KR102432294B1 - Smart Screening Center System Using Surface Sterilizing and Air Sterilizing - Google Patents

Abstract

The present invention relates to a smart infectious disease screening clinic system with occupied-unoccupied state selection type air and surface sterilization functions, wherein the infectious disease screening clinic system comprises: an examination support room where medical personnel who collect samples or investigate whether or not to be infected are accommodated, and an examination room where examinees who are to be examined on whether to be infected with infectious diseases are accommodated. The smart infectious disease screening clinic system automatically recognizes an occupied state in which an examinee exists in the examination room and an unoccupied state in which no examinee exists. In the occupied state, the air in the examination room is circulated and ultraviolet ray C (UVC) is irradiated to perform sterilization for air (air sterilization), and if necessary, the examination room can be additionally set to a negative pressure condition to improve the safety in the examination process like sample collection through efficient discharge of contaminants like infectious sources and to safely protect examinees who enter subsequently. In the unoccupied state, in addition to air sterilization by UVC, the UVC is directly irradiated even on the surface of the examination room like the wall surface to perform sterilization (surface sterilization) and if necessary, the examination support room can be set to a positive pressure condition to more thoroughly prevent the inflow of infectious sources or the like from the examination room to the examination support room and to safely protect medical staff.

Description

[Smart Screening Center System Using Surface Sterilizing and Air Sterilizing]

The present invention relates to an infectious disease screening clinic system for collecting a sample from an examinee in order to test for infection with an infectious disease such as Corona 19, and more specifically, an infectious disease having a test support room and a checkup room In the screening clinic system, the occupancy state with the examinee and the non-occupant state without the examinee are automatically detected in the examination room, and UVC (ultraviolet C) is irradiated while circulating the air in the examination room in the occupancy state to reduce the air quality. The examinee who proceeds with sterilization (air sterilization) and, if necessary, additionally sets the examination room under negative pressure, improves safety in the examination process, such as sample collection, through efficient discharge of contaminants such as infectious agents, and enters the examination room afterward. In addition to air sterilization by UVC, in non-occupancy conditions, UVC is irradiated directly on the surface of the examination room such as walls to sterilize (surface sterilization). In the "Smart Infectious Disease Screening Clinic System with Selectable Air and Surface Sterilization Functions for Occupancy-Non-Occupancy", which can protect medical staff safely by more thoroughly preventing the inflow of infectious agents from the examination room to the examination support room by creating a positive state. it's about

Infectious disease screening clinics collect samples from examinees to test whether they are infected with infectious diseases, and, in some cases, conduct medical examinations such as questionnaires or additional infectious disease tests. In general, an infectious disease screening clinic is equipped with an examination room where examinees are accommodated to be tested for infection with an infectious disease or sample is collected from the examinee, and a test support room where medical staff are accommodated. It consists of a space separated from the support room, that is, an "isolated space".

Respiratory infectious diseases such as COVID-19 are spread not only by contact infection, but also by air infection by fine particles (aerosols) suspended in the air. Therefore, for the examination room in the form of an isolation space, the necessity and importance of not only air sterilization of the air inside, that is, the indoor air, but also the surface of the examination room interior such as a wall or operation panel is very high and very important.

Since a very useful technology related to air sterilization using UVC is disclosed in Korean Patent Registration No. 10-2320336, this prior art, that is, UVC, can be utilized for air sterilization of an examination room consisting of an isolation space. PCT/TR2021/050501 describes a disinfection technique of an operating room using UVC.

However, in using UVC for air sterilization and surface sterilization of examination rooms, it is necessary to solve two problems: <Prevention of UVC harm to human body> and <Maximization of sterilization effect>. When the body is directly exposed to UVC, there is a possibility of loss of vision or causing skin cancer. there should be

The sterilization power of UVC depends on the amount of light, exposure time, and irradiation distance. In particular, the sterilization power decreases as the irradiation distance of UVC increases. It is necessary to keep the distance between the UVC lamp and the surface that the UVC touches as short as possible. In particular, the examination room has a characteristic that there is an occupant state in which the examinee exists (the state in which the examinee enters the examination room for sample collection or examination) and a non-occupant state in which the examinee is absent (the state in which the examinee leaves the examination room). However, in sterilizing the infectious disease screening clinic system, it is not efficient to simply use UVC to continuously sterilize a specific location according to the method suggested in the prior art without considering the characteristics of the infectious disease screening clinic. It may be harmful to examinees and medical staff, so a new method is needed.

Republic of Korea Patent Publication No. 10-2320336 (Notice on November 03, 2021). PCT Publication WO 2021/230843 (PCT/TR2021/050401) (published on November 18, 2021).

