KR20220069243A - A Walltype Air Conditioner For Greenhouse - Google Patents

Abstract

The present invention relates to a wall-type greenhouse air conditioner. According to the present invention, the air conditioner is formed with a frame used as a wall of a greenhouse, and thus installation and assembly can be performed with ease and efficient greenhouse space utilization is possible. In addition, the air inside the greenhouse is introduced and circulated with a heat exchange panel portion coated with an antibacterial fabric layer and a hydrophobic coating layer, and thus moisture removal can be performed in the greenhouse and sterilized air can be re-supplied into the greenhouse. The indoor air introduced through an air inlet, first to third inner circulation ports, and an air outlet is circulated in an extended manner in inner circulation and air purification spaces, and thus sufficient sterilization, deodorization, and dehumidification can be performed.

Description

A Walltype Air Conditioner For Greenhouse

The present invention relates to a wall-type air conditioner for a greenhouse, and more particularly, by forming the air conditioner with a frame used as a greenhouse wall, installation and assembly are simple, and the space of the greenhouse can be used efficiently, and an antibacterial fabric layer and By introducing and circulating indoor air in the greenhouse through the heat exchange panel coated with a hydrophobic coating layer, moisture inside the greenhouse can be dehumidified and the antibacterial air can be re-supplied to the interior of the greenhouse. It relates to a wall-type air conditioner for a greenhouse in which indoor air introduced through an outlet is circulated for a long time in an internal circulation space and an air purification space, and sufficient antibacterial, deodorizing and dehumidifying are achieved.

In the case of cultivating crops in the open field, soil quality, region, temperature, season, etc. act as limiting conditions, and only crops that meet the limiting conditions have no choice but to selectively grow. The facility horticultural industry is gradually expanding as a way to expand the selection of crops that can be grown by artificially adjusting natural conditions, such as, and to meet consumer demand throughout the year.

Facilities The horticultural industry limits the space grown in glass greenhouses or plastic houses, and installs air conditioners to artificially control ideal conditions for crop cultivation, such as internal temperature and humidity.

Various types of technologies have been proposed for the winter heating system and summer cooling system to control temperature, but in order to form ideal conditions for crop cultivation, not only temperature but also humidity and internal CO2 are regulated. In addition, it is necessary to be given an antibacterial function, such as removing pathogens that are harmful to crops.

However, humidity control is generally performed by simply opening the door or window of the greenhouse, and as a result, other conditions inside the greenhouse such as temperature change rapidly. In addition, there is a problem in that enormous energy is consumed to adjust the rapidly changed temperature to the original temperature.

And, although the antibacterial function is mentioned in Korean Patent Registration No. 10-2115021, etc., it is difficult to actually apply to a greenhouse using an expensive photocatalyst, and it is necessary to use a light or UV lamp to activate the photocatalyst, making the facility complicated and maintenance cost There is a downside to this rising.

Republic of Korea Patent Publication No. 10-2115021 Republic of Korea Patent Publication No. 10-1578187

An object of the present invention is to form an air conditioner in a frame used as a wall of a greenhouse, so that it is easy to install and assemble in the greenhouse, and it does not occupy a separate space so that the internal space of the greenhouse can be fully utilized. To provide an air conditioning system.

In addition, an object of the present invention is to configure the heat exchange panel part with a panel coated with a hydrophobic coating layer and an antibacterial fabric layer, and by introducing and circulating air containing moisture in the greenhouse indoors into the heat exchange panel part, air harmonized such as dehumidification and antibacterial in the greenhouse To provide a wall-type air conditioner for greenhouses that can be re-supplied to the interior of

In addition, an object of the present invention is to circulate the indoor air introduced into the heat exchange panel part through the air inlet, the first, second, and third internal circulation ports, and the air outlet in the internal circulation space for a long time, so that sufficient dehumidification and antibacterial properties are achieved for a greenhouse. To provide a wall-type air conditioner.

The technical problems to be achieved by the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned can be clearly understood by those of ordinary skill in the art from the description of the present invention.

