KR20220064853A - negative pressure isolation ward container system - Google Patents

Abstract

The present invention relates to a container. In particular, the container is configured to isolate and hospitalize patients, and to prevent external spread of pathogens and to safely collect excreta from the patients when medical staff treats or nurses the patients. In order to achieve the above object, the negative pressure isolation ward container system according to the present invention comprises: a container (100) having hospital rooms (101A, 101B) and a waiting room (130) therein; an external access door (140A) formed on the container (100) so that people can come and go from an outside of the container (100) to the waiting room (130); a hospital room entrance door (140C) installed to partition the waiting room (130) and the hospital rooms (101A, 101B) so that people can come and go from the waiting room (130) to the hospital rooms (101A, 101B); an unlocking device (141) installed outside the container (100) to lock the external access door (140A); an unlocking device (141) installed inside the waiting room (130) to lock the external access door (140A); an unlocking device (141) installed inside the waiting room (130) to lock the hospital room entrance door (140C); and an unlocking device (141) installed inside the hospital rooms (101A, 101B) to lock the hospital room entrance door (140C).

Description

Negative pressure isolation ward container system

The present invention relates to a negative pressure isolation ward container system constructed by interconnecting negative pressure isolation ward containers. In particular, when a patient is isolated and hospitalized, and a medical staff treats or cares for a patient, the external spread of pathogens is prevented as well as various according to the occurrence degree of the patient. It is configured so that the hospital rooms can be connected and used in a complex manner.

Infectious pathogens are usually transmitted by patient contact. In particular, in the case of respiratory pathogens, pathogens are spread into the air through droplets generated during breathing or conversation of a patient, and pathogens from the spread droplets are introduced into the respiratory tract of others and are transmitted.

Therefore, in the case of respiratory patients, they cannot be admitted to the general ward, they are hospitalized in a separate isolation ward, and treatment is also received in the isolation ward.

Patients with respiratory diseases are hospitalized in an isolated negative pressure ward, and it is difficult to secure a negative pressure isolation ward because the negative pressure ward costs more to install than a general ward and is difficult to manage.

Recently, Middle East Respiratory Syndrome (MERS), Severe Acute Respiratory Syndrom (SARS), Avian Influenza Human Infection (AIHI), Novel swine-origin influenza A ( As various infectious diseases such as H1N1)), Ebola hemorrhagic fever, and corona virus infection-19 (COVID-19) spread, the need for negative pressure isolation changes is increasing, but as described above, installation costs and management are difficult. It is difficult to meet demand.

An object of the present invention is to configure negative pressure isolation fluctuations using a container designed with a closed structure so that negative pressure isolation fluctuations can be quickly secured and supplied when the number of patients with infectious respiratory diseases increases.

In general, a container is a box-shaped article for storing and transporting cargo, and is manufactured with care in preventing leakage. When manufacturing containers to prevent the products stored inside from being damaged by rainwater, focus is placed on preventing leakage.

As described above, a container is an article manufactured with an emphasis on blocking from the outside, and when a container is used as an isolation ward, the original purpose of the container and the purpose of the isolation ward are similar.

In this regard, even in the prior art, technologies for the purpose of configuring a conventional container as a negative pressure isolation ward have been developed, but the development of a negative pressure ward container that is more reasonable and conforms to the purpose of the negative pressure isolation ward is further required, and a number of negative pressure isolation wards have been developed. The development of a structural system that can secure more negative pressure wards by effectively connecting containers is required.

Republic of Korea Patent Publication No. 10-2164518 (Announcement date October 12, 2020) Republic of Korea Patent Publication No. 10-2164523 (published on October 12, 2020)

The present invention was invented to solve the problems of the prior art as described above, and an object of the present invention is to provide a negative pressure isolation ward container system configured to be used by connecting several wards in a complex manner according to the degree of occurrence of the patient.

A negative pressure isolation ward container system according to the present invention for achieving the above object is a plurality of containers having a hospital room and a waiting room therein, a passage connecting the plurality of containers, and a plurality of containers respectively formed in response to the passage It includes an access door and an access door formed in each or any one of the plurality of containers to enter or exit the waiting room from the outside, and the passage and the plurality of containers are hermetically connected to the outside.

Further, according to a preferred embodiment of the present invention, the passage interconnects the waiting rooms formed in the plurality of containers.

