KR102431377B1 - Air conditioning system of negative pressure isolation room - Google Patents

Abstract

According to the present invention, an air conditioning system of a negative-pressure isolated room comprises a single outdoor air-conditioning unit, and isolated room air-conditioning units in multiple isolated rooms. By controlling the isolated room air-conditioning units according to the set temperature of each negative-pressure isolated room, and controlling the opening rate of a variable air volume exhaust damper according to the set pressure of each negative-pressure isolated room, the system not only can individually respond to the air-conditioning loads of the plurality of negative-pressure isolated rooms, but also can individually control according to the use mode including negative-pressure mode, positive-pressure mode, and general hospital room mode of the plurality of negative-pressure isolated rooms, so that conversion between a general hospital room and a negative-pressure isolated room can be made easier.

Description

Air conditioning system of negative pressure isolation room

The present invention relates to an air conditioning system for a negative pressure isolation room, and more particularly, to an air conditioning system for a negative pressure isolation room that can control the temperature and pressure of an entire room and a hospital room and purify the air using a heating/cooling unit installed on the ceiling. .

A negative pressure isolation room is a ward to artificially drop the pressure inside the ward to prevent germs and viruses from spreading out of the ward. In a negative pressure isolation room, a ventilation device is used to maintain the air pressure inside the room at a negative pressure, so that outside air can enter the room, but air from the room cannot go out.

However, the conventional negative pressure isolation room has a problem in that enormous cost and time is consumed for installation and maintenance, and due to this problem, there is a problem in that it is impossible to respond quickly when the number of patients requiring isolation increases explosively.

Korean Patent No. 10-2194329

An object of the present invention is to provide an air conditioning system for a negative pressure isolation room that can control the temperature and pressure of a hospital room, and has a simple structure and is easy to install.

An air conditioning system for a negative pressure isolation room according to the present invention comprises: an outdoor air conditioning unit for precooling or preheating by sucking outdoor air; an outdoor air damper installed on the suction side of the outdoor air conditioning unit and controlling the flow rate of outdoor air flowing into the outdoor air conditioning unit to correspond to the total heating and cooling load of the plurality of negative pressure isolation rooms; a plurality of distribution ducts configured to distribute the air from the outdoor air conditioning unit to the plurality of negative pressure isolation chambers; a plurality of distribution dampers installed in the plurality of distribution ducts to control the flow rate of air introduced into the distribution ducts to correspond to each heating/cooling load of the plurality of negative pressure isolation rooms; a plurality of isolation room cooling and heating units installed in the plurality of distribution ducts to suck in air pre-cooled or preheated from the outdoor air cooling unit and heat or cool it to a set temperature set in the negative pressure isolation room; a plurality of air supply ducts respectively connecting the plurality of isolation room heating and cooling units and the plurality of negative pressure isolation rooms to supply air from the isolation room heating and cooling unit to the negative pressure isolation room, respectively; a constant air quantity supply damper installed in each of the air supply ducts to constantly supply a blow rate of air from the isolation room heating and cooling unit to the negative pressure isolation chamber; a HEPA filter for supply air that is detachably installed at the air supply ports of the negative pressure isolation chambers and filters the air passing through the constant air volume supply damper; a circulation duct for sucking air from the negative pressure isolation chamber and circulating it to the HEPA filter for supply air; a circulation damper installed to open and close the circulation duct; a plurality of exhaust ducts connected to respective exhaust ports of the negative pressure isolation chambers; a HEPA filter for exhaust that is detachably installed at the exhaust ports of the negative pressure isolation chambers to filter the air coming out of the negative pressure isolation chamber; Installed in each of the exhaust ducts, the negative pressure isolation chamber according to a preset pressure for the negative pressure isolation chamber a variable air volume exhaust damper for changing the amount of air discharged from the air; an exhaust fan unit installed in each of the exhaust ducts to exhaust the air from the negative pressure isolation chamber to the outside; a pressure sensor installed inside each of the negative pressure isolation chambers to sense the internal pressure of the negative pressure isolation chamber; An indoor controller installed inside each of the negative pressure isolation chambers to control an opening rate of the variable air volume exhaust damper according to the pressure measured by the pressure sensor and the set pressure to maintain the pressure in the negative pressure isolation chamber at the set pressure; ; Selectively operate the plurality of isolation room heating and cooling units according to a use mode including a negative pressure mode, a positive pressure mode, and a general hospital room mode of the plurality of negative pressure isolation rooms, and selectively open the distribution dampers according to whether the isolation room heating and cooling units operate Including a central controller.

According to another aspect of the present invention, there is provided an air conditioning system for a negative pressure isolation room, comprising: an outdoor air conditioning unit for precooling or preheating by sucking outdoor air; an outdoor air damper installed on the suction side of the outdoor air conditioning unit and controlling the flow rate of outdoor air flowing into the outdoor air conditioning unit to correspond to the total heating and cooling load of the plurality of negative pressure isolation rooms; a plurality of distribution ducts configured to distribute the air from the outdoor air conditioning unit to the plurality of negative pressure isolation chambers; a plurality of distribution dampers installed in the plurality of distribution ducts to control the flow rate of air introduced into the distribution ducts to correspond to each heating/cooling load of the plurality of negative pressure isolation rooms; a plurality of isolation room cooling and heating units installed in the plurality of distribution ducts to suck in air pre-cooled or preheated from the outdoor air cooling unit and heat or cool it to a set temperature set in the negative pressure isolation room; a plurality of air supply ducts respectively connecting the plurality of isolation room heating and cooling units and the plurality of negative pressure isolation rooms to supply air from the isolation room heating and cooling unit to the negative pressure isolation room, respectively; a constant air quantity supply damper installed in each of the air supply ducts to constantly supply a blow rate of air from the isolation room heating and cooling unit to the negative pressure isolation room; a backflow prevention damper for supply air installed in each of the air supply ducts to prevent the air inside the negative pressure isolation chamber from flowing back into the isolation heating/cooling unit; a plurality of exhaust ducts connected to respective exhaust ports of the negative pressure isolation chambers; a variable air volume exhaust damper installed in each of the exhaust ducts to change the amount of air discharged from the negative pressure isolation chamber according to a preset pressure for the negative pressure isolation chamber; a backflow prevention damper for exhaust which is installed in each of the exhaust ducts and prevents the air from the negative pressure isolation chamber from flowing back into the negative pressure isolation chamber; an exhaust HEPA filter installed in the exhaust duct to filter the air passing through the variable air volume exhaust damper; an exhaust fan unit installed in each of the exhaust ducts to exhaust the air that has passed through the exhaust HEPA filter to the outside; a pressure sensor installed inside the negative pressure isolation chamber to sense the internal pressure of the negative pressure isolation chamber; an indoor controller installed inside each of the negative pressure isolation chambers to control an opening rate of the variable air volume exhaust damper according to the pressure measured by the pressure sensor and the set pressure to maintain the pressure in the negative pressure isolation chamber at the set pressure; Selectively operate the plurality of isolation room heating and cooling units according to a use mode including a negative pressure mode, a positive pressure mode, and a general hospital room mode of the plurality of negative pressure isolation rooms, and selectively open the distribution dampers according to whether the isolation room heating and cooling units are operated It contains a central controller.

