KR20060098221A - Air conditioner with fouling suppression function with the same and heat exchanger for antimicrobial/sterilization - Google Patents

Abstract

The present invention relates to a heat exchanger for antibacterial / sterilization and an air conditioning apparatus having a fouling suppression function having the same, in particular, the nano-coating treatment of the heat exchanger, and by installing a drying apparatus in the air conditioning apparatus having the same antibacterial / sterilization and fouling phenomenon It is to suppress. The configuration of the present invention, the heat exchanger is mounted on the cooling / heating, air conditioning, power generation, waste heat recovery, etc., the heat exchanger for performing a heat exchange between two fluids having different temperatures and separated by a solid wall, ) Is characterized in that the silver nano coating layers 21a, 22a, and 10a are formed on the surfaces of the fins 21 and the pipes 22. The drain member 10 accommodates the heat exchanger 20 in the lower side and is formed under the heat exchanger 20 to receive and drain the condensed water generated during the heat exchange; A blower (30) formed at an upper portion of the heat exchanger (20) to discharge heat-exchanged air to the outside; One side of the heat exchanger 20 is characterized in that it provides an air conditioner further added to the drying device (50).

Sterilization, Heat Exchanger, Drying Equipment, Air Conditioning Equipment

Description

Heat exchanger for antibacterial / sterilization and air conditioner with fouling suppression function having same {air conditioner with Fouling suppression function with the same and heat exchanger for antimicrobial / sterilization}

1 is a view schematically showing the internal configuration of a conventional air conditioner.

2 is a view showing the configuration of a heat exchanger according to the present invention.

3 is a view schematically showing the internal configuration of the air conditioner according to the present invention.

4 is a view showing an enlarged cross section of the drain member according to the present invention.

5 is a flowchart showing an operating state of the drying apparatus according to the present invention.

※ Explanation of code about main part of drawing ※

100: air conditioner 10: drain member

20: heat exchanger 21: fin

22: tube 21a, 22a, 10a: silver nano coating layer

30: blowing fan 40: discharge grill

50: drying apparatus 10b: water repellent coating layer

 The present invention relates to a heat exchanger for antibacterial / sterilization and an air conditioning apparatus having a fouling suppression function having the same, in particular, the nano-coating treatment of the heat exchanger, and by installing a drying apparatus in the air conditioning apparatus having the same antibacterial / sterilization and fouling phenomenon It is to suppress.

In general, the demand for air conditioning facilities has recently increased rapidly in homes and offices due to the improvement of living standards and air pollution.

In particular, as the demand for air conditioning equipment, which is a kind of air conditioning equipment, increases, the importance of maintenance after installation is becoming an important factor.

Looking at the schematic configuration of a conventional air conditioner (200), as shown in Figure 1, the heat exchanger 220 for performing a heat exchange between the two fluids different in temperature, separated by a solid wall; A drain member installed at a lower portion of the heat exchanger 220 and configured to receive and drain condensation water generated during heat exchange; It is installed in the upper portion of the heat exchanger 220, and consists of a blow fan 230 for discharging the heat-exchanged air to the outside through the discharge grill 240, and the like.

Moreover, the fin tube type | mold is widely used for the heat exchanger 220 of the said air conditioner 200, The fin tube type heat exchanger mainly uses a round copper tube and aluminum fins.

In the case where the heat exchanger is used as an evaporator (indoor), since a coolant cooled to about 8 ° C flows in the copper pipe, the relative humidity between the fins increases when air of 20 ° C or more flows in. That is, the temperature of the fin surface is maintained at about 10 ℃, but the fin surface temperature is lower than the dew point of the inlet air, condensation (結露) phenomenon occurs that the water droplets form on the fin surface.

However, in most homes and offices, the periodic cleaning and inspection of the air conditioner is rarely performed. Since moisture remains in the heat exchanger at all times, it is not only a good condition for germs and molds, but also for indoor dust and contaminants. It mixes with condensation or moisture generated in the heat exchanger, causing fouling on the heat exchanger surface more quickly.

Here, fouling is generally defined as an undesired solid deposit deposited at the interface, and is applied to gravitational settling and particle transport of various dusts in the air on the heat transfer surface of the heat exchanger. It means that occurs while the particle deposition occurs.

According to the moisture generation and fouling phenomenon, there is a problem that not only harm the health by reducing the cooling capacity and the increase of energy consumption and breeding of bacteria, but also cause bad smell by fungi.

