KR20210149475A - Cooling system type vertical air current with total heat exchanger - Google Patents

Abstract

The present invention relates to a vertical air current type cooling system, which can provide cooling and ventilation functions concurrently with single equipment to increase convenience of use and a degree of freedom of a ventilation facility by integrally manufacturing a full heat exchanger and a cooling apparatus; can enhance cleanness, comfortability and quarantine efficiency of indoor air quality by installing the total heat exchanger in the upper part of the cooling apparatus installed to be buried on a ceiling and at the same time forming the total heat exchanger so as to suck internal air and discharge the inner air to the outside while generating cool air using external air without recycling polluted internal air in a room by supplying introduced external air to the cooling apparatus; can rapidly discharge the indoor polluted air to the outside to effectively prevent infection of an infectious disease due to viruses or the like and thus to maximize quarantine efficiency as well as can enhance ventilation efficiency by being formed such that the indoor air current forms a vertical direction; can dramatically solve the problem that the indoor air current is formed in a horizontal direction to cause a high virus infection rate in a prior art; and can further improve the quarantine efficiency and concurrently reduce air pollution by separating a discharge position of internal air from a breathing height of a human body toward an upper side as far as possible to prevent surrounding people from being in contact with emitted internal air.

Description

Cooling system type vertical air current with total heat exchanger

The present invention relates to a vertical air flow type cooling system equipped with a total heat exchanger, and more particularly, a cooling system and a ventilation system are manufactured as an integral part, so that at least one of cold air and outdoor air is introduced into the room from the upper part and at the same time, the bet is sucked from the lower part Then, it is configured to move the inhaled bet to the upper part and discharge it, so that it is possible to provide cooling and ventilation functions simultaneously with a single device, thereby increasing the convenience of use and freedom of ventilation facilities, as well as inducing the indoor airflow in the vertical direction. As the airflow of the conventional air conditioner or ventilation device rotates horizontally, it is possible to dramatically solve the problem of high transmission rate of viruses, etc. It relates to a vertical airflow cooling system equipped with a total heat exchanger that can solve the problems of significantly lowering air cleanliness, comfort, and quarantine efficiency.

Recently, with the development of industry and the development of urban centers, as the living time in indoor spaces increases exponentially compared to the past, cold air flows into indoor spaces using cooling circulation such as air conditioners and air conditioners. The penetration rate of air conditioners to supply air conditioners has increased exponentially.

In general, air conditioners usually consist of a refrigeration cycle of a compressor, a condenser, an expansion valve, and an evaporator, and after suctioning the bet, use the latent heat of evaporation of the refrigerant according to the refrigeration cycle to cool the suctioned bet and supply it to the room. According to the installation method, it is classified into a ceiling type, a wall-mounted type, and a stand type.

Accordingly, the conventional air conditioner has a problem in that indoor cleanliness and comfort are remarkably deteriorated because even if indoor air is polluted or the air quality is poor, because low-quality bets are recycled back into cold air, ventilation to solve these problems occurs. A device or an air purifier is purchased and used separately, but in this method, each device is an independent and separate device, which is cumbersome to control, which reduces the convenience of use, and it is difficult to bet on a subject that is heat-dissipated by the refrigerant of the evaporator. Because it is used as it is, it has a structural limit that cannot solve the essential problem.

Meanwhile, recently, Corona 19, Middle East Respiratory Syndrome (MERS), Severe Acute Respiratory Syndrome (SARS), and avian influenza (AI) are transmitted through human or livestock. As various types of infectious diseases appear, interest in quarantine systems to prevent the spread of infectious diseases is rapidly increasing.

These infectious diseases are spread to people around them through various infection routes, but among them, respiratory infection is the main route.

In particular, when a large number of occupants are concentrated in limited places such as call centers and offices, the spread of the virus causes a large number of confirmed cases to occur.

However, in the conventional air conditioner 1) when the ceiling type, the outlet for supplying cold air is disposed at the top, but as the inlets for sucking the bet are also disposed on the upper part, the cold air supplied through the outlet goes down and then moves and rotates in the horizontal direction 2) In the case of a stand-type or wall-mounted type, the cold air supplied through the outlet moves and rotates horizontally in the room as the outlet and the inlet for supplying cool air are arranged on the side. Then, it has a characteristic that it is sucked through the suction port, and thus, when the conventional air conditioner is operated, the virus and internally polluted air are spread horizontally along the indoor airflow, causing a problem in that the infection rate and transmission rate are rather increased. do.

1 (a) is an exemplary view for explaining an indoor air flow when a conventional ceiling-type air conditioner is installed, (b) is an exemplary view for explaining an indoor air flow when a conventional stand-type air conditioner is installed .

The conventional ceiling-type air conditioner 910 is installed to be embedded in the ceiling forming the indoor space (S), as shown in (a) of FIG. 1 .

In addition, the conventional ceiling air conditioner 910 has a suction unit 911 for absorbing the bet in the center of the front cover, and a discharge for supplying cold air to the indoor space S on the outside of the suction unit 911 of the front cover. A portion 913 is formed.

The conventional ceiling air conditioner 910 has an advantage of high cooling efficiency as cold air is supplied from the upper portion.

The conventional stand-type air conditioner 920 is installed on the floor of the indoor space S, as shown in FIG. 1(b) .

In addition, in the conventional stand-type air conditioner 920, a discharge part 923 for supplying cold air is formed on the upper part of the front cover, and a suction part 921 for absorbing the bet is formed on the front cover or the side cover.

Such a conventional stand-type air conditioner 910 has the advantage of being efficient in a narrow place because installation and inspection are simple.

However, in the conventional ceiling-type air conditioner 910, a discharge unit 913 to which cold air is supplied is installed on the ceiling, but as the suction unit 911 for sucking bet air is installed on the ceiling, the cold air supplied through the discharge unit 913 is installed on the ceiling. After descending, it moves and rotates in the horizontal direction and ascends and descends to have an airflow characteristic that is sucked into the suction unit 911, and the conventional stand-type air conditioner 920 has a discharge port 923 and an intake port 921 for supplying cool air. As it is disposed on the side, the cold air supplied through the outlet 923 moves and rotates in the horizontal direction in the room, and then is sucked in through the inlet 921 .

That is, the conventional air conditioners 910 and 920 generate an internal airflow having a horizontal motion vector regardless of the type of air conditioner. There is a problem in that radio waves are remarkably spread.

In particular, when an infectious disease such as a highly contagious corona virus spreads as in recent times, the horizontal internal airflow formed by the air conditioner shares the air of the occupants' exhaled air, resulting in group infection.

In addition, the conventional air conditioners 910 and 920 have problems in that indoor cleanliness and comfort are remarkably deteriorated because indoor air is polluted or air quality is deteriorated, because low-quality bets are recycled again into cold air.