The isolation room heating/cooling unit includes a case, a blower provided inside the case to suck in and blow air precooled or preheated by the outdoor air conditioning unit, and the air blown by the blower to the set temperature using hot/cold water. It includes a hot/cold water coil for heating or cooling, and a cold/hot water valve for controlling an amount of hot/cold water supplied to the cold/hot water coil.

Installed inside the negative pressure isolation chamber, further comprising a temperature sensor for sensing the internal temperature of the negative pressure isolation chamber, wherein at least one of the indoor controller and the central controller, the temperature sensed by the temperature sensor and the preset temperature according to the control of the hot and cold water valve and the blower.

The central controller proportionally controls the opening rate of the outdoor air damper according to the number of operation of the plurality of isolation room heating and cooling units.

and an indoor air sensor sensing indoor air quality of the negative pressure isolation chamber in real time, wherein the central controller controls an opening rate of the outdoor air damper according to the indoor air quality sensed by the indoor air sensor.

The HEPA filter for air supply and the HEPA filter for exhaust are detachably coupled to an air supply port installed on the ceiling of the negative pressure isolation room, and are detachably attached to the negative pressure isolation room in a general hospital room mode.

The negative pressure isolation room is divided into a front room and a hospital room, and the air supply duct includes a front air supply duct connecting the isolation room air conditioning unit and the front room, and a hospital room air supply duct connecting the isolation room air conditioning unit and the hospital room, The air supply damper includes a front room constant air volume supply damper installed in the front room air supply duct, and a hospital room constant air volume supply damper installed in the hospital room air supply duct.

The negative pressure isolation room is divided into a front room and a hospital room, and the exhaust duct includes a front room exhaust duct connecting the front room and the exhaust fan unit, and a hospital room exhaust duct connecting the hospital room and the exhaust fan unit, and the amount of variable air. The exhaust damper includes a front room variable air volume exhaust damper installed in the front room exhaust duct, and a hospital room variable air volume exhaust damper installed in the hospital room exhaust duct.

In the negative pressure mode of the negative pressure isolation room, the central controller turns on the air conditioning unit connected to the negative pressure isolation room, and opens the outdoor air damper, the distribution damper, and the constant air volume supply damper, and the indoor controller includes the negative pressure The opening rate of the variable air supply air damper is controlled according to the set pressure set for the isolation chamber.

In the positive pressure mode and the general hospital room mode of the negative pressure isolation room, the central controller turns on the air conditioning unit connected to the negative pressure isolation room, and opens the outdoor air damper, the distribution damper, the circulation damper, and the constant air volume supply damper and the indoor controller controls an opening rate of the variable air amount supply damper according to a set pressure set for the negative pressure isolation chamber.

The air conditioning system of the negative pressure isolation room according to the present invention includes a single outdoor air conditioning unit and a plurality of isolation room cooling and heating units, and controls the isolation room heating and cooling unit according to the set temperature of each negative pressure isolation room, and according to the set pressure of each negative pressure isolation room By controlling the opening rate of the variable air volume exhaust damper, it is possible not only to individually respond to the cooling and heating loads of the plurality of negative pressure isolation rooms, but also according to the use modes including the negative pressure mode, the positive pressure mode and the general hospital room mode of the plurality of negative pressure isolation rooms. Since each can be controlled, switching between a general ward and a negative pressure isolation room can be made easier.

1 is a block diagram schematically showing a control configuration of an air conditioning system of a negative pressure isolation room according to a first embodiment of the present invention.
2 is a view schematically showing a negative pressure mode of the air conditioning system of the negative pressure isolation room according to the first embodiment of the present invention.
3 is a view schematically showing the configuration of the outdoor air cooling unit shown in FIG.
4 is a view schematically showing the configuration of the isolation room heating and cooling unit shown in FIG.
5 is a diagram schematically showing a positive pressure mode of the air conditioning system of the negative pressure isolation room according to the first embodiment of the present invention.
6 is a view schematically showing a general hospital room mode of the air conditioning system of the negative pressure isolation room according to the first embodiment of the present invention.
7 is a view schematically showing a negative pressure mode of the air conditioning system of the negative pressure isolation room according to the second embodiment of the present invention.

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

1 is a block diagram schematically showing a control configuration of an air conditioning system of a negative pressure isolation room according to a first embodiment of the present invention. 2 is a view schematically showing a negative pressure mode of the air conditioning system of the negative pressure isolation room according to the first embodiment of the present invention. 3 is a view schematically showing the configuration of the outdoor air cooling unit shown in FIG. 4 is a view schematically showing the configuration of the isolation room heating and cooling unit shown in FIG.

1 and 2, the air conditioning system of the negative pressure isolation room (R) according to the first embodiment of the present invention includes an outdoor air heating unit (OHU), a plurality of isolation room heating and cooling units (CHU, Cooling and Heating unit), exhaust fan unit (EAU), outside air duct (10), distribution duct (20), supply air duct (30), exhaust duct (40), circulation duct (50), outside air damper (110), distribution Damper 120, circulation damper 130, constant air quantity supply air damper 210, variable air quantity exhaust damper 220, supply air HEPA filter 310, exhaust HEPA filter 320, pressure sensor (P), temperature It includes a sensor T and a room controller RC and a central controller MC.

Referring to FIG. 1 , the negative pressure isolation chambers R will be described as including four first to fourth negative pressure isolation chambers R1 to R4. The negative pressure isolation rooms (R) include an anterior chamber and a hospital room, respectively. The plurality of negative pressure isolation chambers R are connected through a corridor.

The outdoor air conditioning unit (OHU) is provided as a single unit, sucks in outdoor air, pre-cools or preheats it, and then distributes it to the first to fourth isolation room heating and cooling units CHU1 to CHU4 . The outdoor air conditioning unit (OHU) is provided with a central controller (MC) (Main controller). However, the present invention is not limited thereto, and the position of the central controller MC may be variously changed and applied.

The central controller MC transmits and receives control signals to and from the plurality of indoor controllers RC, unit controllers C1 to C4 and the exhaust fan controller C5 to be described later through wireless communication. The central controller MC may control the opening rate of the outdoor air damper 110 according to the temperature sensed by the temperature sensor T.

Referring to FIG. 3 , the outdoor air conditioning unit (OHU) includes a first case 2 , an outdoor air filter 4 provided inside the first case 2 to filter outdoor air, and the outdoor air filter ( 4) a UV lamp 6 for sterilizing the air passing through, a first cold/hot water coil 8 for precooling or preheating the air passing through the UV lamp 6, and the first cold/hot water coil 8 It will be described as an example of a fan coil unit including a first cold/hot water valve (8a) for controlling the flow rate of cold or hot water and a first blower (9) for blowing outside air.

The outdoor air conditioning unit (OHU) is a unit corresponding to the total heating and cooling load of the plurality of negative pressure isolation rooms (R). One side of the outdoor air conditioning unit (OHU) is connected to the outdoor air duct 10 for sucking the outside air, the other side is connected to the distribution duct (20).

An outdoor air damper 110 is installed in the outdoor air duct 10 to control the flow rate of outdoor air flowing into the outdoor air cooling unit OHU to correspond to the total heating and cooling load of the plurality of negative pressure isolation rooms R.

Referring to FIG. 1 , the isolation room air conditioning unit CHU includes four first to fourth isolation room air conditioning units CHU1 to CHU4 to correspond to the number of the negative pressure isolation rooms R, for example. do.