In addition, according to a preferred embodiment of the present invention, it further includes an entrance door installed to partition the waiting room and the hospital room so that the patient can come and go from the waiting room to the hospital room, and the entrance and exit for dividing the room and the waiting room, the waiting room and the passage, and the inside and the outside of the container The door is equipped with a lock release device for unlocking the access door, respectively, on the entry side and the exit side.

Further, according to a preferred embodiment of the present invention, the first and second hospital rooms are formed on both sides of the interior of the container, and the waiting room is formed between the first and second hospital rooms.

In addition, according to a preferred embodiment of the present invention, a sewage tank installed on the bottom surface of the container for storing excrement and sewage discharged from the hospital room, and the sewage tank extending from the sewage tank to the outside of the container to discharge the manure and sewage stored in the sewage tank It further includes a discharge pipe, a monitoring window mounted on the sewage tank to monitor the amount of manure and sewage stored in the sewage tank, and a cleaning pipe extending from the sewage tank to the outside of the container to supply washing water to the sewage tank.

In addition, according to a preferred embodiment of the present invention, a hot wire for preventing freezing is mounted on the sewage tank, and the hot wire is connected to a connection part for supplying power.

In addition, according to a preferred embodiment of the present invention, a negative pressure device is mounted on the inner wall facing the entrance door that divides the hospital room and the waiting room, and the negative pressure device sucks air inside the hospital room and exhausts it to the outside of the container. to filter out pathogens.

In addition, according to a preferred embodiment of the present invention, interlocking control so that the other access door is not opened when any one of the access door dividing the outside and the inside of the container and the entrance door dividing the hospital room and the waiting room is open do.

In addition, according to a preferred embodiment of the present invention, among the external access door dividing the outside of the container and the inside of the waiting room, the passage entrance door dividing the waiting room and the passage, and the hospital room entrance door dividing the waiting room and the hospital room, the external access door If any one of the entrance and exit doors is open, the door to the hospital room is not opened. The access door and the aisle access door are not opened, and the external access door and the aisle access door are interlocked and controlled so that the door can be opened only when the hospital room access door is closed.

Further, according to a preferred embodiment of the present invention, the access door is a transparent sliding door.

In addition, according to a preferred embodiment of the present invention, in the waiting room, an oxygen tank storing oxygen so as to supply oxygen to the hospital room, a speaker generating a warning sound according to a signal generated in the hospital room, and the pressure or differential pressure between the hospital room and the waiting room A pressure display indicating

Further, according to a preferred embodiment of the present invention, a toilet is installed inside the hospital room, a water tank is located in the toilet, and a water supply pipe extending from the water tank extends to the outside of the container.

Further, according to a preferred embodiment of the present invention, a power cabinet is located on one side of the container, a distribution board is mounted inside the power cabinet, and an external power cable is connected to the distribution board.

Further, according to a preferred embodiment of the present invention, the solar panel is mounted on the upper surface of the container, and the cable extending from the solar panel is extended to the power cabinet.

In addition, according to a preferred embodiment of the present invention, the reinforcing bar is fixed to the upper surface of the container so that another container can be seated.

In addition, according to a preferred embodiment of the present invention, the slope footrest is located on the outside of the container in response to the entrance door formed to allow the container to enter or exit the waiting room from the outside.

In addition, according to a preferred embodiment of the present invention, it includes an exhaust pipe extending from the sewage tank to the outside of the container, and an exhaust fan mounted on the end of the exhaust pipe and exhausting clean air filtered by pathogens through a built-in filter to the outside of the exhaust pipe .

In addition, according to a preferred embodiment of the present invention, the support is fixed to the bottom surface of the passage so that the floor of the waiting room and the floor of the passage coincide to support the passage.

As described above, the negative pressure isolation ward container system according to the present invention secures many wards by connecting the negative pressure isolation ward containers for each unit and reduces the contact space with the outside through the passage between the containers. It has the advantage of being able to block the spread of infectious pathogens.

When the number of patients subject to isolation increases rapidly, a plurality of negative pressure isolation ward containers can be connected to secure a ward, which has the advantage of being able to respond appropriately according to the increase or decrease of patients.