In order to solve the above problems and achieve the object, the present invention is formed in a frame and circulates air for a long time through a heat exchange panel part coated with a hydrophobic coating layer and an antibacterial fabric layer, so that sufficient dehumidification and antibacterial properties are achieved while efficiently using space. We provide wall-type air conditioners for greenhouses.

Hereinafter, the present specification will be described in more detail.

The present invention is a frame installed as a wall of a greenhouse to separate indoor and outdoor, and an air purification space for purifying indoor air introduced into the frame; a heat exchange panel unit installed in the air purification space inside the frame, a plurality of heat exchange panels coated with a hydrophobic coating layer are spaced apart, and at least one internal circulation space formed between the heat exchange panels is formed; an air inlet communicating with the heat exchange panel unit from the inside of the greenhouse through the frame through the frame so that indoor air is introduced into the heat exchange panel unit; a communication unit including an air outlet that passes through the frame and communicates from the air purification space to the interior of the greenhouse; a temperature control unit attached to one side of the heat exchange panel unit to adjust a temperature of the heat exchange panel unit; a condensed water storage unit formed at a lower end of the heat exchange panel unit to store and discharge condensed water generated from the heat exchange panel unit; and an antibacterial fabric panel installed in the air purification space and installed on one side of the frame to purify the introduced indoor air.

In the present invention, the heat exchange panel is a planar member, an antibacterial fabric layer coated on both sides of the planar member. and a hydrophobic coating layer laminated on the antibacterial fabric layer, and in the heat exchange panel part, as the four heat exchange panels are spaced apart, first, second, and third internal circulation spaces are formed in the order adjacent to the room, and the communication part is the First, second, and third internal circulation ports including the air inlet are formed at each corner of the heat exchange panel part to communicate with each other so that indoor air is introduced into the first, second, and third internal circulation spaces and sequentially circulates, and the air The inlet communicates from the indoor to a third inner circulation space adjacent to the outdoor, the first inner circulation port communicates from the third inner circulation space to a first inner circulation space adjacent to the room, and the second inner circulation port communicates with the first It communicates from the internal circulation space to the second internal circulation space, the third internal circulation port communicates from the second internal circulation space to the air purification space of the frame, and the air outlet communicates from the air purification space to the room. have.

In the present invention, a blower fan is coupled to the air inlet to introduce indoor air into the internal circulation space, and the air outlet is heat exchanged so that the temperature of the purified air passing through the internal circulation space and the air purification space can be raised. groups may be bound.

In the present invention, the temperature control unit may include: a thermoelectric element attached to one side of the heat exchange panel unit in an outdoor direction; and a water cooling tube adjacent to the thermoelectric element, through which water to cool the thermoelectric element flows.

In the present invention, the heat exchange panel unit surrounds the inner circulation space between the heat exchange panels so that air can flow into the inner circulation space, and the lower end is inclined to the center to discharge the condensed water in the inner circulation space to the lower center It may further include a border hem.

According to the wall-type air conditioner for a greenhouse of the present invention, the entire air conditioner is formed in a frame used as a wall of the greenhouse, so that installation and assembly in the greenhouse is simple, and it does not occupy a separate space, thereby reducing the space inside the greenhouse can be fully utilized.

In addition, according to the wall-type air conditioner for a greenhouse of the present invention, in a closed greenhouse structure in which indoor air is recirculated and used, individual heat exchange panels constituting the heat exchange panel are coated with a hydrophobic coating layer and an antibacterial fabric layer to recirculate indoor air. By doing so, harmonized air such as dehumidification and antibacterial can be periodically circulated inside the greenhouse without adding a complicated configuration.

In addition, according to the wall-type air conditioner for a greenhouse of the present invention, the indoor air introduced through the air inlet, the first, second, and third internal circulation ports, and the air outlet is converted into the internal circulation space of the heat exchange panel part and the air purification space of the frame. By circulating for a long time, air with sufficient dehumidification and antibacterial properties can be supplied into the greenhouse.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the detailed description and description of the claims.