The isolation room heating and cooling unit (CHU) is installed in the distribution ducts 20, and is a unit corresponding to each heating and cooling load of the plurality of negative pressure isolation rooms (R). It is connected to the distribution duct 20 of the isolation room air conditioning unit (CHU), and the other side is connected to the air supply duct 30 . Each of the isolation room heating and cooling units CHU is provided with unit controllers C1 to C4 therein.

The unit controllers C1 to C4 receive an operation signal of the isolation room air conditioning unit CHU from the central controller MC through wireless communication with the central controller MC.

Referring to FIG. 3 , the isolation room air conditioning unit (CHU) includes a second case 12 , an air filter 14 provided inside the second case 12 to filter air, and the air filter ( 14) a second cold/hot water coil 18 for cooling or heating the air passing through, a second cold/hot water valve 18a for controlling the flow rate of cold or hot water flowing into the second cold/hot water coil 18, and blowing air It will be described as an example of a fan coil unit including a second blower 19.

The distribution ducts 20 are provided to correspond to the number of the negative pressure isolation rooms R, and are formed to distribute the air from the outdoor air cooling unit OHU to the plurality of isolation room air conditioning units CHU. Distribution dampers 120 are installed in the distribution ducts 20 to regulate the flow rate of air flowing into the isolation room air conditioning unit (CHU) to correspond to each heating/cooling load of the negative pressure isolation rooms (R).

The air supply ducts 30 are ducts formed to respectively connect the plurality of isolation chamber air conditioning units (CHU) and the plurality of negative pressure isolation chambers (R). The air supply ducts 30 are ducts for guiding the air from the isolation room air conditioning unit (CHU) to the negative pressure isolation room (R).

The air supply ducts 30 include an anterior air supply duct 31 connected to the front chamber in the negative pressure isolation room R, and a hospital room air supply duct 32 connected to a hospital room in the negative pressure isolation chamber R.

The constant air volume supply damper 210 is installed in the air supply duct 30, and the constant air volume (CAV, Constant Air Volume) type damper for constantly supplying the blowing volume of air from the isolation room heating and cooling unit to the negative pressure isolation room. to be.

The constant air volume supply damper 210 includes a front room constant air volume supply damper 211 installed in the front room air supply duct 31 and a hospital room constant air volume supply damper 212 installed in the hospital room air supply duct 32 .

The air supply HEPA filter 310 is detachably installed in the air supply duct 30 to filter the air passing through the constant air quantity supply damper 210 . In this embodiment, the HEPA filter 310 for the air supply will be described as being detachably installed in the air supply port formed on the ceiling or wall surface of the negative pressure isolation chamber (R).

The air supply HEPA filter 310 includes a front air supply HEPA filter 311 installed on the front air supply duct 31 and a hospital room air supply HEPA filter 312 installed on the hospital room air supply duct 32 .

The exhaust fan unit EAU is provided as a single unit, and exhausts the air from the first to fourth negative pressure isolation chambers R1 to R4 to the outside.

The circulation duct 50 is a flow path for sucking air from the negative pressure isolation chamber R and circulating it to the HEPA filter 310 for supply air.

The circulation duct 50 includes an anterior chamber circulation duct 51 connected to the anterior chamber and a ward circulation duct 52 connected to the ward.

The circulation damper 130 is a damper installed to open and close the circulation duct 50 . The circulation damper 130 includes an anterior chamber circulation damper 131 installed in the anterior chamber circulation duct 51 and a hospital room circulation damper 132 installed in the hospital room circulation duct 52 .

The exhaust duct 40 is connected to each exhaust port of the negative pressure isolation chambers (R), and is a flow path for discharging the internal air of the negative pressure isolation chambers (R). The exhaust duct 40 includes a front room exhaust duct 41 connected to the exhaust port of the front room, and a hospital room exhaust duct 42 connected to the exhaust port of the hospital room.

The exhaust HEPA filter 320 is detachably installed in the exhaust duct 40 to filter the air from the negative pressure isolation chambers R. In this embodiment, the exhaust HEPA filter 320 will be described as being detachably installed in the exhaust port formed on the ceiling or wall of the negative pressure isolation chamber (R).

The exhaust HEPA filter 320 includes a front room exhaust HEPA filter 321 installed in the front room exhaust duct 41 and a hospital room exhaust HEPA filter 322 installed in the hospital room exhaust duct 42 .

The variable air volume exhaust damper 220 is installed in the exhaust duct 40 and changes the amount of air discharged from the negative pressure isolation chamber R according to a preset pressure for the negative pressure isolation chamber R. (VAV, Variable Air Volume) type damper.

The variable air volume exhaust damper 220 includes a front room variable air volume exhaust damper 221 installed in the front room exhaust duct 41 and a hospital room variable air volume exhaust damper 222 installed in the hospital room exhaust duct 42 .

The exhaust fan unit EAU is a unit including an exhaust fan installed in the exhaust duct 40 to discharge air from the negative pressure isolation chamber R to the outside.

Referring to FIG. 1 , the exhaust fan unit EAU is provided with an exhaust fan controller C5, and the exhaust fan controller C5 communicates with the central controller MC through wireless communication with the exhaust fan (not shown). receive a control signal from

On the other hand, the negative pressure isolation chambers (R) are provided with a pressure sensor (P) for detecting the indoor pressure and a temperature sensor (T) for detecting the room temperature.

The pressure sensor P includes an anterior chamber pressure sensor P1 installed in the anterior chamber, and a ward pressure sensor P2 installed in the ward.

The temperature sensor T includes a front room temperature sensor T1 installed in the front room and a hospital room temperature sensor T2 installed in the hospital room. The temperature sensed by the temperature sensor T is transmitted to the central controller MC through wireless communication.

In addition, the room controller (RC, Room Controller) is installed in each of the negative pressure isolation chambers (R).

The room controller RC includes a front room room controller RC1 installed in the front room and a hospital room room controller RC2 installed in the hospital room. The indoor controller RC receives values sensed by the pressure sensor P and the temperature sensor P. The indoor controller (RC) may include an input unit for receiving a set pressure or set temperature from a user of the negative pressure isolation chamber (R). In addition, the indoor controller (RC) is in wireless communication with the central controller (MC). The indoor controller RC controls an opening rate of the variable air amount exhaust damper 220 .

The front room indoor controller (RC1) controls the opening rate of the front room folding air volume exhaust damper 221 according to the front room pressure sensed by the front room pressure sensor P1 and the front room preset pressure for the front room, The pressure in the front chamber is maintained at the set pressure in the front chamber.

The ward room controller (RC2) controls the opening rate of the ward air volume exhaust damper 222 according to the ward pressure detected by the ward pressure sensor P2 and the ward set pressure preset for the ward, The pressure in the hospital room is maintained at the set pressure in the hospital room.

In addition, the negative pressure isolation chambers (R) may further include an indoor air sensor (not shown) for detecting indoor air quality in real time.

The central controller MC may control the opening rate of the outdoor air damper 110 according to the indoor air quality sensed by the indoor air sensor (not shown).

The operating method of the air conditioning system of the negative pressure isolation room according to the first embodiment of the present invention configured as described above will be described as follows.

Referring to FIG. 2 , the first negative pressure isolation chamber R1 among the plurality of negative pressure isolation chambers R1 to R4 will be mainly described, and the case where the first negative pressure isolation chamber R1 is in negative pressure mode and heating is set as an example do.