The negative pressure isolation ward container system has the advantage that it is easy to quickly distribute the negative pressure isolation ward container system because it does not require a long construction period due to the construction of the ward as in the prior art as a container with excellent blocking effect from the outside is used as the isolation ward.

The negative pressure isolation ward container system according to the present invention is an external access door installed between the hospital room and the waiting room so that infectious pathogens do not spread to the outside of the container in the hospital room and the waiting room. It is configured to interlock the opening and closing of the access door and manually check the status of the other party's access door and open and close the access door when an error occurs in the interlocking control. Therefore, it is possible to solve the problem of opening all of the access doors by mistake of the medical staff or the patient, and lock release devices are installed on both sides of the access door, respectively, to prevent the patient from moving out of the hospital room without permission.

In addition, in the negative pressure isolation ward container system according to the present invention, a sewage discharge pipe and a washing pipe are connected to the sewage tank to prevent the spread of infectious pathogens according to the patient's excreta collection, and the sewage discharge pipe and the washing pipe are connected to discharge the excrement in a sealed state and also supply washing water and can be cleaned, and a filter is installed on the exhaust fan to prevent external spread of infectious pathogens.

1 is a conceptual diagram showing a negative pressure isolation ward container system according to the present invention,
Figure 2 is a front view of the first container shown in Figure 1,
3 is a rear view of the second container shown in FIG. 1;
4 is a left side view of the first container shown in FIG. 1;
FIG. 5 is a right side view of the first container shown in FIG. 1 .
Figure 6 is a plan sectional view of the negative pressure isolation ward container system shown in Figure 1,
Figure 7 is an image showing the hospital room shown in Figure 1,
8 is an image showing a negative pressure device installed in the hospital room shown in FIG. 7;
9 is an image showing the interior of the toilet installed in the hospital room shown in FIG. 7,
FIG. 10 is a plan sectional view showing the sewage tank of the first container shown in FIG. 1 .

Hereinafter, a preferred embodiment of the negative pressure isolation ward container system according to the present invention will be described in detail with reference to the accompanying drawings.

In the drawings, Figure 1 is a conceptual diagram showing a negative pressure isolation ward container system according to the present invention, Figure 2 is a front view of the first container shown in Figure 1, Figure 3 is a rear view of the second container shown in Figure 1 , FIG. 4 is a left side view of the first container shown in FIG. 1 , and FIG. 5 is a right side view of the first container shown in FIG. 1 . And Figure 6 is a plan sectional view of the negative pressure isolation ward container system shown in Figure 1, Figure 7 is an image showing the hospital room shown in Figure 1, Figure 8 is an image showing the negative pressure device installed in the hospital room shown in Figure 7, 9 is an image showing the interior of the toilet installed in the hospital room shown in FIG. 7 , and FIG. 10 is a plan sectional view showing the sewage tank of the first container shown in FIG. 1 .

As shown in Figure 1, the negative pressure isolation ward container system is a structure in which a plurality of negative pressure isolation ward containers (hereinafter referred to as 'container 100') are connected through a mutual passage 200, each container 100 The provided hospital rooms (101A, 101B) are configured so that medical personnel can perform medical treatment while moving through the passage (200).

Here, each of the hospital rooms 101A and 101B of the container 100 maintains a negative pressure state and blocks the air inside the hospital rooms 101A and 101B from being exhausted to the outside of the container 100 .

The structure of each container will be described in detail below.

1 to 6, the container 100 has a first ward 101A and a second ward 101B formed on the left and right sides of the container 100, and a first ward 101A and a second ward ( A waiting room 130 is formed between 101B). And in the waiting room 130, an external access door 140A formed on one of the front and rear surfaces of the container 100 and a passage access door 140B formed on the other side of the container 100 are formed, and the waiting room 130 ) and the first hospital room (101A) and the waiting room 130 and the inner wall dividing the second hospital room (101B), respectively, a hospital room entrance door (140C) is formed.

A first window 143A formed on the front side of the container 100 and a second window 143B formed on the rear surface of the container 100 are formed in the first hospital room 101A and the second hospital room 101B, respectively. The external access door 140A, the hospital room entrance door 140C, and the first window 143A and the second window 143B have excellent airtightness and block the flow of air in the closed state.