The present invention was developed to solve the limitations and problems of the prior art, and the occupancy state in which the examinee exists in the examination room of the infectious disease screening clinic system consisting of an isolation space separated from other spaces and the non-occupant room in which the examinee does not exist In the occupancy state, UVC (ultraviolet C) is irradiated to the air while circulating the air in the examination room and only air sterilization is carried out. ) to sterilize only the surface, or to sterilize the surface in parallel with the air sterilization, thereby solving the problem of harm to the human body that may occur when air sterilization and surface sterilization using UVC are carried out, while increasing the exposure time of UVC and the irradiation distance of UVC. It aims to provide a technology that can maximize the effect of air sterilization and surface sterilization inside the examination room by reducing

Furthermore, the present invention provides an additional negative pressure state in the examination room as necessary to efficiently discharge contaminants such as infectious agents to improve safety in the sample collection process and examination process, and to safely protect the examinee who enters subsequently The purpose of this is to provide a technology that can protect the medical staff more safely by creating a positive pressure state in the examination support room if necessary.

In order to achieve the above object, in the present invention, as an infectious disease screening clinic system comprising a test support room where medical staff are accommodated, and a checkup room in which examinees who are to be tested for infection with an infectious disease are accommodated, the examination room is equipped with a smart sterilization system, There, the smart sterilization system is installed on the occupancy sensor to determine the occupancy and non-occupancy conditions of the examination room, an elevating module that vertically elevates and lowers the elevating member, and is folded in the elevating state of the elevating member. It has a configuration including a folding module that unfolds when the elevating member descends, and a UVC lamp installed in the folding module to irradiate UVC; When the examination room is identified as a non-occupant state, the elevating member descends to unfold the folding module, and the UVC lamp irradiates UVC on the wall of the examination room to sterilize the surface; When the examination room is identified as occupancy, the folding module is folded as the elevating member rises, and the UVC lamp faces the ceiling. There is provided an infectious disease screening clinic system, characterized in that air sterilization is performed.

In the infectious disease screening clinic system according to the present invention, the occupancy and non-occupancy conditions of the examination room are automatically identified, and UVC (ultraviolet C) is irradiated to the air while circulating the air in the examination room in the occupancy condition, and only air sterilization is performed. Therefore, the body is not directly exposed to UVC in the air sterilization process using UVC, and it is possible to solve the problem of harm to the human body due to direct body exposure to UVC.

In addition, in the present invention, when the examination room is in a non-occupant state, the surface sterilization is carried out by irradiating UVC near the surface of the examination room such as a wall surface. Therefore, according to the present invention, the wall surface of the examination room is always exposed to UVC when no person is present, thereby increasing the sterilization effect according to the prolonged UVC exposure time. The effect of maximizing the effect of air sterilization and surface sterilization of the examination room using UVC is demonstrated.

In addition, the infectious disease screening clinic system of the present invention may further include a pressure control system capable of making the examination room in a negative pressure state and in the examination support room in a positive pressure state if necessary. Through efficient discharge of contaminants such as samples, it is possible to improve safety in the examination process, such as sample collection, and to protect the examinees who enter afterward. This has the effect of protecting the medical staff more safely.

1 is a schematic perspective view showing a basic internal compartment configuration of an infectious disease screening clinic system according to the present invention.
2 is a schematic perspective view showing that the smart sterilization system is operated in the occupancy state of the examination room in which the smart sterilization system of the present invention is installed.
3 is a schematic perspective view showing that the smart sterilization system is operated in a non-resident state of the examination room where the smart sterilization system of the present invention is installed.
Fig. 4 is a schematic side view of the state of Fig. 2;
Fig. 5 is a schematic side view of the state of Fig. 3;
6 and 7 are schematic perspective views showing the smart sterilization system of the present invention in a surface sterilization state in a different looking direction, respectively.
8 and 9 are schematic perspective views showing the state of the intermediate stage in which the smart sterilization system of the present invention is mutually converted from the surface sterilization state to the air sterilization state, respectively, in different directions.
10 and 11 are schematic perspective views showing the smart sterilization system of the present invention in an air sterilization state in different directions, respectively.
12 to 14 are schematic side views viewed in the direction of the arrow M of FIG. 6 sequentially showing the process of changing from the surface sterilization state to the air sterilization state, respectively.
15 to 17 are schematic side views viewed in the direction of arrow N of FIG. 6 sequentially showing the process of changing from the surface sterilization state to the air sterilization state, respectively.
18A to 18C are schematic enlarged views of the circle H of FIG. 6 sequentially showing the bent state of the intermediate hinge part of the folding module, respectively.
19 and 20 are schematic perspective views corresponding to FIGS. 6 and 7 respectively showing a smart sterilization system provided with a plurality of folding modules only on one side of the elevating member.
21 and 22 are schematic perspective views corresponding to FIGS. 8 and 10 of the smart sterilization system illustrated in FIG. 19, respectively.
23 to 25 are schematic side views corresponding to FIGS. 12 to 14 of the smart sterilization system illustrated in FIG. 19, respectively.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. Although the present invention has been described with reference to the embodiment shown in the drawings, which is described as one embodiment, the technical idea of the present invention and its core configuration and operation are not limited thereby. As used herein, "testing support room" refers to a space in which medical staff who collect samples or investigate whether or not infection is present, and "examination room" is a space in which examinees, that is, examinees who are to be tested for infection with infectious diseases are accommodated. means And throughout this specification, including the claims, "indoor space" means an internal space of an examination room in which a examinee is accommodated and is tested for infection with an infectious disease or a sample is collected from the examinee.

