KR101409813B1 - Air conditioner apparatus for dehumidification using heat pipe heat exchanger - Google Patents

Abstract

The present invention relates to an air conditioner using a heat pipe heat exchanger for dehumidification which is capable of being efficiently operated and reducing consumption of energy by pre-heating and re-heating air without additional power in controlling humidity by installing a heat pipe heat exchanger for accommodating the front and rear ends of a heat exchanging line. According to the present invention, the air conditioner using a heat pipe heat exchanger for dehumidification comprises a heat exchanging line in which a working fluid is flowed to cool air flowing according to heat exchange of the working fluid; a heat pipe heat exchanger, which is formed to cover the front and rear ends of the heat exchanging line, for cooling air flowed in the heat exchanging line by heat exchange of the working fluid contained inside and heating air passing through the heat exchanging line; and a ventilating fan for allowing air to pass through the heat exchanging line and the heat pipe heat exchanger and exhausting the air.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an air conditioner for dehumidifying heat pipe heat exchanger,

The present invention relates to an air conditioner that requires humidity or dehumidification, and a heat pipe heat exchanger is installed to accommodate the front and rear ends of the heat exchange line, so that the precooling and reheating of air can be performed without any additional power during humidity control, And more particularly, to an air conditioning system using a heat pipe heat exchanger for dehumidification capable of reducing the temperature of the heat exchanger.

Generally, an air conditioner is a generic term for devices necessary for achieving the purpose of air conditioning including cooling, heating, humidification, dehumidification, humidification, air purification, etc. The air conditioner and the heat source device such as a boiler, , Heat transfer devices such as blowers, pumps, ducts, piping, spouts, suction ports, radiators, and end devices, and automatic control devices that allow these devices to meet the conditions of air conditioning.

In the case of the constant temperature and humidity control device for performing the temperature and humidity control among such air conditioners, a system or an apparatus generating a lot of heat such as a computer room, a precision measuring room, an engine laboratory, a clean room of a semiconductor factory, an electronic substrate production room, By installing them in each space, it is possible to control the temperature inside the space by cooling / heating operation, humidification and dehumidification operation for controlling the humidity inside the space, and air purification operation for maintaining clean air inside the space. It is used to keep the temperature and humidity around the system or device always within a certain range, and it can be more effective especially in the outside air conditioner introducing the entire outside air.

However, in the case of the conventional constant temperature and humidity device, as well as the constant temperature dehumidifying device and the air conditioner, as shown in FIG. 1, in adjusting the humidity, the air introduced into the device is cooled and humidified. It is a low-efficiency method of over-consumption of energy.

That is, in the conventional constant temperature and humidity device, when the temperature reaches the set value but the humidity is high, the pass air is subcooled in the cooling coil to decrease the humidity, and then the absolute humidity is decreased. There is a problem that a system is inefficiently operated such that a large amount of energy is consumed in a vicious cycle such as reheating, and a separate cooling means and reheat means are required to perform cooling and reheating.

Korean Patent No. 0917835

Accordingly, it is an object of the present invention to provide a heat pipe heat exchanger for accommodating the front and rear ends of a heat exchange line, to pre-cool and reheat air without any power at the time of humidity control, thereby reducing energy consumption, And to provide an air conditioning apparatus using a pipe heat exchanger.

To achieve the above object, an air conditioning apparatus using a heat pipe heat exchanger for dehumidification according to the present invention comprises: a heat exchange line for allowing a working fluid to flow into the inside and performing heat exchange with outside air; One or more pipes for cooling the air introduced from the front end of the heat exchange line by heat exchange of the working fluid contained in the shape of wrapping the front end and the rear end of the heat exchange line and for heating the air passing through the heat exchange line at the rear end of the heat exchange line A heat pipe heat exchanger including a body; And a blowing fan for allowing air to pass through the heat exchanging line and the heat pipe heat exchanger and exhausting the air.

As one example, the heat pipe heat exchanger is provided with a U-shaped receiving space to allow the pipe body to be disposed in the accommodating space, and both side surfaces opposed to the front end and the rear end of the heat exchanging line So that the casing of this opened shape can be further configured.

