KR102500598B1 - Negative pressure isolation system - Google Patents

Abstract

One embodiment of the present invention provides a negative pressure isolation system, and in detail, as a negative pressure isolation system installed on a ship, an ISO tank container provided with a plurality and having an accommodation space in which a subject to be isolated is accommodated and isolated, the An ISO tank container is detachably coupled, a support unit formed in a multi-layer structure, a storage unit disposed apart from the ISO tank container and storing a plurality of different fluids, and disposed apart from the ISO tank container, , A power unit for generating and storing power to be supplied to the ISO tank container, and connecting at least one of the storage unit and the power unit to the ISO tank container to supply the fluid or the power to the ISO tank container. It provides a negative pressure isolation system comprising a supply unit to.

Description

Negative pressure isolation system {Negative pressure isolation system}

The present invention relates to an apparatus and a system, and more particularly, to a negative pressure isolation system for isolating a quarantine subject.

Recently, as the number of patients with infectious diseases such as COVID-19 increases, there is a problem of lack of hospital rooms in preparation for patients who occur. As a solution to this problem, in the case of China, a prefabricated hospital room is urgently installed to respond, and in the case of Korea, a movable modular negative pressure ward is proposed.

However, in the above case, there is a limit to quickly constructing large-scale facilities, and there are limitations in that the structure is specialized for land installation, and in the case of existing hospital ships, it takes too much time to build, and due to non-standardized design, it is difficult to expand the hospital room. There is a problem that a lot of time is required for design compatibility and response to

A technical problem to be achieved by the present invention is to provide a negative pressure isolation system for maritime use, which can be standardized and modularized, and can reduce production and installation time by utilizing a maritime ISO container.

The technical problem to be achieved by the present invention is not limited to the above-mentioned technical problem, and other technical problems not mentioned can be clearly understood by those skilled in the art from the description below. There will be.

In order to achieve the above technical problem, a negative pressure isolation system according to an embodiment of the present invention is a negative pressure isolation system installed on a ship, and is provided with a plurality of ISO tank containers having an accommodation space in which an isolation subject is accommodated and isolated. And, the ISO tank container is detachably coupled, a support unit formed in a multi-layer structure, a storage unit disposed spaced apart from the ISO tank container and storing a plurality of different fluids, and spaced apart from the ISO tank container is disposed, and a power unit for generating and storing power for supplying the ISO tank container, and at least one of the storage unit and the power unit is connected to the ISO tank container to transfer the fluid or the liquid to the ISO tank container. A supply unit for supplying power may be included.

In one embodiment of the present invention, a plurality of the ISO tank containers are stacked on the support unit having a multi-layer structure, and some of the plurality of ISO tank containers face another part of the plurality of ISO tank containers. A passage may be disposed between the ISO tank containers arranged to face each other.

In one embodiment of the present invention, doedoe disposed in the passage portion, it may further include a transport unit movable between each layer of the multi-layer structure of the support unit.

In one embodiment of the present invention, the passage portion is detachably connected to the bottom surface of the passage portion, and includes a cover portion having a storage space in which the supply unit is accommodated, and the cover portion has an upper surface thereof, It may be disposed at the same height as the bottom surface of the passage part.

In one embodiment of the present invention, the supply unit has a plurality of supply units arranged to be partitioned from each other inside, and the plurality of different fluids and the power are supplied to the ISO tank container through different supply units. can

In one embodiment of the present invention, the ISO tank container is disposed between the accommodating space and the passage, and isolating the accommodating space from the outside of the ISO tank container, and the accommodating space and the isolation unit; It is spatially separated and may have a connection portion to which the supply unit is detachably connected.

In one embodiment of the present invention, an intermediate branching unit branching the supply unit toward each of the plurality of ISO tank containers may be further included.

In one embodiment of the present invention, further comprising a discharge unit for discharging the air inside the ISO tank container to the outside of the ISO tank container, wherein the discharge unit detects whether or not a virus is contained in the discharged air. A detection sensor and a sterilization unit for sterilization of discharged air may be provided.

In one embodiment of the present invention, a temperature control unit for increasing or decreasing the temperature supplied to the ISO tank container may be further included.

In one embodiment of the present invention, the storage unit includes a plurality of storage tanks, at least some of the plurality of storage tanks store liquefied gas therein, and the temperature control unit uses vaporization heat of the liquefied gas. Thus, the temperature of the fluid supplied to the ISO tank container through the supply unit may be adjusted.

In one embodiment of the present invention, further comprising a control unit for monitoring the state of the quarantined person isolated in the ISO tank container and the internal state of the ISO tank container, and controlling the internal state of the ISO tank container based on the monitoring result. can

In one embodiment of the present invention, the control unit may adjust the internal state of the ISO tank container by adjusting at least one of a temperature and a supply amount of the fluid supplied to the ISO tank container through the supply unit.

The negative pressure isolation system according to embodiments of the present invention may provide a place for isolating a plurality of quarantine subjects by using a support unit having a multi-layer grid structure and a plurality of ISO tank containers detachably connected thereto, Thanks to the simple and quick assembly of the support unit and the ISO tank container, the containment site can be secured quickly even in an emergency. In addition, since the negative pressure isolation system is installed on a ship, it is possible to completely isolate a large number of quarantine subjects without space limitations, and it is possible to move to another country requiring medical assistance by operating a ship.

The effects of the present invention are not limited to the above effects, and should be understood to include all effects that can be inferred from the description of the present invention or the configuration of the invention described in the claims.

1 is a perspective view showing a negative pressure isolation system installed on a ship according to an embodiment of the present invention.
2 shows a portion of a support unit included in a negative pressure isolation system according to an embodiment of the present invention.
3 is a side cross-sectional view showing a negative pressure isolation system according to an embodiment of the present invention.
4 is a schematic cross-sectional view of the negative pressure isolation system of FIG. 3 viewed from above.
5 shows an ISO tank container provided in a negative pressure isolation system according to an embodiment of the present invention.
6 schematically illustrates a connection structure of a negative pressure isolation system and a supply unit provided therewith according to an embodiment of the present invention.
7 shows a cross-sectional view of a supply unit according to an embodiment of the present invention.
8 is a cross-sectional view showing a portion of a negative pressure isolation system according to an embodiment of the present invention.