In Korea Patent Publication No. 10-2018-0083281 (Title of the invention: cooling system using air conditioner and circulation fan), the uniformity of cooling temperature and Although a cooling system capable of saving electricity has been described, in the cooling system, as described above in FIG. 1 , the internal airflow forms a horizontal direction and, at the same time, the motion vector component in the horizontal direction is increased by the blower fans. Therefore, it has the disadvantage that the problem of remarkably lowered quarantine efficiency continues as it is.

The present invention is to solve this problem, and the problem to be solved by the present invention is to provide convenience and ventilation by simultaneously providing cooling and ventilation functions with a single device by manufacturing a heat exchanger and a cooling device in one piece. This is to provide a vertical airflow cooling system that not only increases the degree of freedom of equipment but also reduces the equipment volume, improves space utilization and installation work efficiency, and reduces installation costs.

In addition, another solution to the present invention is to install a total heat exchanger on the upper part of the air conditioner installed to be embedded in the ceiling, and at the same time, the total heat exchanger sucks the bet air and discharges it to the outside. The purpose of this invention is to provide a vertical airflow cooling system that can improve indoor air quality, comfort, and prevention efficiency by using outside air to generate cool air without recycling bets.

In addition, another solution to the present invention is that outdoor air and cold air can be supplied at the same time or any one of outdoor air and cold air can be selectively supplied. This is to provide a vertical airflow cooling system that can increase the airflow and improve the degree of freedom of ventilation facilities.

In addition, another solution to the present invention is that the outlets through which at least one of cold air and outdoor air are introduced are installed to be spaced apart from the ceiling, and at the same time, the horizontal-suction pipe is seated on the floor to form a vertical direction of the airflow in the room, so that ventilation efficiency is achieved. Not only can the indoor airflow be rapidly discharged to the outside, the transmission of infectious diseases such as viruses can be effectively prevented, thereby maximizing the quarantine efficiency. This is to provide a vertical airflow cooling system that can dramatically solve high problems.

In addition, another solution of the present invention is to be installed vertically inside the indoor space (S) and the lower end is horizontally connected to the suction pipe, the upper end penetrates the ceiling and is connected to the suction pipe for the bet vertically - discharging the bet by including the moving pipes This is to provide a vertical airflow cooling system that can further improve quarantine efficiency and reduce air pollution by preventing people from coming into contact with the emitted internal air by separating the location as far upwards from the breathing height of the human body as possible. .

In addition, another solution of the present invention is to discharge the internally polluted air (bet) through the suction holes more quickly and thoroughly to the outside by repeatedly forming suction holes penetrating the inner and outer surfaces of the horizontal-suction pipe in the longitudinal direction. This is to provide a vertical airflow cooling system that can further increase ventilation and quarantine efficiency.

In addition, another solution to the present invention is that the filter installation part is formed on one side of the vertical-moving tube and at the same time the filter part is detachably coupled to the filter installation part of the vertical-moving tube, so that the filter can be replaced without using a separate fastening means. It is to provide a vertical airflow type cooling system that can be replaced quickly and conveniently.

In addition, another solution to the present invention is that the filter installation unit includes a vertical-moving tube in which an opening is formed on the outer circumferential surface of the filter unit, and a cover body that is installed to surround the outer periphery of the vertical-moving tube, and the cover body vertically moves horizontally to the moving tube and An object of the present invention is to provide a vertical airflow cooling system that is rotatably coupled so that the opening is opened or closed according to the horizontal movement of the cover, thereby increasing assembly and work convenience of assembling and disassembling the filter unit.

In addition, another solution to the present invention is that when a plurality of desks are densely located inside the indoor space (S), such as a call center, an office, etc., horizontal-suction pipes are installed on the bottom surface of the indoor space (S) as well as after the desk support plate. By placing it at the end, the vertical airflow phenomenon is further activated to effectively prevent virus transmission among occupants, thereby providing a vertical airflow cooling system that can further improve quarantine efficiency.

The solution of the present invention for solving the above problems is a vertical airflow type cooling system including a cooling device for supplying cold air to the indoor space (S): at least installed on the ceiling to supply outdoor air to the indoor space (S) one or more outlets for outdoor air; at least one cold air outlet installed on the air conditioner or the ceiling to supply cold air generated by the air conditioner to the indoor space (S); At least one suction unit for sucking the air bet of the indoor space (S); a total heat exchanger for supplying the supplied outdoor air to at least one of the air supply outlet and the cooling device, and for discharging the bet air sucked through the suction unit to the outside; and an evaporator for generating cold air by cooling the outside air supplied from the total heat exchanger, and a cooling device for supplying the generated cold air to the cold air outlet.

In addition, in the present invention, the suction part is formed in a cylindrical or polyhedral tubular shape, a gas movement path is formed therein, and suction holes penetrating the inner and outer surfaces are formed at intervals in the longitudinal direction to bet through the suction holes. It is preferable to induce the internal airflow of the indoor space (S) to form a vertical direction by sucking the bet by being seated on the floor surface or indoor structure, and the horizontal-suction tube is seated on the floor surface or indoor structure.

In addition, in the present invention, the vertical airflow cooling system is formed in a cylindrical or polyhedral tubular shape, a gas movement path is formed inside, and the lower end is connected to the horizontal-suction tube, and the upper end is vertically installed so that the upper end is connected to the ceiling. At least one vertical moving pipe for moving the bet sucked by the suction unit to the upper part of the ceiling, the total heat exchanger is installed on the upper part of the ceiling, and the vertical-to the outside by sucking the bet moved by the moving pipe It is preferable to discharge.

In addition, in the present invention, the vertical air flow type cooling system includes: a supply pipe for outdoor air installed between the cooling device and the insulation exchanger to move outside air to the cooling device; At least one supply pipe for outdoor air having one end connected to the supply pipe for outdoor air, the other end being connected to the outlet for outdoor air to discharge outdoor air discharged from the total heat exchanger to the outlet for outdoor air; At least one suction pipe for betting one end connected to the total heat exchanger, the other end being connected to the vertical-moving pipe to move the bet sucked through the vertical-moving pipe to the total heat exchanger; It is preferable to further include at least one cold air supply pipe having one end connected to the air conditioner and the other end connected to the cold air outlet to discharge the cold air generated in the air conditioner to the outlet.

In addition, in the present invention, the vertical airflow cooling system includes: a first inflow switching means installed in the supply pipe for external air to open or close an internal path; It is installed in the air supply wave for the outside air further comprising a second inlet switching means for opening or closing the internal path, the first inflow switching means and the second inflow switching means are open or closed according to external control desirable.

In addition, in the present invention, the vertical-moving tube is preferably coupled to the internal path so that the filter unit is detachably attached.