In addition, it is appropriate that the casing is provided with a heat insulating plate at a portion connecting the side portion and at a portion facing the heat exchange line.

As an example, a wick of a mesh net structure for guiding the flow of working fluid along the longitudinal direction may be formed on the inner surface of the pipe body.

As an example, a wick of a groove structure may be formed on the inner surface of the pipe body to guide the flow of the working fluid along the longitudinal direction.

The width of the upper and lower widths of the groove of the pipe body is different from that of the groove of the pipe body. The upper width of the groove is smaller than the lower width or the upper width of the groove is larger than the lower width. It is reasonable.

In addition, the groove may be formed such that edges of the lower width are rounded.

The grooves may be formed with grooves or protrusions at the corners of the lower width.

As one example, the pipe body may be formed such that a first coating layer is applied to both side portions opposite to the front end and the rear end of the heat exchange line in a 'U' shape, and a second coating layer is applied to a portion connecting both side surfaces , ≪ / RTI >

Wherein the first coating layer comprises 10 to 20 parts by weight of a metal powder, 30 to 50 parts by weight of carbon black having a particle diameter smaller than that of the metal powder, and 1 to 2 parts by weight of a citrate, based on 100 parts by weight of the polyacrylic acid resin,

The second coating layer may include 10 to 20 parts by weight of the metal powder, 30 to 50 parts by weight of the ceramic nano powder, and 1 to 2 parts by weight of the citrate, based on 100 parts by weight of the polyacrylic acid resin.

The air conditioning apparatus using the heat pipe heat exchanger for dehumidifying according to the present invention is provided with a heat pipe heat exchanger for accommodating the front and rear ends of the heat exchanging line to precool and reheat the passing air without adjusting the power There is an advantage in that the apparatus can be efficiently operated, and in particular, the outside air harmonizer incorporating the entire outside air has an advantage of being able to enjoy a greater effect.

1 is a schematic view for explaining a conventional air conditioning apparatus;
2 is a schematic view for explaining an air conditioning apparatus using a heat pipe heat exchanger for dehumidification according to the present invention.
3 is a perspective view showing a configuration of an air conditioner using a heat pipe heat exchanger for dehumidification according to the present invention.
4 is a schematic view for explaining an operating state of an air conditioner using a heat pipe heat exchanger for dehumidification according to the present invention.
5 is a longitudinal sectional view showing a pipe body of a heat pipe heat exchanger according to an embodiment of the present invention;
6 is a cross-sectional view and a longitudinal sectional view showing a pipe body of a heat pipe heat exchanger according to another embodiment of the present invention.
7A and 7B are perspective views showing an embodiment of the angle of the groove of FIG. 6;
Figures 8A-8B are cross-sectional views illustrating embodiments of the formation of the grooves of Figure 6;

Hereinafter, an air conditioning system using a heat pipe heat exchanger for dehumidification according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 is a schematic view for explaining an air conditioning apparatus using a heat pipe heat exchanger of the present invention, and FIG. 3 is a perspective view showing a configuration of an air conditioning apparatus using a heat pipe heat exchanger of the present invention. 4 is a schematic view for explaining an operating state of the air conditioner using the heat pipe heat exchanger according to the present invention.

The present invention relates to an air conditioning apparatus for reducing energy by having a heat pipe heat exchanger (50) configured to surround a front end and a rear end of a heat exchange line.

2, the air passing through the front end of the heat exchange line is precooled by the heat pipe heat exchanger 50 to reduce the cooling load and the temperature of the heat exchange line, thereby increasing the amount of dehumidification. At the same time, The heat pipe heat exchanger 50 reheats the heat exchanger 50 without using any other energy at the rear end of the heat exchanger line.

At this time, the air conditioner referred to in the present invention includes a general air conditioner for performing cooling and heating, a constant temperature and humidity control device for controlling the degree of cleanliness and flow of humidity and air, and a temperature and humidity dehumidifying device.

In the present invention, the term " front end of the heat exchange line " refers to a side to which the air is introduced based on a direction in which the air introduced from the outside flows through the heat exchange line, and the rear end of the heat exchange line refers to the heat exchange line Means the side through which it passes.