Hereinafter, the present invention will be described with reference to the accompanying drawings. However, the present invention may be embodied in many different forms and, therefore, is not limited to the embodiments described herein. And in order to clearly explain the present invention in the drawings, parts irrelevant to the description are omitted, and similar reference numerals are attached to similar parts throughout the specification.

Throughout the specification, when a part is said to be "connected (connected, contacted, combined)" with another part, this is not only "directly connected", but also "indirectly connected" with another member in between. "Including cases where In addition, when a part "includes" a certain component, it means that it may further include other components without excluding other components unless otherwise stated.

Terms used in this specification are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly dictates otherwise. In this specification, terms such as "include" or "have" are intended to indicate that there is a feature, number, step, operation, component, part, or combination thereof described in the specification, but one or more other features It should be understood that the presence or addition of numbers, steps, operations, components, parts, or combinations thereof is not precluded.

1 is a perspective view showing a negative pressure isolation system installed on a ship according to an embodiment of the present invention. 2 shows a portion of a support unit included in a negative pressure isolation system according to an embodiment of the present invention. 3 is a side cross-sectional view showing a negative pressure isolation system according to an embodiment of the present invention, and FIG. 4 is a cross-sectional view briefly showing the negative pressure isolation system of FIG. 3 viewed from above.

Referring to FIGS. 1 to 4 , the negative pressure isolation system 1 may be installed on the sea. Specifically, the negative pressure isolation system 1 according to an embodiment of the present invention is a system for accommodating and isolating quarantine subjects, and may be installed on a ship (S). However, the present invention is not limited thereto, and the negative pressure isolation system 1 may be installed on a marine structure (not shown) and isolate the person subject to isolation by transporting them using a transport means.

A quarantine subject isolated in the negative pressure isolation system 1 may be a patient infected with a virus that can be transmitted to others. The quarantined person may be, for example, a patient infected with Corona 19 (COVID-19). The negative pressure isolation system 1 may include a negative pressure isolation module 10 , a storage unit 20 , a power unit 30 , and a control unit 40 . And, the negative pressure isolation module 10 may include a support unit 100 and an ISO tank container 200 . In addition, the negative pressure isolation module 10 may further include a transport unit 400, a discharge unit 500, a temperature control unit 600, and an intermediate branch unit 700.

The support unit 100 may support the ISO tank container 200 . The support unit 100 may include a main support portion 100a, an auxiliary support portion 100b, and a partition support portion 100c. As exemplarily shown in FIG. 2 , the main support part 100a may be formed by connecting a plurality of frames. Specifically, the main support portion 100a may be formed by connecting a plurality of vertical frames 110 and a plurality of horizontal frames 120 arranged to cross the vertical frames 110 . Accordingly, the main support portion 100a may be formed of a grid-like structure in which a plurality of vertical frames 110 and a plurality of horizontal frames 120 are crossed and connected.

The main support part 100a may include a connection space 130 partitioned in vertical and horizontal directions by a plurality of adjacent vertical frames 110 and horizontal frames 120, wherein the connection space 130 is an ISO tank. It may be a space where the container 200 is seated. As the main support part 100a is formed as a lattice structure, a plurality of connection spaces 130 may also be provided. In this case, the ISO tank container 200 may be seated and supported in each of the plurality of connection spaces 130 .

The main support part 100a may be provided in plurality. At this time, the plurality of main supports (100a) may be arranged in parallel along the longitudinal direction (eg, the Y-axis direction) of the ship (S) so as to face each other on the ship (S). In this case, an auxiliary support part 100b may be disposed between the two main support parts 100a disposed adjacent to each other. The auxiliary support portion 100b may have a structure having the same or similar shape as the main support portion 100a. The main support part (100a) and the auxiliary support part (100b) are arranged in parallel along the longitudinal direction (Y-axis direction) of the ship (S), and may be alternately arranged with each other.

A space between the main support part 100a and the auxiliary support part 100b may be partitioned by the partition support part 100c. Specifically, the partition support portion (100c) is a direction (Y axis direction) perpendicular to the longitudinal direction (eg, X axis direction) of the main support portion (100a) and the auxiliary support portion (100b) or the longitudinal direction of the ship (S) ( Y-axis direction), it may be connected to the main support part (100a) and the auxiliary support part (100b). As an example, the partition support portion 100c may be disposed to pass through the center of the main support portion 100a and the auxiliary support portion 100b. In this case, the inner space partitioned by the main support part 100a and the auxiliary support part 100b may be divided into two by the partition support part 100c. Inside the partition support part 100c, a passage part P to be described later may be disposed.

Meanwhile, the main support part 100a and the auxiliary support part 100b may be connected to each other through a connection frame CF. Specifically, the main support part 100a and the auxiliary support part 100b disposed adjacent thereto may be connected through at least one connection frame CF. Accordingly, the stability of the coupling between the main support part 100a and the auxiliary support part 100b and the durability of the support unit 100 may be improved. Accordingly, it is possible to effectively prevent shaking of the support unit 100 and the ISO tank container 200 installed therein due to external influences such as waves during operation of the ship S, or occurrence of unnecessary vibration or damage.

As exemplarily shown in FIG. 3 , the support unit 100 may be formed in a multi-layered structure. Specifically, as described above, in the support unit 100, the main support part 100a and the auxiliary support part 100b formed in a lattice structure by connecting a plurality of frames are formed by the partition support part 100c and the connection frame CF. It may be a multi-layer lattice structure of a rectangular parallelepiped shape formed by being connected. Meanwhile, although the support unit 100 is illustratively shown in the drawing as a 4-layer lattice structure, the present invention is not limited thereto, and the support unit 100 is stacked according to the increase or decrease in the number of ISO tank containers 200 and quarantine subjects. (100) The number of stacked layers can be changed.

A plurality of ISO tank containers 200 may be disposed on each layer of the support unit 100 . Specifically, as described above, a plurality of connection spaces 130 may be provided in each layer of the support unit 100 having a rectangular parallelepiped multilayer structure. In each of the plurality of connection spaces 130, the ISO tank container 200 may be seated and supported. Some of the plurality of ISO tank containers 200 may be arranged to be spaced apart from other parts of the plurality of ISO tank containers 200 with the passage portion P interposed therebetween. At this time, the passage part P may include a main passage P1 and a sub passage P2.

