KR101503736B1 - Atmosphere heat exchange system and atmosphere heat exchange system using thermal exchange method - Google Patents

Abstract

The present invention relates to an atmospheric heat exchange system and a heat exchange method using the same. The atmospheric heat exchange system of the present invention comprises a floating unit which is equipped to be located in the atmosphere; multiple heat exchange objects which performs heat-exchanging in the atmosphere by being connected to the floating unit; a lifting device which lifts up the heat exchanging objects; and a control unit which controls the operation of the lifting device. According to the present invention, the atmospheric heat exchange system has a simple structure and a heat exchange medium, such as water, is put in a container when cooling is needed and lifted up in the atmosphere. Then the heat-exchange medium, such as water or ice, which is heat-exchanged with the surrounding atmosphere at a lower temperature in the atmosphere, can be moved to the ground. Also, according to the present invention, the floating unit can be supported by a wire without a supporting tower, so a supporting tower does not need to be installed to support a pulley. The medium can be heat-exchanged at any height because a supporting tower is not needed. Also, the atmospheric heat exchange system can be constructed more easily than when the system needs a supporting tower.

Description

TECHNICAL FIELD [0001] The present invention relates to an atmospheric heat exchange system and a heat exchange method using the atmospheric heat exchange system.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an atmospheric heat exchange system and a heat exchange method using the same, and more particularly, to an atmospheric heat exchange system using a temperature difference between a surface and an atmosphere, To an atmospheric heat exchange system and a heat exchange method using the same.

Generally, fossil fuels are used for cooling and refrigeration, or electric energy produced by using fossil fuel or atomic power is used. However, the fossil fuel system is not suitable for polluting the environment due to various pollutants including carbon dioxide . These fossil fuel resources are limited in quantity, and alternative energy technologies are being actively developed to overcome them. These alternative energy technologies include wind, solar, and solar technologies. Although cooling and refrigeration are performed using the electric power produced by these alternative energy sources, there is a problem that the efficiency of energy conversion from alternative electric energy, electric power to cooling and refrigeration is low, which causes a great cost for cooling and refrigeration.

There is an eye cooling and refrigeration technology in connection with more direct heat exchange. In the case of the above-described technique, it is possible to store snow collected in the vicinity of a place where cooling and refrigeration are performed naturally in winter. However, in the case of the above-mentioned technique, the snow contains all kinds of dirt, which causes the snow pool to be cleaned after the snow has melted, and there are various environmental problems such as the melted water and contaminated materials I have. In order to prevent this problem from occurring, you should transport uncontaminated eyes from a distance. However, carrying large amounts of uncontaminated snow causes problems that require another large transport energy, not energy savings.

As a technical form for solving such a problem, there is a technology such as Japanese Patent Application Laid-Open No. 2010-121854 (June 3, 2010, hereinafter referred to as "prior art"). As shown in FIG. 1, the prior art described above relates to a technique of using artificially created snow instead of natural snow in winter for cooling or refrigeration. In order to use it for cooling and refrigeration, It does not need to be stored, and artificial eyes made of purified water purified in an eye reservoir are specifically disclosed to enable the environment-friendly cooling and refrigeration.

In the case of the above-described conventional art, although environmentally friendly technical effects can be obtained by using the artificial snow, energy consumption for making forced artificial eyes by the purified water in the cooling and cooling chambers, etc., This has a problem.

JP 2010-121854A

An object of the present invention is to solve the problems of the prior art as described above. It is an object of the present invention to provide a heat exchange medium such as water at a time when cooling or the like is required through a simple structure, The present invention provides an atmospheric heat exchange system and a heat exchange method using the atmospheric heat exchange system, wherein heat exchange media such as water or ice exchanged with heat by exchanging heat with the surrounding atmosphere can be transported to the ground.

It is another object of the present invention to provide an atmospheric heat exchange system in which a support tower is not required to support a lift device and a height of a heat exchange can be freely adjusted because there is no support tower, .

