KR20220087196A - Sterilization purification reactor module and in-line air purification sterilization device and ventilation system capable of positive and negative pressure including the same - Google Patents

Abstract

The present invention relates to a sterilization and purification reactor module and to an in-line air purification sterilization device and ventilation system capable of positive and negative pressure including the same, and more particularly, to an air purification and sterilization device and ventilation system using an in-line fan capable of positive and negative pressure adjustment it's about
To this end, the in-line air purification and sterilization apparatus of the present invention includes: a body case having an empty interior and air is introduced from one side; Trays for fixing nanotubes respectively formed at the top and bottom of the body case; nanotubes directly or indirectly coupled to the tray for fixing the nanotubes; a holder for fixing an ultraviolet lamp that is introduced into a holder hole formed on a side surface of the body case; and an ultraviolet lamp inserted into the holder for fixing the ultraviolet lamp; It includes a sterilization and purification reactor module comprising a,
an in-line main case and a side case constituting an in-line storage box for accommodating the sterilization and purification reactor module; a filter insertion rail formed inside the storage box and fastened to a second surface of one side of the storage box; and a filter member accommodated in the storage box by the filter insertion rail and configured with a plurality of filters connected to the sterilization and purification reactor module.

Description

Sterilization purification reactor module and in-line air purification sterilization device and ventilation system capable of positive and negative pressure including the same

The present invention relates to a sterilization and purification reactor module and to an in-line air purification sterilization device and ventilation system capable of positive and negative pressure including the same, and more particularly, to an air purification and sterilization device and ventilation system using an inline fan capable of positive and negative pressure adjustment it's about

Modern people live more than 90% of the time indoors and breathe a large amount of air together with people around them. Therefore, indoor air quality has a great significance for public health. In particular, due to the coronavirus outbreak in 2019, indoor air quality management in multi-use facilities and infection control of respiratory diseases are emerging as very important social issues.

In general, indoors of multi-use facilities such as schools, hospitals, shopping malls, underground and subway stations contain fine dust, foreign substances, or microbial contaminants, and these contaminants are to provide.

In addition, the necessity of ventilation of indoor air is emerging due to COVID-19. Negative pressure (isolation) ward facilities are required due to COVID-19, and the indoor air is discharged to the outside to generate negative pressure in the room, and harmful pollutants in the room must be purified and sterilized so that they are not discharged to the outside.

In addition, the operating room of a hospital must maintain positive pressure to prevent external contaminants such as bacteria from entering the interior. In the case of current medical facilities, both positive and negative pressure are required. In this way, when the positive pressure facility and the negative pressure facility are separately constructed, there is a problem in that it is not possible to quickly respond to an emergency situation, and there is a problem in that the construction cost is also increased.

Korean Patent Registration No. 10-1585223 Korean Patent Publication No. 10-2012-0077724

The problem to be solved by the present invention is to propose an air purification and sterilization device capable of both positive pressure and negative pressure.

Another problem to be solved by the present invention is to propose an air purification and sterilization device in which ultraviolet rays are not radiated to the outside.

Another problem to be solved by the present invention is to propose a method for controlling the driving of an in-line fan or an ultraviolet lamp indoors.

Another problem to be solved by the present invention is to propose a method for checking the driving time of an ultraviolet lamp.

To this end, the in-line air purification and sterilization apparatus of the present invention includes: a body case having an empty interior and air is introduced from one side; Trays for fixing nanotubes respectively formed at the top and bottom of the body case; nanotubes directly or indirectly coupled to the tray for fixing the nanotubes; a holder for fixing an ultraviolet lamp that is introduced into a holder hole formed on a side surface of the body case; and an ultraviolet lamp inserted into the holder for fixing the ultraviolet lamp; It includes a sterilization and purification reactor module comprising a,

an in-line main case and a side case constituting an in-line storage box for accommodating the sterilization and purification reactor module; a filter insertion rail formed inside the storage box and fastened to a second surface of one side of the storage box; and a filter member accommodated in the storage box by the filter insertion rail and configured with a plurality of filters connected to the sterilization and purification reactor module.

The sterilization and purification reactor module according to the present invention and the in-line air purification sterilization device and ventilation system capable of positive and negative pressure including the same can quickly change a room to positive or negative pressure by using the rotation direction of the inline fan. In addition, the present invention displays the cumulative lighting time of the UV lamp, so that the user can easily check the replacement time of the UV lamp.