1 is a front view schematically showing the main configuration of a wall-type air conditioner for a greenhouse according to the present invention.
FIG. 2 is a cross-sectional view illustrating a wall-type air conditioner for a greenhouse according to the present invention, taken along the line A-A' of FIG. 1 .
3 is a cross-sectional view illustrating a wall-type air conditioner for a greenhouse according to the present invention, taken along the line B-B' of FIG. 1 .
4 is a perspective view illustrating a heat exchange panel in the wall-type air conditioner for a greenhouse according to the present invention.
5 is a conceptual view for explaining an air flow in a heat exchange panel part in the wall-type air conditioner for a greenhouse according to the present invention. (b) is a cross-sectional view taken along line D-D' of FIG. 4 .
6 is a front view showing the heat exchange panels constituting the heat exchange panel unit in the wall-type air conditioner for a greenhouse according to the present invention individually.

The terms used in this specification have been selected as currently widely used general terms as possible while considering the functions in the present invention, but these may vary depending on the intention or precedent of a person skilled in the art, the emergence of new technology, and the like. In addition, in a specific case, there is a term arbitrarily selected by the applicant, and in this case, the meaning will be described in detail in the description of the corresponding invention. Therefore, the term used in the present invention should be defined based on the meaning of the term and the overall content of the present invention, rather than the name of a simple term.

Unless defined otherwise, all terms used herein, including technical and scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning in the context of the related art, and should not be interpreted in an ideal or excessively formal meaning unless explicitly defined in the present application. does not

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. However, the described embodiments of the present invention may be modified in various other forms, and the scope of the present invention is not limited by the embodiments described below. The shapes and sizes of the elements shown in the drawings may be exaggerated for clearer description.

In addition, the term 'wall-type air conditioner for greenhouses' used throughout the specification may be briefly abbreviated as 'air conditioner', etc., and the terms outdoor and indoor used throughout the specification are divided by the boundary of the greenhouse. It should be understood that the description in the specification refers to the outside of the greenhouse and the inside of the greenhouse, even if the greenhouse is not separately mentioned.

On the other hand, the greenhouse in which the present invention is used refers to a glass greenhouse or a plastic house, etc. that limits the crop cultivation space for the facility horticultural industry, as mentioned in the technology that is the background of the invention. It will be clearly understood by those skilled in the art from the description of the following detailed description, that if it is a configuration that limits the space to control, it can be applied to various types of greenhouses.

1 is a front view schematically showing the main configuration of a wall-type air conditioner for a greenhouse according to the present invention, and FIG. 2 is a line A-A' in FIG. 1 in the wall-type air conditioner for a greenhouse according to the present invention. It is a cross-sectional view by cutting the side along the 3 is a cross-sectional view illustrating a wall-type air conditioner for a greenhouse according to the present invention, taken along the line B-B' of FIG. 1 . 4 is a perspective view showing the heat exchange panel unit 20 in the wall-type air conditioner for a greenhouse according to the present invention. 5 is a conceptual view for explaining the air flow in the heat exchange panel unit 20 in the wall-type air conditioner for a greenhouse according to the present invention, and FIG. and FIG. 5(b) is a cross-sectional view taken along line D-D' of FIG. 4 . 6 is a front view of the heat exchange panel 21 constituting the heat exchange panel unit 20 in the wall-type air conditioner for a greenhouse according to the present invention.

The present invention relates to a wall-type air conditioner for a greenhouse that can be compactly installed in a greenhouse, and can supply air in harmony such as dehumidification and antibacterial into the greenhouse, and as shown in FIGS. 1 to 3, a frame (10) , a heat exchange panel unit 20 , a communication unit 30 , a temperature control unit 40 , a condensate storage unit 50 , and an antibacterial fabric panel 60 .