In order to solve the above problems, some companies are known to manufacture a fin of the heat exchanger made of copper, or an air conditioner using a heat exchanger and a drain member formed with a coating film containing copper, but the effect thereof is insignificant, and Fundamentally, there is a problem that the moisture removal in the heat exchanger and the fouling phenomenon of the surface of the heat exchanger are not suppressed at all.

In addition, copper changes to green when it comes into contact with humid air containing CO ₂ or SO ₂ or salt, and there is a problem of corrosion. As a heat exchanger made of copper or copper coating has a high possibility of corrosion and progresses rapidly, there is also a problem such as a decrease in heat exchange capacity and an increase in maintenance and repair costs.

The present invention has been made to solve the above problems, the object of which is to form a silver nano-coating layer on the tube formed of copper, and the fin and drain member formed of aluminum or copper, and at the same time, the heat exchanger (evaporator) of By installing a drying device on one side, condensation or moisture generated in the heat exchanger (evaporator) can be removed, and the dust and contaminants, etc. can be greatly reduced in the heat exchanger. It is to provide an air conditioner to suppress the fouling phenomenon.

The configuration of the present invention for achieving the above object, the heat exchanger is installed in the cooling / heating, air conditioning, power generation, waste heat recovery, etc., the temperature is different from each other, and performs heat exchange between two fluids separated by a solid wall The heat exchanger is characterized in that the silver nano-coating layer formed on the surface of the fin and the tube.

In addition, a drain member for accommodating the heat exchanger to the lower side inside, formed in the lower portion of the heat exchanger, receiving the condensation water generated during the heat exchange; A fin formed at an upper portion of the heat exchanger to discharge heat-exchanged air to the outside; One side of the heat exchanger is characterized in that the air conditioner having a fouling suppression function further added to the drying device.

Hereinafter, with reference to the accompanying drawings the present invention will be described in detail.

Figure 2 is a view showing the configuration of the heat exchanger according to the present invention, as shown in the cooling / heating, air conditioning, power generation, waste heat recovery, etc., the temperature between each other, between the two fluids separated by a solid wall In the heat exchanger 20 which performs heat exchange, the silver nano coating layers 21a, 22a, and 10a are formed on the surfaces of the fins 21 and the pipes 22.

Here, silver has been known for its strong sterilizing power, far-infrared emission, anion emission, antibacterial and antifungal effects, both from East and West.

In addition, silver has approximately 33% higher thermal and electrical conductivity than copper, has excellent electrical resistance of 8.4%, and has a high possibility of corrosion even when contacted with wet air containing salt. low.

However, silver also tends to discolor in general and simple coatings, so it must be coated with nanoparticles so that discoloration does not occur.

In the heat exchanger 20 coated with silver nanoparticles, the contact angle between the water droplets formed during the heat exchange and the surfaces of the fins 21 and the pipes 22 of the heat exchanger 20 is greater than 90 ° to form a rough 140 °. Therefore, by flowing down well without stagnation on the surface of the heat exchanger 20, the heat transfer efficiency is increased.

In addition, the heat exchanger 20 coated with silver nanoparticles reduces the contact surface between the water droplets generated during the heat exchange with the dust by 90% or more, thereby improving the heat transfer efficiency by providing excellent cleaning effect and good air permeability.

As described above, the heat exchanger 20 nano-coated with silver has about 650 kinds of bacteria propagation suppression and sterilization effect such as bacteria, fungi, and Negionella harmful to the human body by antibacterial action. This is generated, the deodorizing action is also performed more powerfully, the air conditioner to which it is applied is discharged more clean air during heat exchange.

 3 is a view schematically showing the internal configuration of the air conditioner according to the present invention. As shown in the drawing, the heat exchanger 20 described above is provided below the air conditioner 100.

In addition, a drain member 10 is disposed below the heat exchanger 20 to receive and drain the condensed water generated during the heat exchange.

An upper portion of the heat exchanger 20 is provided with an air blow fan 30 for discharging the heat-exchanged air to the outside through the discharge grill 40.

In the vicinity of the heat exchanger 20, a drying apparatus 50 for removing condensation and moisture is provided.

In addition, as can be seen in Figure 4, the drain member 10, the same as the heat exchanger 20, the silver nano-coating layer (10a) is formed on the surface, the water-repellent coating layer (10b) over the silver nano-coating layer (10a) Is further formed.

In addition, the drain member 10 is formed to form an inclination to remove the edge so that the condensation water collected by condensation from the heat exchanger 20 is eliminated without stagnation.

