TWM646133U - Bubble heat conduction device - Google Patents

Abstract

The invention is a bubble heat conduction device, which includes a body. The bottom area of the body is provided with guide rods extending downward. The inner bottom surface of the body is detoured with air pipes, and the air pipes are connected to a For the above fine network tube, the outer end of the air pipe is connected to an air inlet, and the top of the body is provided with an air outlet.

The heat source received by the main body of this creation is conducted through the guide rod at the bottom into the interior of the main body, thereby heating the liquid. Therefore, the heating source is located at the bottom of the main body, and the heat is conducted upward from the bottom, whether it is liquid or compressed air. It has fast heating speed and good efficiency, and can provide sufficient high-pressure and high-temperature compressed air to perform work.

Description

Bubble heat transfer device

This creation is about a device that uses high-temperature liquid to heat air, especially a device that uses heat conduction to heat the liquid. The high-temperature heated air from the liquid is input into the liquid to form bubbles that are quickly heated to form thermally expanded gas, which can then drive a turbine or steam engine. Institutions perform work.

Heat exchangers that generate heat exchange between air and hot water are commonly known. For example, the applicant's application No. 096212333 "Bubble Heat Exchanger", please refer to the bubble heat exchanger 1 shown in Figure 5, which mainly includes a heat exchanger. The main body 10 is filled with liquid at the water level, and an internal pipe 11 for return connection is arranged at the upper top of the main body 10. An air pipe is arranged at the inner bottom of the main body 10. Road 20 flows into the inner pipe 11 from the fluid inlet 111 and is high-temperature steam, which can be high-temperature waste heat discharged from a boiler or turbine. It exchanges heat with the liquid in the body 10 and then cools down to a low-temperature liquid and is discharged from the fluid outlet 112. .

The liquid in the body 10 becomes a high-temperature liquid after heat exchange. The compressed air generated by the air generator 40 is injected into the air inlet 22 and fills the inside of the air pipe 20. The compressed air emerges through the fine mesh pipe 21 and fills it. The entire body 10 floats upward. The bubbles 50 are surrounded by the liquid and generate heat conduction exchange. The bubbles 50 gradually rise upward from the bottom and absorb the heat of the liquid. The bubbles 50 gradually expand to form a larger shape. Large hot bubble 50, formed after leaving the liquid surface The hot air is discharged from the air outlet 23.

The discharged hot air can be properly collected and reused. Because the temperature and pressure of the air are increased, it can be introduced into the cylinder to push the piston to perform work. The energy can be reused, or for indoor heating in winter, or even for the hot air. It is introduced into the boiler combustion chamber as a heating function to achieve energy saving.

Using the bubble type heat exchanger applied by the applicant, the heat source and the internal pipelines arranged in the circuit are located above the inside of the body. The heat source is arranged at the top and rises according to the change of heat density. The temperature of the liquid filled inside the body will be higher than the bottom, and the bubbles will gradually rise upward from the bottom and absorb the heat of the liquid. The temperature difference between the top and the bottom of the liquid will be more obvious.

The bubble heat conduction device of this invention includes a body. The bottom area of the body is provided with guide rods extending downward. Air pipes are arranged in a circuitous way on the bottom surface of the body. The air pipes are connected to more than one fine air pipe. Network pipe, the outer end of the air pipeline is connected to an air inlet, and the top of the body is provided with an air outlet.

The heat source received by the main body of this creation is conducted by the guide rod into the interior of the main body, thereby heating the liquid. Therefore, the heating source is located at the bottom of the main body, and the heat is conducted upward from the bottom, which is in line with the laws of nature, whether it is liquid or compressed The air is heated quickly and efficiently, and can provide sufficient high-pressure and high-temperature compressed air to perform work.

1: Bubble heat transfer device

10:Ontology

11: Guide rod

12:Air outlet

20:Air pipe

21:Network management

22:Air inlet

30:Liquid supply system

31:Water level detector

32:Supply pipeline

40: Geothermal pool

50:Liquid

60: Bubbles

71: Boiler

72:Chimney

73:Waste heat conversion pool

[Figure 1] A three-dimensional view of this creation

〔Figure 2〕Schematic diagram of the plane combination of this creation

[Figure 3] is an embodiment of this creation installed in a geothermal pool.