1 is a schematic perspective view showing the basic internal compartment configuration of the infectious disease screening clinic system 200 according to the present invention. As illustrated in the drawing, the infectious disease screening clinic system 200 according to the present invention includes an examination support room A in which medical staff are accommodated, and an examination room B in which examinees are accommodated. The examination room (B) consists of a separate isolation space that is separated and isolated so as not to communicate with other spaces of the infectious disease screening clinic system 200 including the examination support room (A). As will be described later, the smart sterilization system 100 of the present invention is provided in the examination room B, but illustration of the smart sterilization system 100 is omitted in FIG. 1 for convenience. In addition, the examination support room (A) and the examination room (B) are each provided with a door through which a person can enter, and the illustration of the door is omitted in FIG. 1 for convenience.

As illustrated in the drawing, a partition wall W exists between the examination support room A and the examination room B, and a sight window D and a collection glove G may be installed in the partition wall W. The collection gloves (G) are provided in a form extending from the examination support room (A) to the internal space of the examination room (B), and the medical staff in the examination support room (A0) is completely separated from the examination room (B) and cannot communicate. In the present invention, as will be described later, UVC is used for sterilization and disinfection of the examination room (B), at this time the examination support room (A) The bulkhead (W) between the inspection support room (A) and the examination room (B), and the sight window (D) and sampling gloves (G) that can be installed on the bulkhead (W) to protect ) is UVC blocking treatment (eg, UVC blocking coating, etc.) so that it does not penetrate.

In the infectious disease screening clinic system 200 according to the present invention, the examination room B is provided with a smart sterilization system 100 . And, if necessary, the pressure control system 300 for making the examination room B into a negative pressure state or the examination support room A into a positive pressure state may be further provided in the infectious disease screening clinic system 200 of the present invention.

2 and 3 are schematic perspective views extracted from only the inside of the examination room (B) to show that the smart sterilization system 100 is installed and operated in the examination room (B), respectively, in FIG. 2, the examination room (B) An occupancy state in which a person (examinee) exists is shown, and FIG. 3 shows a non-existent occupancy state in which a person does not exist in the examination room B. In FIG. 4 and 5 are schematic side views of the state of FIGS. 2 and 3 , respectively.

The examination room (B) is a space where specimens are collected from the examinee who is to be tested for infection with an infectious disease or where direct treatment or examination of the examinee is carried out. It is in the form of an isolated space. Although not specifically illustrated in the drawings, an entrance door through which the examinee can enter and exit the examination room B is provided. A smart sterilization system 100 is installed in the examination room (B). The smart sterilization system 100 performs air sterilization to sterilize the air in the examination room when a person is present in the examination room, that is, in the presence state, and when a person is not present in the examination room, that is, non-resident In the 室) state, it has a configuration that proceeds with surface sterilization to sterilize the inner surface of the examination room. When performing surface sterilization, air sterilization may also be carried out in parallel.

First, the smart sterilization system 100 of the present invention will be described in detail. The smart sterilization system 100 includes an occupancy sensor that detects the presence of a person in the examination room (B) to determine occupancy and non-occupancy conditions, and an elevating member (1) that is installed hanging from the ceiling of the examination room (B). And, the elevating module is operated to vertically elevate the elevating member (1) in the examination room, and is installed on the upper surface of the elevating member (1), the elevating member (1) is folded in the elevated state When the elevating member 1 descends, it has a configuration including a folding module that is unfolded in a straight line, and a UVC lamp 2 that is installed in the folding module and irradiates UVC. If necessary, the smart sterilization system 100 may further include an air circulation fan 3 that circulates air at an interval between the elevating member 1 in the elevated state and the ceiling surface of the examination room.

In the smart sterilization system 100 of the present invention, first, the occupancy sensor detects whether a person is present in the examination room B to determine the occupancy state and the non-occupancy state. The occupancy sensor may determine that the door provided in the examination room B is opened in order for a person to enter the examination room B as an occupancy state. Therefore, it should be understood that the "occupancy state" includes not only a state in which a person exists in the examination room B, but also a state in which the door provided in the examination room B is opened in order for a person to enter the examination room B.

The elevating member (1) is suspended at a position spaced apart from the ceiling of the examination room, and the elevating and lowering member (1) is close to the ceiling of the examination room so as not to disturb the examinee in the occupancy state and maintains a certain distance from the ceiling. It is in a rising state facing each other, and in the non-occupant state, the elevating member 1 descends vertically so as to approach the floor surface of the examination room and is in the descending state. The occupancy sensor may be provided on the elevating member 1, but is not limited thereto, and may be installed at any location where it is easy to determine whether or not a person is present in the examination room. The signal measured by the occupancy sensor is transmitted according to a wired/wireless method to a control module that controls the overall operation of the smart sterilization system 100, and the control module according to the signal received from the occupancy sensor is transmitted to the smart sterilization system 100 of the present invention. ) to control the operation of the components (various modules, UVC lamps, elevating members, sensors, fans, etc.) in a wired or wireless manner.

