energy harvesting system can collect more energy by using multiple peripheral energy sources.

Description

Energy harvesting system using multiple ambient energy sources}

The present invention relates to an energy harvesting system (energy harvesting system), and more specifically, using a plurality of ambient energy sources to collect more energy and operate multiple electronics based on the energy based on the ambient energy source It relates to the energy harvesting system used.

It is predicted that the market for ultra-small / low-power IoT devices will explode due to the spread of Internet of Things (IoT) technology in a wide range of fields. However, the limitation of the power supply method such as battery replacement of the IoT device or connection of the power cord is one of the obstacles to the proliferation of IoT services.

Energy harvesting technology is drawing attention as a power supply technology for IoT devices, and research on non-powered driving technology or battery life extension technology of IoT devices has been actively conducted through the fusion of energy harvesting and IoT technology. The demands are also increasing.

Representative energy harvesting energy sources include sunlight, vibration, heat, and wind, and there are devices that operate using the energy sources. Since the existing energy harvesting technology uses only one energy source within a limited environment, there is a problem that it is difficult to utilize if the amount of energy is insufficient.

Korean Patent Publication No. 2017-0101756 (released on September 6, 2017)

Accordingly, an object of the present invention is to provide an energy harvesting system using multiple ambient energy sources capable of collecting more energy in various environments using multiple ambient energy sources, not just one energy source. have.

Another object of the present invention is to provide an energy harvesting system using multiple ambient energy sources capable of improving energy collection efficiency by using less electrical energy collected from each energy converter.

In order to achieve the above object, the present invention is connected to each of a plurality of ambient energy sources, a plurality of energy converters that receive energy from the multiple ambient energy sources and convert them into electrical energy; An electrical energy buffer that receives and collects electrical energy from the plurality of energy converters, and sums the collected electrical energy to a set power level; A constant voltage converter that receives electrical energy from the electrical energy buffer and converts the load into drive power at an available power level; And an electrical energy storage device receiving and storing driving power from the constant voltage converter and providing driving power stored as a load.

When the internal power of a specific energy converter is generated according to the intensity of the surrounding energy source, the plurality of energy converters selectively use the generated internal power as an external power of another energy converter.

The multiple ambient energy sources may include at least two ambient energy sources selected from the group consisting of sunlight, vibration, heat, and wind.

The plurality of energy converters are respectively connected to the plurality of ambient energy sources, and cores that receive energy from the multiple ambient energy sources and convert them into electrical energy; And a controller that controls the driving of the core and uses the generated internal power as an external power of another energy converter when the internal power is generated according to the surrounding energy source intensity.

Each of the plurality of energy converters may include an internal power supply node that selectively supplies the generated internal power to external power of another energy converter when internal power is generated according to the intensity of the surrounding energy source; And an external power node selectively receiving internal power generated from an internal power node of another energy converter.

An energy converter that receives internal power generated from an internal power node of another energy converter may maintain an operation standby state.

In addition, the present invention, each core is connected to a plurality of ambient energy sources, cores that receive energy from the multiple ambient energy sources and convert them into electrical energy; And a controller that controls the driving of the core and uses the generated internal power as an external power of another energy converter when an internal power is generated according to the intensity of the ambient energy source. Provides an energy converter for energy of a harvesting system.

The energy harvesting system according to the present invention may collect more energy by using multiple ambient energy sources, and operate an electronic device based on the energy, rather than using only one energy source.

The energy harvesting system according to the present invention combines small electrical energy collected from each ambient energy source and converts it into a usable electrical energy level.

Since the energy harvesting system according to the present invention can collect more ambient energy in the same environment, it is possible to expand the type of electronic devices that can be operated by using energy harvesting technology. Therefore, when the energy harvesting system according to the present invention is used, it can be utilized in the development of sensors and devices that can be operated using an ambient energy source without a battery.

In the energy harvesting system according to the present invention, when the internal power of a specific energy converter is generated according to the intensity of the surrounding energy source, the generated internal power can be selectively used as an external power of another energy converter, and thus collected in each energy converter It is possible to improve the energy collection efficiency by using less electric energy.

1 is a block diagram showing an energy harvesting system using heterogeneous energy according to an embodiment of the present invention.
FIG. 2 is a block diagram showing the energy converter of FIG. 1.
3 is a block diagram showing the connection structure of the two energy converters of FIG. 1.

It should be noted that in the following description, only parts necessary for understanding the embodiments of the present invention are described, and descriptions of other parts will be omitted without detracting from the gist of the present invention.