According to an aspect of the present invention, there is provided a vacuum cleaner comprising: a float arranged to stay in an atmosphere; A plurality of heat exchange objects connected to the float to cause heat exchange in the atmosphere; A lifting device for lifting and lowering the heat exchange object; And a control unit for controlling the operation of the lift device.

Further, in the float in the present invention, a gas discharger may be provided to adjust the degree of discharge of the internal gas.

Also, in the present invention, a floating height adjusting device may be provided to control the floating height of the floating fluid through the controller.

In addition, in the present invention, the floating height adjusting device may further include: a fixing fluidic wire connected to limit a floating height of the floating fluid; And a sub fluid power source provided at an end of the fixed fluid wire to provide power to wind or unwind the fixed fluid wire.

Further, in the present invention, the lifting device includes a wire movably connected to the float; And a power source provided at both ends of the wire to provide power to lift and lower the heat exchange object connected to the wire while winding or unwinding the wire through the control of the controller.

In addition, the heat exchange object in the present invention may be arranged so that the positions of one side and the other side are opposite to each other.

The heat exchanging object of the present invention is characterized in that the masses of one side and the other side are similar or identical.

In addition, the heat exchange object of the present invention includes a container in which a heat exchange medium is contained, and can exchange heat with surrounding air at a low temperature of the atmosphere.

In addition, the container of the heat exchange object in the present invention may be formed of a metal material having a high thermal conductivity.

Further, the container in the present invention can connect a plurality of small containers to the wire in a line.

In addition, the control unit of the present invention can control the heat exchange efficiency through the height of the heat exchange object on the ground and the residence time in the atmosphere.

In addition, the present invention may further include a meter connected to the float to measure the state of the atmosphere.

Further, in the present invention, a light emitting body may be provided on the float, the fixing fluid wire for fixing the heat exchange object, the float height adjusting device, and the wire of the lift device.

The present invention relates to a method for flooding a float; Injecting a heat exchange medium into one side heat exchange object after floating the float; A step of raising the one-side heat exchanging object into which the heat exchanging medium has been injected upward over the atmosphere; Injecting a heat exchange medium into the other one of the lower heat exchange bodies as the one heat exchange object rises; Exchanging the heat of the one side heat exchange object with ambient air at a low temperature over the atmosphere; A step of lowering the one heat exchange object to collect the heat exchange medium having the heat exchanged therein, and a step of fixing the one-side heat exchange object lowered to the ground to the ground structure and collecting the heat exchange medium, heat exchange using the atmospheric heat exchange system ≪ / RTI >

In addition, according to the present invention, the step of raising the other heat exchanging object to above the atmosphere as the one heat exchanging object descends; Exchanging the heat of the other heat exchange object with ambient air at a lower temperature of the atmosphere; Lowering the other heat exchanging object to collect the heat exchanged medium having the heat exchanged therein, and fixing the other heat exchanging object lowered to the ground to the ground structure and collecting the heat exchanging medium.

According to the present invention, a heat exchange medium such as water is placed in a single container at a point of time when cooling or the like is required through a simple structure, and the heat exchanged with the surrounding atmosphere at a low temperature of the atmosphere over the atmosphere, It is possible to increase the efficiency of energy consumption in transportation of the heat exchanging medium and to increase the efficiency of the maintenance and maintenance of the heat exchanging medium To obtain a technical effect.

In addition, according to the present invention, since the float is supported on the ground by the wire without the support tower, it is not necessary to install the support tower supporting the platform, and the support tower can be freely adjusted, Technical effects such as losing can be expected.

1 is an external perspective view schematically showing an embodiment of a cooling and refrigerating apparatus using artificial snow in the prior art.
2 is a schematic view showing an atmospheric heat exchange system according to the present invention.
FIG. 3 is a side view showing a remaining part of the atmospheric heat exchange system according to the present invention, except for a lift device.
4 is an operational state diagram of an atmospheric heat exchange system according to the present invention.
5 is a block diagram illustrating a heat exchange method using an atmospheric heat exchange system according to the present invention.