The folding module is provided on the upper surface of the elevating member 1, that is, the upper surface facing the ceiling surface of the examination room. When the member 1 is in the lowered state, the folding module is in the extended state so as to be elongated in the vertical direction. When the folding module is folded because the elevating member 1 is in an elevated state, the UVC lamp 2 installed in the folding module is in a state facing the ceiling surface of the examination room. When the air circulation fan 3 operates in this state, the air in the examination room flows in the direction of the ceiling surface, flows between the upper surface of the elevating member 1 and the ceiling surface of the examination room, and then is discharged down toward the inner space of the examination room again. do. In this air flow process, "air sterilization" proceeds by irradiating UVC to the air flowing between the elevating member 1 and the ceiling of the examination room while the UVC lamp 2 is operated. That is, air sterilization proceeds in the occupancy state. At this time, since the UVC lamp 2 is located near the ceiling surface of the examination room and irradiates UVC toward the ceiling surface, the UVC irradiation is not harmful to the examinee accommodated in the examination room. In FIGS. 2 to 5 , the bold arrow F shows that air flows by the air circulation fan 3 , and the small arrow L shows that UVC is irradiated from the UVC lamp 2 .

When the occupancy sensor detects the non-occupancy state of the examination room, the folding module unfolds in a straight line and the elevating member 1 descends to approach the floor surface of the examination room. As the folding module is unfolded, the UVC lamp 2 is also arranged in a straight line and faces the wall of the examination room. When the UVC lamp 2, which is in the form of a straight line, is operated, UVC is irradiated to the wall of the examination room, and "surface sterilization" of the wall is carried out directly. That is, when there is no examinee in the examination room, the surface sterilization of the wall surface by UVC is automatically performed. As described above, the bulkhead (W) between the examination support room (A) and the examination room (B), and the viewing window (D) and collecting gloves (G) that can be installed on the bulkhead (W) are UVC blocking treatment by UVC blocking coating, etc. Therefore, even when UVC irradiation is made on the walls of the examination room, the medical staff accommodated in the examination support room (A) are protected from UVC, so that harmful problems due to UVC irradiation do not occur.

While the surface sterilization of the wall by UVC is in progress, when a person enters the examination room (B), the occupancy sensor recognizes it and identifies it as an occupancy state. Accordingly, the folding module is folded and the elevating member (1) It rises to a position close to the ceiling surface and the UVC lamp 2 faces the ceiling surface of the examination room. In this state, as described above, as the air circulation fan 3 operates, UVC irradiation is made on the air flowing between the upper surface and the ceiling surface of the elevating member 1 while the air sterilization may proceed.

As described above, in the present invention, the examiner automatically identifies the occupancy state and the non-occupancy state accommodated in the examination room, and circulates the air in the indoor space in the occupancy state and irradiates UVC (ultraviolet ray C) to the air. Only air sterilization is carried out. Therefore, the body is not directly exposed to UVC in the air sterilization process using UVC, and it is possible to solve the problem of harm to the human body due to direct body exposure to UVC.

In addition, in the present invention, when the examination room is in a non-occupant state, UVC is irradiated to the surface of the examination room such as a wall surface to perform surface sterilization. Therefore, according to the present invention, the wall surface of the examination room is always exposed to UVC when no person is present, thereby increasing the sterilization effect according to the prolonged UVC exposure time. The effect of maximizing the effect of air sterilization and surface sterilization of the examination room using UVC is demonstrated.

6 to 12 are diagrams of a specific embodiment of the smart sterilization system 100 according to the present invention. Specifically, schematic perspective views showing the smart sterilization system 100 of the present invention in a surface sterilization state in different viewing directions are shown in FIGS. 6 and 7 , respectively. 8 and 9, respectively, in the present invention, as the elevating member 1 is raised or lowered and the folding module is folded, it is a schematic view showing the state of the intermediate stage that is mutually changed from the surface sterilization state to the air sterilization state in different directions A perspective view is shown. 10 and 11 are schematic perspective views showing the smart sterilization system 100 of the present invention in an air sterilization state in different looking directions, respectively. 12 to 14 are schematic side views viewed from the arrow M direction (front direction) of FIG. 6 sequentially showing the process of changing from the surface sterilization state to the air sterilization state, respectively. 15 to 17 are schematic side views viewed from the arrow N direction (lateral direction) of FIG. 6 sequentially showing the process of changing from the surface sterilization state to the air sterilization state, respectively. 6 to 17 , illustration of the examination room is omitted for convenience. In addition, the process of changing from the air sterilization state to the surface sterilization state has been described with reference to FIGS. 2 and 3 above. However, with reference to FIGS. 6 to 17 , the sequence of changing from the surface sterilization state to the air sterilization state is an embodiment of the present invention explain

In the smart sterilization system 100 according to the embodiment shown in FIGS. 6 to 17 , the elevating member 1 is made of a plate member facing the bottom surface of the examination room, and the upper surface of the folding module 20 is The lower end is rotatably coupled. The upper end of the folding module 20 may be fixedly coupled to the ceiling surface of the examination room, but if necessary, it faces the elevating member 1 as in the embodiment of the drawing and is integrally fixed to the ceiling surface of the examination room. The member 4 may be further provided in the smart sterilization system 100 , and the upper end of the folding module 20 may be rotatably coupled and fixed to the lower surface of the ceiling installation member 4 . The ceiling mounting member 4 may also be made of a plate member. When the ceiling mounting member 4 is provided, the advantage of making the installation of the smart sterilization system 100 and the installation of the elevating module easier is exhibited.

