WO2016206444A1 - High-voltage thermoelectric power generation tube - Google Patents

Abstract

Provided is a high-voltage thermoelectric power generation tube, comprising an outer tube (220) and an inner tube (222) nested inside said outer tube (220), the outer tube (220) being in contact with a heat-generating medium and the inner tube (222) being provided with a cooling medium; a plurality of thermoelectric power generation components (224) are mounted between the inner tube (222) and the outer tube (220), the hot ends of the thermoelectric power generation components (224) being connected to the outer tube and the cold ends being connected to the inner tube; generating a temperature difference between the inner tube (222) and the outer tube (220) causes the thermoelectric power generation components to generate power. The high-voltage thermoelectric power generation tube makes ingenious use of the principle of thermoelectric power generation, and within the power generation tube, makes use of the large temperature difference between the inner tube (222) and the outer tube (220) to generate power. In combination with a cold fusion reaction device soaking in the heat-generating medium, the enormous heat generated by the cold fusion reaction is converted to electrical energy, thus seawater is used to generate power.

Description

High pressure temperature difference power generation tube Technical field

The invention relates to a power generating device, in particular to a high-pressure temperature difference power generating tube.

Background technique

The development and innovation of energy is a worldwide problem. At present, the energy that has been developed and utilized by people is oil, coal, ore, solar energy, water power, wind power, etc. The main applications are deep-seated resources such as oil and coal. At the end of the day, and the burning and use of hundreds of years, it also brought a lot of waste gas pollution to the whole earth, and brought more environmental pollution to the natural world while utilizing the resources of nature.

It is scientifically discovered that the sun is a star that continuously undergoes a thermonuclear reaction. It relies on the uninterrupted generation of a nuclear reaction by helium atoms, which generates a large amount of light and heat, which is sent to the stars of the solar system. At the same time, it carries a large number of solar winds. The helium atom forms cosmic dust and is emitted to the universe. Helium atom is a kind of high-energy particle hydrogen isotope. It is the best fuel for nuclear fusion. Most of the helium atoms brought by the solar wind to the earth are scattered on the sea. After hundreds of millions of years of accumulation, The stock of strontium atoms/ions in the ocean is already huge. How to use marine resources and find environmentally friendly energy is a major issue for scientists all over the world.

Through years of experimental research, the applicant has found that a large amount of thermal energy released by extracting a liquid fuel from seawater and exciting a fusion reaction by enriching helium atoms in the liquid fuel can be utilized for power generation. However, the heat generated by the cold fusion reaction tends to generate heat up to 500 degrees or higher. Some existing thermoelectric power generation devices are mostly used in environments below 100 degrees, and are not suitable for the use environment of cold fusion reaction power generation.

Therefore, the prior art needs to be further improved.

Summary of the invention

It is an object of the present invention to provide a high-pressure temperature difference power generation tube capable of converting heat generated by a cold fusion reaction into electrical energy.

To achieve the above object, the present invention adopts the following technical solutions:

A high-pressure temperature difference power generation tube includes an outer tube and an inner tube nested inside the outer tube, the outer tube is in contact with a heating medium, and the inner tube is provided with a cooling medium; the inner tube and the outer tube are installed There are a plurality of thermoelectric power generation components, the hot end of the thermoelectric power generation component is connected to the outer pipe, and the cold end is connected to the inner pipe; the temperature difference generated between the inner pipe and the outer pipe causes the thermoelectric power generation component to generate electricity.

Further, the outer tube is a high temperature alloy tube, and the inner tube is a heat conductive metal tube.

Further, the outer tube is an aluminum alloy tube, and the inner tube is a copper tube.

Further, the thermoelectric power generation elements are evenly arranged along the axial direction and the circumferential direction of the inner tube, and the thermoelectric power generation elements are connected in series, in parallel, or in series and in parallel.

Further, the heat generating medium is a liquid metal.

Further, the liquid metal is a mercury tin-lead alloy or a tin-bismuth alloy.

Further, the cooling medium is cooling water.

Further, the inner tube is connected to a cooling water circulation device, one end of which is connected to the output end of the cooling water circulation device, and the other end of the inner tube is connected to the recovery end of the cooling water circulation device.

Further, the thermoelectric power generation component leads one or more common power output terminals by series, parallel or serial and parallel mixing, and the power output terminal is connected to a power generating device.