Any one layer of the multi-layer structure of the multi-layer structure support unit 100, as exemplarily shown in FIG. 4, a plurality of ISO tank containers 200 is in the longitudinal direction (Y-axis direction) of the ship S Centered on the main passage (P1) provided to extend along, it may be arranged to be symmetrical to each other. As an embodiment, the plurality of ISO tank containers 200 are n (hereinafter, n is defined as an integer of 1 or more) along the width direction (X-axis direction) of the ship S, with the main passage P1 as the center. Is arranged, and n may be arranged along the opposite direction (-X axis direction) so as to be symmetrical thereto.

The plurality of ISO tank containers 200 may be disposed in the same manner on each layer of the multi-layered support unit 100, and hereinafter, for convenience of explanation, on any one layer of the support unit 100 The ISO tank container 200 arrangement structure will be mainly described.

The first row of ISO tank containers 200 are arranged along the width direction (X-axis direction) of the ship S, and may be arranged symmetrically with the main passage P1 therebetween. In addition, the second row of ISO tank containers 200 are also arranged along the width direction (X-axis direction) of the ship S, the same as the first row of ISO tank containers 200, with the main passage P1 in between. and may be arranged so that they are symmetrical to each other.

The second row of ISO tank containers 200 may be arranged to be spaced apart from the first row of ISO tank containers 200 . At this time, a sub passage P2 may be disposed between the ISO tank container 200 in the second row and the ISO tank container 200 in the first row. In this case, the ISO tank containers 200 in the first row may be arranged to face each other with the ISO tank container 200 in the second row and the sub passage P2 interposed therebetween.

The third row of ISO tank containers 200 may be arranged in parallel with the second row of ISO tank containers 200 . In this case, the main support 100a may be disposed between the ISO tank container 200 in the second row and the ISO tank container 200 in the third row. In this case, a part of the discharge unit 500 may be installed in the main support part 100a, and a detailed description thereof will be described later.

The ISO tank container 200 in the third row and the ISO tank container 200 in the fourth row may be arranged in the same manner as the ISO tank container 200 in the first row and the ISO tank container 200 in the second row described above. .

Specifically, the ISO tank containers 200 in the third row are arranged along the width direction (X-axis direction) of the ship S, and may be arranged symmetrically with the main passage P1 therebetween. And, the ISO tank container 200 in the fourth row is also arranged along the width direction (X-axis direction) of the ship S, the same as the ISO tank container 200 in the third row, with the main passage P1 in between. and may be arranged so that they are symmetrical to each other.

The ISO tank container 200 in the fourth row may be disposed to be spaced apart from the ISO tank container 200 in the third row. At this time, a sub passage P2 may be disposed between the ISO tank container 200 in the fourth row and the ISO tank container 200 in the third row. In this case, the ISO tank containers 200 in the third row may be arranged to face each other with the ISO tank container 200 in the fourth row and the sub passage P2 interposed therebetween.

In addition, the ISO tank containers 200 in the fifth to eighth rows may be arranged in the same manner as the ISO tank containers 200 in the first to fourth rows described above. In this way, a plurality of ISO tank container sets may be repeatedly disposed on the ship S by making the four rows of ISO tank containers 200 into one ISO tank container set. At this time, the number of deployed ISO tank container sets may be changed according to the increase or decrease in the number of quarantined persons.

Referring back to FIG. 3 , the transport unit 400 may transport the transport object to a desired floor in the multi-layer structure of the support unit 100 . At this time, the transport object may be, for example, an item to be installed in the ISO tank container 200 disposed on each floor of the support unit 100 or an item necessary for the life or treatment of an isolated quarantine subject. At this time, the transport unit 400 may reciprocate between the lowermost and uppermost layers of the multi-layered support unit 100 . The transport unit 400 may be, for example, an elevator.

The transport unit 400 may be disposed in the passage part P. As an embodiment, the transport unit 400 may be installed in the main passage P1. At this time, the transport unit 400 is installed in the main passage P1, and may be installed at a position where the main passage P1 and the sub passage P2 intersect. In this case, the transport unit 400 is provided with a door that can be selectively opened and closed in front and rear and left and right directions, so that the transport object transported to a desired floor by the transport unit 400 can be freely moved to a desired position.

At least one transport unit 400 may be provided. As an example, a plurality of transport units 400 may be provided. In this case, the transport unit 400 may be installed in each floor of the support unit 100, in the main passage P1, at each position where the main passage P1 intersects the sub passage P2. Accordingly, the transport object can be transported through the transport unit 400 disposed closest to the position where the transport object is to be moved, thereby increasing space utilization.

5 shows an ISO tank container provided in a negative pressure isolation system according to an embodiment of the present invention. Referring to FIG. 5 , the ISO tank container 200 may be isolated from the outside of the ISO tank container 200 after accommodating the person to be quarantined. The size of the ISO tank container 200 can be varied. Specifically, the ISO tank container 200 may change the size according to the size of the ship S, the required isolation space, and the like. The ISO tank container 200 may be, for example, a 20ft or 40ft standard container.

The ISO tank container 200 may have an accommodation space 210 for accommodating quarantine subjects, an isolation unit 220 and a connection unit 230 therein. At this time, the ISO tank container 200 may have components and items necessary for the life and treatment of the subject of quarantine in the accommodation space 210 . For example, in the accommodating space 210, items for the daily life of the quarantined person, such as a bed, toilet, and furniture, and medical devices for treating the quarantined person may be disposed.

The isolator 220 is disposed between the accommodating space 210 and a passage part P to be described later, so as to isolate the accommodating space 210 from the outside of the ISO tank container 200 . As an example, the isolation unit 220 may isolate the accommodation space 210 from the outside of the ISO tank container 200 through an airlock method. In this case, the isolation unit 220 may have an inner passage connected to the receiving space 210, and the first opening/closing unit 211 may be installed in the inner passage. In addition, the isolation unit 220 has an external passage connected to the outside of the ISO tank container 200 or the passage P, and the second opening/closing unit 222 may be installed in the external passage.

The first opening/closing unit 211 and the second opening/closing unit 222 may be opened and closed with a time difference therebetween. Specifically, while the first opening/closing unit 211 is open, the second opening/closing unit 222 may remain closed. Then, after the first opening/closing part 211 is completely closed, the second opening/closing part 222 may be opened. As such, by opening and closing the first opening and closing portion 211 and the second opening and closing portion 222 at this time, the pressure difference between the inside and outside of the ISO tank container 200 is maintained, and when the second opening and closing portion 222 is opened, rapid inflow and outflow of gas is prevented. By blocking, the air inside the ISO tank container 200 may not directly contact the outside air. Accordingly, it is possible to prevent air inside the ISO tank container 200 containing pathogens, viruses, etc. that cause infectious diseases from leaking out to the outside.

