CN111895553B

CN111895553B - Method for adjusting ambient temperature by utilizing photoelectric and thermoelectric conversion effect

Info

Publication number: CN111895553B
Application number: CN202010748765.9A
Authority: CN
Inventors: 娄朝刚; 李晓剑; 刘宗锴; 张程凯
Original assignee: Southeast University
Current assignee: DALIAN STANDARD ELECTROMECHANICAL EQUIPMENT Co.,Ltd.
Priority date: 2020-07-30
Filing date: 2020-07-30
Publication date: 2022-04-08
Anticipated expiration: 2040-07-30
Also published as: CN111895553A

Abstract

The invention relates to a method for regulating environmental temperature by utilizing photoelectric and thermoelectric conversion effect. The photovoltaic cell and/or the thermophotovoltaic cell form a light and/or heat energy absorption device, the photovoltaic cell absorbs indoor visible light and near infrared light, the thermophotovoltaic cell absorbs indoor heat radiation, and the photovoltaic cell and the thermophotovoltaic cell convert the radiation into electricity to achieve the purpose of adjusting the environment temperature. The method utilizes the photoelectric conversion property of the photovoltaic cell and the thermophotovoltaic cell, absorbs various light radiation and heat radiation in a room through a system formed by the photovoltaic cell and the thermophotovoltaic cell, reduces indoor heat, reduces the environmental temperature, and can convert the radiation into electricity. The thermophotovoltaic cell can also be used alone to absorb indoor heat radiation to reduce temperature and generate electricity. This method of adjusting the ambient temperature not only consumes no electric power but also generates electricity. The complex installation process of the traditional air conditioner is not needed, and the air conditioner is quiet and environment-friendly during operation.

Description

Method for adjusting ambient temperature by utilizing photoelectric and thermoelectric conversion effect

Technical Field

The invention relates to a system for adjusting environmental temperature by utilizing a photoelectric conversion effect, which utilizes a photovoltaic cell and a thermophotovoltaic cell to absorb indoor visible light and heat radiation, reduce indoor heat, reduce environmental temperature and simultaneously convert the light and the heat radiation into electric energy. The invention belongs to the field of crossing of a photovoltaic power generation technology and an air conditioning technology.

Background

In the traditional air conditioning technology, the refrigerant is driven by electric power to perform cyclic compression and evaporation processes to complete indoor and outdoor heat exchange, so that the indoor temperature is adjusted. In order to realize heat exchange, the whole air conditioning system needs to be divided into an indoor unit and an outdoor unit, wherein the indoor unit absorbs heat and then discharges the heat through the outdoor unit. In the heat exchange process, the air conditioner absorbs heat energy and discharges heat energy, and the form of the energy is kept unchanged.

There are several problems with this air conditioning technology: firstly, the use of refrigerant freon can destroy the atmospheric ozone layer and increase the ultraviolet rays incident to the ground; secondly, an outdoor unit is needed, holes need to be drilled on the wall of the house during installation, the indoor unit is communicated with the outdoor unit, complexity of the installation process is increased, and high danger exists particularly in installation and maintenance of an air conditioner of a high-rise building; thirdly, after years of use, the firmness of the air conditioner outdoor unit hung on the outer wall is reduced, and potential danger is formed; and fourthly, heat in the room is discharged to the outside, which causes the temperature of the external environment to rise, and particularly, the area near the outdoor unit is more affected.

Disclosure of Invention

The technical problem is as follows: the invention provides a method for adjusting the environmental temperature by utilizing photoelectric and thermoelectric conversion effects, the system is suitable for a room with higher temperature, the indoor temperature can be reduced without power consumption, and meanwhile, the absorbed energy can be utilized for power generation.

The technical scheme is as follows: in order to solve the technical problems, the invention provides a method for adjusting the environmental temperature by utilizing the photoelectric and thermoelectric conversion effect, a photovoltaic cell and/or a thermophotovoltaic cell form an optical and/or thermal energy absorption device, the photovoltaic cell absorbs indoor visible light and near infrared light, the thermophotovoltaic cell absorbs indoor thermal radiation, and the photovoltaic cell and the thermophotovoltaic cell convert the radiation into electricity, thereby achieving the purpose of adjusting the environmental temperature.