The frame 10 is an air purification space 11 in which a heat exchange panel unit 20, a communication unit 30, a temperature control unit 40, a condensed water storage unit 50, an antibacterial fabric panel 60, etc. to be described later are mounted. It is formed therein to purify the indoor air flowing into the air purification space (11). As described above, the present invention is a configuration applied to a closed-type greenhouse that purifies indoor air and re-supply or recirculate it to the interior of the greenhouse. . However, in order to circulate indoor air for a long time, moisture generated by photosynthesis must be removed so that dew condensation does not occur in the greenhouse, harmful bacteria such as mold do not reproduce, and pests and diseases that occur in the process of crop cultivation must be removed continuously. It is necessary to purify the indoor air, such as sterilization. The present invention dehumidifies the indoor air introduced into the heat exchange panel unit 20, the temperature control unit 40, the antibacterial fabric panel 60, etc. mounted in the air purification space 11 of the frame 10, and performs antibacterial and sterilization treatment Even if outdoor air is not introduced through ventilation, etc., indoor air can be re-supplied or recirculated to be used for a long period of time, so that the conditions for growing crops do not change rapidly, thereby satisfying the growing conditions in the greenhouse with minimal energy. On the other hand, the frame 10 of the present invention is installed as a wall of the greenhouse in the subsequent installation and use process, and serves to distinguish the interior and the interior of the greenhouse. The specific shape may vary depending on the overall shape of the greenhouse, but may be formed in a rectangular parallelepiped shape with a thin thickness so as to be installed on the side wall of the greenhouse in order to be universally applied to various designs and for convenience of assembly later. In this way, the heat exchange panel unit 20, the communication unit 30, the temperature control unit 40, the antibacterial fabric panel 60, etc. in the air purification space 11 inside the frame 10 used as the wall of the greenhouse Since parts for air conditioning are mounted, it does not occupy a separate space in the greenhouse, so the space inside the greenhouse can be fully utilized. And, since the air conditioner is formed in a wall type through the frame 10, a plurality of air conditioners can be stacked to configure the wall of the greenhouse, and thus can be formed in a modular form that is easy to install and assemble. On the other hand, the frame 10 is formed in a closed structure to insulate the indoor and outdoor of the greenhouse, but as will be described later, in order to re-supply or recirculate the air in the room, the air inlet 31 and the air outlet 35 A hole through which the is communicated may be formed. And, in order to introduce light into the room, the frame 10 may have a wide surface made of a light-transmitting surface such as glass or a vinyl sheet.

The heat exchange panel unit 20 not only regulates the temperature of the air introduced through heat exchange, but also controls the humidity so that humidity suitable for crop cultivation is maintained in the interior of the greenhouse, and volatile organic matter so that the crop is not infected by pests, etc. Sterilization and antibacterial functions to remove compounds and the like are performed. The heat exchange panel part 20 is installed or mounted in the air purification space 11 inside the frame 10, and as shown in an enlarged view A of FIG. 5(b), a heat exchange panel coated with a hydrophobic coating layer 24 (21) A plurality of spaced apart arrangement, at least one internal circulation space 26 formed between the heat exchange panels 21 is formed. In this case, the heat exchange panel 21 constituting the heat exchange panel unit 20 generally implements a planar shape in a rectangular shape. Instead, the surface shape may be implemented in various forms. As the heat exchange panel 21 is coated with the hydrophobic coating layer 24 and the internal circulation space 26 is formed between the heat exchange panels 21, excessive moisture in the indoor air circulating in the internal circulation space 26 is absorbed by the hydrophobic coating layer. As it is condensed by (24) and discharged to the condensed water storage unit 50 to be described later, it is possible to prevent condensation in the greenhouse by controlling the humidity in the air, and it is possible to block the environment in which harmful bacteria such as mold grow. In more detail, the heat exchange panel 21 may be coated with an antibacterial fabric layer 23 on both sides of the planar member 22 as a skeleton, and a hydrophobic coating layer 24 may be laminated on the coated antibacterial fabric layer 23 . In this way, when the antibacterial fabric layer 23 is added to the heat exchange panel 21, it is possible to remove excessive moisture in the indoor air circulating to the internal circulation space 26, as well as to prevent volatile organic compounds such as pests and diseases from being antibacterial or sterilized. can