The terms or words used in the present specification and claims described below should not be construed as being limited to ordinary or dictionary meanings, and the inventor is appropriate as a concept of terms to describe his or her invention in the best way. It should be interpreted as a meaning and a concept consistent with the technical idea of the present invention based on the principle that it can be defined as such. Therefore, the configuration shown in the embodiments and drawings described in this specification is only a preferred embodiment of the present invention, and does not represent all of the technical spirit of the present invention, and various equivalents that can replace them at the time of this application It should be understood that there may be and variations.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram showing an energy harvesting system using heterogeneous energy according to an embodiment of the present invention.

Referring to FIG. 1, the energy harvesting system 100 according to the present embodiment collects more energy using a plurality of ambient energy sources, not just one ambient energy source, and loads based on the corresponding energy It is a system that operates 80 (electronic device).

The energy harvesting system 100 according to the present embodiment includes a plurality of energy converters 10; an electrical energy buffer 20; a constant voltage converter 60; and an electrical energy storage device. (70; Electrical Energy Storage). The plurality of energy converters 10 are respectively connected to a plurality of ambient energy sources, and receive energy from a plurality of ambient energy sources to convert them into electrical energy. The electrical energy buffer 20 receives and collects electrical energy from the plurality of energy converters 10 and sums the collected electrical energy to a set power level. The constant voltage converter 60 receives the combined electrical energy from the electrical energy buffer 20 and converts the load 80 into driving power at a power level that can be used. In addition, the electrical energy storage unit 70 receives and stores driving power from the constant voltage converter 60 and provides driving power stored in the load 80. At this time, when the internal power of a specific energy converter is generated according to the intensity of the surrounding energy source, the plurality of energy converters 10 may selectively use the generated internal power as an external power of another energy converter.

Here, the multiple ambient energy sources include first to nth ambient energy sources (hereinafter, n is a natural number of 2 or more). Ambient energy sources can be, but are not limited to, sunlight, vibration, heat, and wind. Multiple ambient energy sources include two or more different types of ambient energy sources.

The plurality of energy converters 10 are connected one-to-one to multiple ambient energy sources, and receive energy from each ambient energy source to convert it into electrical energy. The plurality of energy converters 10 includes first to nth energy converters 20, 30 and 40. Each of the plurality of energy converters 10 generates its own internal power source by using surrounding energy sources.

The electrical energy buffer 20 temporarily stores electrical energy converted by the plurality of energy converters 10 and includes passive elements capable of storing electrical energy such as capacitors. The electrical energy buffer 20 converts the electrical energy collected from the plurality of energy converters 10 into a set power level, and transmits it to the constant voltage converter 60.

The constant voltage converter 60 receives the electrical energy stored in the electrical energy buffer 20 and converts the load 80 into driving power at a power level usable.

In addition, the electrical energy storage 70 is an energy storage device that stores driving power for the load 80 to operate, for example, a capacitor, a secondary battery, or the like. The electrical energy storage unit 70 provides stored driving power to the load 80.

The operation principle of the energy harvesting system 100 according to this embodiment will be described as follows.

First, the energy converter 10 receives one or more ambient energy sources and converts them into electrical energy.

Next, the electrical energy converted by the energy converter 10 is accumulated in the electrical energy buffer 20. At this time, since the type and intensity of the surrounding energy source are different depending on the surrounding environment, the amount of electrical energy converted in each energy converter 10 and accumulated in the electrical energy buffer 20 is also different. Therefore, the electrical energy buffer 20 adds up the accumulated electrical energy.

In the case of a load 80 such as an ordinary electronic device, since an operable power level (voltage and current level) is determined, the electrical energy accumulated in the electrical energy buffer 20 cannot be used for the load 80 as it is.

Therefore, the electrical energy accumulated in the electrical energy buffer 20 is transferred to the constant voltage converter 60 to convert the driving power that the load 80 can use, that is, to a constant voltage / current, and convert the converted driving power to the constant voltage converter 60 Is transferred to and stored in the electrical energy storage (70).

In addition, the electrical energy storage unit 70 stores driving power received from the constant voltage converter 60 and provides driving power required by the load 80 among the stored driving power.

When the internal power of the specific energy converter 10 is generated according to the intensity of the surrounding energy source, the plurality of energy converters 10 according to the present embodiment selectively use the generated internal power as the external power of the other energy converter 10 do. Due to this, it is possible to improve energy collection efficiency by using less electrical energy collected from the first to nth energy converters 20, 30, and 40.

