KR200371801Y1 - Turbine driving device utilizing physical energy when vaporizing liquefied gas by natural heat or waste heat - Google Patents

Abstract

The present invention relates to a turbine drive device that produces energy by utilizing various heat generated from nature or waste heat generated from human life and production activities.

There is a difference in heat between objects that are exposed to solar heat, geothermal heat, hot spring water, snow, and cold cold in winter. In addition, the waste heat generated in the production process of various industrial products such as chimney exhaust gas, transformer heat dissipation, engine heat dissipation, cooling radiator heat dissipation, automobile exhaust gas, heating waste water, steel, glass and paper etc. Differences in heat also occur between objects that contact the back and objects that do not. By using this heat difference, the liquefied gas which is easily liquefied and vaporized according to the pressure at room temperature is used as a working fluid to generate the physical energy of the gas generated when the liquid is vaporized by high heat, and this energy is referred to as physical energy (Fan). Drive force) or a turbine that converts it into electricity.

Conventional ocean thermal power generation utilizes the temperature difference between surface water and deep sea water to compress liquefied gas in deep sea water with low temperature, make it liquid, vaporize the liquid by high temperature surface water, and turn turbine by the kinetic energy of this gas. It is a power generation method that produces electricity. However, since this method requires the extraction of deep sea water from distant oceans, it is problematic to be put into practical use due to location constraints and cost. The present invention proposes a turbine driving device that can obtain not only electricity but also physical energy similar to the principle of the generation of marine temperature difference by utilizing the difference in natural heat generated around people's living or waste heat generated from people's life and production activities. do.

Description

Turbine driving device utilizing physical energy when vaporizing liquefied gas by natural heat and waste heat {omitted}

Existing turbine operation methods include repeating the compression-explosion-expansion-compression process of flammable gas, or the method using steam. The method of using the physical energy generated when gas evaporates is ocean temperature difference generation. However, gas turbines and steam turbines not only require fuel, but also generate a lot of waste heat to recover circulating water. In addition, ocean temperature difference generation is still in the research stage because of the problem of having to collect deep sea water, causing location limitations and cost.

The phenomena that occur in the surroundings of the green are the difference in heat between objects exposed to solar heat, geothermal heat, hot spring water, snow, cold and cold air in winter and other objects, and also the chimneys of combustion devices such as steam and boiler recovered after power plant turbine operation. Differences in heat also occur between objects that come into contact with waste heat generated during the production of various industrial products, such as exhaust gas, transformer heat dissipation, engine heat dissipation, radiator heat for cooling, automobile exhaust gas, heating waste water, and steel, glass, and paper. These heats are rather harmful to people's intentions, and they are wasting additional energy by heating or cooling to remove them. These waste heats are partially recycled using heat cycles, but there is no way to convert them into physical or electrical energy when heat (cold heat, heat) is not needed.

In order to protect the natural environment and make the most efficient use of limited energy, it is necessary to devise a method of regenerating and using it instead of the existing method of discarding it in the natural state or consuming additional energy.

The present invention is the difference between the heat generated between the object in contact with natural phenomena and other objects or waste heat generated in various equipment or living environment (steam flue gas of the combustion device such as steam, boiler, etc. Easily liquefy according to pressure at room temperature by using the difference in heat between objects that come into contact with heat dissipation, radiator heat dissipation, automobile exhaust, heating wastewater, and waste heat generated in the production process of various industrial products such as steel, glass, and paper) And it implements a turbine drive device that can recover the physical energy of the gas generated in the process of converting the liquefied gas to the gas as physical energy or electrical energy. In addition, since most waste heat is harmful to the user's intention to generate waste heat, the dual effect should be achieved by recycling waste heat and adding cooling effect. In addition, the waste heat from the waste heat generating peripheral devices should be collected so that the liquid working fluid 13 can absorb a large amount of waste heat when the state changes from the evaporator 15 to the gas state, so that the waste heat utilization can be further increased.

1 is an explanatory diagram of a conventional ocean temperature differential power generation principle.

2 is an explanatory diagram of a turbine driving apparatus using natural heat and waste heat to which the present invention is applied.

3 is an explanatory view of a turbine driving apparatus for cooling a condenser with a cooling medium.

4 is an explanatory view of a turbine driving device for cooling a liquefied gas, a compressor, and a condenser with a cooling medium before compression.

5 is an explanatory diagram of a heat exchange method of a waste heat body, a condenser, a heat sink, and an evaporator.

<Explanation of symbols for two main figures in drawing>

11: compressor 12: condenser

13 liquid working fluid 14 expansion valve

15 evaporator 16 gaseous working fluid

17 turbine 18 generator

21: liquid working fluid storage tank 22: natural heat, waste heat

23: heat sink 24: motor (or engine)

25: generator (or mechanism) 31: cooling medium

Liquefied gases that easily change states with liquids and gases at room temperature include propane, butane, ammonia, carbon dioxide, CFC, HCFC, Freon 22 (HCF22), and hydrocarbons. Natural or waste heat is not high heat, so liquefied gas that easily changes state with liquid and gas at room temperature should be used as working fluid, and ammonia (NH ₃ ) or carbon dioxide (CO ₂ ) It is judged that it is preferable.