When the negative pressure mode and heating are set for the first negative pressure isolation room R1 , the central controller MC turns on the outdoor air heating and cooling unit OHU and the first isolation room heating and cooling unit CHU1 .

In addition, the central controller MC opens the outside air damper 110 and the distribution damper 120 , and blocks the circulation damper 130 .

At this time, the open rate of the outdoor air damper 110 is proportionally controlled according to the number of operation of the isolation room heating and cooling units (CHU). For example, when all of the four isolation room heating and cooling units (CHU) are turned on, the open rate of the outdoor air damper 110 may be set to 100%. In addition, when only three of the isolation room air conditioning units CHU are turned on among the four isolation room air conditioning units CHU, the open rate of the outdoor air damper 110 may be set to 75%.

In the distribution damper 120 , only the damper corresponding to the turned on isolation room air conditioning unit among the four isolation room air conditioning units (CHU) is opened.

The circulation damper 130 is shielded when the first negative pressure isolation chamber R1 is in negative pressure mode.

Accordingly, the outdoor air introduced through the outdoor air duct 10 is preheated while passing through the outdoor air heating and cooling unit (OHU).

The air preheated in the outdoor air conditioning unit (OHU) is heated to a preset temperature while passing through the first isolation room heating and cooling unit (CHU1).

The set temperature is a temperature input through at least one of the front room controller RC1 and the hospital room controller RC2 installed in the front room and the hospital room of the first negative pressure isolation room R1, respectively.

The indoor controller (RC) operates the second cold/hot water valve (18a) and the second blower (19) of the first isolation room air conditioning unit (CHU1) according to the set temperature and the temperature sensed by the temperature sensor (T). to control By controlling the opening rate of the second cold and hot water valve 18a and the blowing force of the second blower 19, the temperature and flow rate of the air heated in the first isolation room air conditioning unit (CHU) can be adjusted.

Accordingly, the air heated to the set temperature in the first isolation room air conditioning unit CHU1 is supplied to the first negative pressure isolation chamber R, and the first negative pressure isolation chamber R is heated.

Also, the indoor controller RC controls the operation of the variable air volume exhaust damper 220 according to the pressure of the first negative pressure isolation chamber R1 sensed by the pressure sensor P and a preset pressure.

That is, in the first negative pressure isolation room R1, the front room indoor controller RC1 installed in the front room controls the front room according to the pressure of the front room detected by the front room pressure sensor P1 and the preset pressure set for the front room. The opening rate of the air volume exhaust damper 221 is controlled. The front room set pressure is a pressure input through the front room indoor controller RC1.

In addition, in the first negative pressure isolation room R1, the ward room controller RC2 installed in the ward is located in the ward according to the ward pressure detected by the ward pressure sensor P2 and the ward set pressure preset for the ward. The opening rate of the air volume exhaust damper 222 is controlled. The set pressure for the hospital room is the pressure input through the room room controller RC2.

2, in this embodiment, when the supply air (SA, Supply Air) flowing into the first negative pressure isolation chamber R1 through the air supply duct 30 is 100%, the exhaust duct 40 The exhaust air (EA, Exhaust Air) discharged through the is controlled to 110%, and the inside of the first negative pressure isolation chamber R1 will be described as maintaining a negative pressure.

Therefore, it is possible not only to cool and heat the negative pressure isolation room (R) through the outdoor air conditioning unit (OHU) and the isolation room heating and cooling unit (CHU), but also to maintain the negative pressure in the entire room and the hospital room of the negative pressure isolation room (R), respectively. have.

In addition, it is possible to individually cool and heat the plurality of negative pressure isolation chambers (R), as well as individually control the pressure. Therefore, it may be easier to convert a general ward into a negative pressure ward or a negative pressure ward into a general ward.

On the other hand, Figure 5 is a diagram schematically showing the positive pressure mode of the air conditioning system of the negative pressure isolation room according to the first embodiment of the present invention.

Referring to FIG. 5 , a case in which the first negative pressure isolation chamber R1 is in a positive pressure mode and heating is set will be described as an example.

When the positive pressure mode and heating are set for the first negative pressure isolation room R1 , the central controller MC turns on the outdoor air heating and cooling unit OHU and the first isolation room heating and cooling unit CHU1 .

In addition, the central controller MC opens all of the outdoor air damper 110 , the distribution damper 120 , and the circulation damper 130 .

At this time, the open rate of the outdoor air damper 110 is proportionally controlled according to the number of operation of the isolation room heating and cooling units (CHU). For example, when all of the four isolation room heating and cooling units (CHU) are turned on, the open rate of the outdoor air damper 110 may be set to 100%. In addition, when only three of the isolation room air conditioning units CHU are turned on among the four isolation room air conditioning units CHU, the open rate of the outdoor air damper 110 may be set to 75%.

In the distribution damper 120 , only the damper corresponding to the turned on isolation room air conditioning unit among the four isolation room air conditioning units (CHU) is opened.

Accordingly, the outdoor air introduced through the outdoor air duct 10 is preheated while passing through the outdoor air heating and cooling unit (OHU).

The air preheated in the outdoor air conditioning unit (OHU) is heated to a preset temperature while passing through the first isolation room heating and cooling unit (CHU1).

The set temperature is a temperature input through at least one of the front room controller RC1 and the hospital room controller RC2 installed in the front room and the hospital room of the first negative pressure isolation room R1, respectively.

The indoor controller (RC) operates the second cold/hot water valve (18a) and the second blower (19) of the first isolation room air conditioning unit (CHU1) according to the set temperature and the temperature sensed by the temperature sensor (T). can be controlled.

Accordingly, the air heated to the set temperature in the first isolation room air conditioning unit CHU1 is supplied to the first negative pressure isolation chamber R, and the first negative pressure isolation chamber R is heated.

Also, the indoor controller RC controls the operation of the variable air volume exhaust damper 220 according to the pressure of the first negative pressure isolation chamber R1 sensed by the pressure sensor P and a preset pressure.

That is, in the first negative pressure isolation room R1, the front room indoor controller RC1 installed in the front room controls the front room according to the pressure of the front room detected by the front room pressure sensor P1 and the preset positive pressure set for the front room. The opening rate of the air volume exhaust damper 221 is controlled. The positive pressure set in the front room is a pressure input through the front room controller RC1.

In addition, in the first negative pressure isolation room (R1), the hospital room controller (RC2) installed in the hospital room adjusts the room pressure detected by the hospital room pressure sensor (P2) and the set positive pressure set in advance for the hospital room according to the set positive pressure for the room. The opening rate of the air volume exhaust damper 222 is controlled. The positive pressure set in the hospital room is the pressure input through the room room controller RC2.

5, in this embodiment, the supply air (SA, Supply Air) flowing into the first negative pressure isolation chamber R1 through the air supply duct 30 is 100% ??, the exhaust duct 40 ) The exhaust air (EA, Exhaust Air) discharged through the is controlled to 90%, the inside of the first negative pressure isolation chamber (R1) will be described as an example to maintain a positive pressure.

Therefore, cooling and heating of the negative pressure isolation room (R) is possible through the outdoor air conditioning unit (OHU) and the isolation room heating and cooling unit (CHU), and the entire room and the hospital room of the negative pressure isolation room (R) are set to a set positive pressure, respectively. can keep

In addition, it is possible to individually cool and heat the plurality of negative pressure isolation chambers (R), as well as individually control the pressure.