Here, the heat exchange line cools the air flowing in accordance with the heat exchange of the working fluid and the working fluid, thereby providing the cooled and humidified air into the space that requires substantial cooling and humidity control.

The heat exchange line may be an evaporator in a general air conditioner including a condenser, a compressor, an evaporator, etc. In the case of an air conditioner using cold water or brine manufactured by an external refrigerator as a heat source, have.

Hereinafter, an evaporator in a general air conditioner including a condenser, a compressor, and an evaporator will be described as an example of a heat exchange line. However, in the present invention, the heat exchange line is not limited to the evaporator, but it is natural that a cooling coil that performs a cooling operation by using cold water or brine as a heat source as described above is also applicable.

4, the compressor 10, the condenser 20, the expansion valve 400 (see FIG. 4), the condenser 20, and the expansion valve 400 And an evaporator 40. The evaporator 40 and the evaporator 40 are structured such that they repeatedly perform vaporization and liquefaction as they perform a heat exchange process.

The compressor 10 is for compressing a refrigerant (hereinafter, referred to as 'working fluid'). The compressor 10 compresses a low-pressure working fluid in a gaseous state moving from the evaporator 40 and converts it into a high- , And discharges the high-pressure working fluid to the condenser (20).

The condenser 20 cools the high-temperature and high-pressure working fluid discharged from the compressor 10 to thereby heat it and change the condensation so as to liquefy the working fluid in the gaseous state.

In this case, the cooling system of the condenser 20 may be variously implemented through a known technique such as water-cooling or air-cooling. In the present invention, however, the cooling fan 200 and the fluid And a cooling fin (210) for cooling the fluid tube due to the cooling air of the cooling fan (200). The cooling fan (200) and the cooling fin (210) The cooling method is presented as an example.

The liquid-converted working fluid in the condenser 20 is moved to the receiver 30 and temporarily stored. The receiver 30 is installed between the condenser 20 and the evaporator 40 and absorbs a change in the amount of the operating fluid due to a load variation of the evaporator 40 to facilitate the operation of the air conditioner It is a matter of course that such a receiver 30 can be selectively applied.

The evaporator 40 changes the working fluid of high temperature and high pressure liquefied in the condenser 20 to the low-temperature and low-pressure working fluid while passing through the expansion valve 400 installed in the evaporator 40, The working fluid evaporates and absorbs the heat of the object to be cooled, thereby performing the cooling action.

The air cooled by the heat exchange according to the evaporation is discharged to a space requiring cooling by a blowing means such as a blower. The evaporator 40 has a plurality of fin structures surrounding the tube, 40 to facilitate the heat transfer and to cool the air that has flowed in a short time.

Here, the working fluid may be various heat transfer fluids suitable for the use temperature, and finally the temperature depending on the heat exchange action may be determined according to the increase or decrease of the type of the working fluid and the amount of the working fluid heat exchanged in the evaporator.

The present invention further includes a heat pipe heat exchanger (50) configured to surround the front end and the rear end of the evaporator (40) in order to reduce energy unnecessarily used in controlling the humidity in the above-described air conditioning apparatus It is characterized by being configured.

In the existing air conditioner, excessive cooling is performed from the cooling coil to increase the dehumidification amount in advance to lower the relative humidity of the blowing air, and then reheat is performed in the post-process to adjust the excessively cooled temperature to the set temperature This process consumes a lot of energy in a vicious cycle. That is, in the case of the existing air conditioner, separate preheating means and reheating means were required to perform preheating and reheating.

Accordingly, in the present invention, the heat pipe heat exchanger 50 performing the pre-cooling and reheating functions by heat exchange itself without external power is disposed at the front end and the rear end of the evaporator 40, thereby maximizing the energy saving.

In addition to the above-described air conditioner, the present invention accommodates the outside of the evaporator 40 and cools the air introduced into the evaporator 40 by heat exchange of the internal working fluid, A heat pipe heat exchanger 50 for heating air passing therethrough and a blowing fan 60 for allowing air to pass through the evaporator 40 and the heat pipe heat exchanger 50 and to discharge the air to a required space .