Although not shown in the drawings, the isolation unit 220 may include a sensor for detecting air pressure inside the isolation unit 220 and a sensor for detecting whether the opening/closing units 211 and 222 are malfunctioning. With these sensors, air pressure inside the isolation unit 220 can be sensed and controlled, and operating states and failures of the opening/closing units 211 and 222 can be monitored and managed in real time.

The supply unit 300 may be connected to the connection unit 230 . The connection part 230 is a person who branches again the plurality of supply parts (C1 to C4), the vacuum nozzle (C5), and various types of cables (C _C , C _N , C _P ) included in the supply unit 300 A base portion JB and an inner branch portion JB' may be provided. Due to the branching part JB and the inner branching part JB', the fluid or power supplied through the supply unit 300 can be properly supplied to each appropriate supply target location. A detailed connection structure between the supply unit 300 and the connection unit 230 will be described later.

The connection unit 230 may include a duct unit D connected to the accommodation space 210 inside the ISO tank container 200. One end of the duct unit D may be connected to the accommodation space 210, and the other end of the duct unit D may be connected to the first discharge pipe 510 of the discharge unit 500. The duct unit D is provided with a fan for discharging, and by the operation of the fan, air (eg, polluted air) in the accommodation space 210 is discharged to the outside of the ISO tank container 200. can make it In addition, the duct unit D may include a fire detection sensor (not shown), and it is possible to detect whether or not a fire occurs inside the ISO tank container 200 by such a sensor.

The connection part 230 may be disposed between the accommodating space 210 and the passage part P. The connection part 230 may be completely spatially partitioned from the isolation part 220 . Accordingly, even when the first opening/closing part 211 or the second opening/closing part 222 is opened, air inside the ISO tank container 200 or outside air is introduced into the connection part 230 or the ISO tank through the connection part 230. It is possible to prevent air outside the container 200 from being introduced into the accommodating space 210 .

6 schematically illustrates a connection structure of a negative pressure isolation system and a supply unit provided therewith according to an embodiment of the present invention. 7 shows a cross-sectional view of a supply unit according to an embodiment of the present invention. 8 is a cross-sectional view showing a portion of a negative pressure isolation system according to an embodiment of the present invention.

Referring to FIG. 6 , the storage unit 20 may store various types of fluids to be supplied to the ISO tank container 200 . Storage unit 20 may be disposed on the vessel (S). Specifically, the storage unit 20 may be disposed on the ship S and spaced apart from the ISO tank container 200. In this case, the fluid stored in the storage unit may be supplied to the ISO tank container 200 through a supply unit 300 to be described later.

The storage unit 20 may include a plurality of storage tanks to correspond to various types of fluids to be supplied to the ISO tank container 200 . In this case, in each of the plurality of storage tanks, various types of fluids, for example, air for supplying into the ISO tank container 200, medical gas used for treatment of the quarantined person, water necessary for the quarantined person's life, and oxygen , liquefied gases such as nitrogen can be stored. As such, various types of fluids stored in the plurality of storage tanks may be supplied to the ISO tank container 200 through the supply unit 300 to be described later.

In this case, each storage tank may have a filling nozzle (not shown) for filling a new fluid therein. And, each storage tank may be provided with a sensor (not shown) for detecting at least one of the amount and pressure of the fluid stored therein. The result value measured by the sensor is transmitted to the control unit 40, which will be described later, and the control unit 40 can control any one of the amount and pressure of the fluid inside the storage tank based on the result value received. .

The temperature control unit 600 may control the temperature of the fluid supplied from the storage unit 20 to the ISO tank container 200 . The temperature control unit 600 may be disposed between the storage unit 20 and the ISO tank container 200 . In this case, one end of the supply unit 300 is connected to the storage unit 20, and the other end of the supply unit 300 passes through the temperature control unit 600 and extends to the ISO tank container 200, so that the ISO tank It may be connected to the container 200.

The temperature control unit 600 may include a cooler (not shown) and a heater (not shown). As an example, water or air stored in any one storage tank of the storage unit 20 may be heated while passing through a heater through the supply unit 300 to increase its temperature. Then, heated air or hot water may be supplied into the ISO tank container 200 .

As another embodiment, water or air stored in any one storage tank of the storage unit 20 may be cooled while passing through a cooler through the supply unit 300 to lower its temperature. Then, cooled air or cold water may be supplied into the ISO tank container 200. For example, the cooler may cool air or water flowing through the supply unit 300 by using heat of vaporization when liquefied gas stored in one storage tank is vaporized.

The power unit 30 may generate power to supply to the ISO tank container 200 . In addition, the power unit 30 may supply the generated power to devices in the ISO tank container 200 and the ship S as needed by storing the generated power. The power unit 30 may be disposed on the ship S and spaced apart from the ISO tank container 200. In this case, power generated by the power unit 30 or stored in the power unit 30 may be supplied to the ISO tank container 200 through a supply unit 300 to be described later.

The power unit 30 may include a communication module (not shown). The communication module may be integrally provided with the power unit 30 or may be provided separately. The communication module may wirelessly communicate with a land structure, an offshore structure, or another vessel. In addition, the communication module may perform wireless communication with the outside of the ship (S) by using a communication satellite. The communication module has a communication cable (C _N ), and this communication cable (C _N ) may be connected to the ISO tank container 200 through the supply unit 300 .

The control unit 40 monitors at least one of the internal state of the ISO tank container 200, the health state of the quarantined person, or the operating state of the negative pressure isolation module 10 disposed outside the ISO tank container 200. can

Although not shown in the drawing, the control unit 40 may monitor the state of the quarantined person through a sensor or camera installed inside the ISO tank container 200 . In this case, the quarantine subject detection sensor may be a sensor provided in a medical bed or medical equipment. The control unit 40 may control medical equipment wirelessly or instruct a medical staff to be dispatched to the ISO tank container 200 based on the detected current health condition of the subject to quarantine.

