KR102568175B1 - MEP Module Device Negative Pressure Ward Modular System Using Dead Space - Google Patents

Abstract

The MEP modular device negative pressure ward modular system using a dead space according to the present invention includes a support forming a floor slab, a column and a beam, an infill box seated inside the support to form a space, and an internal environment provided in the infill box an interface for controlling the infill box; a wastewater cartridge provided in the support to store wastewater generated in the infillbox; and a wastewater cartridge disposed in a dead space formed between the support and the infillbox to provide a thermal environment and ventilation inside the infillbox. and a MEP module device that creates an environment suitable for a negative pressure ward by applying differential pressure performance.

Description

MEP Module Device Negative Pressure Ward Modular System Using Dead Space}

The present invention relates to a modular system for a MEP module device using a dead space, and more particularly, to utilize a dead space that can include an MEP module device in a dead space space generated in the process of installing a modular system for a negative pressure ward. A MEP module device relates to a negative pressure ward modular system.

In recent years, as new and unknown infectious diseases that threaten humanity continue to emerge, the onset cycle of infectious diseases is gradually shortening. We are warning about the emergence of a powerful virus.

In fact, after the first confirmed case of COVID-19 in Korea, the pandemic started in just one month, resulting in a situation where the supply of facilities to accommodate patients could not keep up with demand. A fundamental solution is needed.

In the past, screening clinics were operated using containers or tents without preparation for facilities dedicated to infectious diseases.

Therefore, it is necessary to respond to a new virus disaster that spreads over a long period of time, and to secure customized modular facilities and performance considering room-by-room layout, module combination, and MEP relationship in consideration of the movement of medical staff and patients from the initial planning stage.

However, the negative pressure ward modular facility has a problem that the modular interior space is narrowed as a dead space is generated around the concrete structure formed by the walls, infill units, columns and beams (especially under the beams).

In addition, the negative pressure ward modular facility requires an MEP module device to form negative pressure in the patient's ward and corridor, but there is a problem that the number of wards must be reduced or the medical space for medical staff must be reduced due to the narrowed space due to the dead space. occurs

Domestic Patent Publication No. 10-2022-0064852 (2022.05.19)

An object of the present invention is to provide a modular MEP module device negative pressure ward modular system using a dead space capable of providing a MEP module device that creates negative pressure in a dead space formed by a plurality of beams and an upper slab of a concrete structure.

Another object of the present invention is to provide a modular system for a MEP module device negative pressure ward using a dead space capable of providing a MEP module device for managing patients and negative pressure facilities in a dead space formed in a space under a beam of a concrete structure.

MEP module device negative pressure ward modular system using dead space according to one aspect of the present invention for achieving the above object is a support forming a floor slab, a column and a beam, and an infill seated inside the support to form a space A box, an interface provided in the infill box to control the internal environment, a wastewater cartridge provided in the support to store wastewater generated in the infill box, and disposed in a dead space formed between the support and the infill box. It is possible to provide a MEP module device that creates an environment suitable for a negative pressure ward by applying a thermal environment, ventilation, and pressure differential performance to the inside of the infill box.

The MEP module device may include a ceiling kit for applying a thermal environment, ventilation, and differential pressure performance to the inside of the infill box, and a side kit for supplying oxygen to a patient and responding to power outages within the infill box.

The ceiling kit may be provided in a first dead space formed on an upper portion of the infill box surrounded by a plurality of beams.

The ceiling kit includes a temperature and humidity regulator for adjusting the temperature, humidity and supply air in the inpill box, an exhaust device for supplying clean air and pressure and maintaining pressure in the inpill box, and a HEPA formed on the ceiling in the inpill box to one end of the exhaust device. A filter and a duct for performing UV sterilization treatment may be provided.

The side kit may be provided in a second dead space formed under the beam, which is a side surface of the infill box.

The side kit includes a boiler that heats the faucet with hot water, a medical gas cylinder for supplying medical oxygen to the patient in the infill box, a medical gas manifold that connects the medical gas cylinder to the patient's bed and enables gas distribution and mixing, and the temperature and humidity control system. A controller, a control panel corresponding to facilities of the exhaust device and the medical gas cylinder, and an uninterruptible power supply that supplies power as an emergency power source even when power to the temperature and humidity controller and the exhaust device are cut off may be provided.