In addition, in the present invention, the vertical-moving tube has a circular pipe-shaped filter installation portion formed on one side thereof, and the filter installation portion is the vertical-moving tube and has an inner tube having an opening formed on one side, and is installed as if surrounding the outer periphery of the inner tube. It further comprises a hollow cylinder-shaped cover body coupled to the inner tube body so as to be movable up and down and rotatable, wherein the inner tube body has a flange formed on an outer peripheral surface of a point adjacent to the lower end of the opening, at the same height as the lower end of the opening A locking protrusion is formed on the inner circumferential surface to support the filter unit, and a lower end portion is connected to the flange, and a guide protrusion with an upper end disposed at the same height as the upper end of the opening is formed protruding from the outer circumferential surface, from the opening. Spaced apart upward, a fixing protrusion is formed to protrude at a point having the same width as the guide protrusion in the width direction, and the cover body is formed in a hollow cylindrical shape having a length greater than the opening, and is formed outwardly on the inner circumferential surface to form an upper end and A sliding groove extending to the lower end is formed, and is formed outwardly on the inner peripheral surface adjacent to the upper end and extended in the width direction, the end of which is connected to the sliding groove. is the same as the length of the cover body, and the cover body is inserted with the guide protrusion into the sliding groove to move up and down along the guide protrusion, and closes the opening of the inner pipe body when moving downward, When moving upward, the fixing protrusion is inserted while the insertion of the guide protrusion is released into the sliding groove, and when the fixing groove is rotated at the same height as the fixing protrusion, the fixing protrusion is inserted into the fixing groove It is preferable that the state moved upward is fixed.

In addition, in the present invention, the horizontal-suction pipe is preferably seated at a point adjacent to the rear end of the support plate on which the article is seated when the structure of the indoor space (S) is a desk.

According to the present invention having the above problems and solutions, the problem to be solved by the present invention is to increase the convenience of use and the degree of freedom of ventilation facilities by simultaneously providing cooling and ventilation functions with a single device by manufacturing a heat exchanger and a cooling device in one piece. Not only that, but the equipment volume is reduced, so space utilization and efficiency of installation work are improved, and installation costs are reduced.

In addition, according to the present invention, the total heat exchanger is installed on the upper part of the air conditioner installed to be embedded in the ceiling, and the total heat exchanger sucks the bet air and discharges it to the outside. It is configured to generate cold air by utilizing outside air without doing so, so that cleanliness, comfort, and prevention efficiency of indoor air quality can be improved.

In addition, according to the present invention, since outdoor air and cold air can be supplied at the same time or either one of outdoor air and cold air can be selectively supplied, outdoor air and cold air can be appropriately selected in response to climate change, thereby increasing convenience and efficiency of use. , the degree of freedom of ventilation equipment can be improved.

In addition, according to the present invention, the outlets through which at least one or more of cold air and outside air are introduced are installed to be spaced apart from the ceiling, and at the same time, the horizontal-suction pipe is seated on the floor to form a vertical direction of the air flow in the room, so that ventilation efficiency can be increased. In addition, it is possible to maximize the quarantine efficiency by effectively preventing the transmission of infectious diseases such as viruses by quickly discharging indoor polluted air to the outside. can be solved with

In addition, according to the present invention, it is installed vertically inside the indoor space (S) and the lower end is connected to the horizontal-suction pipe, and the upper end penetrates the ceiling and is connected to the suction pipe for the bet vertically-by including the moving pipes, the discharge position of the bet is set by the human body. It is possible to further improve quarantine efficiency and reduce air pollution at the same time by preventing people from coming into contact with the emitted internal air by separating it upward as much as possible from the breathing height of the patient.

In addition, according to the present invention, the suction holes penetrating the inner and outer surfaces of the horizontal-suction pipe are repeatedly formed in the longitudinal direction, so that the internally polluted air (bet) is more rapidly and thoroughly discharged to the outside through the suction holes, thereby providing ventilation and prevention efficiency can be further increased.

In addition, according to the present invention, the filter installation part is formed on one side of the vertical-moving tube and at the same time the filter part is detachably coupled to the filter installation part of the vertical-moving tube, so that the filter can be replaced without using a separate fastening means, so filter replacement work is convenient and is done quickly.

In addition, according to the present invention, the filter installation unit includes a vertical-moving tube in which an opening is formed on the outer circumferential surface of the filter unit, and a cover body installed to surround the outer periphery of the vertical-moving tube, wherein the cover body is horizontally moved and rotatably coupled to the vertical-moving tube. As a result, the opening is opened or closed according to the horizontal movement of the cover, thereby further enhancing the assembly and work convenience of assembling and disassembling the filter unit.

In addition, according to the present invention, when a plurality of desks are concentrated inside the indoor space (S), such as a call center, an office, etc. By further activating the vertical airflow phenomenon, it is possible to effectively prevent the spread of the virus among occupants, thereby further improving the quarantine efficiency.

1 (a) is an exemplary view for explaining an indoor air flow when a conventional ceiling-type air conditioner is installed, (b) is an exemplary diagram for explaining an indoor air flow when a conventional stand-type air conditioner is installed .
2 is a block diagram showing a vertical airflow cooling system according to an embodiment of the present invention.
3 is a side view of FIG. 2 ;
FIG. 4 is a plan view of FIG. 2 .
FIG. 5 is a conceptual diagram for explaining FIG. 2 .
6 is a block diagram showing the air conditioner and total heat exchanger of FIG. 2 .
7 is a conceptual diagram illustrating FIG. 6 .
FIG. 8 is a perspective view showing the horizontal-suction pipe of FIG. 2 .
FIG. 9 is a perspective view showing the vertical-moving tube of FIG. 2 .
10 is an enlarged perspective view of the filter installation part of FIG.
11 is a perspective view illustrating a state in which the cover body of FIG. 10 is moved upward.
12 is an exploded perspective view of FIG. 10 .
13 is a perspective view showing the inner tube of FIG. 10 .
Fig. 14 is a perspective view showing the cover body of Fig. 10;
15 is a cross-sectional view of FIG. 14 .
FIG. 16 is an exemplary view for explaining an operation process of the cover body of FIG. 14 .
17 is an exemplary view for explaining the inner circumferential surface of the cover body and the inclined surface of the inner tube body of FIG. 10 .
18 is an exemplary view showing a state in which the horizontal suction tube of the present invention is installed on a desk.

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings.

2 is a block diagram showing a vertical airflow cooling system according to an embodiment of the present invention, FIG. 3 is a side view of FIG. 2 , FIG. 4 is a plan view of FIG. 2 , and FIG. 5 is a conceptual diagram for explaining FIG.