In addition, the present invention can improve the sterilization effect by the ultraviolet lamp by chrome plating the case and the nanotube constituting the sterilization and purification reactor module.

1 shows a sterilization and purification reactor module according to an embodiment of the present invention.
2 shows a nanotube according to an embodiment of the present invention.
3 illustrates a process of photocatalytic coating of nanotubes according to an embodiment of the present invention.
4 is a view showing the fastening state of a plurality of sterilization and purification reactor modules according to an embodiment of the present invention.
5 shows an in-line air purification and sterilization apparatus according to an embodiment of the present invention.
6 shows an air purification and sterilization system according to an embodiment of the present invention.
7 shows the configuration of a control box according to an embodiment of the present invention.

The foregoing and further aspects of the present invention will become more apparent through preferred embodiments described with reference to the accompanying drawings. Hereinafter, it will be described in detail so that those skilled in the art can easily understand and reproduce through these embodiments of the present invention.

1 shows a sterilization and purification reactor module according to an embodiment of the present invention. Hereinafter, a sterilization and purification reactor module according to an embodiment of the present invention will be described in detail with reference to FIG. 1 . In particular, Fig. 1 (a) shows a perspective view of the sterilization and purification reactor module, and Figure 1 (b) shows an exploded perspective view of the sterilization and purification reactor module.

1 , the sterilization and purification reactor module 100 includes a body case, a nanotube fixing tray, a UV lamp fixing holder, an UV lamp, a tray insertion boss, a nanotube, a control board, and an UV lamp stabilizer. Of course, other configurations other than the above-described configuration may be included in the sterilization and purification reactor module proposed in the present invention.

The body case 102 has an empty interior so that components can be mounted, and has a rectangular parallelepiped shape with an open top and an open bottom. The body case 102 is mounted or combined with each component constituting the sterilization and purification reactor module 100 proposed in the present invention. The inside of the body case 102 is plated with reflective chrome, so that ultraviolet rays are reflected inside instead of radiating to the outside. The body case may be composed of one member or two members. That is, the body case 102 may be composed of a main case 102a composed of three side members and a reactor cover 102b constituting one side surface.

The nanotube fixing tray 104 is formed on the inner top and bottom of the body case 102 . That is, as shown in FIG. 1 , the nanotube fixing tray 104 is formed at the top and bottom of the body case 102 , respectively. The nanotube fixing tray 104 is formed on both sides of the inner upper end of the body case 102 and at the same time formed on both sides of the inner lower end.

The holder 106 for fixing the UV lamp is fastened to the body case while being positioned between the two trays 104 for fixing the nanotube. The material of the holder 106 for fixing the UV lamp is preferably made of rubber, but may be made of a material other than rubber. The reason for forming the rubber material is to prevent damage due to impact.

The holder 106 for fixing the UV lamp is inserted into the holder hole formed in the body case 102, and the UV lamp 108 is inserted into the holder 106 for fixing the UV lamp while the holder 106 for fixing the UV lamp is inserted. is brought in

The ultraviolet lamp 108 is fastened to the holder 106 for fixing the ultraviolet lamp. The ultraviolet lamp 108 emits ultraviolet rays by power supplied from the outside.

The tray insertion boss 110 is coupled to the nanotube fixing tray 104 . As shown in FIG. 1 , a plurality of bosses 110 for tray insertion are arranged on the tray 104 for fixing nanotubes. The tray insertion boss 110 is preferably fixedly coupled to the nanotube fixing tray 104, but may be coupled in a detachable manner. In detail, in a state in which the tray insertion boss 110 is fastened to both ends of the nanotube 112 , it is inserted into the nanotube fixing tray 104 .

The nanotubes 112 are coupled to the boss 110 for tray insertion. The nanotube 112 includes a circular cover for inserting a tray larger than the tube diameter, the surface has a honeycomb structure, and the inside is empty for free movement of air.

The shape of the nanotube 112 will be described later. The nanotube 112 is coated with a photocatalyst on the outside, and air introduced from the outside is sterilized by the coated photocatalyst. Of course, the air introduced from the outside is sterilized and purified not only by the nanotubes 112 but also by the UV lamp.

One side of the body case 102 flows in from the outside, and the other side is sterilized and purified air flows out. That is, one side of the body case 102 is supplied with external air by the driven fan, and the sterilized and purified air is discharged from the other side of the body case 102 .