The terms or words used in the present specification and claims are intended to mean that the inventive concept of the present invention is in accordance with the technical idea of the present invention based on the principle that the inventor can appropriately define the concept of the term in order to explain its invention in the best way Should be interpreted as a concept.

Throughout the specification, when an element is referred to as "comprising ", it means that it can include other elements as well, without excluding other elements unless specifically stated otherwise. Also, the term " part "in the description means a unit for processing at least one function or operation, which may be implemented by hardware or software or a combination of hardware and software.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, the structure of an embodiment of an atmospheric heat exchange system and a heat exchange method using the same according to the present invention will be described in detail with reference to the drawings.

FIG. 2 is a schematic view of the atmospheric heat exchange system of the present invention. FIG. 3 is a side view of the atmospheric heat exchange system of the present invention, Respectively.

According to these drawings, the atmospheric heat exchange system of the present invention comprises a float 11, a float meter 12, a lifting device 20, heat exchange objects 31 and 32 for switching a heat exchange medium into an available state, 40 and a floating height adjustment device.

2 is provided with left and right heat exchange objects on one side 31 and the other side 32 and the wires of the elevation device 20 of FIG. A plurality of wires provided up to the three wires 21a, 21b and 21c are used as the lifting device power source provided for the one heat exchanging object 31 of FIG. 2 for the sake of convenience as the elevating device first power source 23a, The elevating device power source provided in the elevating device 32 will be referred to as the elevating device second power source 23b. The lifting device first wire 21a is provided between the one heat exchange object 31 and the elevation device first power source 23a and the one provided between the one heat exchange object 31 and the other heat exchange object 32, The second wire 21b is provided between the second heat exchanging object 32 and the second power source 23b of the elevating device. The third wire 21c is referred to as the elevating device third wire 21c. The pulley of the elevating apparatus 20 is a plurality of pulleys provided up to the first to fourth pulleys 22a, 22b, 22c and 22d and the pulley of the elevating apparatus first wire 21a, The elevator 23b and the third pulley 23c and the third elevator wire 21c provided on the first elevator 22a and the elevator second wire 21b are provided on the elevating device 4 And is referred to as a pulley 23d. The wire of the float 11 shown in FIG. 2 is a plurality of wires provided from the first wire 13a to the second wire 13b. Hereinafter, 13a on the right side and the float second wire 13b on the right side.

The float 11 is filled with an organism and stays in the air above the atmosphere. The float height adjusting device, which will be described later, is arranged to stably stay above the atmosphere, And connected with the fluid second wire 13b to be fixed on the ground. At this time, the float 11 is provided with a gas discharger (not shown) for controlling the degree of discharge of the internal gas through the control of the controller 40 to descend to the ground.

The floatmeter 12 is installed at the lower end of the float 11 to measure a weather condition such as a temperature above the atmosphere, a temperature above the atmosphere, wind intensity, and the like.

The heat exchange objects 31 and 32 are connected to the float 11 to exchange heat in the atmosphere specified by the position of the float 11, On the other hand, one heat exchange object 31 and one heat exchange object 32 are provided on both sides, but one or more heat exchange objects 31, 32 may be provided in the front, rear, left, and right sides.

Although not shown in the drawing, the heat exchange object 31 and 32 are provided with a container containing a heat exchange medium such as water, and the container may be formed of a metal material having a high thermal conductivity. Alternatively, a plurality of small containers may be connected in series through wires to implement a heat exchange object vessel. That is, a plurality of small vessels are connected in series by wires to reduce the heat exchange time, and there is a technical advantage that the heat exchange performance can be improved by increasing the contact area with the atmosphere above the atmosphere.

When one of the heat exchange objects 31 and 32 is located on the upper side (over the atmosphere) and the other heat exchange objects 31 and 32 are disposed opposite to each other, Is located on the lower side (ground).