In the vertical airflow cooling system (1) according to an embodiment of the present invention, 1) the thermoelectric exchanger and the cooling device are integrally manufactured, so that cooling and ventilation functions can be provided simultaneously with a single device, and 2) the cooling device is introduced through the total heat exchanger. The indoor air quality is improved by not recycling polluted indoor air by utilizing the outside air as the cold air of the air conditioner, and 3) the indoor space (S) airflow is in the vertical direction to increase the infectivity. It is possible to dramatically prevent the transmission of diseases, and 4) the filter unit 20 is configured to be detachably attached to the vertical-moving tube 7 so that the filter replacement can be performed quickly and conveniently.

In addition, the vertical airflow cooling system 1 of the present invention is installed to be embedded in the ceiling 22 of the indoor space S, as shown in FIGS. 2 to 5 , to cool the outdoor air supplied from the total heat exchanger 3 to be described later. A cooling device (4) for supplying to the indoor space (S), a total heat exchanger (3) installed in conjunction with the cooling device (4) and supplying the introduced outdoor air to the cooling device (4), and an indoor space (S) Outlet outlets 8 for outdoor air installed to be spaced apart from the ceiling 22 of ) installed to be spaced apart from the air conditioner 4 and supplying the cold air discharged from the air conditioner 4 to the indoor space S, and the cold air discharge units 9, which are horizontally seated on the floor surface 21 of the indoor space S, Horizontal-suction pipes (5) for sucking the bet (room air), and the horizontal-consisting of vertical-moving pipes (7) connected to the suction pipes (5).

At this time, for convenience of explanation, in FIGS. 2 to 5 , the cooling device 4 discharges cold air into the indoor space through the cooling air outlets 9 as an example. However, the cooling device 4 is a conventional ceiling-type air conditioner. It goes without saying that it can be installed to be embedded in the ceiling 22 and supply cold air through the outlets of the front cover. Any one of the methods using these or a mixture thereof may be applied.

At this time, in FIGS. 2 to 5, for convenience of explanation, the present invention has been described as being installed in the indoor space (S) of a single-story single structure, but the present invention can be applied to multi-story structures such as apartments and buildings, When applied to the structure, the air conditioner (4) and the total heat exchanger (3) are installed in the duct space of the ceiling.

Also, although not shown in the drawings, the air conditioner 4 has an outdoor unit installed outside and is connected to the outdoor unit and a refrigerant pipe (not shown) through which the refrigerant circulates.

In addition, the indoor space (S) of the present invention means a closed place surrounded by the ceiling 22, the floor surface 21, and the side walls 23, the ceiling 22 of the indoor space (S) outside the indoor air A plurality of outlet ports 8 for outdoor air supplying outdoor air to the space S and outlet ports 9 for cold air supplying cold air to the indoor space S are provided. Such an indoor space (S) can be applied to a variety of enclosed places such as residential spaces, classrooms, gyms, outdoor waiting boxes, offices, and the like.

FIG. 6 is a block diagram illustrating the air conditioner and total heat exchanger of FIG. 2 , and FIG. 7 is a conceptual diagram illustrating FIG. 6 .

The total heat exchanger 3 is a device for heat-exchanging the sucked bet and the introduced outside air, and then discharging the bet to the outside, and supplying the introduced outside air to the cooling device 4 and the outlets 8 for outside air.

At this time, the total heat exchanger (3) is connected to the cooling device (4) and the external air supply pipe (19) to supply the outside air to the cooling device (4).

The cooling device 4 is a device that cools the outside air supplied from the total heat exchanger 3 using the evaporator 45 to generate cool air, and then supplies the generated cold air to the cold air outlets 9 .

As shown in FIGS. 6 and 7 , the cooling device 4 includes a housing 41 , a cooling fan 43 , and an evaporator 45 .

The housing 41 has a housing shape in which a space is formed therein, a first flow path 48 through which outside air is introduced is formed on the upper surface, and a cold air exhaust hole through which the cold air generated by the evaporator 45 is discharged on the lower surface. (49) is formed.

In addition, the cold air supply pipe 13 for cold air is connected to the cold air discharge hole 49 of the housing 41 . At this time, the cold air supply pipe 13 is 1) if the cooling device 4 is installed on the upper part of the ceiling, it is made in plurality in correspondence to the quantity of the cold air outlets 9, so that the end is at the cold air outlets 9. Each may be configured to be connected, and 2) If the air conditioner 4 is installed to be embedded in the ceiling, the end may be configured to be connected to the outlet of the front cover of the housing 41 .

In addition, at this time, the first flow path 48 of the housing 41 is provided with a supply pipe 19 for external air, which will be described later, so that the cooling device 4 receives external air from the total heat exchanger 3 through the supply pipe 19 for external air, The supplied external air is cooled through the evaporator 45 to generate cold air.

In addition, the second flow pipe 49 of the housing 41 is connected to each of the cold air supply pipes 13 to be described later, so that the cooling device 4 is connected to the second flow path pipe 49 -> cold air supply pipe 13. It is possible to supply cold air to the indoor space (S) through the outlets (9) for cold air -> cold air.

The cooling fan 43 is installed in a position adjacent to the first flow path 48 of the housing 41 , is installed on the upper portion of the evaporator 45 , and the outside air introduced through the first flow path 48 is directed to the evaporator 45 . It is a device that generates wind power to move.

The evaporator 45 is an element constituting a refrigeration cycle of a general air conditioner together with a compressor, a condenser, and an expansion valve, and is a cooling fan using latent heat of evaporation of the refrigerant by evaporating the liquid refrigerant expanded by the expansion valve (not shown). (43) to cool the moving outside air.

Since the configuration and operation method of the evaporator 45 is a technique commonly used in a cooling device, a detailed description thereof will be omitted.

In addition, the cold air generated by the evaporator 45 moves to the second flow path pipe 49 by the cooling fan 43 , and the cold air supply pipes 13 are connected to the second flow path pipe 49 , respectively, and the cold air The air supply pipes 13 are connected to the cold air outlets 9 to supply cold air to the indoor space (S).

At this time, in the present invention, for convenience of explanation, it is assumed that the cooling device 4 discharges cold air into the indoor space through the second flow pipe 49 , the cold air supply pipes 13 , and the cold air outlets 9 . However, it goes without saying that the air conditioner 4 may be installed to be embedded in the ceiling 22 like a conventional ceiling air conditioner and supply cold air through the outlets of the front cover, and such air conditioner 4 The cold air supply method of the present invention can be applied to any one or a mixture of the method using the ceiling outlet and the conventional front cover method of the present invention.

Looking at the total heat exchanger 3 again with reference to FIGS. 6 and 7 , the total heat exchanger 3 is installed on the upper part of the cooling device 4 to introduce outdoor air and at the same time suck the bet, and then It is a device for discharging the bet to the outside by heat-exchanging the bet, and supplying the outside air to at least one of the air conditioner 4 and the air supply pipe 12 for outside air.