On the other hand, Figure 6 is a view schematically showing the general ward mode of the air conditioning system of the negative pressure isolation room according to the first embodiment of the present invention.

Referring to FIG. 6 , a case in which the first negative pressure isolation room R1 is in a general hospital room mode and heating is set will be described as an example.

The general hospital room mode is a mode in which the first negative pressure isolation room R1 is not used as an isolation room, and the pressure is not controlled by using the general hospital room.

When the first negative pressure isolation room R1 is set to the general hospital room mode, the hospital room manager may detach both the HEPA filter 310 for supply air and the HEPA filter 320 for exhaust. Since the air supply HEPA filter 310 is detachably coupled to the air supply duct 30, the hospital room manager is easily detachable from the air supply port of the first negative pressure isolation room R1. In addition, since the exhaust HEPA filter 320 is also detachably coupled to the exhaust duct 40 , the hospital room manager is easily detachable from the exhaust port of the first negative pressure isolation room R1 .

By detaching both the HEPA filter 310 for supply and the HEPA filter 320 for exhaust in the general hospital room mode, the lifespan of the HEPA filter 310 for supply air and the HEPA filter 320 for exhaust can be increased. .

When the first negative pressure isolation room R1 is set to be heated, the central controller MC turns on the outdoor air heating and cooling unit OHU and the first isolation room heating and cooling unit CHU1.

In addition, the central controller MC opens all of the external air damper 110 , the distribution damper 120 , and the circulation damper 130 .

Accordingly, the outdoor air introduced through the outdoor air duct 10 is preheated while passing through the outdoor air heating and cooling unit (OHU).

The air preheated in the outdoor air conditioning unit (OHU) is heated to a preset temperature while passing through the first isolation room heating and cooling unit (CHU1).

The set temperature is a temperature input through at least one of the front room controller RC1 and the hospital room controller RC2 installed in the front room and the hospital room of the first negative pressure isolation room R1, respectively.

The indoor controller (RC) operates the second cold/hot water valve (18a) and the second blower (19) of the first isolation room air conditioning unit (CHU1) according to the set temperature and the temperature sensed by the temperature sensor (T). can be controlled.

Accordingly, the air heated to the set temperature in the first isolation room air conditioning unit CHU1 is supplied to the first negative pressure isolation chamber R, and the first negative pressure isolation chamber R is heated.

In addition, by opening the circulation damper 130 to circulate the indoor air RA of the first negative pressure isolation chamber R1 , ventilation of the first negative pressure isolation chamber R1 is possible.

The air conditioning system of the negative pressure isolation room according to the first embodiment of the present invention configured as described above is controllable differently depending on the use mode including the negative pressure mode, the positive pressure mode, and the general ward mode for the negative pressure isolation rooms. When the number of patients increases, it is very easy to convert a general ward into a negative pressure isolation room.

On the other hand, Figure 7 is a view schematically showing the negative pressure mode of the air conditioning system of the negative pressure isolation room according to the second embodiment of the present invention.

Referring to FIG. 7 , in the air conditioning system of the negative pressure isolation room according to the second embodiment of the present invention, a separate HEPA filter is not installed in the air inlet of the negative pressure isolation room (R), and air is supplied to the air supply duct (30). A backflow prevention damper 410 is installed, and a separate HEPA filter is not installed at the exhaust port of the negative pressure isolation chamber R, and a backflow prevention damper 510 for exhaust and a HEPA filter 600 for exhaust are installed in the exhaust duct 40. It is different from the first embodiment in that it is installed, and the rest of the configurations and actions are similar. Therefore, the same reference numerals are used for similar components, and detailed descriptions thereof are omitted, and different configurations will be described in detail.

The backflow prevention damper 410 for supply air is a damper that prevents the air inside the negative pressure isolation room R from flowing back into the isolation room air conditioning unit CHU. Since the air inside the negative pressure isolation room R is prevented from flowing back into the isolation room heating and cooling unit CHU, a separate HEPA filter does not need to be installed at the air supply port of the negative pressure isolation room R.

The backflow prevention damper 410 for supply air includes a backflow prevention damper 411 for front air supply installed in the front air supply duct 31 and a backflow prevention damper 412 for hospital room supply installed in the hospital room supply duct 32. include

The backflow prevention damper 510 for exhaust is a damper that prevents the air from the negative pressure isolation chamber R from flowing back into the negative pressure isolation chamber R again. Since the reverse flow of the contaminated air from the negative pressure isolation chamber R to the negative pressure isolation chamber R is prevented, a separate HEPA filter does not need to be installed at the exhaust port of the negative pressure isolation chamber R.

The backflow prevention damper 510 for exhaust includes a backflow prevention damper 511 for front exhaust installed in the front exhaust duct 41 and a hospital room backflow prevention damper 512 installed in the hospital exhaust duct 42. .

The exhaust HEPA filter 600 filters the air that has passed through the exhaust variable air volume damper 220 in the exhaust duct 40 .

In the air conditioning system of the negative pressure isolation room according to the second embodiment of the present invention configured as described above, the anti-return damper 410 for supply and the anti-return damper 510 for exhaust are installed, so that one HEPA filter for exhaust Since only 600 may be installed, the structure may be simplified and the cost may be reduced.

Although the present invention has been described with reference to the embodiments shown in the drawings, which are merely exemplary, those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Accordingly, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

OHU: outdoor air conditioning unit CHU: isolation room heating and cooling unit
EAU: Exhaust fan unit 10: Outside air duct
20: distribution duct 30: supply air duct
40: exhaust duct 50: circulation duct
110: outside air damper 120: distribution damper
130: circulation damper 210: constant air flow damper
220: variable air volume exhaust damper 310: HEPA filter for supply air
320: HEPA filter for exhaust

Claims (11)