In addition, the heat exchange object 31, 32 may have the same mass M1 on one side and the same mass M2 on the other side. A mass M2 similar to the mass M1 of the one heat exchanging object 31 is provided to the other heat exchanging object 32 in a state where the one heat exchanging object 31 is once raised to the set height H, When the one side heat exchanging object 31 is lowered, the other side heat exchanging object 32 connected by the lifting device second wire 21b is automatically lifted so that the mass M1 of the one side heat exchanging object 31 and the mass M1 of the other side heat exchanging object 32, The mass M2 of the heat exchange object is similar, so that the energy consumption at the time of repeated rise / fall of the heat exchange object becomes very small. In other words, only when the height of the heat exchange object 31 or 32 rises or falls, only one force is required to move the heat exchange object 31 or the other heat exchange object 32, so that the repetitive height rise / do.

The masses M1 and M2 of the heat exchange object 31 and 32 may be set in advance in the control unit 40 and the masses M1 and M2 of the heat exchange objects 31 and 32 may be measured. The masses M1 and M2 of the heat exchange object 31 and 32 may be measured through the control unit 40 (not shown), and the measurement value may be sent to the control unit 40 to determine the mass of the heat exchange.

The elevating device 20 functions to raise and lower the heat exchanging object 31 and 32. The elevating device 20 includes elevating device wires 21a, 21b and 21c, elevating device sheaves 22a, 22b, 22c and 22d and elevating device power source 23a , And 23b.

The lifting device second and third sheaves 22b and 22c are connected in parallel at a lower end of the float 11 so as to have a single groove or multiple grooves on the surface, (Wheel). At this time, the lifting device second and third sheaves 22b and 22c are installed at the lower end of the float meter 12. The elevating device first and fourth sheaves 22a and 22d disposed on the lower side connect the elevation device first and third wires 21a and 21c positioned vertically to the elevation device first and second power sources 23a and 23b, Direction (horizontal direction).

The lifting device wires 21a, 21b and 21c are connected to the heat exchanging objects 31 and 32 while the lifting device second wires 21b are seated on the surfaces of the elevating devices 2 and 3, And the elevation device first and third wires 21a and 21c are connected to the elevation device first and second power sources 23a and 23b and use products having set strengths. At this time, when the elevator wires 21a, 21b, and 21c are connected to the heat exchange objects 31 and 32 without being a single wire, a heavier object can safely be raised above the atmosphere.

The lifting device first and second power sources 23a and 23b wind the lifting device first and third wires 21a and 21c so that the heat exchange objects 31 and 32 can move from the ground to the air or over the atmosphere The first and third wires 21a and 21c are provided at both ends of the lifting apparatuses 21a and 21c to rotate the driving shaft through the control of the controller 40. The first and third wires 21a and 21c, And a driving motor is provided for lifting and lowering the connected heat exchange objects 31 and 32, for example.

In this case, when one of the heat exchange objects 31 and 32 is lowered, only the first and second power sources 23a and 23b are driven, and the first and second power sources 23a and 23b are powered So that it is not driven.

Alternatively, both of the elevating device first and second power sources 23a and 23b may be driven. That is, the lifting device power source 23b located close to the other heat exchange object 32 at the other side of the heat exchange object 31 when the one heat exchange object 31 is lifted is operated to close the lifting device third wire 21c, The elevating device first power source 23a adjacent to the one heat exchanging object 31 closes the elevating device first wire 21a and the lifting device first wire 21a is brought close to the one heat exchanging object 31 at one side when the other heat exchanging object 32 rises. The elevating device second power source 23b adjacent to the second heat exchanging object 32 uncovers the elevating device third wire 21c while only the first power source 23a is operated to wind the elevating device first wire 21a.

Meanwhile, the elevating device first and second power sources 23a and 23b may include a driving motor in a single or multiple structure, or alternatively, a fuel engine such as a diesel engine may be used.

The suspension height regulating device is constituted to control the suspension height of the float 11 through the control part 40 and includes the fixing fluid wires 13a and 13b and the fluid fluid power sources 14a and 14b.

The fixing fluid wires 13a and 13b connect the float 11 and the fluid fluid power sources 14a and 14b to be described later provided on the ground so as to limit the floating height of the float 11, And supports the float (11).