At this time, in the present invention, for convenience of explanation, the structure and shape of the total heat exchanger 3 have been described as an example of FIG. 6 , but the structure and shape of the total heat exchanger 3 is not limited to FIG. 6 , and various known structures and It can be configured in a shape.

The total heat exchanger 3 includes a housing 31 , a heat exchange means 32 , an air supply fan 313 , and an exhaust fan 323 .

The housing 31 is formed as an enclosure having a space therein.

In addition, the housing 31 has an air supply inlet hole 311 and an exhaust discharge hole 321 formed on one side, and an air supply exhaust hole 312 and an exhaust inlet hole 322 are formed on the other side.

At this time, a supply air passage 310, which is a path through which the introduced outside air moves, is formed between the supply air inlet hole 311 and the air supply discharge hole 312, and the supply air passage 310 at a point adjacent to the supply air outlet hole 312 is provided with air supply. A fan 313 is installed.

In addition, a supply pipe 19 for outside air is installed in the supply/discharge hole 312 of the housing 31, so that the outside air introduced through the total heat exchanger 3 is supplied to the cooling device 4 through the supply pipe 19 for outside air. .

At this time, the cold air supply pipe 13 is coupled to the external air supply pipe 19 , respectively, and ends of the cold air supply pipes 13 are respectively connected to the outlets 8 .

In addition, the first inflow switching means 191 for opening or closing the internal path is installed on one side of the supply pipe 19 for outside air connected between the cooling device 4 and the total heat exchanger 3, so that the vertical air flow type cooling system of the present invention is installed. In (1), the cooling and ventilation functions can be provided simultaneously or only the ventilation function can be provided depending on whether the first inflow switching means 191 is opened or closed.

In addition, the second inflow switching means 121 for opening or closing the internal path is installed on one side of each of the external air supply pipes 12, so that the vertical airflow cooling system 1 of the present invention is a second inflow switching means 121 Depending on whether the air conditioner is opened or closed, it is possible to provide a cooling and ventilation function at the same time or only a cooling function.

That is, the user controls the opening/closing state of the first and second inflow switching means 191 and 121 through a remote controller or operation panel to select one of 1) a single cooling function, 2) a single ventilation function, and 3) a combined cooling and ventilation function. Because any one can be selected and used, the convenience of use and the degree of freedom of the ventilation system are increased.

In addition, in the present invention, as four outlets for outdoor air 8 and outlets 9 for cold air of the ceiling 22 are installed, respectively, the outlets for outdoor air 8 and outlets for cold air 9 are connected one-to-one. The quantity of the supply pipes 12 for outdoor air and the supply pipes 13 for cold air has also been described as an example of 4, respectively, but their quantity is not limited thereto, and consists of 1 to 3 or 5 or more. can be At this time, it is natural that the cold air outlets 9 and cold air supply pipes 13 may not be separately installed when the cooling device is operated only by the cold air supply method through the front cover.

That is, in the total heat exchanger 3, the outside air introduced through the supply air inlet hole 311 according to the air flow formed by the air supply fan 313 follows the supply air passage 310 1) Supply air exhaust hole 312 -> For outdoor air It is supplied to the cooling device 4 through the supply pipe 19, or 2) the supply air outlet hole 312 -> the outdoor air supply pipe 19 -> the outdoor air supply pipes 12 -> the outdoor air outlets 8 It is supplied to the indoor space (S) through the

Also, between the exhaust inlet hole 322 and the exhaust outlet hole 321 of the housing 31, an exhaust passage 320, which is a path for the introduced bet air, is formed, and an exhaust passage at a point adjacent to the exhaust outlet 321. An exhaust fan 323 is installed on the 320 .

In addition, suction pipes 11 for betting are connected to the exhaust inlet hole 322 of the housing 31, and one end of the suction pipes 11 for betting is connected to the exhaust inlet hole 322 of the housing 31, the other The ends are connected to each of the vertical-moving tubes 7 .

In addition, in the present invention, as the vertical-moving tube 7 is installed four, the vertical-moving tube 7 and the one-to-one connected suction pipe 11 have been described as an example that the number of suction pipes 11 is also four, but the vertical-moving tube (7) and the number of suction pipes 11 for betting is not limited thereto, and may consist of 1 to 3 or 5 or more.

That is, the total heat exchanger 3 according to the air flow formed by the exhaust fan 323 is vertical-moving pipes 7 -> suction pipes 11 for betting -> exhaust inlet hole 322 -> exhaust passage 320 ) -> The bet is discharged to the outside through the exhaust discharge hole 321.

The heat exchange means 32 is installed inside the housing 31, between the exhaust flow path 320 and the supply air flow path 310, and the outside air passing through the supply air flow path 310 and the exhaust flow path 320 passing through the bet By transferring the heat absorbed from one side to the other side and performing heat exchange for both direct heat and latent heat, it is possible to increase the exhaust heat recovery efficiency according to ventilation and reduce energy loss for heating and cooling.

The outdoor air outlets 8 are installed to be embedded in the ceiling 22 of the indoor space S, and are connected to the outdoor air supply pipes 12, respectively, and the outdoor air introduced through the total heat exchanger 3 is installed in the indoor space S ) as a means of supply.

The cold air outlets 9 are installed to be buried in the ceiling 22 of the indoor space S, and are respectively connected to the cold air supply pipes 13 for cooling air introduced through the air conditioner 4 to the indoor space (S). ) as a means of supply.

FIG. 8 is a perspective view showing the horizontal-suction pipe of FIG. 2 .

The horizontal-suction pipe 5 is horizontally seated on the floor surface 21 of the indoor space S, and in detail, it is preferable to be installed on each side of the floor surface 21 . At this time, in the present invention, for convenience of explanation, the horizontal-suction pipe 5 has been described as being seated on the bottom surface 21 as an example, but the horizontal-suction pipe 5 is seated on an indoor structure (desk, table, etc.) It may be configured to rapidly inhale the air expelled due to the user's inhalation.

In addition, the horizontal-suction pipe 5 is formed in the shape of a long rod in which the gas movement path 50 is formed, as shown in FIG. 8 .

In addition, the horizontal-suction pipe 5 is formed so that the suction holes 51 through which the bet is introduced through the inner and outer peripheral surfaces are repeatedly formed in the longitudinal direction to suck the bet in the indoor space (S), and the airflow in the vertical direction to the indoor space (S) By forming a ventilator, it is possible to quickly discharge indoor polluted air to the outside, thereby effectively preventing the spread of infectious diseases by minimizing contact with occupants, as well as a conventional ventilation device that moves the internal air in the horizontal direction and By rotating it, it can dramatically solve the problem of being vulnerable to virus propagation.

This horizontal-suction pipe 5 has both ends open and is connected to an adjacent horizontal-suction pipe, or it can be connected to the vertical-moving pipe 7 with both ends closed.