The wastewater cartridge may be inserted in a sliding manner into a spaced space formed below the floor slab and connected to a sewage pipe in the infill box.

According to the MEP module device negative pressure ward modular system using the dead space according to the present invention, the ceiling kit is placed in the first dead space formed on the top of the beam and the inpill box to create an environment suitable for the negative pressure facility inside the inpill box. can

In addition, a device for performing maintenance on the ceiling kit and supplying power in case of an emergency may be provided by placing a side kit in the second dead space formed under the beam and on both sides of the infill box.

1 is a perspective view showing the overall appearance of the MEP module device negative pressure ward modular system using a dead space according to the present invention.
Figure 2 is a perspective view showing a detailed appearance of the MEP module device in Figure 1;
Figure 3 is a plan view showing a detailed appearance of the waste water cartridge in Figure 1;

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings. However, it goes without saying that the present invention is not limited to these embodiments and can be modified in various forms.

In the drawings, in order to clearly and concisely describe the present invention, parts not related to the description are omitted, and the same reference numerals are used for the same or extremely similar parts throughout the specification. In addition, in the drawings, the thickness, width, etc. are enlarged or reduced in order to make the description more clear, and the thickness, width, etc. of the present invention are not limited to those shown in the drawings.

And when a part in the entire specification is said to "include" another part, it does not exclude other parts unless otherwise stated, and may further include other parts.

1 is a perspective view showing the overall appearance of the MEP module device negative pressure ward modular system utilizing a dead space according to the present invention.

As shown in FIG. 1, the MEP module device negative pressure ward modular system using a dead space includes a support 100 forming a floor slab 110, a column 120 and a beam 130, and the inside of the support 100 The inpillbox 200 installed in the inpillbox 200 to form a space, the interface 300 provided in the inpillbox 200 to control the internal environment, and the support 100 to remove wastewater generated from the inpillbox 200. It is disposed in the wastewater cartridge 400 to store and in the dead space 10, 20 formed between the support 100 and the infill box 200 to apply a thermal environment, ventilation and differential pressure performance to the inside of the infill box 200. Thus, an MEP module device 500 may be provided to create an environment suitable for a negative pressure ward.

Here, the support 100 includes a floor slab 110, a column 120, and a beam 130 prefabricated of precast concrete, and the floor slab 110 is provided at a site location where the modular system is installed, The support 100 may be formed by erecting the pillar 120 and the beam 130.

In the support 100, a space is formed under the top where the beam 130 is formed and the bottom where the beam 130 is formed. This space is a space where the infill box 200 cannot be inserted, and is called a dead space. can do.

The infill box 200 may be inserted inside the support 100 to form a space, and may be provided in the space so that a patient's room and medical facilities and examinations by medical staff are possible.

The inpillbox 200 is inserted into the support 100, and a dead space, which is an unusable space, may be formed on the top and both sides of the inpillbox 200 by the pillar 120 and the beam 130. .

The interface 300 is provided inside the infill box 200 and can create an environment suitable for a negative pressure ward by controlling the MEP module device 500 to be described later.

The wastewater cartridge 400 is formed between the floor slab 110 and the infill box 200 and can be removed or mounted in a sliding manner to store and treat wastewater generated in the negative pressure ward.

The MEP module device 500 is seated in the dead space formed by the inpillbox 200 and the support 100, and creates a negative pressure environment in the inpillbox to treat patients and prevent secondary infection.

The MEP module device 500 lowers the air pressure of the infill box 200 to that of the surrounding rooms so that air flows from the outside to the inside of the infill box 200 at all times, and air contaminated with viruses or germs is discharged to the outside. It is possible to prevent the spread of infectious diseases by providing a device to prevent it from happening.

The MEP module device 500 is equipped with a high-airtight and high-performance thermal environment, ventilation, and pressure differential performance inside the infill box 200, and the MEP module device 500 located in a dead space that is difficult to check frequently is connected to the interface 300. It can be connected for maintenance and control.