3, the heat pipe heat exchanger 50 includes a casing 500 having a U-shaped groove 501 and a receiving space 502 therein, A plurality of pipe bodies 510 disposed along the space 502 and a working fluid 520 exchanging heat with the air filled in the pipe body 510.

The casing 500 is formed in an upright shape by a combination of horizontal or vertical frames, and each side is opened so that air introduced from the outside can pass through. A housing space is provided in a U shape so that the pipe body 510 is disposed in the accommodation space 502 and the evaporator 40 is disposed in the groove 501, Side portions (portions A in Fig. 4) opposed to the front end and the rear end of the base 40 are open. In order to allow the casing 500 to open only at both side portions (A portion in FIG. 4) opposite to the front end and the rear end of the evaporator 40, heat exchange with the flowing air is performed, and at the same time, In order to prevent the efficiency of the working fluid flowing through the pipe body 510 from decreasing as the heat exchange is performed in the portion B, the portion connecting the both side portions, that is, the portion B in FIG. 4, forms a closed end.

3, a heat insulating plate 503 is formed on a portion of the casing 500 facing the evaporator 40 as a portion connecting the side portions (portion B), so that heat exchange is performed only in the portion A And the heat exchange is blocked in the portion B and the efficiency is doubled. The heat insulating plate 503 may be formed of a variety of known materials and may have a detachable structure.

The pipe body 510 is installed along the longitudinal direction of the casing 500 in the accommodating space 502 of the casing 500 as described above and includes a U- Structure. The pipe main body 510 has a structure in which the working fluid 520 is received therein and the working fluid 520 can flow and circulate from one end to the other end or from one end to the other end according to heat exchange .

The pipe main body 510 has a plurality of pipe main bodies 510. The pipe main bodies 510 are spaced apart from each other by a predetermined distance and are disposed side by side in the housing space 502 of the casing 500. One end of the pipe main body 510 is connected to the front end of the evaporator 40 And the other end thereof is provided so as to face the rear end of the evaporator 40.

The pipe body 510 is preferably made of aluminum or copper having a good heat transfer coefficient and a wick for guiding the flow of the working fluid 520 liquefied in the longitudinal direction of the pipe body 510 . Corrosion-resistant materials can be used when corrosive gases pass through.

The wick is provided in the circulation process of the working fluid 520 and has a capillary structure to return the working fluid 520 in the liquid state from the condenser to the evaporator. That is, the wick feeds back the liquefied working fluid 520 using the capillary phenomenon and the gravity due to the surface tension of the liquid, and the wick will be described in detail below.

The working fluid 520 is filled in the pipe body 510 and serves to transport heat by phase change of gas and liquid. Like the working fluid circulating in the air conditioner, various working fluids Fluid can be used.

The operation of the air conditioner using the heat pipe heat exchanger according to the present invention will be described with reference to FIG.

One end of the heat pipe heat exchanger 50 is referred to as a evaporator 50A and the other end of the heat pipe heat exchanger 50 is a portion facing the front end of the evaporator 40, The portion facing the rear end of the evaporator 40 is referred to as a condensing portion 50B.

The working fluid 520 of the heat pipe heat exchanger 50 includes a working fluid 520A in a gaseous state and a working fluid 520B in an extra liquid state that does not change into a gas having a pressure corresponding to a constant temperature And this extra liquid working fluid 520B is present in the wick of the pipe body 510. [

First, the air introduced from the outside by the blowing fan 60 passes through the evaporator 50A of the heat pipe heat exchanger 50, and the outside air is relatively cooled by the temperature of the outlet of the evaporator 40 The working fluids 520A and 520B existing in the pipe main body 510 corresponding to the evaporator 50A absorb heat and start to evaporate rapidly due to the heat of vaporization, The pressure difference with the condensing part 50B is generated, and the evaporated working fluid 520A in the gaseous state is moved to the condensing part 50B.