FIG. 9 is a perspective view showing the vertical-moving tube of FIG. 2 .

The vertical-moving tube 7 is installed vertically in the indoor space S, and in detail, it is preferable to be installed at each corner of the indoor space S so as not to obstruct the movement of occupants.

In addition, the vertical-moving pipe 7 has the lower end connected to the horizontal-suction pipe 5, and the upper end protrudes upward through the ceiling 22 and is connected to the suction pipe 11 for betting of the total heat exchanger 3 horizontally- It provides a path for moving the bet sucked through the suction pipe (5) to the suction pipe (11) for betting.

In addition, the vertical-moving tube 7 is formed in the shape of a long-length pipe in which a path 71 through which the bet moves is formed, as shown in FIG. 9 .

In addition, a filter installation part 70 is formed at an intermediate point in the longitudinal direction of the vertical-moving tube 7 , and the filter part 20 is detachably coupled to the filter installation part 70 .

As described above, in the vertical airflow cooling system 1 of the present invention, 1) cold air outlets 9 and outdoor air outlets 8 for supplying cold air and outdoor air to the indoor space (S) are installed on the ceiling, and the bet air is sucked in. The horizontal-suction pipes 5 are configured to be installed on the floor surface, thereby inducing the formation of airflow in the vertical direction of the indoor space (S) and quickly discharging the bet to the outside, thereby minimizing contact with occupants. By effectively preventing the spread of infectious diseases such as viruses in the indoor space (S), it is possible to purify the indoor air quality, thereby increasing the air cleanliness, comfort and ventilation efficiency, and at the same time maximizing the quarantine efficiency.

In addition, the vertical airflow cooling system 1 does not directly discharge the bet sucked through the horizontal-suction pipes 5 to the outside through the side wall, but moves it upward through the vertical-moving pipes 7 and then discharges it from the top. By being configured, the position at which the bet is discharged can be spaced upward as far as possible from the height of the area where the person breathes, and accordingly, the indoor space (S) and the external person adjacent to it are prevented from coming into contact with the emitted internal polluted air. It is possible to further prevent unnecessary transmission of infectious diseases and reduce air pollution at the same time.

10 is an enlarged perspective view of the filter installation part of FIG. 9 , FIG. 11 is a perspective view illustrating a state in which the cover body of FIG. 10 is moved upward, and FIG. 12 is an exploded perspective view of FIG. 10 .

The filter installation unit 70 of FIGS. 10 to 12 is a vertical-moving tube (hereinafter referred to as an inner tube) 710 formed at a midpoint of the aforementioned vertical-moving tube 7 of FIG. 9, and the outer side of the inner tube 710 It consists of a cover body 720 installed to surround the , and a filter unit 20 inserted into the opening 711 of the inner tube body 710 and installed in the inner space of the inner tube body 710 .

The cover body 720 is installed to surround the outer periphery on the inner tube body 710 , and is coupled to the inner tube body 710 to be vertically movable and rotatable.

In addition, the filter unit 20 is inserted through the opening 711 of the inner tube body 710 of the filter installation unit 70 , so that the filter unit 20 is installed in the inner space of the inner tube body 710 .

13 is a perspective view showing the inner tube of FIG. 10 .

As shown in FIG. 13 , the inner tube body 710 has an opening 711 having a predetermined length and area through which the filter unit 20 passes. At this time, the opening 711 is formed in a size cut in half by the cross section of the vertical-moving tube 7 .

In addition, the filter unit 20 inserted through the opening 711 is installed into the inner space corresponding to the opening 711 of the inner tube body 710, so that the filter unit 20 is connected to the inner tube body through the opening 711. 710) and detachable.

Also, although not shown in the drawings, a locking jaw (not shown) is formed to protrude inwardly on an inner peripheral surface of the same height as the lower end of the opening 711 of the inner tube body 710 , and the locking jaw is an arc of the inner peripheral surface of the inner tube body 710 . By being formed to extend along the support the filter unit 20 inserted into the inner tube body (710).

At this time, the filter unit 20 of the present invention has an outer diameter equal to the inner diameter of the inner tube body 710 , but is formed in a cylindrical shape having a finely smaller length than the opening 711 , and various types of known filters may be applied. , it is preferably composed of a three-stage filter of pre-dust collection-hepa.

In addition, on the outer peripheral surface adjacent to the opening 711 of the inner tube body 710 in the width direction, a guide protrusion 713 protruding from the outer peripheral surface and extending in the longitudinal direction is formed to protrude.

At this time, the upper end of the guide protrusion 713 is formed at the same height as the upper end of the opening 711 of the inner tube body 710 , and the lower end is disposed below the lower end of the opening 711 . That is, the guide protrusion 713 is formed to have a longer length than the opening 711 .

In addition, a flange 714 protruding outward from the outer circumferential surface and extending along a circular arc is formed on the outer circumferential surface of the inner tube body 710 . At this time, the upper surface of the flange 714 is formed to be in contact with the lower end of the guide protrusion 713 , and when assembling, the lower end of the cover body 720 is in contact with the upper surface to support the cover body 720 .

In addition, a fixing protrusion 713 is formed to protrude from the outer peripheral surface of the outer peripheral surface of the point spaced upward from the opening 711 of the inner tube body 710 . At this time, the fixing protrusion 713 is formed at a point spaced upward from the guide protrusion 713 of the inner tube body 710 , and is formed at the same position in the width direction as the guide protrusion 713 .

At this time, the separation distance from the upper end of the fixing protrusion 713 to the upper end of the guide protrusion 712 is the same as or slightly smaller than the length of the cover body 720 of FIG. 14 to be described later.

14 is a perspective view showing the cover body of FIG. 10 , FIG. 15 is a cross-sectional view of FIG. 14 , and FIG. 16 is an exemplary view for explaining an operation process of the cover body of FIG. 14 .

14 and 15, the cover body 720 has an inner diameter equal to the outer diameter of the inner tube body 710, but is formed in a hollow pipe shape with a length longer than the opening 711 of the inner tube body 710, Doedoe coupled to the outside of the inner tube body 710, is coupled to the inner tube body 710 so as to be vertically movable and rotatable.

In addition, a linear sliding groove 721 is formed on the inner circumferential surface of the cover body 720 to the outside as the inner circumferential surface and extends to the upper end and the lower end. At this time, by inserting the guide protrusion 713 of the inner tube body 710 into the sliding groove 721 , the cover body 720 is movable in a straight direction along the guide protrusion 713 .

In addition, the length of the sliding groove 721 of the cover body 720 is formed to a predetermined length greater than the distance between the guide protrusion 712 and the fixing protrusion 713 of the inner tube body 710 .