Wherein,

the photovoltaic cell or the thermophotovoltaic cell is a cell or a cell assembly, and electricity generated by the cell or the cell assembly is stored in a rechargeable battery or a capacitor or is directly sent to a power grid.

The thermophotovoltaic cell adopts a narrow-gap semiconductor with a gap width smaller than 0.3eV as an absorption layer.

The thermal photovoltaic cell comprises a heterojunction which is a pn junction, an nn junction or a pp junction, and the fermi level difference of two materials composing the heterojunction is more than 0.1 eV.

The thermal photovoltaic cell is composed of an absorption layer, an electron transport layer and a hole transport layer, wherein the Fermi level difference of the two transport layer materials is more than 0.1 eV.

The photovoltaic cell and the thermophotovoltaic cell are composed of Schottky junctions composed of narrow-gap semiconductor and metal electrodes.

Has the advantages that: the method for adjusting the environment temperature can reduce the indoor temperature without consuming electric power and can output electric power at the same time. All parts do not need to move, and the device is high in reliability and easy to maintain. No need of refrigerant, cleanness and environmental protection. The heat exchange is not needed indoors and outdoors, and the device can be placed indoors and is convenient to install and use. Compared with the traditional air conditioner, the air conditioner has great advantages.

The method is particularly suitable for rooms with heating devices, such as rooms for placing computer server clusters, boiler rooms for boiling water and other places with higher temperature. After the heat radiation of the indoor object is absorbed by the battery, the indoor heat is reduced, and the temperature is also reduced. The room temperature will tend to stabilize until the radiated heat reaches equilibrium with the reduced heat.

Detailed Description

The present invention will be further illustrated below with reference to specific embodiments, which are to be understood as merely illustrative and not limitative of the scope of the present invention.

The method for adjusting the environmental temperature can be realized by a photovoltaic cell and a thermophotovoltaic cell together, and can also be realized by the thermophotovoltaic cell alone. When in use, the photovoltaic cell and the thermophotovoltaic cell can be packaged into a cell component and connected with a rechargeable battery. The battery assembly absorbs indoor light radiation and heat radiation, reduces indoor heat to reduce temperature, converts the radiated energy into electricity, and charges the electricity into a rechargeable battery or sends the electricity into a power grid.

Wherein the photovoltaic cell adopts a photovoltaic cell which is commercialized; the thermophotovoltaic cell adopts a narrow bandgap semiconductor with the bandgap width less than 0.3eV as an absorption layer; the thermal photovoltaic cell comprises a heterojunction, the heterojunction can be a pn junction, an nn junction or a pp junction, and the Fermi level difference of two materials forming the heterojunction is more than 0.1 eV; the thermophotovoltaic cell can be composed of an absorption layer, an electron transport layer and a hole transport layer, wherein the Fermi level difference of the two transport layer materials is more than 0.1 eV; the photovoltaic cell and the thermophotovoltaic cell can be formed by a Schottky junction formed by a narrow forbidden band semiconductor and a metal electrode; the photovoltaic cell and the thermophotovoltaic cell can be made of organic materials or inorganic materials; the photovoltaic cell and the thermophotovoltaic cell can be cell sheets or cell components.

Example 1

1. 10 monocrystalline silicon photovoltaic cells are connected in series to be packaged into a component, and a rechargeable battery is connected;

2. 10 bismuth telluride/germanium thermophotovoltaic cells are connected in series to be packaged into a component which is connected with a rechargeable battery;

3. the two assemblies are arranged side by side, the monocrystalline silicon photovoltaic cell assembly absorbs visible light and near infrared radiation, the bismuth telluride/germanium thermophotovoltaic cell assembly absorbs thermal radiation, and generated electricity is charged into the rechargeable battery.