Through this, the MEP modular device negative pressure ward modular system using the dead space according to the present invention is a negative pressure ward modular environment in the dead space 10, 20 formed by the pillars 120 and beams 130 of the support 100. It is possible to maximize the use of space by providing the MEP module device 500 to create a.

In addition, the wastewater cartridge 400 is provided in a sliding manner between the infill box 200 and the floor slab 110 to store wastewater generated in the negative pressure ward modular, and can be taken out and treated by sliding.

Next, the MEP module device of the negative pressure ward modular system using the dead space according to the present invention will be described in detail.

2 is a perspective view showing a detailed appearance of the MEP module device in FIG. 1;

Referring to FIG. 2, the MEP module device 500 includes a ceiling kit 510 that applies a thermal environment, ventilation, and differential pressure performance to the inside of the infill box 200, and supplies oxygen to patients and power outages within the infill box 200. A corresponding side kit 520 may be provided.

Here, the ceiling kit 510 is provided in the first dead space 10 formed on the upper part of the inpilbox 200 surrounded by the plurality of beams 130, and the side kit 520 is provided in the inpilbox 200. It may be provided in the second dead space 20 formed under the side beam 130.

The ceiling kit 510 includes a temperature and humidity controller 511 that controls the temperature, humidity and supply air within the inpillbox 200, an exhaust device 512 that supplies pressure and pressure maintenance in the inpillbox 200 and clean air, and A HEPA filter and a duct 513 for performing UV sterilization treatment may be provided at one end of the exhaust device 512 formed on the ceiling in the 200.

The temperature and humidity controller 511 is located above the inpillbox 200 and can control temperature and humidity in the inpillbox 200 and supply air to the room.

The exhaust device 512 is located above the infill box 200 and may be provided as an important device for creating a negative pressure facility while exhausting air in the infill box 200 . At this time, one more exhaust device 512 may be provided for backup purposes in preparation for any device failure.

The duct 513 is connected to the temperature and humidity controller 511 and the exhaust device 512. First, the temperature and humidity controller 511 supplies air to the infill box 200 through the duct 513 and returns it from the lower part of the patient's head. It can escape to the exhaust device 512 again.

The duct 513 is equipped with a HEPA filter and a UV sterilizer at the exhaust end so that air contaminated with viruses or germs is not discharged to the outside, thereby preventing the spread of infectious diseases.

Next, the side kit 520 includes a boiler 521 for heating the faucet with hot water, a medical gas cylinder 522 for supplying medical oxygen to the patient in the infill box 200, and a medical gas cylinder 522 to the patient's bedside. A medical gas manifold 523 that is connected and capable of distributing and mixing gas, a temperature and humidity controller 511, an exhaust device 512, and a control panel 524 corresponding to facilities of the medical gas cylinder 522, and the temperature and humidity controller 511 and an uninterruptible power supply 525 that supplies power as an emergency power source even when power to the exhaust device 512 is cut off.

The medical gas cylinder 522 is provided in the second dead space 20 formed on the side of the infill box 200 to supply medical oxygen to the patient and requires frequent replenishment. A quick replenishment is possible.

The medical gas manifold 523 is connected to the medical gas cylinder 522 and is connected to the patient's bedside, and may adjust or mix medical oxygen distribution and supply the patient.

The control panel 524 includes a control panel 524 corresponding to the facilities of the temperature and humidity controller 511 and the exhaust device 512 provided in the ceiling kit 510, and a control panel corresponding to the facilities of the medical gas cylinder 522 ( 524) may be provided, respectively. At this time, the position of the control panel 524 is the side kit 520, and the temperature and humidity controller 511 and the exhaust device 512 provided in the ceiling kit 510 can only be connected with a line.

The uninterruptible power supply 525 is used when the power of the temperature and humidity controller 511 and the exhaust device 512 provided in the ceiling kit 510 is cut off in an unexpected situation, the temperature and humidity controller 511 and the exhaust device 512 ) can supply power in an emergency.

The uninterruptible power supply 525 may be connected to the temperature and humidity controller 511 and the exhaust device 512 of the ceiling kit 510 and provided in the side kit 520. In addition, since it is provided on the side, maintenance can be relatively easy.