In addition, on the inner peripheral surface adjacent to the upper end of the cover body 720 , a fixing groove 722 that is formed outwardly on the inner peripheral surface and extends in an arc direction is formed, and the fixing groove 722 has an end connected to the sliding groove 721 .

When the cover body 720 moves downward along the inner tube body 710, as shown in Fig. 16 (a), the lower end is in contact with the flange 714 of the inner tube body 710, but the upper end is the inner tube body ( By being disposed above the opening 711 of the 710 , the opening of the inner tube body 710 is sealed.

When a force is applied to the cover body 720 upward in this state, the cover body 720 moves upward along the guide protrusion 712, and when the upward movement continues, as shown in (b) of FIG. Similarly, the upper end of the guide protrusion 712 of the inner tube body 710 is disposed at the lower end of the sliding groove 721 of the cover body 720 and the inner tube body 710 into the sliding groove 721 of the cover body 20 at the same time. of the fixing protrusion 713 is inserted.

At this time, when the cover body 720 is moved upward a predetermined amount, as shown in FIG. ), the fixing protrusion 713 is positioned at the position of the fixing groove 722 , and the opening 711 of the inner tube body 710 is opened to the outside.

When the cover body 720 is rotated in this state, as shown in FIG. 16 (d), the fixing protrusion 713 of the inner tube body 710 is inserted into the fixing groove 722 of the cover body 720 to cover the cover. It is possible to fix the sieve 720 .

That is, the user can fix the cover body 720 by moving the cover body 720 upward and then rotating the cover body 720, and in this state, the filter unit ( 20) can be replaced and inspected quickly and conveniently.

In addition, the filter installation unit 70 of the present invention has the same characteristics as in FIG. 17 .

17 is an exemplary view for explaining the inner circumferential surface of the cover body and the inclined surface of the inner tube body of FIG. 10 .

The inner tube body 710 of the filter installation part 70 of the present invention is inclined so that the outer peripheral surface from the point where the flange 714 is installed to the upper end becomes smaller from the lower part to the upper part.

At this time, although not shown in the drawings, a region (not shown) for returning the currently reduced outer diameter to the original outer diameter is formed at the upper end of the inner tube body 710 so as to address the vertical-moving tube 7 .

The inner circumferential surface of the cover body 720 is inclined to correspond to the outer circumferential surface of the inner tube body 710 so that the inner diameter decreases from the bottom to the top.

At this time, the inner diameter of the cover body 720 is configured to have the same size as the outer diameter of the inner tube body 710 when it moves to the bottom and is seated on the flange 714, as shown in FIG. 17 (a). .

That is, when the cover body 720 receives a force upward in a state of being seated on the flange 714 as shown in FIG. The movement is made smoothly, and it is fixed by the fixing protrusion 713 to maintain the upwardly moved state without free fall.

In addition, when the cover body 720 moves downward to move the inner tube body 710 in which the opening 711 is formed, the interval between the inner circumferential surface and the outer circumferential surface of the inner tube body 710 becomes narrower, and in the lowermost section, the inner circumferential surface is the inner tube body The opening of the inner tube body 710 is sealed and sealed by the cover body 720 by coming in contact with the outer peripheral surface of the 710 and moving downward in an interference fit manner, and thus the contaminated air in the room moving upward is leaked to the outside. It is not thoroughly moved to the suction pipe 11 for betting.

18 is an exemplary view showing a state in which the horizontal suction tube of the present invention is installed on a desk.

The horizontal suction pipe 5 of the present invention is, as shown in FIG. 18, when the indoor space S is an environment in which a plurality of desks 400 are dense, such as a call center, an office, etc. In consideration of the working characteristics of the desk worker By installing it on the top surface adjacent to the rear end of the support plate 410 of the desk 400 as well as the bottom surface of the indoor space (S), the vertical airflow phenomenon is further activated, and the introduced outside air passes through the desk worker's breathing area and then is quickly sucked in. and, accordingly, it is possible to more effectively prevent the spread of infectious diseases such as viruses, thereby increasing ventilation and quarantine efficiency.

When the horizontal-suction pipe 5 is installed on the desk 400, both ends of the horizontal-suction pipe 5 may be connected to the other horizontal suction pipe or may be connected to the vertical-moving pipe 7 in a sealed state.

As described above, in the vertical airflow cooling system 1, which is an embodiment of the present invention, since the heat exchanger and the cooling device are integrally manufactured, it is possible to simultaneously provide cooling and ventilation functions with a single device, thereby increasing the convenience of use and the degree of freedom of ventilation facilities. In addition, as the equipment volume is reduced, the space utilization and the efficiency of the installation work are improved, and the installation cost is reduced.

In addition, in the vertical airflow cooling system (1) of the present invention, a total heat exchanger is installed on the upper part of the cooling device installed to be embedded in the ceiling, and at the same time, the total heat exchanger sucks in air and discharges it to the outside, but the introduced outside air is supplied to the cooling device. Therefore, it is possible to increase the cleanliness, comfort and quarantine efficiency of indoor air quality by using outdoor air to generate cold air without recycling indoor polluted air.

In addition, since the vertical airflow cooling system 1 of the present invention can supply outdoor air and cold air at the same time or selectively supply any one of outdoor air and cold air, outdoor air and cold air can be appropriately selected in response to climate change. Convenience and efficiency can be increased, and the degree of freedom of ventilation equipment can be improved.

In addition, in the vertical airflow cooling system (1) of the present invention, the outlets through which at least one of cold air and outside air are introduced are installed to be spaced apart from the ceiling, and at the same time, the horizontal-suction pipe is seated on the floor so that the airflow in the room forms a vertical direction. As a result, not only can the ventilation efficiency be increased, but also the indoor airflow can be quickly discharged to the outside to effectively prevent the transmission of infectious diseases such as viruses, thereby maximizing the quarantine efficiency. It will be possible to dramatically solve the problem of high transmission rate.

In addition, the vertical airflow cooling system (1) of the present invention is installed vertically inside the indoor space (S) and the lower end is connected to the horizontal-suction pipe, the upper end penetrates the ceiling and is connected to the suction pipe for betting. By doing this, the discharge position of the bet is spaced upward from the breathing height of the human body as much as possible to prevent people around from coming into contact with the emitted internal air, thereby further improving quarantine efficiency and reducing air pollution.

In addition, in the vertical airflow cooling system 1 of the present invention, suction holes penetrating the inner and outer surfaces of the horizontal-suction pipe are repeatedly formed in the longitudinal direction, so that the internally polluted air (bet) is more rapidly and thoroughly discharged through the suction holes. As it is discharged, ventilation and quarantine efficiency can be further improved.

In addition, in the vertical airflow cooling system (1) of the present invention, the filter installation part is formed on one side of the vertical-moving tube and at the same time the filter part is detachably coupled to the filter installation part of the vertical-moving tube, so that filter replacement is possible without using a separate fastening means. Therefore, filter replacement work can be done conveniently and quickly.

