WO2018119545A1 - Device for using atmospheric low-temperature source - Google Patents

Abstract

Provided is a device for using an atmospheric low-temperature source, belonging to the technical field of power generation. The device comprises a high-altitude heat exchanger, a low-altitude heat exchanger, and a descending airflow adiabatic conduit and an ascending airflow adiabatic conduit connecting the high-altitude heat exchanger and the low-altitude heat exchanger together, wherein the ambient temperature of the low-altitude heat exchanger is higher than that of the high-altitude heat exchanger, and a gas in the low-altitude heat exchanger is cooled after ascending to the high-altitude heat exchanger along the ascending airflow adiabatic conduit, and then descends to the low-altitude heat exchanger along the descending airflow adiabatic conduit, thus forming a circularly flowing airflow to drive a turbine to generate power. When an ambient temperature difference between the low-altitude heat exchanger and the high-altitude heat exchanger is not greater than an atmospheric convection temperature difference corresponding to an altitude difference therebetween, a falling temperature value of per mass unit of gas in the device when the per mass unit of gas adiabatically ascends per height unit in the ascending airflow adiabatic conduit is less than a falling temperature value of per mass unit of air when the per mass unit of air adiabatically ascends per height unit outside the ascending airflow adiabatic conduit at the same altitude.

Description

Utilization device of atmospheric low temperature source Technical field

The invention belongs to the technical field of power generation, and particularly relates to a device for utilizing an atmospheric low temperature source.

Background technique

In the troposphere, the air is heated up to generate a gas stream that can be used to propel the turbine to generate electricity.

According to the power generation law of the turbine, the higher the airflow speed, the higher the power generation and the lower the unit power cost. In this way, the use of high-speed airflow to generate electricity can reduce the cost of the turbine power generation system.

Solar chimney power generation is one of the simple structures that adapts to lower heat source temperatures. However, the efficiency is low, and the air contains a small amount of particulate pollutants, which reduces the life of the turbine and limits the flow rate of the airflow.

Summary of the invention

In view of the above technical problems, the present invention proposes an apparatus for utilizing an atmospheric low temperature source, including a high heat exchanger and a low heat exchanger, and a descending airflow connecting the high heat exchanger and the low heat exchanger together. Adiabatic duct and updraft adiabatic duct, the ambient temperature of the lower heat exchanger is higher than the ambient temperature of the high heat exchanger, and the gas in the lower heat exchanger rises along the rising air duct to the high heat exchanger The post-cooling descends along the downdraft adiabatic conduit to the lower heat exchanger, forming a circulating flow stream and propelling the turbine to generate electricity;

When the temperature difference between the environment where the low heat exchanger is located and the environment where the high heat exchanger is located is not more than the atmospheric convection temperature difference corresponding to the altitude difference between the two, the unit mass of the gas in the device is insulated in the ascending airflow adiabatic duct. The temperature value dropped after rising the unit height is lower than the temperature value of the unit mass air outside the rising airflow adiabatic duct at the same altitude after the adiabatic rise unit height; thus, energy can be obtained from the environment to push the turbine to work;

When the temperature difference between the environment where the low heat exchanger is located and the environment where the heat exchanger is located is higher than the altitude of both When the difference in atmospheric convection temperature corresponds to the difference, the temperature of the unit mass of gas in the device is increased by the adiabatic rise unit temperature in the ascending airflow adiabatic duct, and the temperature per unit mass of the air outside the rising airflow adiabatic duct at the same altitude is The temperature value dropped after the adiabatic rises the unit height; thus, when the internal gas is air, the amount of heat generated per unit of heat can be increased;

The installation position of the high heat exchanger is higher than the sea level;

If the installation position of the low heat exchanger is in seawater and there is no atmosphere around the low heat exchanger, the atmospheric temperature of the lower heat exchanger corresponding to the altitude is T ₀ -0.0065h, wherein T ₀ is Sea level atmospheric temperature, in degrees Celsius, h is the altitude value, in meters, where h is a negative value.

The elevation of the high heat exchanger is lower than the corresponding top of the atmospheric troposphere at its location.

A portion of the lower end of the downdraft adiabatic conduit is lower than the lower heat exchanger.

The descending airflow adiabatic duct and the updraft adiabatic duct, and the high-end heat exchanger adopts a balloon filled with any one of hydrogen gas or helium gas or two gas compositions as a filling to realize lift-off and high-altitude fixing.

The beneficial effects of the invention are:

By utilizing the natural conditions of the earth, the airflow can be generated without additional power source; the lower end of the downdraft adiabatic duct is lower than the low heat exchanger, which is beneficial to control the direction of the airflow; the low heat exchanger can also be used as the low temperature source.

When there is an additional heat source, the present invention can increase the amount of heat generation per unit of heat with respect to the circulating medium being air.