Here, as shown in FIG. 3 , the external entrance door 140A to the hospital room entrance door 140C are transparent sliding automatic doors, and each entrance door 140A, 140B, 140C operates in conjunction as described later. Alternatively, each can be manually operated, and a lock release device 141 is installed on the entry side and exit side of each entrance door 140A, 140B, 140C to limit the patient's entry in the manual operation. In order to advance or enter through each of the access doors 140A, 140B, and 140C, the corresponding access doors 140A, 140B, and 140C are configured to be opened only when the lock is released by the lock release device 141 .

In the waiting room 130, an oxygen tank 131 for supplying oxygen to the first hospital room 101A and the second hospital room 101B is installed, and the oxygen stored in the oxygen tank 131 through the manifold is stored in the first hospital room 101A. ) and the second ward 101B, so that the patient can inhale oxygen.

And on the inner wall of the waiting room 130, a pressure display 133 for displaying the internal pressure of the first and second hospital rooms 101A and 101B, the internal pressure of the waiting room 130, and the difference between the two internal pressures is mounted. A speaker 135 that generates a warning sound when an emergency bell is pressed in any one of the first ward 101A and the second ward 101B is mounted in the waiting room 130 .

On the other hand, as shown in FIGS. 7 and 8 , in the first ward 101A and the second ward 101B, a bed 102 on which a patient can lie, a storage box 103 for accommodating medical equipment, and a cart 105 ), and a negative pressure device 120 that draws in air from each of the hospital rooms 101A and 101B and discharges it to the outside of the container 100 is mounted on the inner wall facing the hospital room entrance door 140C.

And partition walls for forming the toilet 110 are formed on the inner wall side on which the negative pressure device 120 is mounted, and the toilet entrance door 110D is formed on the partition wall.

As shown in FIG. 9 , a sink 113 and a toilet 111 are installed inside the toilet 110 , and a water tank 115 is mounted on one side of the inside of the toilet 110 .

On the bottom of the container 100, as shown in FIG. 10, a waste water tank 160 is installed in each of the first hospital room 101A and the second hospital room 101B, one at a time, and a washbasin 113 and a toilet 111. The sewage drained through the effluent is stored in each sewage tank 160 .

On the other hand, an air conditioner 137 is installed in the first hospital room 101A, the second hospital room 101B, and the waiting room 130, respectively, to cool and cool the inside of the hospital rooms 101A and 101B, and an outdoor unit 138 connected to the air conditioner 137. is mounted on the outside of the container 100 .

A water supply pipe 117 for supplying water to the water tank 115 located in the toilet 110 of each hospital room 101A, 101B is formed on the outside of the container 100, and to discharge the sewage water from the sewage tank 160 A monitoring window 163 for observing the amount of sewage in the discharge pipe 161 and the sewage tank 160 for A negative pressure hood 121 for evacuating to the outside of the container 100 is mounted on the outer wall of the container 100 .

In addition, a heating wire (not shown) surrounding the sewage tank 160 is installed in order to prevent the sewage water of the sewage tank 160 mounted on the bottom of the container 100 from freezing in winter, and a heating wire is installed on the outside of the container 100 . A connected connection portion 155 is formed. Therefore, when power is supplied through the connection part 155, heat is generated from the heating wire, the frozen sewage water is thawed by the heat, and an appropriate temperature is maintained.

In addition, in the waste water tank 160 , an exhaust pipe extends to the top of the container, and an exhaust fan 167 is mounted on the exhaust pipe to exhaust odors from the inside of the waste water tank 160 to the outside of the container 100 . At this time, the exhaust fan 167 is equipped with a filter to filter the air exhausted from the sewage tank 160 to the outside. As such, as the air exhausted from the waste water tank 160 is filtered, infectious pathogens that can be introduced into the waste water tank 160 through the toilet 111 are exhausted to the outside of the container 100 through the exhaust pipe and transmitted to others. can be blocked

In addition, a power cabinet 150 is mounted on one side of the container 100 , a distribution board 151 is mounted inside the power cabinet 150 , and an external power cable is connected to the distribution board 151 . Solar panels 153 are fixed to the upper surface of the container 100 , and power generated from the solar panel 153 is charged in a rechargeable battery accommodated in the power cabinet 150 . Therefore, the equipment installed in the container 100 is operated with external power or power generated from the solar panel 153 .