The folding module 20 includes two lamp installation members composed of elongated members, that is, a first lamp installation member 20a and a second lamp installation member 20b, and the first and second lamp installation members 20a , 20b) has a configuration that is rotatably connected to each other by an intermediate hinge portion (20c). The lower end of the folding module 20 (specifically, the lower end of the second ramp installation member 20b) is rotatably coupled to the upper surface of the elevating member 1, and the upper end of the folding module 20 (specifically, the first 1 The upper end of the lamp installation member (20a)) is rotatably coupled to the ceiling surface or the ceiling installation member (4) of the examination room. A UVC lamp 2 is installed in each of the first and second lamp installation members 20a and 20b to form an elongated shape. In the drawings, the UVC lamp 2 is shown in the form of an elongated tube, but this is an example and the present invention is not limited thereto. Therefore, a plurality of small lamps may be arranged in a long row to be disposed on the first and second lamp installation members 20a and 20b, and UVC lamps 2 of various shapes and methods may be formed on the first and second lamp installation members 20a, 20a, 20b) can be installed.

Therefore, when the examination room is in a non-occupant state, as shown in FIGS. 6, 7, 12 and 15, the elevating member 1 descends in the direction of the floor surface of the examination room so as to approach the floor surface of the examination room, Accordingly, the first and second lamp installation members 20a and 20b are arranged to be elongated in the vertical direction, and at the same time, the UVC lamps 2 are also continuously arranged to be elongated in the vertical direction and face the wall surface of the examination room. In this state, the UVC lamp 2 irradiates UVC to the wall of the examination room, and surface sterilization proceeds.

When the examination room changes from the non-occupant state to the occupancy state, rotation occurs in the intermediate hinge portion 20c as shown in FIGS. 8, 9, 13 and 16, and the intermediate hinge portion 20c moves away from the wall of the examination room As it moves, the folding module 20 is gradually bent, and finally, the folding module 20 is completely folded as shown in Figs. ) and the UVC lamp (2) installed therein is laid down horizontally so as to face the direction of the ceiling of the examination room. In this state, the UVC lamp 2 irradiates UVC in the direction of the ceiling of the examination room. When flowing or the ceiling mounting member 4 is provided, air sterilization proceeds by UVC irradiation while flowing between the elevating member 1 and the ceiling mounting member 4 .

In forming the intermediate hinge portion 20c in a rotatable shape so that the space between the first and second lamp installation members 20a and 20b can be bent, the ends of the first and second lamp installation members 20a and 20b are horizontal It is preferable that the intermediate hinge portion 20c is made in a shape adjacent to each other in the direction. In each of (a) to (c) of FIG. 18 , a schematic enlarged view showing an enlarged and bent state of the circle H portion of FIG. 6 , that is, the intermediate hinge portion 20c, is shown in order. The lower end of the first lamp installation member 20a positioned upward in the vertical direction and the upper end of the second lamp installation member 20b positioned downward in the vertical direction are coupled in a rotatable form in the intermediate hinge portion 20c, 15 (a) to (c), the lower end of the first lamp installation member (20a) and the upper end of the second lamp installation member (20b) are rotatably coupled in a state in contact with the horizontal side surface it is preferable According to this configuration, as shown in FIGS. 6, 7, 12, 15 and 18 (a), when the surface sterilization of the examination room proceeds, the first and second lamp installation members 20a and 20b are each Although the center lines do not form a perfect straight line with each other and are shifted from each other, the overall length is lengthened in the vertical direction to be in a continuous position, and the UVC lamps 2 provided in each of the first and second lamp installation members 20a and 20b are also It is continuously arranged so as to be elongated in the vertical direction so that all UVC lamps 2 are in a state capable of irradiating UVC toward the wall surface of the examination room.

On the other hand, when the state shown in FIGS. 10, 11, 14, 17 and 18 (c) is reached by folding by rotation at the intermediate hinge part 20c for air sterilization, the first and second While the lamp installation members 20a and 20b are positioned side by side in the horizontal direction, each of the UVC lamps 2 is made in a state capable of irradiating UVC toward the ceiling of the examination room. That is, as shown in (a) to (c) of FIG. 18 , the lower end of the first lamp installation member 20a and the upper end of the second lamp installation member 20b are in contact with the middle hinge portion 20c in the horizontal direction. According to ), when the folding module 20 is folded, the UVC lamps 2 are all laid down to be horizontally arranged, and accordingly, all the UVC lamps 2 can be irradiated with UVC toward the ceiling of the examination room. According to this configuration, the advantage of very high efficiency of air sterilization is exhibited.