The auxiliary fluid power sources 14a and 14b are provided at the lower ends of the fixed fluid wires 13a and 13b to provide power to uniformly wind or unwind the fixed fluid wires 13a and 13b, The driving shaft is rotated through the control of the driving shaft 40 to wind the fixing fluid wires 13a and 13b and to lift the float 11 connected to the fixing fluid wires 13a and 13b.

The control unit 40 controls the operation of the lifting device first and second power sources 23a and 23b and the auxiliary fluid power sources 14a and 14b of the floating height regulating device and transmits the measurement signal from the auxiliary fluid meter 12 And controls the lifting device first and second power sources 23a and 23b, the auxiliary fluid power sources 14a and 14b and the auxiliary fluid meter 12 through a wireless or wire communication system. In this way, the control unit 40 can control the upward and downward speeds of the heat exchange target bodies 31 and 32 according to the atmospheric condition of the atmosphere.

In addition, the control unit 40 can control the heat exchange efficiency through the height of the heat exchange object 31, 32 on the ground and the residence time in the atmosphere.

On the other hand, a light emitting body (not shown) is provided on the float 11, the heat exchange objects 31 and 32, the fixing fluid wires 13a and 13b and the elevator wires 21a, 21b and 21c, It is possible to prevent collision with a flying object or the like when raising the float 11 and the heat exchange object 31, 32 over the upper atmosphere.

5 is a block diagram of a heat exchange method using the atmospheric temperature distribution of the present invention.

According to the present invention, the heat exchange method using the atmospheric temperature distribution according to the present invention comprises a float floating step (S200), a heat exchange medium injection step (S210) in one heat exchange object, a step of ascending the atmosphere above the one heat exchange object (S220) (S230), a heat exchange step S240 of one side heat exchange object, a lowering step S250 of one side heat exchange object, a one side heat exchange object fixing and a heat exchange medium collection step S260, An ascending step S270, a heat exchanging step S280 of the other heat exchanging object, a descending step S290 of the other heat exchanging object, and a second heat exchanging object collecting step S300.

The floating fluid floatation step S200 is performed by operating the auxiliary fluid power sources 14a and 14b through the control of the control unit 40 in the state where the floating gas is injected into the float fluid 11, 13b raise the floating height of the float 11 to a height above the defined atmospheric temperature.

The step of injecting the heat exchange medium (S210) into the one-way heat exchange object is a step of supplying a heat exchange medium such as water or the like into the container of the heat exchange object (31). In this case, when the heat exchange medium is injected into the one side heat exchange object (S210), there is a problem in the heat exchange object (31, 32), and when the heat exchange medium such as water flows out from the atmosphere, It is environmentally friendly against pollution.

When the float height of the float 11 is set, the elevating mechanism second power source 23b disposed on the other side is operated through the control of the controller 40, When the wire 21c is wound, one side heat exchange object 31 rises. At this time, the lifting device second wire 21b is moved along the second and third lifting devices 22b and 22c.

The step of injecting the heat exchange medium (S230) into the other heat exchange object is a step of supplying a heat exchange medium such as water into the container of the other heat exchange object (32) relatively lowered during the step S220 of ascending the atmosphere of the one heat exchange object. At this time, when the heat exchange medium is injected into the heat exchange object on the ground, the heat exchange object is fixed to the ground structure (not shown in the drawing) and the heat exchange medium injection operation is performed.

The heat exchange step S240 of one side heat exchange object is performed such that the heat exchange medium such as water (liquid state), which is a heat exchange medium contained in the vessel after the one side heat exchange object 31 is lifted up to the atmosphere by the elevation device 20, Exchanges heat with the surrounding atmosphere at a temperature to provide a heat exchange medium such as water (low temperature liquid) or ice (solidified solid) at a desired temperature range.

In the descending step S250 of the one-way heat exchanging object, a heat exchange medium such as water or ice exchanged with heat is stored in the upper part of the atmosphere. If the cooling is required, the control unit 40 controls the elevating device 1 The power source 23a is operated to wind the lifting device first wire 21a so that the one heat exchange target 31 is lowered.