1 is a view for explaining the principle of the conventional ocean temperature difference generation. The principle is as follows. The working fluid is compressed by the compressor 11 in the gaseous state and the compressed gas is a liquid working fluid 13 which is deprived of heat from the condenser 12 to the low temperature deep water and this liquid flows along the tube to the sea surface layer. It is moved and flows into the liquid state inside the evaporator 15 through the expansion valve 14. This liquid expands while absorbing heat of surface water, which is a relatively high temperature, in the evaporator 15 to become a gaseous state. The gaseous working fluid 16 rotates the turbine 17 by the physical force retained, so that electrical energy is generated from the generator 18 attached to the turbine. The gaseous working fluid 16 which turned the turbine descends again, is sucked by the compressor 11, and is compressed, and repeats the process previously performed.

2 is a view illustrating a turbine driving apparatus using natural heat and waste heat to which the present invention according to the present invention is applied. The principle of operation is as follows. The working fluid is compressed by the compressor 11 in a gaseous state and the compressed gas is a liquid working fluid 13, which loses heat to the low temperature atmosphere in the condenser 12 and the liquid is operated in a liquid state along the tube. It is stored in the fluid storage tank 21 and the liquid working fluid 13 of this tank flows in the liquid state into the evaporator 15 through the expansion valve 14. The liquid working fluid storage tank 21 has been added as a shock absorber to allow the entire system to operate smoothly. This liquid uses heat of the heat sink 23 which discharges heat (including exhaust gas) generated from the condenser 12, the natural heat, the waste heat body 22, and the compressor running motor (or the engine), which are relatively higher than the atmosphere. It absorbs inside the evaporator 15 and expands into a gaseous state. At this time, the degree of heat exchange is adjusted in consideration of the amount of waste heat of the condenser 12, the waste heat body 22, and the heat sink 23, the scale of the evaporator 15, and the like. It is also within the scope of the present invention to adjust the structure to maximize the sum of the cooling effect. The gaseous working fluid 16 rotates the turbine 17 with the physical force retained, so that electrical or physical energy is generated in the generator (or mechanism) 25 attached to the turbine. The gaseous working fluid 16 which has turned the turbine is again sucked into the compressor 11 and compressed, thereby repeating the previous process. It is also included in the scope of the present invention to make a self-heating heat and waste heat body 22 that incorporates a large latent heat material in the solid container and the user vessel that absorbs solar heat to efficiently integrate the solar heat. If the natural heat / waste heat body 22 is lower than a certain place, the natural heat / waste heat body 22 and the condenser 12 will exchange heat, and the evaporator 15 may be placed at any place to reverse the heat cycle. By forming, it is possible to implement a turbine according to the present invention, which is also included in the scope of the present invention.

FIG. 3 adds a structure in which heat exchange occurs between the condenser 12 and the cooling medium 31 to liquefy gas at a low temperature in FIG. 2, and the principle is the same as that of FIG. 2.

4 is a view in which a pipe, a compressor, and a condenser 12 flowing into the compressor in FIG. 2 add a structure in which heat exchange occurs with the cooling medium 31 so that the working fluid can be compressed and liquefied at a low ambient temperature. Same as FIG.

FIG. 5 is a view for explaining a heat exchange method for effectively exchanging heat with the condenser 12, the natural heat and waste heat body 22, and the heat sink 23, which supply heat to the evaporator as described in FIG. 2. Internal condenser 12, natural heat / waste heat 22 and heat sink 23 penetrate inside the evaporator 15 to increase heat exchange effect, condenser 12 on the surface of evaporator 15, natural heat and waste heat. An external contact type in which the sieve 22 and the heat sink 23 are in contact with each other to achieve heat exchange, penetrates the condenser 12 inside the evaporator 15 to increase the heat exchange effect between the evaporator 15 and the condenser 12, And a mixed type in which the waste heat body 22 and the heat sink 23 come into contact with the surface of the evaporator 15 to regulate heat exchange. In the mixed type, the object passing the inside of the evaporator 15 may be a combination of the condenser 12, the natural heat / waste heat body 22, and the heat sink 23.

It is used to improve people's energy utilization and to remove waste heat that harms people by producing renewable energy by using natural heat and waste heat that are enormous but not very high temperature difference around environment. By preventing the waste of additional energy, it is expected to provide a breakthrough in the production of renewable energy.

Claims (3)

Liquefied gas working fluids 13 and 16 that easily change state with liquids and gases at room temperature, and compressors 11, condensers 12, expansion valves 14, and evaporators 15 forming a refrigeration cycle. A condenser 12 for exchanging heat with the evaporator 15, a natural heat / waste heat element 22, and a heat sink 23; The liquid working fluid 13 is installed between the condenser 12 and the expansion valve 14 and stores the liquid working fluid 13 generated in the condenser 12 in the evaporator 15 through the expansion valve 14. A liquid working fluid storage tank 21 for supplying; It is installed in the pipe between the evaporator 15 and the compressor 11, characterized in that the turbine (17) operating the generator (or mechanical device) 25 characterized by utilizing the physical energy during the vaporization of liquefied gas by natural heat and waste heat Turbine drive. The method of claim 1, wherein the cooling medium 31 is heat-exchanged with the condenser 12 in order to liquefy the gas at a low temperature. Turbine drive. The method according to claim 1, characterized in that a cooling medium (31) is formed in which heat is exchanged with the condenser (12) and the pipe between the turbine and the compressor (11) in order to liquefy the gas at a low temperature. Turbine drive device using physical energy when vaporizing liquefied gas.