Hereinafter, the operation relationship of the container 100 and the opening/closing order of the access doors 140A, 140B, and 140C will be described in detail.

When the external access door 140A, the hospital room access door 140C, and the first window 143A and the second window 143B are closed, the negative pressure device 120 mounted on the hospital room 101A, 101B is operated to operate the hospital room. The air inside the 101A and 101B is introduced into the negative pressure unit 120 and then exhausted to the outside of the container 100 through the negative pressure unit hood 121 .

By such a flow of air, the hospital rooms 101A and 101B are in a negative pressure state lower than atmospheric pressure. In this state, even if the hospital room entrance door 140C dividing the waiting room 130 and the hospital rooms 101A and 101B is opened, the air in the waiting room 130 flows to the hospital rooms 101A and 101B due to the pressure difference. Pathogens spread in 101A and 101B do not spread to the waiting room 130 , and are filtered by a filter installed in the negative pressure device 120 while staying in the hospital rooms 101A and 101B or passing the negative pressure device 120 . Clean air filtered with pathogens is exhausted to the outside of the container 100 through the negative pressure hood 121 .

Specifically, the negative pressure unit 120 includes a pre-filter and a HEPA filter, so that the air in the hospital rooms 101A and 101B passes through the pre-filter and the HEPA filter. At this time, droplets and pathogens contained in the air are filtered by a pre-filter and a HEPA filter to prevent the spread of pathogens.

On the other hand, in order to pass through each of the access doors (140A, 140B, 140C) must be unlocked. Only medical staff should be able to unlock and enter each access door 140A, 140B, 140C, and the patient should be restricted from moving from the wards 101A, 101B to the waiting room 130. This is for the purpose of preventing the spread of pathogens as the patient moves to the waiting room 130 .

In addition, when any one of the external access door 140A and the passage access door 140B is opened, the opening of the hospital room access door 140C should be restricted.

In a state in which either one of the external access door 140A and the passage access door 140B is opened, the air of the waiting room 130 is exposed to the outside. This is because the air of 101A and 101B is exposed to the outside of the container 100 through the waiting room 130 and can be diffused to the outside of the corresponding container 100 .

Therefore, it is preferable that interlocking control is possible so that the hospital room access door 140C is not opened in a state in which any one of the external access door 140A and the passage access door 140B is opened.

In addition, each of the access doors 140A, 140B, 140C is provided with a lock release device 141 on both sides, respectively. Therefore, in order to move from the outside of the container 100 to the inside of the hospital rooms 101A and 101B, the lock must be unlocked twice to be able to enter the hospital rooms 101A and 101B, and from the hospital rooms 101A and 101B to the outside of the container 100 Even if you advance to the , unlocking must be done twice. This is to prevent the patient from escaping to the outside of the container 100 without permission, and in particular, when opening the hospital room access door 140C in the hospital rooms 101A and 101B, a time for unlocking the lock is required. It can be visually confirmed whether the door 140A or the passage access door 140B is opened. This is to solve the problem of an error occurring in the interlocking control or unconsciously opening the access door 140C. In this way, in order to be able to check whether the external access door 140A or the passage access door 140B is opened in the hospital room, it is preferable that the hospital room access door 140C is transparent, and vice versa. In order to check whether the 140C is opened, it is preferable that the external access door 140A and the passage access door 140B are also transparent.

On the other hand, when the patient is active in the ward 101A, 101B and washes or excretes in the toilet 110 , sewage and excreta are stored in the sewage tank 160 mounted on the bottom of the container 100 . The amount of sewage stored in the sewage tank 160 can be checked through the monitoring window 163, and in order to discharge the sewage filled in the sewage tank 160, the sewage tank 160 through a discharge pipe 161 extended to the sewage tank 160 ( 160) is discharged and treated. Even at this time, by sealing the connection part of the external waste water tank and the discharge pipe 161, and discharging the waste water through a vacuum pump, it is possible to prevent pathogens from spreading into the atmosphere during the waste water discharge process.

A cleaning pipe 165 is connected to the sewage tank 160, supplying washing water through the washing pipe 165 to clean the sewage tank 160, and discharging the washing water through the discharge pipe 161 to drain the sewage tank 160. Wash.

Each of the containers 100 ( 100A, 100B) configured in this way is connected to the passage 200 as shown in FIG. 1 .