The communication unit 30 communicates with the internal circulation space 26 of the heat exchange panel unit 20 and the air purification space 11 inside the frame 10 so that indoor air is introduced and circulated, and the purified air is re-supplied to the room. In a configuration that preferentially includes an air inlet 31 and an air outlet 35 . The air inlet 31 is configured to introduce indoor air into the heat exchange panel unit 20 , and communicates with the heat exchange panel unit 20 from the inside of the greenhouse through the frame 10 . Through this, indoor air containing excessive moisture and requiring antibacterial or sterilization treatment may be introduced into and circulated in the air conditioner. The air outlet 35 is configured to discharge the purified air to the interior of the greenhouse through the heat exchange panel unit 20 and the air purification space 11, and penetrates the frame 10 from the air purification space 11 to the interior of the greenhouse communicated with Through this, purified air such as dehumidification and antibacterial can be re-supplied to the room, minimizing external ventilation and circulating the indoor air inside the greenhouse for a long time. Additionally, a blower fan 36 may be coupled to the air inlet 31 to forcibly supply air in the greenhouse room requiring purification to the heat exchange panel unit 20, through which the indoor air of the greenhouse is transferred to the heat exchange panel unit ( 20) can be introduced into the internal circulation space 26 to circulate in the air conditioner. And, in the air outlet 35 through which the purified air is re-supplied into the room, the air cooled as it passes through the internal circulation space 26 of the heat exchange panel unit 20 and the air purification space 11 of the frame 10 . The heat exchanger 37 may be coupled to increase the temperature, and through this, the hot and dehumidified air may be re-supplied in the interior of the greenhouse.

In more detail, the heat exchange panel unit 20 may be formed by arranging four heat exchange panels 21 spaced apart from each other, and thus three internal circulation spaces 26 may be formed. For convenience of referring to the internal circulation space 26, the first internal circulation space 26a, the second internal circulation space 26b, and the third internal circulation space 26c are referred to in the order adjacent to the interior of the greenhouse. In addition, for convenience of reference, the heat exchange panel 21 is also a first heat exchange panel 21a, a second heat exchange panel 21b, a third heat exchange panel 21c, and a fourth heat exchange panel 21d in the order adjacent to the interior of the greenhouse. to be referred to as In this case, the first internal circulation port 32, including the air inlet 31, the first internal circulation port 32, the second so that the air is circulated to each internal circulation space 26 with a certain direction and flows into the air purification space 11 The internal circulation port 33 and the third internal circulation port 34 may be formed at each corner of the heat exchange panel unit 20 to communicate. Referring to FIG. 5 , the form of air circulation in the internal circulation space 26 of the heat exchange panel unit 20 and the air purification space 11 of the frame 10 will be described in detail. First, through the air inlet 31 , the interior of the greenhouse The air inlet 31 communicates from the outside to the third internal circulation space 26c so that indoor air requiring purification from the outside flows into the third internal circulation space 26c adjacent to the outdoors. That is, as shown in FIGS. 5 and 6 , the air inlet 31 extends from the indoor frame 10 of the greenhouse to the first heat exchange panel 21a, the second heat exchange panel 21b, and the third heat exchange panel 21c. ) and connected to the third internal circulation space 26c. Next, through the first internal circulation port 32, the first internal circulation port 32 is the third so that the air of the third internal circulation space 26c is circulated to the first internal circulation space 26a adjacent to the room. The internal circulation space 26c and the first internal circulation space 26a are communicated. That is, as shown in FIGS. 5 and 6 , the first internal circulation port 32 is connected to the first internal circulation space 26a by communicating with the third heat exchange panel 21c and the second heat exchange panel 21b. do. Next, through the second internal circulation port 33, the second internal circulation port 33 is a first internal circulation so that the air of the first internal circulation space 26a is circulated to the second internal circulation space 26b. The space 26a communicates with the second internal circulation space 26b. That is, as shown in FIGS. 5 and 6 , the second internal circulation port 33 is connected to the second internal circulation space 26b by communicating with the second heat exchange panel 21b. And, through the third internal circulation port 34, so that the air of the second internal circulation space 26b is circulated to the air purification space 11 inside the frame 10, the third internal circulation port 34 is 2 The internal circulation space (26b) and the air purification space (11) are communicated. That is, as shown in FIGS. 5 and 6 , the third internal circulation port 34 is connected to the air purification space 11 by communicating with the second heat exchange panel 21b and the first heat exchange panel 21a. As such, the air circulated to the air purification space 11 is further purified by performing antibacterial, sterilizing and deodorizing functions by the antibacterial fabric panel 60 of the air purification space 11 to be described later. Finally, the additionally purified air is re-supplied back into the interior of the greenhouse through the air outlet 35, and for this, the air outlet 35 communicates with the indoor frame 10 to connect the air purification space 11 and the greenhouse. Connect the interior. In this way, by forming a plurality of internal circulation spaces 26 and circulating air through various communication units 30 for a long time, the air in the heat exchange panel unit 20 is converted into an antibacterial fabric layer 23 and a hydrophobic coating layer 24 . The coated heat exchange panel 21 and the antibacterial fabric panel 60 to be described later installed in the air purification space 11 collide in large numbers, thereby maximizing the sterilization, deodorization and dehumidification effects. 4 to 6, each position of the communication unit 30 is shown at specific positions of up, down, left, and right, but this is one example, and the position of each of the communication units 30 may be exchanged or changed in various ways. .