In the evaporator 50A of the heat pipe heat exchanger 50, the liquid working fluid 520B existing in the wick absorbs heat from the air passing through the evaporator 50A, and the gaseous working fluid 520A ), The precooling of the passing air is performed as the heat is absorbed.

Further, the heat energy due to the phase change in the evaporator 50A is moved to the condenser 50B as described above.

On the other hand, the working fluid 520A in the gaseous state moved to the condenser 50B of the heat pipe heat exchanger 50 is heat-exchanged with the air cooled in the evaporator 40 to heat the heat energy absorbed from the evaporator 50A The heat is transferred from the main body 510 itself to the rear end side of the evaporator 40 in contact with the condensing portion 50B so that the air that has passed through the rear end of the evaporator 40 is reheated.

The working fluid 520A that has released heat in the condenser 50B is again liquefied by the working fluid 520B in the liquid state and returns to the evaporator 50A through the wick of the pipe body 510, A preheating and reheating process can be repeatedly performed.

As described above, according to the present invention, precooling and reheating are performed at the front end and the rear end of the evaporator 40 through heat transfer and circulation processes according to a phase change of vaporization and liquefaction using the heat pipe heat exchanger 50, No separate power source, pre-cooling means or reheat means is required in the control process, so that the consumption of energy can be reduced and high-efficiency operation is possible.

In addition, the heat pipe heat exchanger 50 may be configured to be detached from the evaporator 40 at a predetermined distance from the evaporator 40, , It is preferable to be selectively applied to the case of a constant temperature and humidity device which is desorbed in a heating device and humidity control is required.

FIG. 5 is a cross-sectional view showing a pipe body of a heat pipe heat exchanger according to an embodiment of the present invention, and FIG. 6 is a cross-sectional view and a longitudinal sectional view showing a pipe body of a heat pipe heat exchanger according to another embodiment of the present invention. FIGS. 7A and 7B are perspective views showing an embodiment of the angle of the groove of FIG. 6, and FIGS. 8A and 8B are longitudinal sectional views showing an embodiment of the formation of the groove of FIG. 6. FIG.

As described above, the wick formed in the pipe main body 510 is a capillary structure for flowing the working fluid in the liquid state from the condensing portion to the evaporator at the phase change of the working fluid 520, The capillary pressure acts as a driving force for returning the liquid working fluid 520 from the condensing portion 50B to the evaporating portion 50A.

The wick of the pipe body 510 may be formed by forming a porous mesh net 511 on the inner surface of the pipe body 510 as shown in FIG. 5, and the wick of the pipe body 510 And a groove 512 forming a groove on the inner surface.

In the present invention, the groove 512 structure is shown as a wick of the pipe body 510, and various embodiments that can improve the heat transfer efficiency with respect to the structure of the groove 512 are shown.

Specifically, as shown in FIG. 7A, the wick of the groove 512 has an angle of 0 deg in the longitudinal direction of the pipe body 510 on the inner circumferential surface of the pipe body 510 of the cylindrical body And a groove 512 parallel to the longitudinal direction of the pipe body 510 is continuously formed.

7B, the groove 512 of the wick may be formed on the inner circumferential surface of the pipe body 510 so that the angle in the longitudinal direction of the pipe body 510, that is, deg.], grooves may be continuously formed in parallel with the longitudinal direction of the pipe body 510, or with a turning angle between 0 and 90 [deg.].

8A, the groove 512 according to an exemplary embodiment of the present invention has an upper width D1, which is an opening toward the center point of the pipe body 510 in the pipe body 510, ), And the cross-sectional area of the inside increases.

Here, the groove 512 of this embodiment can be formed by rounding both corners of the lower width D2 as shown in FIG. 8B, so that the friction of the liquid flow path can be reduced with the increase of the cross-sectional area.

The groove 512 shown in Fig. 8C is a groove 513 formed inside the lower width D2 of the groove 512. The groove 512 shown in Fig. And the protrusion 514 is formed inside the lower width D2.