The passage 200 is a structure that connects the rear surface of the first container 100A and the front surface of the second container 100B, and is a passage between the passage entrance door 140B of the first container 100A and the passage of the second container 100B. Connect the access door 140B.

The passage 200 has a box structure in which both sides facing each other are open, and one end of the passage 200 surrounds and connects the passage access door 140B of the first container 100A, and the other end of the passage 200 is the second As a structure to surround and connect the passage access door 140B of the container 100B, the interior of the passage 200 and the exterior of the passage 200 are sealed so that there is no passage. In some cases, when the passage 200 is long, although not shown in the drawing, the windows 143A and 143B or the closed windows described above may be formed on the sidewall of the passage 200 .

On the other hand, the floor of the passage 200 should coincide with the floor of the waiting room 130 of the first container 100A and the floor of the waiting room 130 of the second container 100B. To this end, the support 201 is fixed to the bottom surface of the passage 200, and the first container 100A and the second container 100B are connected in a state where the passage 200 is raised from the ground by the height of the support 201. .

The bottom of the passage 200 coincides with the floor of the waiting room 130 of the first container 100A and the floor of the waiting room 130 of the second container 100B, so that the first container 100A and the second container 100B It is constructed so that a cart, a stretcher, or a wheelchair can move it with wheels moving between them.

In addition, a slope footrest 203 is installed in the external access door 140A of the first container 100A and the external access door 140A of the second container 100B located in the front so that a stretcher or a wheelchair can be installed in the containers 100A, 100B. ) can be easily configured to move from the inside to the outside or from the outside to the inside of the container (100A, 100B).

And in explaining the negative pressure isolation ward container system according to the present invention, although it is shown in the drawing that the containers connected by the passage are located on the ground as a single storey, the containers are stacked and placed and a railing is installed in the stacked containers to install the negative pressure isolation ward The container system can also be configured with multiple layers. To this end, a reinforcing bar 170 is fixed to the upper edge of the container so that the container can be stacked.

100, 100A, 100B: Container
101A, 101B: Hospital room
102: bed
103: storage
105 : cart
110: toilet
110D : door
111: toilet bowl
113: washbasin
115: water tank
117: water pipe
120: negative pressure
121 : Hood
130: waiting room
131: oxygen tank
133: pressure displayer
135: speaker
137: air conditioner
138: outdoor unit
140A, 140B, 140C: Entrance door
141: unlocking device
143A, 143B: window
150: power cabinet
151: distribution panel 153: solar panel
160: sewage tank
161: discharge pipe
163: watch window
165: cleaning tube
167: exhaust fan
170: reinforcing bar
200: passage
201 : support
203: slope scaffold

Claims (18)