[Figure 4] is an embodiment of the invention installed in a boiler and chimney combination

[Figure 5] is a schematic diagram of the plan combination of Xi Zhi Application No. 096212333

Please refer to Figures 1 and 2. The bubble heat conduction device 1 of the present invention mainly includes a body 10. The bottom area of the body 10 is provided with a downwardly extending guide rod 11. The length of the guide rod 11 can be determined according to the application. Depending on the location, an air pipe 20 is arranged on the inner bottom surface of the main body 10 in a roundabout way. The air pipe 20 is connected to more than one fine mesh pipe 21. The outer end of the air pipe 20 is connected to an air inlet 22. The main body 10 An air outlet 12 is provided at the top.

The main body 10 is provided with a liquid supply system 30, which includes a water level detector 31 located inside the main body 10 and a supply pipeline 32. One end of the supply pipeline 32 is connected to the main body 10, and the other end is connected to a liquid source. Liquids must be replenished or replaced at any time50.

Please refer to Figure 3. This invention uses geothermal conduction as an example. The bubble heat conduction device of this invention is located above a geothermal pool 40. The water temperature of the geothermal pool 40 is 95 degrees Celsius. The body 10 faces The downwardly extending guide rod 11 is deeply inserted into the geothermal pool 40 to exchange heat with the high-temperature pool water and conduct heat into the body 10 along the guide rod 11. Liquid 50 is injected into the body 10, and the liquid 50 is Water, the height of the liquid 50 is higher than the air pipe 20, and the high temperature of the geothermal pool 40 is conducted into the bottom of the body 10, and the liquid inside the body 10 is heated to above 85 degrees, so that it can be carried out Heat conduction through bubbles.

Please refer to Figure 3. Compressed air enters from the air inlet 22 outside the air pipe 20. The compressed air emerges through the fine mesh tube 21 and becomes fine bubbles 60. It floats upward and leaves the liquid, and fills the entire body 10 . The bubbles 60 break away from the liquid surface and form hot air, which is discharged from the air outlet 12 provided at the top of the body 10 .

The air outlet 12 provided at the top of the body 10 discharges high-temperature and high-pressure compressed air. Since the temperature and pressure of the air are increased, it can be introduced into the cylinder to push the piston to perform work, or to perform indoor heating function in winter, or even to Hot air is introduced into the boiler combustion chamber for heating function to achieve energy saving.

In addition to being applied to the geothermal pool 40 to capture geothermal heat, this invention can also be applied to environments with different high-temperature emissions, such as the chimney of a boiler. Please refer to Figure 4. A waste heat conversion pool 73 is provided between the boiler 71 and the chimney 72. The waste heat steam or high-temperature air generated after the combustion of 71 passes through the waste heat conversion pool 73 and is then discharged into the environment from the chimney 72. The bubble heat transfer device 1 of this invention is set on the waste heat conversion pool 73, and the guide rod 11 extending downward from the body 10 is placed deeply. Entering the waste heat conversion pool 73, it exchanges heat with the high-temperature steam in the pool, conducts heat to the heating liquid 50 inside the body 10, and the high-temperature liquid 50 then combines with the bubbles generated by the compressed air discharged from the inside of the body 10 and the network pipe 21 Through heat exchange, the high-temperature and high-pressure compressed air can be used for work. In addition, part of the carbon dioxide contained in the compressed air will be dissolved in the high-temperature liquid 50 to capture the carbon dioxide and follow the liquid 50.

From the foregoing description, it can be known that the heat source received by the main body 10 of the present invention is the high-temperature pool water of the geothermal pool 40 or the high-temperature steam of the boiler 71. The heat is conducted into the interior of the main body 10 through the guide rod 11, thereby heating the liquid 50, thus heating. The source is located at the bottom of the body 10, and heat is conducted upward from the bottom, which is in line with the laws of nature. Whether it is liquid 50 or compressed air, the heating speed is fast and efficient, and it can provide a sufficient amount of high-pressure and high-temperature compressed air to perform work and improve The lack of conventional technology is deeply innovative and practical.

1: Bubble heat transfer device

10:Ontology

11: Guide rod

12:Air outlet

20:Air pipe

21:Network management

22:Air inlet

30:Liquid supply system

31:Water level detector

32:Supply pipeline

Claims (1)

A bubble heat conduction device, including a body, the bottom area of the body is provided with guide rods extending downwards, air pipes are arranged in a circuitous way on the bottom surface of the body, and the air pipes are connected to more than one fine mesh tube , the outer end of the air pipe is connected to an air inlet, and the top of the body is provided with an air outlet.

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