The groove 513 or the projection 514 is formed in the lower width D2 of the groove 512 in this way to the other end (condensing portion) 50B in one end (vaporizing portion) 50A of the heat pipe heat exchanger 50, The amount of liquid evaporated per unit time in the evaporator 50A increases, so that the liquid is rapidly recirculated from the condenser 50B to the evaporator 50A to ensure continuous heat transfer (The cross sectional area of the groove is increased) and the circulation of the working fluid 520 is made by the pressure difference, the structurally induced capillary pressure [Delta] Pcap is proportional to the pressure loss [Delta] P1 and [Delta] Pv in the liquid flow path and the gas flow path, The grooves 512 are formed sufficiently to compensate for the pressure difference Pg in the liquid due to the difference DELTA Pph at the interface and the relative height difference between the evaporator 50A and the condenser 50B in the gravitational field .

Considering the above factors, the pressure relationship for operation of the normal heat pipe heat exchanger 50 is as follows.

? Pcap??? P1 +? Pv +? Pph +? Pg

Accordingly, the present invention proposes a shape of the groove 512 in which the above-mentioned? Pcap is made larger and the above-mentioned? P1 is made smaller in order to improve the efficiency of the heat pipe heat exchanger 50.

Therefore, in order to maximize the return force from the other end (condensing portion) 50B of the heat pipe heat exchanger 50 to the one end (vaporizing portion) 50A, the capillary pressure [Delta] Pcap is maximized, The pressure loss DELTA P1 in the liquid flow path is reduced by reducing the friction of the flow and by increasing the cross-sectional area of the groove 512, the heat transfer area in the condensing portion 50B and the evaporation portion 50A is increased, The transmission efficiency can be increased.

Meanwhile, in the present invention, condensation is generated in repeated heat exchange processes in the pipe main body 510. When corrosive or the like is generated due to dew condensation, external moisture, and the like, the problem of leakage of the working fluid is controlled, A coating layer is formed on the outer circumferential edge of the pipe body 510 to double the efficiency of heat exchange.

That is, as described above, the pipe body 510 is formed such that the first coating layer is applied to both side portions opposite to the front end and the rear end of the heat exchange line (evaporator 40) in a U shape, So that the second coating layer is applied. As shown in FIG. 4, the first coating layer is applied to the A portion, and the second coating layer is coated to the B portion.

First, the first coating layer and the second coating layer are made of a polyacrylic resin as a main component, and this is to prevent the occurrence of condensation by adding water to the coating layer as a water-soluble binder.

The composition of the first coating layer may include 10 to 20 parts by weight of a metal powder, 30 to 50 parts by weight of carbon black having a particle diameter smaller than that of the metal powder, and 1 to 2 parts by weight of a citrate, based on 100 parts by weight of the polyacrylic acid resin do.

The metal powder is not limited to titanium dioxide, silicon dioxide, manganese or the like, and the metal powder functions as a frame in the coating layer to reinforce the strength of the coating layer.

Carbon black having a particle diameter smaller than that of the metal powder is compounded at the above mixing ratio so that the carbon black of the fine particles is filled in the frame formed by the metal powder so as to achieve a tight structure. The rustproof property of the main body 510 is doubled.

Particularly, the carbon black has excellent physical properties such as thermal conductivity, so that heat exchange is facilitated in the A portion (FIG. 4) of the pipe body 510 together with the metal powder to improve preheating and reheat efficiency.

The reason why the first coating layer is blended with carbon black is that when only the metal powder is blended for thermal conductivity, there is a problem of rust prevention due to corrosion, so that carbon black having resistance against corrosion and having good thermal conductivity is blended .

The reason for limiting the compounding range of the carbon black is that it is difficult to exhibit the function of improving the rustproofing property and the thermal conductivity in the case of less than 30 parts by weight, and is uneconomical in the case of exceeding 50 parts by weight and rather the property is deteriorated.

On the other hand, the second coating layer is characterized in that 10 to 20 parts by weight of the metal powder, 30 to 50 parts by weight of the ceramic nano powder, and 1 to 2 parts by weight of the citrate are added to 100 parts by weight of the polyacrylic acid resin.

In the case of the second coating layer, it is the same as the first coating layer that the metal powder functions as a frame and the ceramic nanopowder is filled in the frame to improve the rust prevention property by the tight structure.