In addition, the vertical airflow cooling system (1) of the present invention includes a vertical-moving tube in which the filter installation part has an opening formed on the outer circumferential surface, and a cover body installed as if surrounding the outer peripheral part of the vertical-moving pipe, but the cover body is located on the vertical-moving pipe. By being coupled to be horizontally movable and rotatable, the opening is opened or closed according to the horizontal movement of the cover, thereby further enhancing assembly and disassembly of the filter unit and ease of operation.

In addition, the vertical airflow cooling system 1 of the present invention provides horizontal-suction pipes to the floor surface of the indoor space S as well as the desk when a large number of desks are concentrated inside the indoor space S, such as a call center or an office. By placing it at the rear end of the support plate, the vertical airflow phenomenon can be further activated, effectively preventing the spread of viruses among occupants, and further improving the quarantine efficiency.

1: Vertical airflow cooling system 3: Total heat exchanger 4: Air conditioning system
5: horizontal-suction pipe 7: vertical-moving pipe 8: outdoor air outlet
9: Outlet for cold air 11: Suction pipe for betting 12: Air supply pipe for outside air
13: cold air supply pipe 20: filter unit 21: bottom surface
22: Ceiling 23: Sidewall 31: Housing
32: heat exchange means 51: suction hole 310: air supply flow path
311: air inlet hole 41: housing 43: cooling fan
45: Evaporator 48: First flow path 49: Second flow path tube
51: suction hole 121: second inflow switching means 191: first inflow switching means
70: filter installation part 312: supply air exhaust hole 323: air supply fan
320: exhaust passage 321: exhaust exhaust hole 322: exhaust inlet hole
323: exhaust fan 710: inner tube body 711: opening
712: guide protrusion 713: fixed protrusion 714: flange
720: cover body 721: sliding groove 722: fixed groove

Claims (8)

In the vertical air flow type cooling system including a cooling device for supplying cold air to the indoor space (S):
at least one outlet for outdoor air installed on the ceiling to supply outdoor air to the indoor space (S);
at least one cold air outlet installed on the air conditioner or the ceiling to supply cold air generated by the air conditioner to the indoor space (S);
At least one suction unit for sucking the air bet of the indoor space (S);
a total heat exchanger for supplying the supplied outdoor air to at least one of the air supply outlet and the cooling device, and discharging the bet air sucked through the suction unit to the outside;
and an evaporator for generating cold air by cooling the outside air supplied from the total heat exchanger, and a cooling device for supplying the generated cold air to the cold air outlet. The method of claim 1, wherein the suction unit
It is formed in a cylindrical or polyhedral tubular shape, a gas movement path is formed therein, and suction holes penetrating the inner and outer surfaces are formed at intervals in the longitudinal direction to suck the bet through the suction holes - it includes a suction pipe do,
The horizontal-suction pipe is seated on a floor surface or an indoor structure and sucks the bet to induce the internal airflow of the indoor space (S) to form a vertical direction. The method of claim 2, wherein the vertical airflow cooling system is
Formed in a cylindrical or polyhedral tubular shape, a gas movement path is formed therein, and the lower end is connected to the horizontal-suction pipe, the upper end is vertically installed so that the upper end is connected to the ceiling, and the bet sucked by the suction unit is placed on the ceiling. At least one or more vertical to move upwards - further comprising a moving tube,
The total heat exchanger
It is installed on the upper part of the ceiling and the vertical-air flow type cooling system, characterized in that it sucks the bet moved by the vertical pipe and discharges it to the outside. The method of claim 3, wherein the vertical airflow type cooling system is
a supply pipe for outside air installed between the cooling device and the insulation exchanger to move outside air to the cooling device;
At least one supply pipe for outdoor air having one end connected to the supply pipe for outdoor air, the other end being connected to the outlet for outdoor air to discharge the outdoor air discharged from the total heat exchanger to the outlet for outdoor air;
At least one suction pipe for betting one end connected to the total heat exchanger, the other end being connected to the vertical-moving pipe to move the bet sucked through the vertical-moving pipe to the total heat exchanger;
Vertical airflow type cooling, characterized in that it further comprises at least one supply pipe for cold air having one end connected to the air conditioner and the other end connected to the outlet for cold air to discharge the cold air generated in the air conditioner to the outlet. system. 5. The method of claim 4, wherein the vertical air flow type cooling system is
a first inflow switching means installed in the supply pipe for outdoor air to open or close an internal path;
Further comprising a second inlet switching means installed in the supply pipe for the outdoor air to open or close the internal path,
The vertical airflow cooling system, characterized in that the first inflow switching means and the second inflow switching means are opened or closed according to an external control. [6] The vertical airflow cooling system according to any one of claims 3 to 5, wherein a filter unit is detachably coupled to the internal path to the vertical-moving tube. According to claim 6, wherein the vertical - a filter installation portion of the circular pipe shape is formed on one side of the pipe,
The filter installation part
The vertical-moving tube further includes an inner tube having an opening formed on one side, and a hollow cylinder-shaped cover body that is installed to surround the outer periphery of the inner tube and coupled with the inner tube to be vertically movable and rotatable,
The inner body is
A flange is formed on an outer circumferential surface of a point adjacent to the lower end of the opening, and a locking jaw protruding inward to support the filter unit is formed on an inner circumferential surface of the same height as the lower end of the opening, and the lower end is connected to the flange, and the upper end is A guide protrusion disposed at the same height as the upper end of the opening is formed to protrude from the outer circumferential surface, and a fixing protrusion is formed to protrude upward from the opening, and at a position having the same width as the guide protrusion in the width direction,
The cover body
It is formed in a hollow cylindrical shape having a length greater than the opening, and a sliding groove is formed on the inner circumferential surface to the outside and extending to the upper end and the lower end, and is formed outwardly on the inner circumferential surface adjacent to the upper end and extends in the width direction, the end of which is a sliding groove A fixing groove connected to the
The separation distance from the upper end of the fixing protrusion to the upper end of the guide protrusion is the same as the length of the cover body,
The cover body
The guide protrusion is inserted into the sliding groove and moves up and down along the guide protrusion, and when it moves downward, it closes the opening of the inner tube body, and when moving upward, the insertion of the guide protrusion into the sliding groove is released When the fixing protrusion is inserted and the fixing groove is rotated at the same height as the fixing projection, the fixing protrusion is inserted into the fixing groove and the upwardly moved state is fixed. . 8. The method of claim 7, wherein the horizontal-suction pipe is
When the structure of the indoor space (S) is a desk, the vertical airflow cooling system, characterized in that it is seated at a point adjacent to the rear end of the support plate on which the article is seated.

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