The operation of the drying apparatus 50 is performed as shown in the flowchart of FIG. 5.

That is, during operation of the air conditioner 100, if the compressor (not shown) operation is stopped, the operation of the drying apparatus 50 is made while switching to the drying mode, condensation and moisture remaining in the heat exchanger (evaporator) 20 Will be removed quickly. Then, the drying mode is stopped when the compressor is operated, and is operated to cool by heat exchange.

Here, the drying apparatus 50 is composed of an air blower for drying by blowing dry air by the nozzle, it is also possible to adjust the drying time using a timer.

In addition, the drying apparatus 50 may alternatively be configured as a heater using electricity.

Accordingly, the silver nano coating layers 21a and 22a formed on the fin 21 and the tube 22 of the heat exchanger 20 and the drying apparatus 50 installed to remove condensation and moisture generated in the heat exchanger 20. By binding, as well as antibacterial and bactericidal action, significantly suppress the occurrence of fouling.

That is, by the drying device 50, by completely removing condensation and moisture generated in the heat exchanger 20 during operation of the air conditioning equipment, the heat exchanger 20 is always in a dry state, It primarily prevents the habitat environment of various bacteria such as harmful Negionella, mold, and bacteria.

Accordingly, since the heat exchanger 20 is free of condensation, moisture, and the like, particle deposition of dust and contaminants in the room becomes difficult, and fouling phenomenon due to deposition is significantly suppressed, thereby preventing contamination of the heat exchanger 20. It can prevent, the performance degradation of the heat exchanger 20 can be prevented, and the power loss due to the performance degradation can be prevented.

In addition, even if there is a slight moisture remaining in a place located in some corners of the heat exchanger 20, due to the formation of the silver nano-coating layer (21a, 22a), antibacterial and sterilization action is made to prevent the growth of various bacteria can do.

Further, in the present invention, since the coating layer 10b is further formed by the water repellent coating material on the silver nano coating layer 10a, the condensation water due to condensation generated during heat exchange of the heat exchanger 20 is prevented. In case of receiving and draining water, the drainage is done quickly with little residual rate of condensed water. Therefore, the environment where various bacteria can be inhabited is not achieved. do.

As described in detail above, by the silver nano coating layer formed on the heat exchanger and the drain member of the present invention, antibacterial and sterilization of various harmful bacteria such as Negionella bacteria, bacteria and molds, and discharged by blowing as the anion is generated. The air to be cleaned is effective to keep the indoor air in a clean state, and condensation formed on the heat exchanger (evaporator) by forming a drying device on one side of the air conditioner to which the heat exchanger (evaporator) is applied. By removing the moisture, the fouling phenomenon can be suppressed or prevented. Also, the fouling phenomenon can be suppressed or prevented, and therefore, the performance of the heat exchanger can be prevented from being deteriorated and the power loss can be prevented. . In addition, by coating the heat exchanger with silver nanoparticles, the water droplets formed during the heat exchange flows well without stagnation on the surface of the heat exchanger, thereby increasing the heat transfer efficiency. In addition, the heat exchanger coated with the silver nanoparticles of the present invention reduces the contact surface between the dust and the water droplets generated during the heat exchange, so that the air permeability is improved, thereby increasing the heat transfer efficiency.

Claims (5)

In the heat exchanger which is installed in cooling / heating, air conditioning, power generation, waste heat recovery, etc., the heat exchange is performed between two fluids having different temperatures and separated by solid walls, The heat exchanger 20, the heat exchanger for antibacterial / sterilization, characterized in that the silver nano-coating layer (21a, 22a, 10a) formed on the surface of the fin (21) and the pipe (22). A drain member 10 accommodating the heat exchanger 20 according to claim 1 below and formed in a lower portion of the heat exchanger 20 and receiving and condensing water generated during heat exchange; A blower (30) formed at an upper portion of the heat exchanger (20) to discharge heat-exchanged air to the outside; One side of the heat exchanger 20, the air conditioner having an antimicrobial / sterilization and fouling suppression function, characterized in that further added to the drying device (50). The air conditioner according to claim 2, wherein the drying device (50) comprises one of an air blower or a heater using electricity. The air conditioner according to claim 2 or 3, wherein the drying device (50) is operable only when the air conditioner is in a compressor stop mode. The antimicrobial / sterilization and fouling of claim 2, wherein a silver nanocoat layer 10a is formed on the drain member 10, and a water repellent coating layer 10b is further formed on the silver nanocoat layer 10a. Air conditioner with suppression function.

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