The folding module 20 including the first and second ramp installation members 20a and 20b and the intermediate hinge portion 20c described above may be provided on opposite sides of the elevating member 1, respectively, and further A plurality of folding modules 20 may be provided at intervals along the side surface of the elevating member 1 . By disposing the plurality of folding modules 20 as above, it is possible to more efficiently perform surface sterilization on the entire wall surface of the examination room.

The elevating module for elevating the elevating member 1 in the vertical direction may include a configuration using a wire, a configuration using extension/contraction of a telescopic vertical member, and a motor for bending the hinge portion. Specifically, in the case of an elevating module using a wire, the lower end of the wire is connected to the elevating member 1, and the upper end of the wire is connected to a winding device such as a winch to unwind the wire by the operation of the winding device. It can have a configuration in which the elevating member 1 is vertically lowered by making it sag, and the elevating member 1 is vertically raised by pulling the wire.

6 to 17, the elevating module basically has a configuration for elevating and lowering the elevating member 1 using a wire as above, but in addition to this, rotational bending of the folding module 20 is performed. It has more configurations that can make it more stable and reliable. Specifically, in the embodiment shown in FIGS. 6 to 17 , the lower end of the wire 11 is fastened to the intermediate hinge portion 20c, and more specifically, the lower end of the wire 11 forms the intermediate hinge portion 20c. It is coupled to the lower end of the first lamp installation member 20a or the upper end of the second lamp installation member 20b. The upper end of the wire 11 is coupled to the winding device 10 . Therefore, when the wire 11 is wound and pulled by the winding device, the intermediate hinge portion 20c of the folding module 20 is pulled away from the wall of the examination room, and accordingly, the intermediate hinge portion 20c of the folding module 20 Rotational bending and folding according to it are reliably and stably made.

In the case of the embodiment shown in FIGS. 6 to 17 , since the plurality of folding modules 20 are provided on both sides of the elevating member 1 opposite to each other at intervals, the plurality of folding modules 20 are simultaneously installed. The lower ends of the wires 11 are individually coupled to each intermediate hinge portion 20c of each of the plurality of folding modules 20 to be bent. Since the plurality of wires 11 are present in this way, in the embodiment shown in FIGS. 6 to 17 , the winding device 10 includes a winding shaft 12 to which the upper ends of the plurality of wires 11 are coupled at the same time. are doing Since a plurality of folding modules 20 are provided on both sides of the elevating member 1 opposite to each other, two winding shafts 12 are also provided side by side, and the two winding shafts 12 are It is connected to the central drive shaft 13 by a force transmission member 14 . Therefore, when the central drive shaft 13 is rotated by a power source 15 such as a motor, the rotational force is transmitted to each winding shaft 12 by the force transmission member 14, so that the two winding shafts 12 are simultaneously As the plurality of wires 11 connected to the winding shaft 12 are simultaneously pulled, the plurality of folding modules 20 are simultaneously bent. When the wire 11 is continuously pulled, the folding module 20 is folded by rotation at the intermediate hinge portion 20c as described above, and accordingly, the first and second lamp installation members 20a and 20b are horizontally adjacent to each other. are positioned side by side, and each provided UVC lamp 2 is made in a state capable of irradiating UVC toward the ceiling of the examination room. In the non-occupancy state of the examination room, by actively rotating the winding shaft 12 or using the self-weight of the elevation member 1, the wire 11 is unwound from the winding shaft 12 and extended to extend the elevation member. (1) is lowered.

In particular, in arranging the two winding shafts 12 in the above configuration, the winding shaft 12 is arranged in a position opposite to the intermediate hinge portion 20c pulled by the wire 11 as illustrated in the figure. it is preferable If this is described in more detail using the expression "left and right" in the lateral direction (the direction indicated by arrow N in FIG. 6 ), for example, connected to the folding module disposed on the left side of the elevating member 1 The winding shaft 12 to which the upper end of the wire is coupled is disposed in the right direction opposite to this, and the upper end of the wire connected to the folding module disposed on the right side of the elevating member 1 is coupled to the winding shaft 12 is arranged in the left direction opposite to this. When each winding shaft 12 rotates in this arrangement, the wire 11 coupled thereto is wound and the wire 11 is pulled toward the winding shaft 12 in the direction of the intermediate hinge of the folding module 20 . (20c) moves away from the wall of the examination room, and accordingly, bending and folding in the intermediate hinge portion 20c of the folding module 20 are more reliably and stably made. That is, as described above, by arranging the winding shafts 12 at positions opposite to the intermediate hinge portion 20c pulled by the wire, respectively, bending at the intermediate hinge portion 20c and folding of the folding module 20 accordingly The advantage of being able to induce more easily is exhibited.

However, in the present invention, the configuration of the elevating module for elevating the elevating member 1 in the vertical direction is not limited to that illustrated above. In particular, in vertically elevating the elevating member 1 using a wire, for example, each wire is connected to the edge of the elevating member 1, and the ceiling surface or ceiling installation member 4 of the examination room. It is also possible to use a simple structure in the form of installing a winding device that can wind a wire, such as a winch, on the . In addition, as mentioned above, a telescopic member is installed between the ceiling surface or the ceiling mounting member 4 and the elevating member 1 to extend/retract in a telescopic structure. (1) can be raised and lowered.