The energy converter 10 of the energy harvesting system 100 according to this embodiment will be described with reference to FIGS. 1 to 3 as follows. Here, FIG. 2 is a block diagram showing the energy converter 10 of FIG. 1. And FIG. 3 is a block diagram showing the connection structure of the two energy converters 20 and 30 of FIG. 1.

Referring to FIG. 2, the energy converter 10 according to the present embodiment includes a core 11 and a controller 13. The core 11 is connected to a plurality of ambient energy sources, respectively, and receives energy from multiple ambient energy sources to convert it into electrical energy. And the controller 13 controls the driving of the nose 13 language.

At this time, in order for the energy converter 10 to operate, operating power must be applied to the core 11 and the controller 13. For example, the energy converter 10 generates its own internal power source (VDD_INT) using a peripheral energy source and uses the generated internal power source as an operating power source and uses a separate external power source (VDD_EXT) as an operating voltage. There is a way.

When the internal power generated by itself is used as the operating power, there is an advantage of not having to use a separate external power. However, since an energy source cannot be collected and converted until an operating power source for operating the energy converter is generated during initial operation, collection of a very small energy source is impossible.

On the other hand, when an external power source is used as the operating power source, since the operating voltage is already supplied to the core 11 and the controller 13, the energy converter maintains an operation standby state, so it is relatively small compared to the method using the internal power source. It is also possible to collect energy sources, and it is possible to improve the electrical energy conversion efficiency of the input energy source of the energy converter. However, there is a disadvantage in that a separate external power source must be used, and this has a disadvantage in that it cannot be used in an environment in which there is no battery or an external power source connection is impossible, and an energy harvesting system that operates using only ambient energy sources is impossible.

The present embodiment provides the energy converter 10 in a manner that combines the advantages of the internal power supply with the advantages of an external power supply. That is, when the internal power source VDD_INT is generated according to the intensity of the surrounding energy source, the controller 11 of the energy converter 10 according to the present embodiment selectively uses the generated internal power source as the external power source VDD_EXT of another energy converter. do.

The energy converter 10 according to the present exemplary embodiment may include an internal power node 15 and an external power node 17. The internal power node 15 may selectively supply the generated internal power VDD_INT to the external power VDD_EXT of another energy converter when the internal power VDD_INT is generated according to the intensity of the surrounding energy source. In addition, the external power node 17 selectively receives the internal power VDD_INT generated from the internal power node of another energy converter.

That is, when an internal power source (VDD_INT) is generated in a specific energy converter according to the strength of the surrounding energy source, the internal power node of the energy converter in which the corresponding internal power source (VDD_INT) is generated is selectively provided to an external power node of another energy converter to provide other energy converters. It is a structure that can be used as an external operating power source (VDD_EXT).

Since the energy converter receiving the internal power (VDD_INT) generated from the internal power node of another energy converter can maintain the standby state of operation, it is possible to collect very small energy sources, and convert the electrical energy of the input energy source of the energy converter Efficiency can be improved.

Referring to FIG. 3, the first and second energy converters 20 and 30 include first and second cores 21 and 31 and first and second controllers 23 and 33.

In addition, the internal power nodes 25 and 35 of the first and second energy converters 20 and 30 and the external power nodes 27 and 37 are selectively connected to cross each other. That is, the internal power board 25 of the first energy converter 20 is selectively connected to the external power node 37 of the second energy converter 30. The external power board 27 of the first energy converter 20 is selectively connected to the internal power node 35 of the second energy converter 30.

Therefore, when the internal power is generated from the first energy converter 20, the internal power board 25 of the first energy converter 20 is selectively connected to the external power node 37 of the second energy converter 30 to remove the An internal power source (VDD_INT) generated by the 1 energy converter 20 may be provided to the second energy converter 30.

Conversely, when the internal power is generated from the second energy converter 30, the internal power board 35 of the second energy converter 30 is selectively connected to the external power node 27 of the first energy converter 20 to remove the internal power. 2 The internal power source VDD_INT generated in the energy converter 30 may be provided to the first energy converter 20.

Meanwhile, FIG. 3 discloses an example in which the internal power nodes 25 and 35 and the external power nodes 27 and 37 of the first and second energy converters 20 and 30 are selectively connected to each other, but are not limited to this. no. It can be expanded to n energy converters depending on the number of energy sources collected. Depending on the surrounding energy source situation, it is possible to selectively use the internal power of the energy converter, which itself has generated internal power among n energy converters, as the external power of other n-1 energy converters.