an outdoor air conditioning unit for precooling or preheating by sucking the outdoor air;
an outdoor air damper installed on the suction side of the outdoor air conditioning unit and controlling the flow rate of outdoor air flowing into the outdoor air conditioning unit to correspond to the total heating and cooling load of the plurality of negative pressure isolation rooms;
a plurality of distribution ducts configured to distribute the air from the outdoor air conditioning unit to the plurality of negative pressure isolation chambers;
a plurality of distribution dampers installed in the plurality of distribution ducts to control the flow rate of air introduced into the distribution ducts to correspond to each heating/cooling load of the plurality of negative pressure isolation rooms;
a plurality of isolation room cooling and heating units installed in the plurality of distribution ducts to suck in air pre-cooled or preheated from the outdoor air cooling unit and heat or cool it to a set temperature set in the negative pressure isolation room;
a plurality of air supply ducts respectively connecting the plurality of isolation room heating and cooling units and the plurality of negative pressure isolation rooms to supply air from the isolation room heating and cooling unit to the negative pressure isolation room, respectively;
a constant air quantity supply damper installed in each of the air supply ducts to constantly supply a blow rate of air from the isolation room heating and cooling unit to the negative pressure isolation room;
a HEPA filter for supply air that is detachably installed at the air supply ports of the negative pressure isolation chambers and filters the air that has passed through the constant air quantity supply air damper;
a circulation duct for sucking air from the negative pressure isolation chamber and circulating it to the HEPA filter for supply air;
a circulation damper installed to open and close the circulation duct;
a plurality of exhaust ducts connected to respective exhaust ports of the negative pressure isolation chambers;
a HEPA filter for exhaust which is detachably installed at the exhaust ports of the negative pressure isolation chambers and filters the air from the negative pressure isolation chambers;
a variable air volume exhaust damper installed in each of the exhaust ducts to change the amount of air discharged from the negative pressure isolation chamber according to a preset pressure for the negative pressure isolation chamber;
an exhaust fan unit installed in each of the exhaust ducts to exhaust the air from the negative pressure isolation chamber to the outside;
a pressure sensor installed inside each of the negative pressure isolation chambers to sense the internal pressure of the negative pressure isolation chamber;
An indoor controller installed inside each of the negative pressure isolation chambers to control an opening rate of the variable air volume exhaust damper according to the pressure measured by the pressure sensor and the set pressure to maintain the pressure in the negative pressure isolation chamber at the set pressure; ;
Selectively operate the plurality of isolation room heating and cooling units according to a use mode including a negative pressure mode, a positive pressure mode, and a general hospital room mode of the plurality of negative pressure isolation rooms, and selectively open the distribution dampers according to whether the isolation room heating and cooling units are operated including a central controller that makes
The negative pressure isolation room is divided into an anterior chamber and a ward,
The air supply duct includes a front air supply duct connecting the isolation room air conditioning unit and the front room, and a hospital room air supply duct connecting the isolation room air conditioning unit and the hospital room,
The air conditioning system for a negative pressure isolation room, wherein the constant air volume supply damper includes a front room constant air volume supply damper installed in the front room air supply duct and a hospital room constant air volume air supply damper installed in the hospital room air supply duct. an outdoor air conditioning unit for precooling or preheating by sucking the outdoor air;
an outdoor air damper installed on the suction side of the outdoor air conditioning unit and controlling the flow rate of outdoor air flowing into the outdoor air conditioning unit to correspond to the total heating and cooling load of the plurality of negative pressure isolation rooms;
a plurality of distribution ducts configured to distribute the air from the outdoor air conditioning unit to the plurality of negative pressure isolation chambers;
a plurality of distribution dampers installed in the plurality of distribution ducts to control the flow rate of air introduced into the distribution ducts to correspond to each heating/cooling load of the plurality of negative pressure isolation rooms;
a plurality of isolation room cooling and heating units installed in the plurality of distribution ducts to suck in air pre-cooled or preheated from the outdoor air cooling unit and heat or cool it to a set temperature set in the negative pressure isolation room;
a plurality of air supply ducts respectively connecting the plurality of isolation room heating and cooling units and the plurality of negative pressure isolation rooms to supply air from the isolation room heating and cooling unit to the negative pressure isolation room, respectively;
a constant air quantity supply damper installed in each of the air supply ducts to constantly supply a blow rate of air from the isolation room heating and cooling unit to the negative pressure isolation room;
a backflow prevention damper for supply air installed in each of the air supply ducts to prevent the air inside the negative pressure isolation room from flowing back to the isolation room heating/cooling unit;
a plurality of exhaust ducts connected to respective exhaust ports of the negative pressure isolation chambers;
a variable air volume exhaust damper installed in each of the exhaust ducts to change the amount of air discharged from the negative pressure isolation chamber according to a preset pressure for the negative pressure isolation chamber;
a backflow prevention damper for exhaust which is installed in each of the exhaust ducts and prevents the air from the negative pressure isolation chamber from flowing back into the negative pressure isolation chamber;
an exhaust HEPA filter installed in the exhaust duct to filter the air passing through the variable air volume exhaust damper;
an exhaust fan unit installed in each of the exhaust ducts to exhaust the air that has passed through the exhaust HEPA filter to the outside;
a pressure sensor installed inside the negative pressure isolation chamber to sense the internal pressure of the negative pressure isolation chamber;
An indoor controller installed inside each of the negative pressure isolation chambers to control an opening rate of the variable air volume exhaust damper according to the pressure measured by the pressure sensor and the set pressure to maintain the pressure in the negative pressure isolation chamber at the set pressure; ;
Selectively operate the plurality of isolation room heating and cooling units according to a use mode including a negative pressure mode, a positive pressure mode, and a general hospital room mode of the plurality of negative pressure isolation rooms, and selectively open the distribution dampers according to whether the isolation room heating and cooling units are operated including a central controller that makes
The negative pressure isolation room is divided into an anterior chamber and a ward,
The air supply duct includes a front air supply duct connecting the isolation room air conditioning unit and the front room, and a hospital room air supply duct connecting the isolation room air conditioning unit and the hospital room,
The air conditioning system for a negative pressure isolation room, wherein the constant air volume supply damper includes a front room constant air volume supply damper installed in the front room air supply duct and a hospital room constant air volume air supply damper installed in the hospital room air supply duct. an outdoor air conditioning unit for precooling or preheating by sucking the outdoor air;
an outdoor air damper installed on the suction side of the outdoor air conditioning unit and controlling the flow rate of outdoor air flowing into the outdoor air conditioning unit to correspond to the total heating and cooling load of the plurality of negative pressure isolation rooms;
a plurality of distribution ducts configured to distribute the air from the outdoor air conditioning unit to the plurality of negative pressure isolation chambers;
a plurality of distribution dampers installed in the plurality of distribution ducts to control the flow rate of air introduced into the distribution ducts to correspond to each heating/cooling load of the plurality of negative pressure isolation rooms;
a plurality of isolation room cooling and heating units installed in the plurality of distribution ducts to suck in air pre-cooled or preheated from the outdoor air cooling unit and heat or cool it to a set temperature set in the negative pressure isolation room;
a plurality of air supply ducts respectively connecting the plurality of isolation room heating and cooling units and the plurality of negative pressure isolation rooms to supply air from the isolation room heating and cooling unit to the negative pressure isolation room, respectively;
a constant air quantity supply damper installed in each of the air supply ducts to constantly supply a blow rate of air from the isolation room heating and cooling unit to the negative pressure isolation chamber;
a HEPA filter for supply air that is detachably installed at the air supply ports of the negative pressure isolation chambers and filters the air that has passed through the constant air quantity supply air damper;
a circulation duct for sucking air from the negative pressure isolation chamber and circulating it to the HEPA filter for supply air;
a circulation damper installed to open and close the circulation duct;