DRAWINGS

Figure 1 is a schematic view of a circulating gas flow generating device of the present invention.

detailed description

The embodiments are described in detail below with reference to the accompanying drawings.

Example 1

As shown in Figure 1, the apparatus includes a high heat exchanger and a low heat exchanger, and a downflow adiabatic duct and an updraft adiabatic duct connecting the high heat exchanger and the low heat exchanger, low Heat exchange The ambient temperature of the device is higher than the ambient temperature of the heat exchanger at the high point. The gas in the lower heat exchanger rises along the rising airflow adiabatic pipe to the high heat exchanger and then cools down to the lower part along the descending airflow adiabatic conduit. a heat exchanger that forms a circulating flow of gas and drives the turbine to generate electricity;

In this example, the gas in the device is hydrogen. Before the circulating airflow is formed, the air pressure in the lower heat exchanger is the same as the ambient air pressure. The low heat exchanger is located at the tropical sea. The high heat exchanger is located in the atmosphere at 1500 meters above the lower heat exchanger. This absorbs heat from the seawater and creates a circulating airflow that pushes the turbine to do work.

Example 2

As shown in Figure 1, the apparatus includes a high heat exchanger and a low heat exchanger, and a downflow adiabatic duct and an updraft adiabatic duct connecting the high heat exchanger and the low heat exchanger, low The ambient temperature of the heat exchanger is higher than the ambient temperature of the high heat exchanger, and the gas in the lower heat exchanger rises along the rising airflow adiabatic conduit to the high heat exchanger and then cools down along the descending airflow adiabatic conduit. To the low heat exchanger, a circulating flow of air is formed and the turbine is driven to generate electricity.

In this example, the gas in the device is helium, and the helium gas pressure in the lower heat exchanger is the same as the ambient pressure before the circulating gas flow is formed. The low heat exchanger is located in a solar greenhouse on the ground with a temperature of 200 degrees Celsius. The ambient temperature is 18 degrees Celsius. The high heat exchanger is located in the air 100 meters above the heat exchanger. The amount of heat generated per unit of heat can be increased by using air as the circulating medium.

The above embodiments are only preferred embodiments of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art can easily think of changes or replacements within the technical scope disclosed by the present invention. All should be covered by the scope of the present invention. Therefore, the scope of protection of the present invention should be determined by the scope of the claims.

Claims (4)

1. An apparatus for utilizing an atmospheric low temperature source, comprising: a high heat exchanger and a low heat exchanger, and a descending airflow adiabatic duct and an updraft connecting the high heat exchanger and the low heat exchanger Insulated conduit, the ambient temperature of the lower heat exchanger is higher than the ambient temperature of the high heat exchanger, and the gas in the lower heat exchanger rises along the rising airflow adiabatic duct to the high heat exchanger and then cools down. The airflow adiabatic conduit descends to the lower heat exchanger, forming a circulating flow stream and propelling the turbine to generate electricity;

   When the temperature difference between the environment where the low-end heat exchanger is located and the environment where the heat exchanger is located is not greater than the difference in the tropospheric temperature difference corresponding to the altitude difference between the two, the unit mass of gas in the device is insulated in the ascending airflow adiabatic duct. The temperature value dropped after rising the unit height is lower than the temperature value of the unit mass air outside the rising airflow adiabatic duct at the same altitude after the adiabatic rise unit height; thus, energy can be obtained from the environment to push the turbine to work;

   When the temperature difference between the environment where the low heat exchanger is located and the environment where the heat exchanger is located is greater than the difference of the tropospheric temperature difference corresponding to the altitude difference between the two, the unit mass of gas in the device rises adiabatically in the ascending airflow adiabatic duct. The temperature value dropped after the unit height is greater than the temperature value of the unit mass air outside the rising airflow adiabatic duct at the same altitude after the adiabatic rise unit height; thus, the unit heat can be increased when the internal gas is air. Power generation

   The installation position of the high heat exchanger is higher than the sea level;

   If the installation position of the low heat exchanger is in seawater and there is no atmosphere around the low heat exchanger, the atmospheric temperature of the lower heat exchanger corresponding to the altitude is T ₀ -0.0065h, wherein T ₀ is Sea level atmospheric temperature, in degrees Celsius, h is the altitude value, in meters, where h is a negative value.
2. The apparatus of claim 1 wherein said elevated heat exchanger has an altitude that is lower than a corresponding upper portion of the atmospheric troposphere at its location.
3. The device according to claim 1, wherein said lower end of said descending airflow adiabatic conduit Partially lower than the lower heat exchanger.
4. The device according to claim 1, wherein the descending airflow adiabatic conduit, the updraft adiabatic conduit, and the high heat exchanger employ a balloon filled with hydrogen or helium or a combination of two gas compositions. Realize the establishment and fixed at high altitude.

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