As described above, the energy converter 10 according to the present exemplary embodiment may improve energy collection efficiency when collecting multiple energy sources without connecting a battery and a separate external power source. That is, when the internal power source VDD_INT of the specific energy converter 10 is generated according to the intensity of the surrounding energy source, the energy harvesting system 100 according to the present exemplary embodiment selectively converts the generated internal power source VDD_INT into another energy converter ( Since it can be used as an external power source (VDD_EXT) of 10), it is possible to improve energy collection efficiency by using less electrical energy collected by each energy converter 10.

The energy harvesting system 100 according to the present exemplary embodiment may collect more energy using a plurality of ambient energy sources, and operate an electronic device based on the corresponding energy, rather than using only one energy source. .

The energy harvesting system 100 according to the present embodiment converts the small electrical energy collected from each ambient energy source into an usable electrical energy level.

Since the energy harvesting system 100 according to this embodiment can collect more ambient energy in the same environment, it is possible to expand the type of electronic devices that can be operated by using energy harvesting technology. Therefore, when the energy harvesting system 100 according to the present embodiment is used, it can be utilized in the development of sensors and devices that can be operated using an ambient energy source without a battery.

On the other hand, the embodiments disclosed in the specification and the drawings are merely presented as specific examples for ease of understanding, and are not intended to limit the scope of the present invention. It is obvious to those skilled in the art to which the present invention pertains that other modifications based on the technical idea of the present invention can be implemented in addition to the embodiments disclosed herein.

10: energy converter
11: core
13: controller
20: first energy converter
30: second energy converter
40: nth energy converter
50: electrical energy buffer
60: constant voltage converter
70: electrical energy storage
80: load
100: energy harvesting system

Claims (8)

A plurality of energy converters respectively connected to a plurality of ambient energy sources and receiving energy from the plurality of ambient energy sources and converting them into electrical energy;
An electrical energy buffer that receives and collects electrical energy from the plurality of energy converters, and sums the collected electrical energy to a set power level;
A constant voltage converter that receives electrical energy from the electrical energy buffer and converts the load into drive power at an available power level; And
It includes; an electric energy storage that receives and stores driving power from the constant voltage converter and provides driving power stored as a load.
The plurality of energy converters,
An energy harvesting system using multiple ambient energy sources, characterized in that when the internal power of a specific energy converter is generated according to the intensity of the surrounding energy source, the generated internal power is selectively used as an external power of another energy converter. According to claim 1,
The multiple ambient energy source is an energy harvesting system using multiple ambient energy sources, characterized in that it comprises at least two ambient energy sources selected from the group consisting of solar, vibration, heat and wind. According to claim 1, Each of the plurality of energy converters,
A core that is connected to the multiple ambient energy sources, and receives energy from the multiple ambient energy sources to convert it into electrical energy; And
A controller that controls the driving of the core and uses the generated internal power as an external power of another energy converter when the internal power is generated according to the intensity of the surrounding energy source;
Energy harvesting system using a plurality of ambient energy sources, characterized in that it comprises a. According to claim 1, Each of the plurality of energy converters,
An internal power supply node that selectively supplies the generated internal power to external power of another energy converter when the internal power is generated according to the surrounding energy source intensity; And
An external power node selectively receiving internal power generated from an internal power node of another energy converter;
Energy harvesting system using a plurality of ambient energy sources, characterized in that it comprises a. According to claim 1,
An energy harvesting system using multiple ambient energy sources, characterized in that the energy converter receiving internal power generated from an internal power node of another energy converter maintains an operation standby state. A core which is connected to a plurality of ambient energy sources, and which receives energy from the multiple ambient energy sources and converts it into electrical energy; And
A controller that controls the driving of the core and uses the generated internal power as an external power of another energy converter when the internal power is generated according to the intensity of the surrounding energy source;
Energy converter for energy of an energy harvesting system using a plurality of ambient energy sources comprising a. The method of claim 6,
An internal power supply node that selectively supplies the generated internal power to external power of another energy converter when the internal power is generated according to the surrounding energy source intensity; And
An external power node selectively receiving internal power generated from an internal power node of another energy converter;
Energy converter for energy of the energy harvesting system using a plurality of ambient energy sources further comprising a. The method of claim 7, wherein the controller,
An energy converter for energy in an energy harvesting system using multiple ambient energy sources, characterized by maintaining internal power standby by receiving internal power from another energy converter to the external power node.

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