In addition, although not shown in the drawings, the controller 40 controls the temperature, humidity or air inside the ISO tank container 200 through a container detection sensor (not shown) for detecting a state inside the ISO tank container 200. Contamination can be monitored. When the temperature inside the ISO tank container 200 is too high or too low, the controller 40 may control the temperature control unit 600 to adjust the temperature inside the ISO tank container 200 to an optimal temperature. And, when the humidity inside the ISO tank container 200 is too high or too low, the control unit 40 adjusts the amount of air supplied through the supply unit 300 to adjust the humidity inside the ISO tank container 200. can be adjusted to optimum humidity. In addition, the control unit 40 generates a warning signal when the degree of air pollution inside the ISO tank container 200 is equal to or greater than a preset reference value, and informs the medical staff, and at the same time places the quarantined person in a temporary quarantine place in the ship S (not shown). ), it can be instructed to sterilize and purify the air in the ISO tank container 200.

The control unit 40 may control the internal state of the ISO tank container 200 based on the internal state of the ISO tank container 200 or the monitoring result of the quarantined person. At this time, a specific method for the control unit 40 to control the internal state of the ISO tank container 200 will be described in detail below.

Referring to FIG. 7 , the supply unit 300 may connect at least one of the storage unit 20 and the power unit 30 to the ISO tank container 200 . The supply unit 300 may supply at least one or more of various fluids stored in the storage unit 20 to the ISO tank container 200 or supply power generated in the power unit 30 to the ISO tank container 200. . At this time, the supply unit 300 may include an outer portion 310 and an inner portion 320 .

The outer portion 310 is disposed outside the inner portion 320 in the circumferential direction and surrounds the inner portion 320 to protect the inner portion 320 from external impact. The outer portion 310 may include a reinforcing member between an outer surface of the outer portion 310 and the inner portion 320 . At this time, the outer portion 310 and the reinforcing member (not shown) may be made of a flexible material so that deformation and arrangement are easy.

Inside the inner portion 320, a plurality of supply units may be disposed. At this time, the plurality of supply units may be arranged spaced apart from each other. Any one of the plurality of supply units may be partitioned to be completely separated from the other supply units in space. At this time, the inner part 320 and the plurality of supply parts may be made of a flexible material so as to be easily deformed and disposed like the outer part 310 or the reinforcing member.

The plurality of supply units may include a first supply unit C1, a second supply unit C2, a third supply unit C3, and a fourth supply unit C4. In addition to the plurality of supply parts described above, the inner part 320 may further include a vacuum nozzle C5, a control cable C _C , a communication cable C _N , and a power cable C _P .

The first supply unit C1 supplies air stored in the storage unit 20 to the ISO tank container 200, and the second supply unit C2 supplies nitrogen stored in the storage unit 20 to the ISO tank container 200. can Also, the third supply unit C3 supplies NO gas into the ISO tank container 200, and the fourth supply unit C4 supplies oxygen or medical gas to the ISO tank container 200.

The vacuum nozzle C5 may discharge air in the space between the outer shell and the inner shell of the ISO tank container 200 to the outside of the ISO tank container 200 . At this time, the vacuum nozzle (C5) is provided with a vacuum pump, and the air existing in the space between the outer shell and the inner shell of the ISO tank container 200 can be discharged to the outside of the ISO tank container 200 by the operation of the vacuum pump. .

The vacuum nozzle C5 may further include a vacuum sensor (not shown) for detecting a vacuum state between the outer shell and the inner shell of the ISO tank container 200 . In this case, a vacuum state measurement value between the outer shell and the inner shell of the ISO tank container 200, measured by the vacuum sensor, may be transmitted to the control unit 40. The control unit 40 may control the degree of vacuum between the outer shell and the inner shell based on the received measurement value.

The control cable C _C may connect the control unit 40 and the ISO tank container 200. The control cable (C _C ) may connect the control unit 40 with at least one of the power unit 30, the storage unit 20, or the temperature control unit 600, and the control cable (C _C ) is a negative pressure isolation system ( All sensors provided in 1) and the control unit 40 can be connected. A control signal generated by the control unit 40 and/or measurement result values measured by each sensor may be transmitted/received through the control cable C _C .

The communication cable C _N may connect the communication module and the ISO tank container 200 . As a result, quarantine subjects isolated in the ISO tank container 200 can use wireless communication, and thus can freely communicate with medical personnel or the outside of the ship S.

The power cable C _P may connect the power unit 30 and the ISO tank container 200 . In addition, the power cable C _P may connect the power unit 30 to a specific place or a specific component in the negative pressure isolation system 1 requiring power supply, in addition to the ISO tank container 200 . As a result, the power generated by the power unit 30 can be transferred to the ISO tank container 200 and to a specific place and a specific component requiring power.

According to the supply unit 300 as described above, a plurality of cables (C1 to C4), a vacuum nozzle (C5) and various types of cables (C _C , C _N , C _P ) in one supply unit 300, and by connecting with the ISO tank container 200 through this supply unit 300, the above-mentioned various supply parts (piping, etc.) and cables are provided separately On the other hand, it can facilitate organization and increase the utilization of space.

The discharge unit 500 may discharge air inside the ISO tank container 200 to the outside. As exemplarily shown in FIG. 6, a part of the discharge unit 500 is connected to the ISO tank container 200, and another part of the discharge unit 500 is connected to the ISO tank container 200 or the negative pressure isolation module 10. ) can be extended outside. The discharge unit 500 may discharge air discharged from the inside of the ISO tank container 200 to the outside of the ISO tank container 200 or the outside of the negative pressure isolation module 10 . In this case, the discharge unit 500 may include a first discharge pipe 510 and a second discharge pipe 520 . In addition, the discharge unit 500 may further include a discharge detection sensor 530 and a sterilization unit 540 .

The first discharge pipe 510 may be arranged to communicate with the ISO tank container 200 . Specifically, the first discharge pipe 510 may communicate with one side of the accommodation space 210 of the ISO tank container 200 . At this time, one side of the accommodation space 210 to which the first discharge pipe 510 is connected may be a side disposed opposite to the isolation unit 220 and the connection unit 230 .

A plurality of first discharge pipes 510 may be provided. In this case, the first discharge pipe 510 is disposed on the main support 100a installed between the ISO tank containers 200 in adjacent rows, or in the first row arranged first in the longitudinal direction of the ship S. It may be disposed on the main support 100a installed adjacent to the ISO tank container 200 or the ISO tank container 200 of the final row.