Further, the power generating device includes a power generation control device and a power storage device electrically connected to each other, and the power generation control device is electrically connected to the thermoelectric power generation component for filtering and controlling a current output by the thermoelectric power generation component to obtain a high voltage stable DC current. The storage device is a capacitive high-voltage DC storage device.

The invention provides a high-pressure temperature difference power generation tube, which utilizes the principle of temperature difference power generation skillfully, and utilizes a large temperature difference between the inner tube and the outer tube to generate electricity in the power generation tube. The combination of the cold fusion reaction device and the immersion in the heating medium can convert the huge heat generated by the cold fusion reaction into electrical energy, so that the great idea of using seawater to generate electricity can be realized, and has great development prospects.

DRAWINGS

1 is a cross-sectional view of a high-pressure temperature difference power generation tube according to an embodiment of the present invention.

detailed description

The technical solutions of the present invention will be described in detail below with reference to the accompanying drawings and specific embodiments.

Scientists have discovered through experiments that seawater is rich in helium atoms, which in turn can be used as a raw material for nuclear reactions. The seawater concentrate is extracted from seawater by reverse osmosis technology, and the fresh water and impurities are filtered out. When the total amount of dissolved solids (TDS value) in the seawater concentrate is equal to or greater than 30,000 mg/liter, the obtained seawater is concentrated. The liquid can be used as a liquid fuel. That is, the concentration of cerium ions contained in a certain amount of seawater concentrate reaches a certain value, and a cold fusion reaction can be generated under a specific condition to generate a large amount of energy.

Although it can be found that seawater is rich in helium atoms and can be used as a liquid fuel, how to truly convert it into energy is also a major problem for contemporary scientists to explore. In order to enable the liquid fuel obtained by seawater extraction to undergo reaction conversion, the atomized seawater can be converted into heat energy by using a cold fusion reaction device; however, how to convert the converted heat energy into electrical energy further becomes New research topics.

As shown in FIG. 1, in order to solve the above problems, the present invention provides a high-pressure temperature difference power generation tube. The high-pressure temperature difference power generation tube includes an outer tube 220 and an inner tube 222 nested and installed in the outer tube 220. The outer tube 220 is in contact with a heat-generating medium, and the inner tube 222 is provided with a cooling medium; the inner tube 222 A plurality of thermoelectric power generation elements 224 are mounted between the outer tube 220 and the outer tube 220. The hot end of the thermoelectric power generation element 224 is connected to the outer tube 220, and the cold end is connected to the inner tube 222. The temperature difference between the inner tube 222 and the outer tube 220 is The thermoelectric power generation element 224 is caused to generate electricity and be transmitted to an external power generating device.

Since the high-pressure thermoelectric power generation tube of the present invention is mainly used in combination with a cold fusion reaction device, in order to prevent the large heat generated by the cold fusion reaction of the outer tube 220 from melting, in the present embodiment, the heat-generating medium is a liquid metal such as mercury tin-lead alloy or Tin-bismuth alloy; the outer tube 220 is selected from a high-temperature alloy tube, specifically an aluminum alloy tube. The liquid metal has a high melting point and high heat transfer efficiency, and the heat released in the cold fusion reaction device heats the liquid metal to rapidly heat up and transfer the heat to the outer tube 220 of the high-pressure temperature difference power generation tube. Mercury tin-lead alloy or tin-bismuth alloy has a melting point of 200-300 degrees Celsius, which can conduct heat quickly and does not react with aluminum alloy tubes. The aluminum alloy tube immersed in liquid metal can reach a temperature of 400-500 degrees Celsius.

Further, the cooling medium is cooling water, and is mainly used to lower the temperature of the inner tube 222. In order to ensure good thermal conductivity, the inner tube 222 is a heat conductive metal tube, specifically a copper tube. The inner tube 222 is connected to a cooling water circulation device, one end of the inner tube 222 is connected to the output end of the cooling water circulation device, and the other end of the inner tube 222 is connected to the recovery end of the cooling water circulation device. The cooling water circulation device is configured to continuously pass cooling water into the inner pipe and recover it for circulating refrigeration to ensure that the temperature of the inner pipe is below 100 degrees Celsius.

Preferably, the thermoelectric power generation elements 224 are evenly arranged along the axial direction and the circumferential direction of the inner tube 222, and all of the thermoelectric power generation elements 224 are connected in series, parallel or serially and in parallel to one or more common power output terminals, the power supply. The output is connected to a power generating device to store or output electrical energy.