A UV lamp ballast 114 and a control board 116 are formed on the side of the body case 102 . The UV lamp ballast 114 controls the lighting of the UV lamp 108 . The control board 116 controls the operation of the air purification reactor module.

2 shows a nanotube according to an embodiment of the present invention. Hereinafter, a nanotube according to an embodiment of the present invention will be described in detail with reference to FIG. 2 .

The nanotubes have a honeycomb structure, and a photocatalyst is applied thereto. Also, as shown in FIG. 2 , the nanotubes may be manufactured to have various lengths. That is, one side of the nanotube has a fastening structure, and the total length of the nanotube may be extended by combining the two nanotubes.

Nanotubes increase the reflective efficiency by coating a metal material with high reflective efficiency, such as chromium, and increase the photocatalytic effect by making the area of the portion irradiated with ultraviolet light relatively wider than the area of other portions. That is, the nanotube has a hollow honeycomb structure, and the cut surface of the honeycomb is formed to be inclined so that the area of the outer surface of the honeycomb structure formed of the nanotube is relatively wider than the area of the inner surface. In relation to the present invention, the size of the photocatalyst particles is 3 to 10 nm. A process for manufacturing the photocatalyst-coated nanotube will be described later with reference to FIG. 3 .

3 illustrates a process of photocatalytic coating of nanotubes according to an embodiment of the present invention. Hereinafter, a photocatalytic coating process of a nanotube according to an embodiment of the present invention will be described with reference to FIG. 3 .

In order to increase the photocatalytic efficiency of the nanotube, a process of increasing the spreadability (wettability) of the photocatalyst while reducing the surface energy of the base material is required.

The process of reducing the surface energy of the base material first cleans the base material. That is, in the first washing, the base material is washed using ultrasonic waves in a state in which the washing agent is added.

After the first washing, the base material is washed a second time. Unlike the first washing, the secondary washing uses ultrasonic waves in pure distilled water to clean the base material. As such, the present invention washes the base material at least twice in different environments.

The base material that has undergone the washing process is subjected to an electric drying process. Electric drying is performed at 120° C. for 60 minutes. Next, we will look into ways to increase the photocatalytic spreadability of nanotubes.

To increase the spreadability of the photocatalyst, the photocatalyst is applied in the form of a spray to the base material that has been washed and dried. The particle size of the photocatalyst is preferably 36 to 10 nm. Afterwards, the Young's modulus is measured. The contact angle should be less than 10ㅀ. In a state where the surface energy of the base material is low, the photocatalyst is applied thinly and uniformly to the base material. After that, the photocatalyst-coated base material is electro-dried, and the electro-drying is performed at 120° C. for 60 minutes.

4 is a view showing the fastening state of a plurality of sterilization and purification reactor modules according to an embodiment of the present invention. As shown in FIG. 4 , the sterilization and purification reactor module may be coupled to one sterilization and purification reactor module or two or more sterilization and purification reactor modules depending on the size of the inline air purification and sterilization device. Figure 4 (a) shows two sterilization and purification reactor modules, Figure 4 (b) shows a state in which three sterilization and purification reactor modules are fastened.

5 shows an in-line air purification and sterilization apparatus according to an embodiment of the present invention. Hereinafter, an in-line air purification and sterilization apparatus according to an embodiment of the present invention will be described in detail with reference to FIG. 5 .

Figure 5 (a) shows a cross-section of the air purifying and sterilizing device, Figure 5 (b) shows an exploded perspective view of the air purifying and sterilizing device.

The air purification and sterilization device 500 includes a first connection port, a first flange, a rail for filter insertion, a filter member, a second flange, an inline main case, a sterilization and purification reactor module, a side case, a third flange, a fourth flange, and the second Includes connector. Of course, other configurations other than the above-described configuration may be included in the air purification and sterilization apparatus proposed in the present invention.

The first connector 502 introduces or exhausts air from the outside. The first connector 502 is fastened to an external member. The shape of the first connector 502 may be variously formed, and FIG. 5 shows the first connector 502 having a cylindrical shape.