Specifically, some of the plurality of first discharge pipes 510 may be disposed on the main support 100a installed adjacent to the ISO tank container 200 in the first row. Another part of the plurality of first discharge pipes 510 may be disposed on the main support 100a installed between the ISO tank container 200 in the second row and the ISO tank container 200 in the third row, and Another part of the first discharge pipe may be disposed on the main support 100a installed between the ISO tank container 200 in the third row and the ISO tank container 200 in the fourth row. In addition, the remaining parts of the plurality of first discharge pipes 510 may be repeatedly arranged in the same manner as this arrangement, and overlapping descriptions thereof will be omitted.

The plurality of first discharge pipes 510 may be arranged to communicate with one side of each of the plurality of ISO tank containers 200 arranged adjacent to each first discharge pipe 510 . Accordingly, a plurality of ISO tank containers 200 may be connected to one first discharge pipe 510 . In addition, the air discharged from the plurality of ISO tank containers 200 communicating with one first discharge pipe 510 in this way, the first discharge pipe 510 extends from the inside of the first discharge pipe 510 described above. It can move to the second discharge pipe 520 along the direction to be.

As exemplarily shown in FIG. 6 , the second discharge pipe 520 may be disposed in the main passage P1. The second discharge pipe 520 may be disposed on the side opposite to the bottom surface P1a of the main passage P1, that is, on the upper side of the main passage P1 adjacent to the ceiling. Also, the second discharge pipe 520 may extend along the main passage P1 in the longitudinal direction (Y-axis direction or -Y-axis direction). At this time, the first discharge pipe 510 may extend from the ISO tank container 200 along the width direction (X-axis direction or -X-axis direction) of the ship S, and communicate with the second discharge pipe 520. . In this case, one end of the second discharge pipe 520 extends to the outside of the negative pressure isolation module 10, so that the air discharged from the ISO tank container 200 flows through the first discharge pipe 510 and the second discharge pipe 520. Passing through in turn, it is possible to move toward the outside of the negative pressure isolation module 10 .

The discharge detection sensor 530 may be disposed in at least one of the first discharge pipe 510 and the second discharge pipe 520 . As an embodiment, the emission sensor 530 is disposed in the first discharge pipe 510 to determine whether or not viruses are contained in the air discharged from the ISO tank container 200, that is, whether the discharged air is contaminated and The degree of contamination can be detected. As another embodiment, the emission detection sensor 530 is disposed in the second discharge pipe 520 to detect the degree of contamination of the air discharged from the negative pressure isolation module 10 to the outside.

As another embodiment, the emission detection sensor 530 may be provided with at least two or more. In this case, the discharge detection sensor 530 may be disposed in both the first discharge pipe 510 and the second discharge pipe 520 . In this case, one of the plurality of emission detection sensors first detects whether or not the air discharged from the ISO tank container 200 through the first discharge pipe 510 is contaminated and the degree of contamination, and then the plurality of ISO tank containers ( 200), whether or not the air discharged through the second discharge pipe 520 in which the plurality of first discharge pipes 510 connected to each other are gathered together and the degree of contamination may be detected secondarily. In this way, by double contamination detection, it is possible to more precisely detect whether the air discharged to the outside of the negative pressure isolation module 10 is infected with a virus.

The sterilization unit 540 may sterilize the air discharged through the discharge unit 500 . The sterilization unit 540 may include a sterilizing liquid storage unit (not shown) and a spray nozzle (not shown). When the discharge of air is sensed by the discharge sensor 530, the sterilization unit may spray the sterilizing solution toward the discharged air through the spray nozzle. As a result, the air discharged from the ISO tank container 200 to the outside through the discharge unit 500 can be sterilized, so that the virus originating from the quarantined person is discharged to the ship S or to the outside of the ISO tank container 200. exposure can be prevented.

As an example, the sterilizing liquid may be sprayed in a vaporized state. In this case, the sterilizing liquid in a vaporized state is uniformly spread in the air discharge passage in the discharge unit 500, thereby improving sterilization efficiency.

The sterilization unit 540 may adjust the amount of the sterilizing liquid sprayed through the spray nozzle based on the resultant value measured by the emission detection sensor 530 . Specifically, the measurement result value measured by the emission detection sensor 530 may be transmitted to the control unit 40 . In this case, the measurement result value may include information about the degree of virus contamination of the discharged air. The control unit 40 may spray an appropriate amount of sterilizing liquid toward the air discharge passage in the discharge unit 500 based on the received measurement result value.

That is, the control unit 40 may control the sterilization unit 540 to spray a large amount of sterilizing liquid when the degree of contamination of the discharged air is severe, and a smaller amount when the degree of contamination of the discharged air is slight. The sterilization unit 540 may be controlled to spray the sterilizing solution. As a result, unnecessary waste of sterilization solution can be prevented, and the spread of viruses and infectious diseases to the outside of the ISO tank container 200 can be prevented by completely sterilizing the contaminated air and then discharging it to the outside even when the degree of air contamination is severe. can do.

A plurality of sterilization units 540 may be provided. In this case, the sterilization unit 540 may be disposed in both the first discharge pipe 510 and the second discharge pipe 520 . In this case, one of the plurality of sterilization units 540 is installed at a portion where the ISO tank container 200 and the first discharge pipe 510 are connected to primarily sterilize the air discharged from the ISO tank container 200. can do. And, as described above, the other one of the plurality of sterilization units 540 is disposed at the discharge end of the second discharge pipe 520 and can secondarily sterilize the air discharged from the second discharge pipe 520 to the outside. there is. Accordingly, by doubly sterilizing the air discharged from the ISO tank container 200, the sterilization efficiency of the air discharged to the outside of the negative pressure isolation module 10 is increased, thereby preventing the virus from spreading to the outside.

Referring to FIG. 8 , the passage portion P may include a storage space in which the supply unit 300 is accommodated and a cover portion that selectively opens and closes the storage space. And, when the cover part closes the storage space, the upper surface of the cover part may be disposed to be at the same height as the bottom surface of the passage part P. As a result, the upper surface of the cover part can be continued without a height difference from the bottom surface of the passage part P. And, at least one through hole through which the supply unit 300 passes may be formed in the cover part.