a plurality of exhaust ducts connected to respective exhaust ports of the negative pressure isolation chambers;
a HEPA filter for exhaust which is detachably installed at the exhaust ports of the negative pressure isolation chambers and filters the air from the negative pressure isolation chambers;
a variable air volume exhaust damper installed in each of the exhaust ducts to change the amount of air discharged from the negative pressure isolation chamber according to a preset pressure for the negative pressure isolation chamber;
an exhaust fan unit installed in each of the exhaust ducts to exhaust the air from the negative pressure isolation chamber to the outside;
a pressure sensor installed inside each of the negative pressure isolation chambers to sense the internal pressure of the negative pressure isolation chamber;
An indoor controller installed inside each of the negative pressure isolation chambers to control an opening rate of the variable air volume exhaust damper according to the pressure measured by the pressure sensor and the set pressure to maintain the pressure in the negative pressure isolation chamber at the set pressure; ;
Selectively operate the plurality of isolation room heating and cooling units according to a use mode including a negative pressure mode, a positive pressure mode, and a general hospital room mode of the plurality of negative pressure isolation rooms, and selectively open the distribution dampers according to whether the isolation room heating and cooling units operate including a central controller that makes
The negative pressure isolation room is divided into an anterior chamber and a ward,
The exhaust duct includes a front room exhaust duct connecting the front room and the exhaust fan unit, and a hospital room exhaust duct connecting the hospital room and the exhaust fan unit,
The air conditioning system for a negative pressure isolation room, wherein the variable air volume exhaust damper includes a front room variable air volume exhaust damper installed in the front room exhaust duct and a hospital room variable air volume exhaust damper installed in the hospital room exhaust duct. an outdoor air conditioning unit for precooling or preheating by sucking the outdoor air;
an outdoor air damper installed on the suction side of the outdoor air conditioning unit and controlling the flow rate of outdoor air flowing into the outdoor air conditioning unit to correspond to the total heating and cooling load of the plurality of negative pressure isolation rooms;
a plurality of distribution ducts configured to distribute the air from the outdoor air conditioning unit to the plurality of negative pressure isolation chambers;
a plurality of distribution dampers installed in the plurality of distribution ducts to control the flow rate of air introduced into the distribution ducts to correspond to each heating/cooling load of the plurality of negative pressure isolation rooms;
a plurality of isolation room cooling and heating units installed in the plurality of distribution ducts to suck in air pre-cooled or preheated from the outdoor air cooling unit and heat or cool it to a set temperature set in the negative pressure isolation room;
a plurality of air supply ducts respectively connecting the plurality of isolation room heating and cooling units and the plurality of negative pressure isolation rooms to supply air from the isolation room heating and cooling unit to the negative pressure isolation room, respectively;
a constant air quantity supply damper installed in each of the air supply ducts to constantly supply a blow rate of air from the isolation room heating and cooling unit to the negative pressure isolation room;
a backflow prevention damper for supply air installed in each of the air supply ducts to prevent the air inside the negative pressure isolation room from flowing back to the isolation room heating/cooling unit;
a plurality of exhaust ducts connected to respective exhaust ports of the negative pressure isolation chambers;
a variable air volume exhaust damper installed in each of the exhaust ducts to change the amount of air discharged from the negative pressure isolation chamber according to a preset pressure for the negative pressure isolation chamber;
a backflow prevention damper for exhaust which is installed in each of the exhaust ducts and prevents the air from the negative pressure isolation chamber from flowing back into the negative pressure isolation chamber;
an exhaust HEPA filter installed in the exhaust duct to filter the air passing through the variable air volume exhaust damper;
an exhaust fan unit installed in each of the exhaust ducts to exhaust the air that has passed through the exhaust HEPA filter to the outside;
a pressure sensor installed inside the negative pressure isolation chamber to sense the internal pressure of the negative pressure isolation chamber;
An indoor controller installed inside each of the negative pressure isolation chambers to control an opening rate of the variable air volume exhaust damper according to the pressure measured by the pressure sensor and the set pressure to maintain the pressure in the negative pressure isolation chamber at the set pressure; ;
Selectively operate the plurality of isolation room heating and cooling units according to a use mode including a negative pressure mode, a positive pressure mode, and a general hospital room mode of the plurality of negative pressure isolation rooms, and selectively open the distribution dampers according to whether the isolation room heating and cooling units are operated including a central controller that makes
The negative pressure isolation room is divided into an anterior chamber and a ward,
The exhaust duct includes a front room exhaust duct connecting the front room and the exhaust fan unit, and a hospital room exhaust duct connecting the hospital room and the exhaust fan unit,
The air conditioning system for a negative pressure isolation room, wherein the variable air volume exhaust damper includes a front room variable air volume exhaust damper installed in the front room exhaust duct and a hospital room variable air volume exhaust damper installed in the hospital room exhaust duct. an outdoor air conditioning unit for precooling or preheating by sucking the outdoor air;
an outdoor air damper installed on the suction side of the outdoor air conditioning unit and controlling the flow rate of outdoor air flowing into the outdoor air conditioning unit to correspond to the total heating and cooling load of the plurality of negative pressure isolation rooms;
a plurality of distribution ducts configured to distribute the air from the outdoor air conditioning unit to the plurality of negative pressure isolation chambers;
a plurality of distribution dampers installed in the plurality of distribution ducts to control the flow rate of air introduced into the distribution ducts to correspond to each heating/cooling load of the plurality of negative pressure isolation rooms;
a plurality of isolation room cooling and heating units installed in the plurality of distribution ducts to suck in air pre-cooled or preheated from the outdoor air cooling unit and heat or cool it to a set temperature set in the negative pressure isolation room;
a plurality of air supply ducts respectively connecting the plurality of isolation room heating and cooling units and the plurality of negative pressure isolation rooms to supply air from the isolation room heating and cooling unit to the negative pressure isolation room, respectively;
a constant air quantity supply damper installed in each of the air supply ducts to constantly supply a blow rate of air from the isolation room heating and cooling unit to the negative pressure isolation chamber;
a HEPA filter for supply air that is detachably installed at the air supply ports of the negative pressure isolation chambers and filters the air that has passed through the constant air quantity supply air damper;
a circulation duct for sucking air from the negative pressure isolation chamber and circulating it to the HEPA filter for supply air;
a circulation damper installed to open and close the circulation duct;
a plurality of exhaust ducts connected to respective exhaust ports of the negative pressure isolation chambers;
a HEPA filter for exhaust which is detachably installed at the exhaust ports of the negative pressure isolation chambers and filters the air from the negative pressure isolation chambers;
a variable air volume exhaust damper installed in each of the exhaust ducts to change the amount of air discharged from the negative pressure isolation chamber according to a preset pressure for the negative pressure isolation chamber;
an exhaust fan unit installed in each of the exhaust ducts to exhaust the air from the negative pressure isolation chamber to the outside;
a pressure sensor installed inside each of the negative pressure isolation chambers to sense the internal pressure of the negative pressure isolation chamber;
An indoor controller installed inside each of the negative pressure isolation chambers to control an opening rate of the variable air volume exhaust damper according to the pressure measured by the pressure sensor and the set pressure to maintain the pressure in the negative pressure isolation chamber at the set pressure; ;
Selectively operate the plurality of isolation room heating and cooling units according to a use mode including a negative pressure mode, a positive pressure mode, and a general hospital room mode of the plurality of negative pressure isolation rooms, and selectively open the distribution dampers according to whether the isolation room heating and cooling units are operated including a central controller that makes
In the negative pressure mode of the negative pressure isolation room,
The central controller turns on the air conditioning unit connected to the negative pressure isolation room, and opens the outdoor air damper, the distribution damper, and the constant air volume supply damper,
The indoor controller is an air conditioning system for a negative pressure isolation room to control an opening rate of the variable air volume exhaust damper according to a set pressure set for the negative pressure isolation room. an outdoor air conditioning unit for precooling or preheating by sucking the outdoor air;