The first flange 504 supplies air introduced from the first connector 502 to the filter member 508 , or supplies air introduced from the filter member 508 to the first connector 502 . To this end, one side of the first flange 504 is coupled to the first connector 502 , and the other side is coupled to the inline main case 512 and the side cases 514 ( 514a to 514c ). The area of the first flange 204 coupled to the first connector 502 is relatively smaller than the area of the first flange 504 coupled to the inline main case 512 and the side case 514 .

The filter insertion rail (506; 506a, 506b) is located at one end of the inner space composed of the inline main case 512 and the side case 514, and is formed on one side (506a) and the other side (506b), respectively. The filter inserting rail 56 accommodates the filter member 508 . The filter member 508 filters the air introduced from the outside. The filter member 508 may be composed of a HEPA filter, a medium filter, a carbon filter, and a pre-treatment filter, and is located at one end of the inner space composed of the inline main case 512 and the side case 514 . Of course, other filters in addition to the above-described filter may be included in the filter member 508 proposed in the present invention.

The inline main case 512 accommodates the sterilization and purification reactor module 100 and the filter member 508 constituting the air purification and sterilization device 500 . The inline main case 512 includes a lower end portion, a side portion connected to the lower end portion, and an upper portion connected to the side portion. At the lower end and upper end, a hole is formed in the center to allow the movement of air. That is, air moves to the first flange 504 and the first connector 502 through the hole formed at the lower end, and air moves to the fourth flange 518 and the second connector 520 through the hole formed at the upper end. do.

The side case 514 is composed of three members, and is fastened to the inline main case 512 . That is, the three side cases 514 together with the side portions of the inline main case 512 constitute a side surface of the storage case. That is, the side case 514 and the inline main case 512 are coupled to each other to form a rectangular storage case, and as described above, the sterilization and purification reactor module 100 and the filter member 508 are accommodated inside the storage case. do. The side case 514 includes fastening means fastened to a wall or other member.

The second flange 510 connects the filter member 508 and the sterilization and purification reactor module 100 . That is, one side of the second flange 510 is fastened to the rail 506 for filter insertion, and the other side is fastened to the sterilization and purification reactor module 100 .

The sterilization and purification reactor module 100 is accommodated in the interior formed by the inline main case 512 and the side case 514, and performs the configuration and functions as described above in FIG. 1 .

The third flange 516 connects the bottom surface of the upper end of the inline main case 512 and the sterilization and purification reactor module 100 . That is, one side of the third flange 516 is coupled to the bottom surface of the upper end of the inline main case 512 , and the other side is coupled to the sterilization and purification reactor module 10 .

The fourth flange 518 connects the inline main case 512 and the second connector 520 . That is, one side of the fourth flange 518 is coupled to the second connector 520 , and the other side is coupled to the upper surface of the upper end of the inline main case 512 .

The second connector 520 is coupled to the fourth flange 518 . As such, the present invention proposes an in-line air purification and sterilization device.

6 shows an air purification and sterilization system according to an embodiment of the present invention. Hereinafter, an air purification and sterilization system according to an embodiment of the present invention will be described in detail with reference to FIG. 6 .

Referring to FIG. 6 , the air purification and ventilation system 600 includes an inline fan 610 , an air purification and sterilization device 500 , and a control box 620 . Of course, other configurations other than the above-described configuration may be included in the air purification and sterilization system proposed in the present invention.

The in-line fan 610 is coupled to the air purification and sterilization device 500, and the fan is mounted therein. In the inline fan 610, a fan mounted therein is driven by power supplied from the outside. The inline fan 610 rotates in a first direction or in a second direction opposite to the first direction by power supplied from the outside. When the inline fan 610 rotates in the first direction, air moves from one side of the inline fan to the other side. When the in-line fan 610 rotates in the second direction, air moves from the other side to one side.

The in-line fan 610 is coupled to the second connector of the air purification and sterilization device 500 . When the in-line fan 610 rotates in the first direction, the in-line fan 610 supplies air to the air purifying and sterilizing device 500 , and when rotating in the second direction, the in-line fan 610 turns on the air purifying and sterilizing device 500 . ) is supplied with air. As described above, the present invention can control the rotation direction of the in-line fan to adjust the state of the room connected to the air purification and sterilizer to negative pressure or positive pressure.

The air purifying and sterilizing device 500 is coupled to the in-line fan 610 , and in particular, the second connector is coupled to the in-line fan. The configuration and operation of the air purifying sterilizer is the same as described in FIG. 5 .