A plurality of containers 100 having a hospital room (101A, 101B) and a waiting room 130 therein;
a passage 200 connecting the plurality of containers 100;
An access door 140B respectively formed in the plurality of containers 100 to correspond to the passage 200;
Each or any one of the plurality of containers 100 includes an entrance door 140A formed to enter or exit the waiting room 130 from the outside,
A negative pressure isolation ward container system, characterized in that the passage 200 and the plurality of containers 100 are hermetically connected to the outside.
According to claim 1,
The passage 200 is a negative pressure isolation ward container system, characterized in that interconnecting the waiting rooms 130 formed in the plurality of containers (100).
3. The method of claim 2,
It further includes an entrance door (140C) installed by dividing the waiting room (130) and the hospital room (101A, 101B) so as to be able to come and go from the waiting room (130) to the hospital rooms (101A, 101B),
Hospital rooms 101A, 101B and waiting room 130, waiting room 130 and passage 200, and entrance and exit doors 140A, 140B, 140C dividing the inside and outside of the container 100, respectively, enter and exit the entrance side and exit side. A negative pressure isolation ward container system, characterized in that it is equipped with a lock release device (141) for unlocking the door.
4. The method of claim 3,
A first ward 101A and a second ward 101B are formed on both sides of the interior of the container 100, and a waiting room 130 is formed between the first ward 101A and the second ward 101B. negative pressure isolation ward container system.
5. The method of claim 4,
A sewage tank 160 installed on the bottom of the container 100 and storing excrement and sewage discharged from the hospital rooms 101A and 101B;
A discharge pipe 161 extending from the sewage tank 160 to the outside of the container 100 to discharge the manure and sewage stored in the sewage tank 160;
a monitoring window 163 mounted on the sewage tank 160 to monitor the amount of manure and sewage stored in the sewage tank 160;
Negative pressure isolation ward container system, characterized in that it further comprises a cleaning pipe (165) extending from the sewage tank (160) to the outside of the container (100) so as to supply the washing water to the sewage tank (160).
6. The method of claim 5,
A negative pressure isolation ward container system, characterized in that the hot wire for preventing freezing is mounted on the sewage tank 160, and the hot wire is connected to a connection part 155 for supplying power.
4. The method of claim 3,
A negative pressure device 120 is mounted on the inner wall facing the entrance door dividing the hospital rooms (101A, 101B) and the waiting room, and the negative pressure device 120 sucks the air inside the hospital rooms (101A, 101B) to the container 100 A negative pressure isolation ward container system, characterized in that it filters pathogens through a built-in filter when exhausting to the outside of the ward.
4. The method of claim 3,
When any one of the access door 140A dividing the outside and the inside of the container 100, and the entrance door 140C dividing the hospital rooms 101A and 101B and the waiting room 130 is open, the other door A negative pressure isolation ward container system, characterized in that the interlocking control is not opened.
9. The method of claim 8,
An external access door 140A dividing the outside of the container 100 and the inside of the waiting room, a passage access door 140B partitioning the waiting room 130 and the passage 200, the waiting room 130 and the hospital rooms 101A, 101B ), among the ward entrance doors 140C, when any one of the external entrance door 140A and the passage entrance door 140B is open, the ward entrance door 140C is not opened, and the external entrance door ( 140A) and the passage access door 140B are both open only when the hospital room access door 140C is closed, and when the hospital room access door 140C is open, the external access door 140A and the passage access door 140B are open. Negative pressure isolation ward container system, characterized in that interlocking control so that the external access door (140A) and the passage access door (140B) can be opened only when the hospital room access door (140C) is closed.
10. The method according to any one of claims 1 to 9,
The access door (140A, 140B, 140C) is a negative pressure isolation ward container system, characterized in that a transparent sliding door.
According to claim 1,
In the waiting room 130,
An oxygen tank 131 storing oxygen so as to supply oxygen to the hospital rooms 101A and 101B, a speaker 135 that generates a warning sound by a signal generated in the hospital rooms 101A and 101B, and the hospital rooms 101A and 101B ) and a negative pressure isolation ward container system, characterized in that the pressure displayer 133 indicating the pressure or differential pressure of the waiting room 130 is mounted.
According to claim 1,
A toilet 110 is installed inside the hospital rooms 101A and 101B, and a water tank 115 is located in the toilet 110 , and a water supply pipe 117 extending from the water tank 115 is directed to the outside of the container 100 . Negative pressure isolation ward container system, characterized in that extended.
According to claim 1,
A negative pressure isolation ward container, characterized in that a power cabinet 150 is located on one side of the container 100, a distribution board 151 is mounted inside the power cabinet 150, and an external power cable is connected to the distribution board 151 system.
14. The method of claim 13,
A negative pressure isolation ward container system, characterized in that the solar panel 153 is mounted on the upper surface of the container 100, and the cable extended from the solar panel 153 is extended to the power cabinet 150.
According to claim 1,
A negative pressure isolation ward container system, characterized in that the reinforcing bar 170 is fixed to the upper surface of the container 100 so that another container can be seated.
3. The method of claim 2,
Negative pressure isolation ward container system, characterized in that the slope scaffold 203 is located on the outside of the container 100 in response to the entrance door 140A formed so that the container can enter or exit the waiting room 130 from the outside.
6. The method of claim 5,
an exhaust pipe extending from the sewage tank 160 to the outside of the container 100;
Negative pressure isolation ward container system, which is mounted on the end of the exhaust pipe and includes an exhaust fan 167 for exhausting clean air that has filtered pathogens through a built-in filter to the outside of the exhaust pipe.
According to claim 1,
A negative pressure isolation ward container system, characterized in that the support 201 is fixed to the bottom surface of the passage 200 so that the floor of the waiting room 130 and the floor of the passage 200 coincide with the floor of the passage 200 to support the passage 200.

Images