an outdoor air damper installed on the suction side of the outdoor air conditioning unit and controlling the flow rate of outdoor air flowing into the outdoor air conditioning unit to correspond to the total heating and cooling load of the plurality of negative pressure isolation rooms;
a plurality of distribution ducts configured to distribute the air from the outdoor air conditioning unit to the plurality of negative pressure isolation chambers;
a plurality of distribution dampers installed in the plurality of distribution ducts to control the flow rate of air introduced into the distribution ducts to correspond to each heating/cooling load of the plurality of negative pressure isolation rooms;
a plurality of isolation room cooling and heating units installed in the plurality of distribution ducts to suck in air pre-cooled or preheated from the outdoor air cooling unit and heat or cool it to a set temperature set in the negative pressure isolation room;
a plurality of air supply ducts respectively connecting the plurality of isolation room heating and cooling units and the plurality of negative pressure isolation rooms to supply air from the isolation room heating and cooling unit to the negative pressure isolation room, respectively;
a constant air quantity supply damper installed in each of the air supply ducts to constantly supply a blow rate of air from the isolation room heating and cooling unit to the negative pressure isolation room;
a backflow prevention damper for supply air installed in each of the air supply ducts to prevent the air inside the negative pressure isolation room from flowing back to the isolation room heating/cooling unit;
a plurality of exhaust ducts connected to respective exhaust ports of the negative pressure isolation chambers;
a variable air volume exhaust damper installed in each of the exhaust ducts to change the amount of air discharged from the negative pressure isolation chamber according to a preset pressure for the negative pressure isolation chamber;
a backflow prevention damper for exhaust which is installed in each of the exhaust ducts and prevents the air from the negative pressure isolation chamber from flowing back into the negative pressure isolation chamber;
an exhaust HEPA filter installed in the exhaust duct to filter the air passing through the variable air volume exhaust damper;
an exhaust fan unit installed in each of the exhaust ducts to exhaust the air that has passed through the exhaust HEPA filter to the outside;
a pressure sensor installed inside the negative pressure isolation chamber to sense the internal pressure of the negative pressure isolation chamber;
An indoor controller installed inside each of the negative pressure isolation chambers to control an opening rate of the variable air volume exhaust damper according to the pressure measured by the pressure sensor and the set pressure to maintain the pressure in the negative pressure isolation chamber at the set pressure; ;
Selectively operate the plurality of isolation room heating and cooling units according to a use mode including a negative pressure mode, a positive pressure mode, and a general hospital room mode of the plurality of negative pressure isolation rooms, and selectively open the distribution dampers according to whether the isolation room heating and cooling units are operated including a central controller that makes
In the negative pressure mode of the negative pressure isolation room,
The central controller turns on the air conditioning unit connected to the negative pressure isolation room, and opens the outdoor air damper, the distribution damper, and the constant air volume supply damper,
The indoor controller is an air conditioning system for a negative pressure isolation room to control an opening rate of the variable air volume exhaust damper according to a set pressure set for the negative pressure isolation room. an outdoor air conditioning unit for precooling or preheating by sucking the outdoor air;
an outdoor air damper installed on the suction side of the outdoor air conditioning unit and controlling the flow rate of outdoor air flowing into the outdoor air conditioning unit to correspond to the total heating and cooling load of the plurality of negative pressure isolation rooms;
a plurality of distribution ducts configured to distribute the air from the outdoor air conditioning unit to the plurality of negative pressure isolation chambers;
a plurality of distribution dampers installed in the plurality of distribution ducts to control the flow rate of air introduced into the distribution ducts to correspond to each heating/cooling load of the plurality of negative pressure isolation rooms;
a plurality of isolation room cooling and heating units installed in the plurality of distribution ducts to suck in air pre-cooled or preheated from the outdoor air cooling unit and heat or cool it to a set temperature set in the negative pressure isolation room;
a plurality of air supply ducts respectively connecting the plurality of isolation room heating and cooling units and the plurality of negative pressure isolation rooms to supply air from the isolation room heating and cooling unit to the negative pressure isolation room, respectively;
a constant air quantity supply damper installed in each of the air supply ducts to constantly supply an airflow amount of the air from the isolation room heating and cooling unit to the negative pressure isolation room;
a HEPA filter for supply air that is detachably installed at the air supply ports of the negative pressure isolation chambers and filters the air that has passed through the constant air quantity supply air damper;
a circulation duct for sucking air from the negative pressure isolation chamber and circulating it to the HEPA filter for supply air;
a circulation damper installed to open and close the circulation duct;
a plurality of exhaust ducts connected to respective exhaust ports of the negative pressure isolation chambers;
a HEPA filter for exhaust which is detachably installed at the exhaust ports of the negative pressure isolation chambers and filters the air from the negative pressure isolation chambers;
a variable air volume exhaust damper installed in each of the exhaust ducts to change the amount of air discharged from the negative pressure isolation chamber according to a preset pressure for the negative pressure isolation chamber;
an exhaust fan unit installed in each of the exhaust ducts to exhaust the air from the negative pressure isolation chamber to the outside;
a pressure sensor installed inside each of the negative pressure isolation chambers to sense the internal pressure of the negative pressure isolation chamber;
An indoor controller installed inside each of the negative pressure isolation chambers to control an opening rate of the variable air volume exhaust damper according to the pressure measured by the pressure sensor and the set pressure to maintain the pressure in the negative pressure isolation chamber at the set pressure; ;
Selectively operate the plurality of isolation room heating and cooling units according to a use mode including a negative pressure mode, a positive pressure mode, and a general hospital room mode of the plurality of negative pressure isolation rooms, and selectively open the distribution dampers according to whether the isolation room heating and cooling units are operated including a central controller that makes
In the positive pressure mode of the negative pressure isolation room and the general hospital room mode,
The central controller turns on the isolation room air conditioning unit connected to the negative pressure isolation room, and opens the outdoor air damper, the distribution damper, the circulation damper, and the constant air quantity supply damper,
The indoor controller is an air conditioning system for a negative pressure isolation room to control an opening rate of the variable air volume exhaust damper according to a set pressure set for the negative pressure isolation room. 8. The method according to any one of claims 1 to 7,
The isolation room heating and cooling unit,
A case, a blower provided inside the case to suck in and blow air pre-cooled or preheated by the outdoor air conditioning unit, and a cold/hot water coil for heating or cooling the air blown by the blower to the set temperature using cold/hot water and a hot and cold water valve for controlling the amount of hot and cold water supplied to the cold and hot water coil,
A temperature sensor for sensing the internal temperature of the negative pressure isolation chamber is installed inside the negative pressure isolation chamber,
At least one of the indoor controller and the central controller controls the cold/hot water valve and the blower according to the temperature sensed by the temperature sensor and the preset temperature. 8. The method according to any one of claims 1 to 7,
The central controller is
An air conditioning system of a negative pressure isolation room for proportionally controlling an opening rate of the outdoor air damper according to the number of operation of the plurality of isolation room heating and cooling units. 8. The method according to any one of claims 1 to 7,
Further comprising an indoor air sensor for detecting the indoor air quality of the negative pressure isolation room in real time,
The central controller is an air conditioning system of a negative pressure isolation room to control an opening rate of the outdoor air damper according to the indoor air quality detected by the indoor air sensor. 4. The method according to claim 1 or 3,
The HEPA filter for the air supply is detachably coupled to the air supply port of the negative pressure isolation room, and is detachably detached during the normal hospital room mode of the negative pressure isolation room,
The HEPA filter for exhaust is detachably coupled to the exhaust duct or the exhaust port of the negative pressure isolation room, and is detachable from the negative pressure isolation room in a general hospital room mode.

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