The one-way heat exchange object fixation and heat exchange medium collection step (S260) is a step of fixing the one-side heat exchange object 31 lowered to the ground to the ground structure and collecting the heat exchange medium.

The step of ascending over the atmosphere of the other heat exchange target object S270 is a step in which the one heat exchanging object 31 is lowered and the other side heat exchanging object 32 is lifted by the lifting apparatus 20 controlled by the control unit 40. [

That is, in the step S270 of rising the atmosphere of the other heat exchange object, the mass M2, which is the same as the mass M1 of the one heat exchange object 31 in the state where the one heat exchange object 31 is raised to the set height H (M1) of the one heat exchanging object (31) and the other heat exchanging object (32) are located on the other heat exchanging object (32) because the other heat exchanging object The mass of the heat exchange object is equal to the mass M2 of the heat exchange object, so that the energy corresponding to the mass difference of the heat exchange object is consumed at the repeated elevation rise / fall of the heat exchange object, resulting in a technical advantage that energy consumption is very small.

As a result, it is possible to prevent the other heat exchanging object over the atmosphere from falling down without further energy consumption, and to continue the rise of the new heat exchanging object that the specific heat exchanging object is lowered and replaced on the ground, without additional energy consumption.

For example, the calculation of the energy efficiency of the heat exchange system using the atmospheric temperature distribution (in the case of one rise in altitude) is as follows.

- To compute the energy efficiency, the mass (M1) of one side of the heat exchange object (31) is compared with the reference value.

- Energy (E1) and power (P1) raising 1 ton to a height of 2 km above ground at a very slow rate in one hour.

- E1 = M1gh = 2 × 10 7 J = 5.6 kWh, P1 = 5.6 kW

- At a height of 2 km above the ground, the temperature is 13 ° C lower than the surface (the environmental reduction rate used in atmospheric science is -6.5 ° C / km).

- Energy required to lower 1 ton of water by 13 ° C (E2)

- E2 = 1.3 x 10 ⁷ cal = 5.5 x 10 ⁷ J = 15.4 kWh

- E1 <E2 Then we can see that exchanging the energy by lifting the surface above the atmosphere above the surface is more efficient.

- Efficiency index η = E2 / E1 × 100 = 275%, 2.75 times

The mass M2 of the other heat exchanging object 32 can be set to be similar to the mass M1 of the one heat exchanging object 31 when the mass M1 of the one heat exchanging object 31 is determined.

When the mass M1 of the one-side heat exchange object 31 is raised up to the predetermined height, the mass M2 of the other heat exchange object 32 is increased to a set height from now on. The energy consumption depends on the mass difference of the heat exchange medium, It can be seen that the energy generated by the frictional force is limited to be much smaller than E1.

The energy required for raising the mass M2 of the other heat exchange object 32 to the set height H is increased in addition to the energy required for initially increasing the mass M1 of the heat exchange object 31 on one side to the set height H. small.

The number of iterations is determined by the time it takes to heat up the heat exchanger once and perform the heat exchange.

For example, if one side heat exchange object 31 is raised one time and the one side heat exchange object 31 and the other side heat exchange object 32 are repeatedly lowered and raised 40 times, the efficiency index η = E2 / E1 × 40 × 100 = 11,000%, and 110 times, respectively.

At this time, the elevator first and second power sources 23a and 23b can be given an output of up to 1000 kW depending on the selection, and can be realized very easily when P1 = 5.6 kW.

In the heat exchange step S280 of the other heat exchange object, the other heat exchange object 32 is lifted up to the atmosphere by the lifting device 20, and then the heat exchange medium such as water contained in the container is heated at a low temperature Exchanged to form a heat exchange medium such as water or ice exchanged at a desired temperature range.

In the descending step (S290) of the other heat exchange object, if the water or ice exchanged with heat is stored in the upper part of the atmosphere and cooling is required, the elevating device second power source (23b) is operated through the control of the control part And the other third heat exchanging object 32 is lowered by winding the device third wire 21c.

The other side heat exchange object fixing and heat exchange medium collection step (S300) is a step of fixing the other side heat exchange object (32) lowered to the ground to the ground structure and collecting the heat exchange medium.