In the case of the second coating layer, ceramic nanopowder is filled in the frame made of the metal powder to improve the heat insulating property. That is, in FIG. 4, the heat exchange at the portion B is prevented to improve the efficiency.

The ceramic nano powder has a low thermal expansion coefficient to impart a heat shielding function to the second coating layer. By mixing the ceramic nano powder, the heat transfer from the pipe body 510 to the outside is blocked, It is to increase the reheat efficiency.

As the ceramic nano powder, various materials can be used, and examples thereof include zirconium and magnesium oxide. In the case of the ceramic nano powder, the mixing range is also limited because if it is less than 30 parts by weight, it is difficult to exhibit the function of improving rust resistance and heat resistance. If it exceeds 50 parts by weight, it is not economical, will be.

In addition, the first coating layer and the second coating layer further include 1 to 2 parts by weight of citrate relative to 100 parts by weight of the polyacrylic resin. The reason why the citrate is further blended is that the And uniform carbon black and ceramic nano powder in the frame are uniformly distributed over the entire coating layer so that uniform physical properties are exhibited.

That is, in the case of small particles of carbon black and ceramic nano powder, the particles are small and tend to aggregate with each other. Therefore, when the particles are mixed as they are, it is impossible to secure uniform physical properties by uneven filling. .

The reason why the citrate uniformly fills the carbon black and the ceramic nano powder is to provide a repulsive force between the particles to control the agglomeration between the particles to achieve uniform filling.

In other words, by predominating the repulsive electrostatic force between the carbon black and the ceramic nano powder, it provides a counter reaction to the van der Waals forces which cause agglomeration between the particles.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification, but should be defined by the claims.

10: compressor 20: condenser
30: Receiving machine 40: Evaporator
50: heat pipe heat exchanger 60: blowing fan
500: casing 510: pipe body
520: working fluid

Claims (9)

A heat exchange line for allowing the working fluid to flow into the inside and performing heat exchange with the outside air;
One or more pipes for cooling the air introduced from the front end of the heat exchange line by heat exchange of the working fluid contained in the shape of wrapping the front end and the rear end of the heat exchange line and for heating the air passing through the heat exchange line at the rear end of the heat exchange line A heat pipe heat exchanger including a main body and a casing in the form of a U-shaped shape and having a housing space therein so that the pipe body is disposed in the accommodating space and both side portions opposed to the front end and the rear end of the heat exchanging line are opened; group; And
And a blowing fan for allowing air to pass through the heat exchanging line and the heat pipe heat exchanger and exhausting the air,
The pipe body is coated with a first coating layer on both side portions opposite to the front end and the rear end of the heat exchange line in a U shape and a second coating layer is coated on a portion connecting both side surfaces,
Wherein the first coating layer comprises 10 to 20 parts by weight of a metal powder, 30 to 50 parts by weight of carbon black having a particle diameter smaller than that of the metal powder, and 1 to 2 parts by weight of a citrate, based on 100 parts by weight of the polyacrylic acid resin,
Wherein the second coating layer comprises 10 to 20 parts by weight of the metal powder, 30 to 50 parts by weight of the ceramic nano powder, and 1 to 2 parts by weight of the citrate, based on 100 parts by weight of the polyacrylic acid resin. Air conditioning system.
delete The method according to claim 1,
Wherein a heat insulating plate is formed at a portion of the casing that connects the side portion and opposes the heat exchange line.
The method according to claim 1,
Wherein a wick of a mesh net structure for guiding the flow of working fluid along the longitudinal direction is formed on the inner surface of the pipe body.
The method according to claim 1,
And a wick having a groove structure for guiding the flow of the working fluid along the longitudinal direction is formed on the inner surface of the pipe body.
6. The method of claim 5,
The groove of the pipe body
Wherein a width of the upper width and a width of the lower width of the heat pipe are different from each other.
The method according to claim 6,
Wherein the grooves are rounded at corners of the lower width.
The method according to claim 6,
Wherein the grooves are formed with grooves or protrusions at corners of the lower width. delete

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