Example 2

1. 10 gallium arsenide photovoltaic cells are connected in series to be packaged into a component and connected with a rechargeable battery;

2. connecting 50 antimony telluride/silicon thermal photovoltaic cells in series to be packaged into a component, and connecting a rechargeable battery;

3. the two components are placed in front of each other, the monocrystalline silicon photovoltaic cell component is placed in front of the monocrystalline silicon photovoltaic cell component and absorbs visible light and near infrared radiation, the antimony telluride thermal photovoltaic cell component absorbs thermal radiation after the monocrystalline silicon photovoltaic cell component is placed in back of the monocrystalline silicon photovoltaic cell component and generates electricity which is charged into the rechargeable battery.

Example 3

1. 30 monocrystalline silicon photovoltaic cells are connected in series to be packaged into a component, and a rechargeable battery is connected;

2. 100 bismuth telluride/copper schottky thermophotovoltaic cells are connected in series to be connected with a rechargeable battery;

Example 4

1. Packaging 1 cadmium telluride thin film photovoltaic cell into an assembly in series;

2. connecting 20 bismuth telluride/copper Schottky thermophotovoltaic cells in series and packaging into a component;

3. placing the two modules side by side in a room and connecting the two modules in series to a rechargeable battery;

4. when the solar battery works, the monocrystalline silicon photovoltaic battery component absorbs visible light and near infrared radiation, the bismuth telluride/copper thermal photovoltaic battery component absorbs thermal radiation, and generated electricity is charged into the rechargeable battery.

Example 5

1. 20 amorphous silicon thin film photovoltaic cells are connected in series to be packaged into a component and connected with a rechargeable battery;

2. 20 bismuth telluride/germanium thermophotovoltaic cells are connected in series to be packaged into a component and connected with a rechargeable battery;

3. the two assemblies are arranged in a room side by side, the amorphous silicon thin film photovoltaic cell assembly absorbs visible light, the bismuth telluride/germanium thermophotovoltaic cell assembly absorbs heat radiation, and generated electricity is charged into the rechargeable battery.

Example 6

1. 100 bismuth telluride/copper Schottky thermophotovoltaic cells are connected in series to be packaged into a component;

2. the assembly is connected to a power grid through an AC-DC conversion device;

3. the assembly is placed in a room to absorb thermal radiation to reduce the ambient temperature.

Example 7

1. 20 organic thin-film photovoltaic cells are connected in parallel to be packaged into a component, and the component is connected with a rechargeable battery;

2. 80 bismuth telluride/copper schottky thermophotovoltaic cells are connected in series to be packaged into a component and connected with a rechargeable battery;

3. the two assemblies are placed in front of each other, the photovoltaic cell assembly is placed in front of the photovoltaic cell assembly and absorbs visible light and near infrared radiation, the antimony telluride thermal photovoltaic cell assembly absorbs heat radiation after the photovoltaic cell assembly is placed in back of the photovoltaic cell assembly, and generated electricity is charged into the rechargeable battery.

Claims

1. A method for regulating ambient temperature using photoelectric and thermoelectric conversion effects, comprising: the photovoltaic cell and the thermophotovoltaic cell form a light and heat energy absorption device, the photovoltaic cell absorbs indoor visible light and near infrared light, the thermophotovoltaic cell absorbs indoor heat radiation, and the photovoltaic cell and the thermophotovoltaic cell convert the radiation into electricity to achieve the purpose of adjusting the environmental temperature; the device is suitable for places with heating devices at higher temperature;

the photovoltaic cell or the thermophotovoltaic cell is a cell or a cell assembly, and electricity generated by the cell or the cell assembly is stored in a rechargeable battery or a capacitor or is directly sent to a power grid;

the thermophotovoltaic cell adopts a narrow bandgap semiconductor with the bandgap width less than 0.3eV as an absorption layer;

2. The method for regulating the ambient temperature using the photoelectric and thermoelectric conversion effect according to claim 1, wherein: the thermal photovoltaic cell is composed of an absorption layer, an electron transport layer and a hole transport layer, wherein the Fermi level difference of the two transport layer materials is more than 0.1 eV.

3. The method for regulating the ambient temperature using the photoelectric and thermoelectric conversion effect according to claim 1, wherein: the photovoltaic cell and the thermophotovoltaic cell are composed of Schottky junctions composed of narrow-gap semiconductor and metal electrodes.