In conclusion, unlike the prior art, the present invention does not need to store snow for a long time from winter to summer, and unlike the prior art in which natural eyes and artificial eyes are made in winter, it is not time- It can be used in hot tropical regions throughout the year, and there is a technical advantage in that better heat exchange efficiency can be obtained by operating the heat exchange system especially when the temperature is lowered at night.

While the invention has been shown and described with reference to certain preferred embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. This is possible.

Therefore, the scope of the present invention should not be limited by the described embodiments, but should be determined by the equivalents of the appended claims, as well as the appended claims.

11: float 12: floatometer
13a: fixing fluid first wire 13b: fixing fluid second wire
14a: float first power source 14b: float second power source
20: elevating device 21a: elevating device first wire
21b: lifting device second wire 21c: elevating device third wire
22a: lifting device first pulley 22b: lifting device second pulley
22c: elevating device 3rd pulley 22d: elevating device 4th pulley
23a: elevating device first power source 23b: elevating device second power source
31, 32: heat exchange object 40:

Claims (15)

A float arranged to stay above the atmosphere;
A plurality of heat exchange objects connected to the float to cause heat exchange in the atmosphere;
A lifting device for lifting and lowering the heat exchange object; And
And a control unit for controlling operation of the lift device.
The method according to claim 1,
Wherein the auxiliary fluid is provided with a gas discharger for regulating the degree of discharge of the internal gas.
The method according to claim 1,
And a floating height regulating device for controlling the floating height of the floating fluid through the control part.
4. The apparatus according to claim 3,
A fixing fluidic wire connected to restrict a floating height of the floating fluid; And
And a sub fluid power source provided at an end of the fixing fluid wire to provide power to wind or unwind the fixing fluid wire.
2. The apparatus according to claim 1,
A wire movably connected to the float; And
And a power source provided at both ends of the wire to provide power for lifting and lowering the heat exchange object connected to the wire while winding or unwinding the wire through the control of the control unit.
The method according to claim 1,
Wherein the heat exchange object is arranged so that one side and the other side are opposite to each other.
The method according to claim 6,
Wherein the heat exchange object has a mass of one side and the other side that are similar or identical.
The method according to claim 1,
The heat exchange object includes a container for containing a heat exchange medium therein, and exchanges heat with surrounding air at a low temperature of the atmosphere.
9. The method of claim 8,
Wherein the container of the heat exchange object is formed of a metal material having a high thermal conductivity.
9. The method of claim 8,
The vessel connecting a plurality of small vessels in line to the wire.
The method according to claim 1,
Wherein the control unit controls the heat exchange efficiency through the height of the heat exchange object on the ground and the residence time in the atmosphere.
The method according to claim 1,
And a meter connected to the float to measure a state over the atmosphere.
The method according to claim 1,
A heat exchanging system using an atmospheric temperature distribution in which an illuminant is installed on the float, the heat exchange object, the immobilizing auxiliary fluid wire of the floating height regulating device, and the wire of the lift device.
Floating the float;
Injecting a heat exchange medium into one side heat exchange object after floating the float;
A step of raising the one-side heat exchanging object into which the heat exchanging medium has been injected upward over the atmosphere;
Injecting a heat exchange medium into the other one of the lower heat exchange bodies as the one heat exchange object rises;
Exchanging the heat of the one side heat exchange object with ambient air at a low temperature over the atmosphere;
Lowering the one heat exchange object to collect the heat exchanged medium with heat; and
And fixing the one side heat exchange object lowered to the ground to the ground structure and collecting the heat exchange medium.
15. The method of claim 14,
A step of raising the other heat exchanging object to above the atmosphere as the one heat exchanging object descends;
Exchanging the heat of the other heat exchange object with ambient air at a lower temperature of the atmosphere;
Lowering the other heat exchange object for collecting the heat exchange medium in which the heat is exchanged; and
Further comprising the step of fixing the other side heat exchanging object lowered to the ground to the ground structure and collecting the heat exchanging medium.

Images