As mentioned above, in the smart sterilization system 100 of the present invention, the ceiling installation member 4 may be omitted if necessary. That is, the upper end of the folding module 20 is fixedly coupled to the ceiling surface of the examination room without the ceiling installation member 4, and the winding shaft 12, the driving shaft 13, etc. The module can also be installed on the ceiling surface. However, in the case of having the ceiling installation member 4 as illustrated above, the upper end of the folding module 20 is coupled to the ceiling installation member 4 and the elevating module can be installed on the ceiling installation member 4, so that the present invention The smart sterilization system 100 of the whole can have the form of an assembly, and accordingly, the smart sterilization system 100 of the present invention is pre-assembled and manufactured in advance, and then transferred to the examination room and installed in such a way as to be installed. The advantage of facilitating the construction of the smart sterilization system 100 of the present invention is exhibited.

As mentioned above, in the infectious disease screening clinic system of the present invention, depending on the situation, the internal space of the examination room (B) is made into a negative pressure state or the internal space of the examination support room (A) is set to a positive pressure state. The pressure control system 300 to make may be further provided as needed. The pressure regulation system 300 is controlled by the control module.

The pressure control system 300 includes a suction port 310 formed in the examination room B, a suction fan for sucking air of the examination room B from the suction port 310, and an exhaust pipe for exhausting the suctioned air from the examination room to the outside. is comprised of 1 and 2 , the suction port 310 is exemplified as being formed at the lower end of the wall surface of the examination room B, but the position of the suction port 310 is not limited thereto. The exhaust pipe is provided to be connected to the suction port, and the installation position of the suction fan can be appropriately selected inside or outside the examination room (B), so the illustration of the suction fan and the exhaust pipe is omitted in the drawings.

When the pressure control system 300 is further provided in the infectious disease screening clinic system, when the examination room B is identified as occupant, the suction fan is operated under the control of the control module to suck air from the examination room through the suction port 310. It is discharged to the outside of the examination room (B) through the exhaust pipe to make the examination room (B) in a negative pressure state. In such a negative pressure condition in the examination room (B), infectious sources such as viruses or other contaminants that may be discharged during the process of collecting samples from the examinee or examining or treating the examinee are discharged and removed from the examination room (B). It is possible to greatly improve the safety of the ongoing sample collection or examination/treatment process.

On the other hand, the pressure control system 300 may further include a configuration for making the internal space of the inspection support room (A) into a positive pressure state if necessary. That is, in the pressure control system 300 to make the internal space of the inspection support room (A) into a positive pressure state, the discharge port 320 formed in the inspection support room (A), and an air supply pipe for supplying external air to the discharge port And, an air supply fan for supplying outdoor air to the outlet 320 may be further provided. 1 and 2, the discharge port 320 is exemplified as being formed on the upper end of the wall surface of the inspection support room (A), but the position of the discharge port 320 is not limited thereto. The air supply pipe is provided to be connected to the discharge port, and the installation location of the air supply fan can be appropriately selected inside or outside the inspection support room (A), so the illustration of the air supply fan and the air supply pipe is omitted in the drawings.

Therefore, during sample collection or treatment, or in other necessary situations, the control module operates the air supply fan to inhale the outside air and supply the inhaled outside air to the examination support room (A) through the air supply pipe and the outlet to provide the examination support room (A). It creates positive pressure. By making the test support room (A) in a positive pressure state in this way, it is possible to more thoroughly block the influx of infectious agents or other contaminants into the test support room (A), and thus safely protect the medical staff accommodated in the test support room (A). be able to do

In describing the smart sterilization system 100 of the present invention above, on the opposite sides of the elevating member 1, the first and second lamp installation members 20a, 20b and the intermediate hinge portion 20c are included. The folding modules 20 have been described as facing each other. That is, in the case of the embodiment shown in FIGS. 1 to 17 , a plurality of folding modules 20 are installed along the interval also on the left side of the elevating member 1 in the transverse direction, and facing the elevating member 1 It also has a configuration in which a plurality of folding modules 20 are installed along intervals on the right side of the .

However, in configuring the smart sterilization system 100 of the present invention, a plurality of folding modules 20 may be provided at intervals only on one side of the elevating member 1 . 19 to 25 are views showing the smart sterilization system 100 provided with a plurality of folding modules 20 only on one side of the elevating member 1 as described above, and FIGS. 19 and 20 are respectively FIGS. 6 and FIG. It is a schematic perspective view corresponding to 7 , and FIGS. 21 and 22 are schematic perspective views corresponding to FIGS. 8 and 10 , respectively. And FIGS. 23 to 25 are schematic side views corresponding to FIGS. 12 to 14, respectively. The embodiment of the smart sterilization system 100 illustrated in FIGS. 19 to 25 is only in that a plurality of folding modules 20 are provided at intervals not on both sides of the elevating member 1, but on one side of FIGS. 1 to Since it is different from the embodiment shown in FIG. 17 and is the same in other configurations, operating processes, and effects, the same reference numerals are used, and detailed descriptions thereof are omitted.