And, the heat exchange panel unit 20, the internal air is not cloudy in the designed direction, to prevent leakage, and to discharge the condensed water condensed in the internal circulation space 26, internal circulation as shown in FIG. Surrounding the space 26, the lower end may further include a rim end 25 that slopes to the center. Due to the edge end 25 , the air in the heat exchange panel unit 20 does not leak and can flow in a predetermined direction in the internal circulation space 26 . And, the condensed water in the inner circulation space 26 due to the gradient of the lower edge of the rim is discharged to the center of the lower end, moved to the condensed water storage 50 to be described later, and may be discharged to the outside.

The temperature control unit 40 is configured to adjust the temperature of the air circulating in the heat exchange panel unit 20 , and is attached to one side of the heat exchange panel unit 20 . Specifically, the temperature control unit 40 may include a thermoelectric element 41 and a water cooling tube 42 for cooling the thermoelectric element 41 .

The thermoelectric element 41 may be attached to one side of the side surface of the heat exchange panel unit 20 in the outdoor direction. air can be cooled. Accordingly, since the air circulating in the heat exchange panel unit 20 is cooled and the amount of water vapor that it can contain is reduced, moisture can be more easily condensed on the hydrophobic coating layer 24 of the heat exchange panel 21 . In this way, as well as being able to cool, by heating the air according to the situation, it is possible to adjust the indoor cultivation conditions of the greenhouse.

The water cooling tube 42 is configured to cool the heated thermoelectric element 41 as the thermoelectric element 41 absorbs heat of circulating air, and is adjacent to the thermoelectric element 41 and exchanges heat by heat conduction. . Accordingly, the heat of the thermoelectric element 41 is transferred to the water flowing through the water cooling tube 42 , and the thermoelectric element 41 is cooled while the water flowing through the water cooling tube 42 is heated. The water heated in this way may be supplied to the inside of the greenhouse and used as a configuration to control the temperature conditions of crop cultivation.

The condensed water storage unit 50 is configured to store condensed water generated from the heat exchange panel unit 20 and discharge it to the outside when a predetermined water level is exceeded, and is formed at the lower end of the heat exchange panel unit 20 . Condensate discharge may be configured simply to discharge the contained water by coupling the nozzle to the bottom of the condensate storage unit 50, but although not shown, a manual or automatic valve may be coupled to drain the water.