When the high-pressure temperature difference power generation tube provided by the invention works, it is immersed in the heat-generating medium together with the cold fusion reaction device, and the cold fusion reaction occurring in the cold fusion reaction device generates a large amount of heat, and is transmitted to the high-pressure temperature difference power generation tube through the heat-generating medium. The tube 220 is such that the temperature of the outer tube 220 reaches 400-500 degrees Celsius; while the cooling water in the inner tube 222 is continuously circulated to keep the temperature of the inner tube 222 below 100 degrees Celsius. The large temperature difference between the inner tube 222 and the outer tube 220 causes the thermoelectric power generation element 224 to generate electrical energy. To increase the electric quantity, a plurality of thermoelectric power generation elements 224 can be embedded side by side between the outer tube 220 and the inner tube 222, through parallel or series connection. A direct current of about 500 volts and a current of about 10 amps is obtained, that is, high voltage direct current is obtained.

The power generating device further includes a power generation control device and a power storage device electrically connected to each other, and the power generation control device is electrically connected to the thermoelectric power generation element 224, and the current output from the thermoelectric power generation element 224 is filtered and controlled by the power generation control device and the power storage device to Obtain high voltage and stabilize DC current. The power generation control device can be electrically connected to a plurality of high-voltage temperature difference power generation tubes respectively, respectively controlling the magnitude and voltage of the current output by each of the high-pressure temperature difference power generation tubes, so as to summarize the currents outputted by the respective high-pressure temperature difference power generation tubes and transmit the currents. Store to the storage device. The accumulator can be a capacitive high voltage DC accumulator.

The invention provides a high-pressure temperature difference power generation tube, which utilizes the principle of temperature difference power generation skillfully, and utilizes a large temperature difference between the inner tube and the outer tube to generate electricity in the power generation tube. The combination of the cold fusion reaction device and the immersion in the heating medium can convert the huge heat generated by the cold fusion reaction into electrical energy, so that the great idea of using seawater to generate electricity can be realized, and has great development prospects.

Claims (10)

1. A high-pressure temperature difference power generation tube, comprising: an outer tube and an inner tube nested inside the outer tube, the outer tube being in contact with a heat generating medium, wherein the inner tube is provided with a cooling medium; the inner tube and the outer tube A plurality of thermoelectric power generation components are installed between the tubes, the hot end of the thermoelectric power generation component is connected to the outer tube, and the cold end is connected to the inner tube; the temperature difference generated between the inner tube and the outer tube causes the thermoelectric power generation element to generate electricity.
2. The high-pressure temperature difference power generation tube according to claim 1, wherein the outer tube is a high-temperature alloy tube, and the inner tube is a heat-conductive metal tube.
3. The high-pressure temperature difference power generation tube according to claim 2, wherein the outer tube is an aluminum alloy tube, and the inner tube is a copper tube.
4. The high-pressure temperature difference power generation tube according to claim 1, wherein the thermoelectric power generation elements are uniformly arranged in the axial direction and the circumferential direction of the inner tube, and the thermoelectric power generation elements are connected in series, in parallel, or in series and in parallel.
5. The high-pressure temperature difference power generation tube according to claim 1, wherein the heat generating medium is a liquid metal.
6. The high-pressure temperature difference power generation tube according to claim 5, wherein the liquid metal is a mercury tin-lead alloy or a tin-bismuth alloy.
7. The high-pressure temperature difference power generation tube according to claim 1, wherein the cooling medium is cooling water.
8. The high-pressure temperature difference power generation tube according to claim 7, wherein the inner tube is connected to a cooling water circulation device, one end of the inner tube is connected to an output end of the cooling water circulation device, and the other end of the inner tube is connected to the cooling water circulation device. The recycling end is connected.
9. The high-pressure temperature difference power generation tube according to claim 1, wherein the thermoelectric power generation element leads one or more common power output terminals by series, parallel or serial-parallel mixing, the power output terminal and a power generating device. connection.
10. The high-pressure temperature difference power generation tube according to claim 9, wherein the power generation device includes a power generation control device and an electric storage device electrically connected to each other, and the power generation control device is electrically connected to the thermoelectric power generation element for the thermoelectric power generation element. The output current is filtered and controlled to obtain a high voltage stable DC current; the storage device is a capacitive high voltage DC storage device.

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