Specifically, as exemplarily shown in FIG. 8 (a), the main passage P1 is directed downward from the bottom surface P1a to the bottom surface P1a of the main passage P1 ( For example, a first accommodation space P1b concavely formed in a -Z axis direction) may be provided. Also, the first cover P1c may be detachably disposed above the first storage space P1b. In this case, the first accommodation space P1b may be formed to have the same or similar length as the main passage P1 by extending in the longitudinal direction (Y-axis direction) of the main passage P1. Also, the first cover P1c may extend along the longitudinal direction of the first storage space P1b or the longitudinal direction of the main passage P1, and may have the same length as the first storage space P1b.

As exemplarily shown in FIG. 8(b), the sub-passage P2 is formed concavely in a direction from the bottom surface P2a of the sub-passage P2 toward the lower side (-Z axis direction) of the second accommodation. A space P2b may be provided. Also, the second cover P2c may be detachably disposed above the second storage space P2b.

The second accommodating space P2b may extend in the longitudinal direction (X-axis direction or -X-axis direction) of the sub-passage P2 to have the same or similar length as the sub-passage P2. Also, the second cover may extend along the longitudinal direction of the second storage space P2b or the longitudinal direction of the sub-passage P2, and may be formed to have the same length as the second storage space P2b. Meanwhile, the second storage space P2b may be formed to be connected to the first storage space P1b at a portion where the sub passage P2 intersects the main passage P1. Accordingly, the first storage space P1b and the second storage space P2b can communicate with each other.

The second cover P2c may be provided with a through hole h penetrating from an upper surface to a lower surface of the second cover P2c. When the second cover P2c closes the upper portion of the second storage space P2b, the through hole h may communicate the inside and outside of the second storage space P2b.

In the case described above, the supply unit 300 extends from the outside of the negative pressure isolation module 10 toward the negative pressure isolation module 10, and at this time, a part of the supply unit 300 is the storage space of the passage part P. It can be extended while being stored inside.

Specifically, at least a portion of the supply unit 300 is stored in the first storage space P1b of the main passage P1 along the first storage space P1b in the longitudinal direction of the main passage P1 ( Y-axis direction). At this time, the first storage space P1b is closed by the first cover P1c, and thus exposure of the supply unit 300 to the main passage P1 can be minimized. Accordingly, it is possible to prevent an object from being disturbed by the supply unit 300 when transporting an object through the main passage P1.

The branch unit 700 may branch the supply unit 300 toward the ISO tank container 200. A plurality of branching units 700 may be provided. In this case, the plurality of branching units 700 may be disposed spaced apart from each other in the passage part P, so that the supply unit 300 may be branched into the plurality of ISO tank containers 200, respectively. At this time, a plurality of branching units 700 are provided in each of the passages P of each layer of the multi-layered support unit 100, but in the following, for convenience of description, any one of the multi-layered support units 100 The branch unit 700 provided in the layer will be mainly described. In this case, the branch unit 700 may include a first branch unit 710 and a second branch unit 720 .

The first branch unit 710 may branch the supply unit 300 extending in the first accommodation space P1b. At this time, the first branching unit 710 may branch the supply unit 300 toward the second accommodation space P2b or the ISO tank container 200 . The first branch unit 710 may be disposed in the main passage P1.

As an example, the first branch unit 710 may be disposed in the first accommodation space P1b of the main passage P1. The first branch unit 710 may be located adjacent to a portion where the main passage P1 and the sub passage P2 intersect in the first accommodation space P1b. In this case, the first branch unit 710 may firstly branch a part of the supply unit 300 extending in the first storage space P1b to extend toward the second storage space P2b.

As shown in FIG. 8(a) , the first branch unit 710 may be provided with a pair arranged symmetrically as one set. In this case, any one of the pair of first branch units 710 forming one set may extend the supply unit 300 in the first storage space P1b to the second storage space P2b formed in one direction. , and the other one of the pair of first branch units 710 extends the supply unit 300 in the first storage space P1b in a direction opposite to the above-described second storage space P2b. ) can be branched.

The second branch unit 720 may be disposed in the second storage space P2b of the sub passage P2. The second branch unit 720 may be disposed adjacent to the ISO tank container 200 in the second accommodation space P2b. In this case, the second branch unit 720 may secondarily branch a part of the supply unit 300 extending in the second storage space P2b to extend toward the branch part JB of the connection part 230. there is.

Specifically, a portion of the supply unit 300 branched from the first storage space P1b and extended in the second storage space P2b is branched by the second branch unit 720, forming a through hole h. It can be extended to the outside of the second storage space (P2b) through. At this time, a pair of through-holes (h) may be provided, and the pair of through-holes (h) are located at both ends of the second cover (P2c) based on the width direction (Y-axis direction) of the sub-passage (P2). They may be formed adjacent to each other. Also, the pair of through holes (h) may be located on the lower side of the branch portion (JB) provided in the ISO tank container 200 disposed adjacent to each other.

The second branching unit 720 may branch the supply unit 300 toward at least one branching part JB. Specifically, a portion of the supply unit 300 extending in the second storage space P2b by the second branch unit 720 passes through any one of the pair of through holes h to the second storage space. It extends to the outside of (P2b) and can be connected to the branching part (JB) of the ISO tank container 200 disposed above the through hole (h). And, by the second branch unit 720, the other part of the supply unit 300 extending in the second storage space P2b passes through the other one of the pair of through holes h to the second storage space. It extends to the outside of (P2b) and can be connected to the branching part (JB) of another ISO tank container 200 disposed above the through hole (h).

As described above, by the first branching unit 710 and the second branching unit 720, the supply unit 300 extending in the passage P is the position where the plurality of ISO tank containers 200 are disposed. can be guided by In addition, each of the first branch unit 710 and the second branch unit 720 is spaced apart from each other by a plurality of arrangements, thereby supporting the supply unit 300 extending in the storage space, thereby supplying the supply unit 300 It can be stably placed and connected on the negative pressure isolation module (10).

The supply unit 300 secondarily branched by the second branch unit 720 may be detachably connected to the branch part JB provided in the ISO tank container 200 . Accordingly, the supply unit 300 can be easily separated from the branching part JB and recombined as needed.

In addition, one end of the supply unit 300 is connected to the branching part JB of the ISO tank container 200, and a plurality of supply units provided in the supply unit 300 (C1 to C5) and various types of cables (C _C , C _N , C _P ) are branched from the supply unit 300 inside the connection part 230 through the branching part JB and the internal branching part JB', so that the accommodation space 210 of the ISO tank container 200 ) or may be connected to the isolation unit 220.