Next, the wastewater cartridge of the MEP module device negative pressure ward modular system using the dead space according to the present invention will be described in detail.

3 is a plan view showing a detailed appearance of the wastewater cartridge in FIG. 1;

Referring to FIG. 3 , the wastewater cartridge 400 may be inserted into a spaced apart space formed below the floor slab 110 in a sliding manner and connected to a sewage pipe within the infill box 200 .

The inside of the inpillbox 200 is equipped with a patient's room, medical facilities for medical staff, and a treatment room, and facilities requiring a sewage pipe such as a shower room, toilet, and kitchen room may also be provided inside.

At this time, the method of treating wastewater generated in the sewage pipe is different from that of general buildings. As described above, the modular system stores wastewater generated in the shower room, toilet and kitchen room, and when the stored wastewater is full, the wastewater cartridge 400 is opened and treated. may be provided in this way.

In the wastewater cartridge 400, a slidable cartridge 410 is formed between the infillbox 200 and the floor slab 110, and a wastewater storage 420 is formed inside the cartridge to be connected to the sewage pipe of the infillbox 200. can

Through this, the MEP module device negative pressure ward modular system using the dead space according to the present invention includes the MEP module device 500 in the first dead space 10 formed on the ceiling of the support 100 and the infill box 200. By disposing the ceiling kit 510, the inside of the infill box 200 can be created as an environment suitable for a negative pressure ward.

In addition, by placing the side kit 520, which is the MEP module device 500, in the second dead space 20 formed on both sides of the support 100 and the infill box 200, maintenance and emergency management of the ceiling kit 510 A device for supplying power may be provided.

In addition, a method of forming a space between the infill box 200 and the floor slab 110 to slide the wastewater cartridge 400 to store wastewater and take out and treat the stored wastewater by sliding may be provided.

In the above, the MEP module device negative pressure ward modular system using a dead space according to an embodiment of the present invention has been described, but the spirit of the present invention is not limited to the embodiments presented herein. In addition, those skilled in the art who understand the spirit of the present invention may easily propose other embodiments by adding, changing, deleting, adding, etc., elements within the same spirit, but this is also within the spirit of the present invention. will say that

10: first dead space (ceiling) 20: second dead space (side)
100: support 110: floor slab
120: column 130: beam
200: infill box 300: interface
400: wastewater cartridge 500: MEP module device
510: ceiling kit 511: temperature and humidity controller
512: exhaust system 513: duct
520: side kit 521: boiler
522: medical gas cylinder 523: medical gas manifold
524: control panel 525: uninterruptible power supply

Claims (7)

Supports forming floor slabs, columns and beams;
A plurality of infill boxes seated inside the support to form a space and disposed adjacent to a side surface with at least one beam interposed therebetween;
an interface provided in the infill box to control the internal environment;
A wastewater cartridge for storing wastewater generated in the infill box;
A MEP module device disposed in a dead space formed between the support and the infill box to create an environment suitable for a negative pressure ward inside the infill box,
The MEP module device,
A temperature and humidity regulator for controlling temperature and humidity and supply air, an exhaust device for maintaining pressure and pressure and supplying clean air, and a HEPA filter and a duct for performing UV sterilization are provided at one end of the exhaust device to provide a thermal environment inside the infill box, A ceiling kit that applies ventilation and differential pressure performance;
A boiler that heats a faucet with hot water, a medical gas cylinder that supplies medical oxygen to a patient, a medical gas manifold that connects the medical gas cylinder to a patient's bed and is capable of distributing and mixing gas, the temperature and humidity controller, the exhaust device, and the medical gas manifold. A control panel corresponding to the facilities of the gas cylinder, and an uninterruptible power supply that supplies power as an emergency power supply even if the power of the temperature and humidity controller and the exhaust device is cut off, to supply oxygen to the patient in the infill box and to respond to power outages. kit includes,
The ceiling kit is provided in a first dead space formed above the infill box surrounded by a plurality of beams, and the side kit is provided in a second dead space formed under a beam between adjacently arranged infill boxes,
The wastewater cartridge is inserted in a sliding manner into the spaced space formed below the floor slab and connected to the sewage pipe in the infill box.

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