The antibacterial fabric panel 60 is installed in the air purification space 11 inside the frame 10 and is configured to perform antibacterial, sterilizing and deodorizing functions. The antibacterial fabric panel 60 is coupled to the outdoor side in the air purification space 11 and is installed in close proximity to one surface of the frame 10 inside. As such, as the antibacterial fabric panel 60 is installed in the air purification space 11, the indoor air introduced into the air purification space 11 through the internal circulation space 26 of the heat exchange panel unit 20 is antibacterial, Purify by performing sterilization and deodorization functions.

From the above description, those skilled in the art to which the present invention pertains will understand that the present invention may be implemented in other specific forms without changing the technical spirit or essential characteristics thereof. In this regard, it should be understood that the embodiments described above are illustrative in all respects and not restrictive.

10: frame
11: Air purification space
20: heat exchange panel unit
21: heat exchange panel
21a: first heat exchange panel
21b: second heat exchange panel
21c: third heat exchange panel
21d: fourth heat exchange panel
22: planar member
23: antibacterial fabric layer
24: hydrophobic coating layer
25: border hem
26: internal circulation space
26a: first internal circulation space
26b: second internal circulation space
26c: third internal circulation space
30: communication part
31: air inlet
32: first internal circulation port
33: second internal circulation port
34: third internal circulation port
35: air outlet
36: blow fan
37: heat exchanger
40: temperature control unit
41: thermoelectric element
42: water cooling tube
50: condensate storage unit
60: antibacterial fabric panel

Claims (5)

a frame installed as a wall of a greenhouse to separate indoor and outdoor, and an air purification space for purifying indoor air introduced into the frame;
a heat exchange panel part installed in the air purification space inside the frame, a plurality of heat exchange panels coated with a hydrophobic coating layer are spaced apart, and at least one internal circulation space formed between the heat exchange panels is formed;
an air inlet communicating with the heat exchange panel unit from the inside of the greenhouse through the frame through the frame so that indoor air is introduced into the heat exchange panel unit; a communication unit including an air outlet that passes through the frame and communicates from the air purification space to the interior of the greenhouse;
a temperature control unit attached to one side of the heat exchange panel unit to control a temperature of the heat exchange panel unit;
a condensate storage unit formed at a lower end of the heat exchange panel unit to store and discharge condensed water generated from the heat exchange panel unit; and
Containing, including;
A wall-type air conditioner for greenhouses. The method according to claim 1,
The heat exchange panel is a planar member, an antibacterial fabric layer coated on both sides of the planar member. A hydrophobic coating layer laminated on the antibacterial fabric layer,
In the heat exchange panel unit, as the four heat exchange panels are spaced apart, first, second, and third internal circulation spaces are formed in the order adjacent to the room,
The communication unit communicates by forming first, second, and third internal circulation ports including the air inlet at each corner of the heat exchange panel unit so that indoor air is introduced into the first, second, and third internal circulation spaces and circulates sequentially. and
The air inlet communicates from the indoor to a third inner circulation space adjacent to the outdoor, the first inner circulation port communicates from the third inner circulation space to a first inner circulation space adjacent to the room, and the second inner circulation port is the The first internal circulation space communicates from the second internal circulation space, the third internal circulation port communicates from the second internal circulation space to the air purification space of the frame, and the air outlet communicates from the air purification space to the room. felled,
A wall-type air conditioner for greenhouses. The method according to claim 1,
A blowing fan is coupled to the air inlet to introduce indoor air into the internal circulation space,
A heat exchanger is coupled to the air outlet to increase the temperature of the purified air passing through the internal circulation space and the air purification space,
A wall-type air conditioner for greenhouses. The method according to claim 1,
The temperature control unit,
a thermoelectric element attached to one side of the heat exchange panel in an outdoor direction; and
A water cooling tube adjacent to the thermoelectric element, through which water to cool the thermoelectric element flows, includes;
A wall-type air conditioner for greenhouses. The method according to claim 1,
The heat exchange panel unit,
In order to allow air to flow into the inner circulation space, it surrounds the inner circulation space between the heat exchange panels, and the lower end further includes an edge end that is inclined to the center and discharges the condensed water in the inner circulation space to the center of the lower end,
A wall-type air conditioner for greenhouses.

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