In the case of the smart sterilization system 100 in which a plurality of folding modules 20 are provided only on one side of the elevating member 1 as described above, in addition to the examination room B of the infectious disease screening clinic system 200 , , It can be installed and utilized wherever UVC sterilization is required on the wall. In the case of the smart sterilization system 100 provided with a plurality of folding modules 20 only on one side of the elevating member 1, when the folding module 20 is unfolded, one wall is irradiated with UVC, so yes For example, the above-described embodiment can be used in any indoor space having a wall that requires sterilization, such as a general hospital room, a general medical room, or a school classroom.

1: No elevating
2: UVC lamp
3: Air circulation fan
4: Ceiling installation member
10: winding device
11: wire
12: winding axis
13: drive shaft
20: folding module
20a: first lamp installation member
20b: second lamp installation member
20c: middle hinge part
100: smart sterilization system
200: Infectious disease screening clinic system
A: Inspection Support Office
B: Examination room

Claims (8)

An infectious disease screening clinic system comprising a test support room where medical staff are accommodated, and a checkup room where examinees who are to be tested for infection with an infectious disease are accommodated,
The examination room is equipped with a smart sterilization system,
The smart sterilization system is installed in an occupancy sensor that detects the occupancy and non-occupancy conditions of the examination room, an elevating module that vertically elevates and lowers the elevating member, and is installed in the elevating member to fold and lift the elevating member in the elevated state. It has a configuration including a folding module that unfolds when the descending member descends, and a UVC lamp installed in the folding module to irradiate UVC;
When the examination room is identified as a non-occupant state, the elevating member descends to unfold the folding module, and the UVC lamp irradiates UVC on the wall of the examination room to sterilize the surface;
When the examination room is identified as occupancy, the folding module is folded as the elevating member rises, and the UVC lamp faces the ceiling. Infectious disease screening clinic system, characterized in that air sterilization proceeds. According to claim 1,
The elevating member of the smart sterilization system is made of a plate member facing the floor surface of the examination room;
The smart sterilization system is further provided with a ceiling installation member that is integrally fixed to the ceiling surface of the examination room while facing the elevating member;
The folding module of the smart sterilization system is composed of an elongated member and is configured to include first and second lamp installation members rotatably connected to each other by an intermediate hinge portion;
an upper end of the first lamp mounting member is rotatably coupled to a lower surface of the ceiling mounting member;
The lower end of the second ramp installation member is rotatably coupled to the upper surface of the elevating member;
UVC lamps are installed on each of the first and second lamp installation members, an infectious disease screening clinic system. 3. The method of claim 1 or 2,
The elevating module of the smart sterilization system is configured to include a wire and a winding device for winding or unwinding the wire;
Infectious disease screening clinic system, characterized in that it has a configuration in which the elevating member is vertically lowered by hanging the wire down by the operation of the winding device, or the elevating member is vertically raised by pulling the wire. 4. The method of claim 3,
The lower end of the wire is coupled to the lower end of the first lamp installation member or the upper end of the second lamp installation member constituting the intermediate hinge part of the folding module, so that when the wire is wound and pulled by the winding device, the intermediate hinge part is far from the wall of the examination room Infectious disease screening clinic system, characterized in that it has a configuration in which rotational bending at the intermediate hinge part and folding of the folding module are made while lowering. 3. The method of claim 1 or 2,
In the smart sterilization system, the infectious disease screening clinic system, characterized in that a plurality of folding modules are provided on both sides of the elevating member facing each other at intervals. 5. The method of claim 4,
In the smart sterilization system, the winding device of the elevating module is configured to include a winding shaft to which the upper end of the wire is coupled, and a driving shaft connected to the winding shaft by a force transmission member to transmit rotational force to the winding shaft to rotate;
Two winding shafts are provided side by side, and each of the two winding shafts is arranged at a position in place of the intermediate hinge portion to which the wire to be pulled is coupled;
Infectious disease screening clinic system, characterized in that as the wire coupled to the winding shaft is wound and pulled in the winding axis direction, the intermediate hinge part also moves in the winding axis direction to move away from the wall of the examination room. 3. The method of claim 1 or 2,
a suction port formed in the examination room, a suction fan for sucking air from the examination room from the suction port, and an exhaust pipe for exhausting the suctioned air from the examination room to the outside;
Infectious disease screening clinic system, characterized in that the system further comprises a pressure control system that makes the internal space of the examination room a negative pressure state by sucking air from the examination room through the suction port by the operation of the suction fan and discharging it to the outside of the examination room through the exhaust pipe. 8. The method of claim 7,
A discharge port formed in the inspection support room, an air supply pipe for supplying outdoor air to the discharge port, and an air supply fan for supplying outdoor air to the discharge port are further provided in the pressure control system;
Infectious disease screening clinic system, characterized in that the outside air is sucked by the operation of the air supply fan, and the inhaled outside air is supplied to the examination support room through the air supply pipe and the outlet to make the examination support room in a positive pressure state.

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