As such, the supply unit 300 includes a plurality of supply units (C1 to C4), a vacuum nozzle (C5), and various types of cables (C _C , C _N , C _P ) therein, from the outside to the ISO tank container ( 200), it is possible to easily organize pipes and cables from the outside of the ISO tank container 200, and after being connected to the ISO tank container 200, a plurality of supply units (C1 to C4), vacuum nozzles (C5) ) and various types of cables (C _C , C _N , C _P ) are branched again and connected to required positions, respectively, thereby increasing the overall space utilization of the negative pressure isolation system (1).

On the other hand, from above, a structure in which a plurality of ISO tank containers 200 are connected and the supply unit 300 is disposed and branched through the passage part P in any one of the multi-layered support units 100 centrally explained. However, in all layers of the multi-layer structure, the supply units 300 may be arranged and branched in the same or similar manner, and duplicate descriptions thereof will be omitted. On the other hand, as one embodiment, the supply units 300 disposed on all floors of the multi-layer structure may be disposed in a connected state, but as another embodiment, the supply units 300 disposed on each floor are not connected to each other. It may be arranged for each floor in a state.

In the support unit 100 having a multi-layer structure according to an embodiment of the present invention, although not shown in the drawing, the inner diameter of the supply unit provided in the supply unit 300 may be formed differently for each layer. Specifically, based on the height direction (Z-axis direction) of the ship (S), the inner diameter of the supply unit provided in the supply unit 300 may be reduced toward higher floors. Accordingly, the flow rate of the fluid supplied by the supply unit of the supply unit 300 toward the upper layer portion may be faster than that of the lower layer portion. Accordingly, the flow rate of the fluid supplied increases in proportion to the height of the layer, and accordingly, the fluid can be supplied at the same rate to all ISO tank containers 200 disposed in the support unit 100 having a multi-layer structure.

As another embodiment, various methods may be applied, such as arranging an auxiliary pump (not shown) in the supply unit disposed on each floor or differently controlling the supply speed of the fluid for each floor through the control unit 40. am.

As described above, the negative pressure isolation system 1 according to the embodiments of the present invention uses the support unit 100 having a multi-layer grid structure and a plurality of ISO tank containers 200 detachably connected thereto, A place for isolating a person to be isolated can be prepared, and through simple and quick assembly of the support unit 100 and the ISO tank container 200, the isolation place can be quickly secured even in an emergency. In addition, since the negative pressure isolation system 1 is installed on the ship S, it is possible to completely isolate a large number of quarantine subjects without space restrictions, and it is possible to move to other countries requiring medical assistance by operating the ship S. .

The above description of the present invention is for illustrative purposes, and those skilled in the art can understand that it can be easily modified into other specific forms without changing the technical spirit or essential features of the present invention. will be. Therefore, the embodiments described above should be understood as illustrative in all respects and not limiting. For example, each component described as a single type may be implemented in a distributed manner, and similarly, components described as distributed may be implemented in a combined form.

The scope of the present invention is indicated by the following claims, and all changes or modifications derived from the meaning and scope of the claims and equivalent concepts should be interpreted as being included in the scope of the present invention.

1: negative pressure isolation system
10: negative pressure isolation module
20: storage unit
30: power unit
40: control unit
100: support unit
200: ISO tank container
300: supply unit
400: transport unit
500: discharge unit
600: temperature control unit
700: branch unit
S: ship
P: Passage

Claims (12)

In the negative pressure isolation system installed on the ship,
ISO tank containers provided with a plurality and having an accommodation space in which quarantine subjects are accommodated and isolated;
a support unit to which the ISO tank container is detachably coupled and formed in a multi-layered structure;
a storage unit disposed to be spaced apart from the ISO tank container and storing a plurality of different fluids;
a power unit disposed apart from the ISO tank container and generating and storing power to be supplied to the ISO tank container; and
and a supply unit connecting at least one of the storage unit and the power unit to the ISO tank container to supply the fluid or the power to the ISO tank container. According to claim 1,
A plurality of the ISO tank containers are stacked on the support unit having a multi-layer structure,
Some of the plurality of ISO tank containers are arranged to face another part of the plurality of ISO tank containers, and a passage is disposed between the ISO tank containers arranged to face each other. According to claim 2,
The negative pressure isolation system further includes a carrying unit disposed in the passage portion and movable between each layer of the multilayer structure of the support unit. According to claim 2,
The passage portion includes a cover portion detachably connected to a bottom surface of the passage portion and having a storage space in which the supply unit is accommodated,
The negative pressure isolation system of claim 1 , wherein an upper surface of the cover part is disposed at the same height as a bottom surface of the passage part. According to claim 1,
The supply unit has a plurality of supply parts arranged to be partitioned from each other inside,
The negative pressure isolation system, wherein the plurality of different fluids and the power are supplied to the ISO tank container through different supply units. According to claim 2,
The ISO tank container,
an isolation unit disposed between the accommodating space and the passage, and isolating the accommodating space from the outside of the ISO tank container; and
A negative pressure isolation system comprising: a connection part spatially separated from the accommodation space and the isolation part and to which the supply unit is detachably connected. According to claim 1,
An intermediate branch unit branching the supply unit toward each of the plurality of ISO tank containers. According to claim 2,
Further comprising a discharge unit for discharging the air inside the ISO tank container to the outside of the ISO tank container,
The discharge unit,
An emission detection sensor for detecting whether a virus is contained in the discharged air; and
A negative pressure isolation system comprising: a sterilization unit for sterilization of discharged air. According to claim 1,
Further comprising a negative pressure isolation system; a temperature control unit for increasing or decreasing the temperature of the fluid supplied to the ISO tank container. According to claim 9,
The storage unit includes a plurality of storage tanks,
At least some of the plurality of storage tanks store liquefied gas therein,
The temperature control unit uses the heat of vaporization of the liquefied gas to control the temperature of the fluid supplied to the ISO tank container through the supply unit. According to claim 1,
Negative pressure isolation system further comprising a control unit for monitoring the state of the quarantined person isolated in the ISO tank container and the internal state of the ISO tank container, and controlling the internal state of the ISO tank container based on the monitoring result. According to claim 11,
The control unit controls the internal state of the ISO tank container by adjusting at least one of a temperature and a supply amount of the fluid supplied to the ISO tank container through the supply unit.

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