The control box 620 is wired or wirelessly connected to the inline fan 610 and the air purification and sterilization device 500 . The control box 620 controls the operation of the in-line fan 610 or the air purification and sterilization device 500 . The control box 620 may be attached to the wall in the form of a wall pad, and may be configured in other forms. Hereinafter, the configuration of the control box will be described.

7 shows the configuration of a control box according to an embodiment of the present invention. Hereinafter, the configuration of another control box according to an embodiment of the present invention will be described in detail with reference to FIG. 7 .

Referring to FIG. 7 , the control box includes a power switch, a fuse, a noise filter, an SMPS, a control module, a display module, a relay, a UV on/off switch, a time reset switch, and a red lamp. Of course, other configurations other than the above-described configuration may be included in the control box proposed in the present invention.

In addition, as described above, the control box is connected to the in-line fan and the air purifying and sterilizing device, and in particular, connected to the ultraviolet lamp of the air purifying and sterilizing device to control the operation. The control box controls the operation of the inline fan and the UV lamp by interlocking it, and when the operation of the inline fan is stopped, the power consumption can be reduced by flickering the UV lamp.

The power switch 620a turns on/off the power supplied from the outside. When the power switch 620a is turned off, the driving of the control box is stopped.

The fuse 620b performs a function of automatically shutting off when the power supplied from the outside exceeds the set power. That is, the fuse 620b performs a function of protecting internal components with external power.

The noise filter 620c filters noise included in the external power supply.

The SMPS (620d) drops the voltage of the supplied power to the voltage used in the internal components. That is, the SMPS 620d drops the supplied voltage to 5V.

The display module 620e displays various information including the driving state and time of the control box. The display module 620e displays various information according to a control command from the control module.

The relay 620g is positioned between the control module 620f and the inline fan 610 and the control module 620f and the air purification and sterilization device, and turns on/off the power delivered to the inline fan 610 .

The UV on/off switch 620h operates the driving of the UV lamp 108 . That is, the user controls the operation of the UV lamp 108 by manipulating the UV on/off switch 620h.

The time reset switch 620i initializes the lighting time of the UV lamp. The present invention accumulates and displays the lighting time of the UV lamp so that the user can know the lighting time of the UV lamp. The time reset switch 620i initializes the lighting time of the UV lamp when replacing the UV lamp.

The red lamp 620j turns on the red lamp 620j when replacement of the UV lamp is required so that the user can check it.

Although the present invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible therefrom. .

100: sterilization purification reactor module 102: body case
104: nanotube fixing tray 106: UV lamp fixing holder
108: UV lamp 110: tray insert boss
112: nanotube 114: ultraviolet lamp ballast
116: control board

Claims (9)

The body case is empty and air is introduced from one side;
Trays for fixing nanotubes respectively formed at the top and bottom of the body case;
nanotubes directly or indirectly coupled to the tray for fixing the nanotubes;
a holder for fixing an ultraviolet lamp that is introduced into a holder hole formed on a side surface of the body case; and
an ultraviolet lamp inserted into the holder for fixing the ultraviolet lamp; It includes a sterilization and purification reactor module comprising a,
an in-line main case and a side case constituting an in-line storage box for accommodating the sterilization and purification reactor module;
a filter insertion rail formed inside the storage box and fastened to a second surface of one side of the storage box; and
The in-line air purification and sterilization apparatus according to claim 1, comprising a filter member accommodated in the storage box by the filter insertion rail and comprising a plurality of filters connected to the sterilization and purification reactor module.
The in-line air purification sterilization apparatus according to claim 1, further comprising a tray insertion boss coupled to both ends of the nanotube and introduced into the nanotube fixing tray.
According to claim 2, wherein the nanotubes,
In order to reduce the surface energy of the nanotubes, the base material is first washed with ultrasonic waves in distilled water to which a cleaning agent is added, and the drying process is sequentially performed after the second washing is performed with ultrasonic waves in distilled water,
In order to increase the wettability of the photocatalyst, the photocatalyst is applied to the base material after the primary washing, secondary washing and drying processes are completed in the form of a spray, and then the drying process is performed.
The method of claim 1,
a first connector;
a first flange coupled to the first connector;
the storage box having a first side of one side fastened to the first flange, and a second side of the other side fastened with a fourth flange;
The in-line air purifying sterilization device, characterized in that it includes a second connector fastened to the fourth flange.
5. The method of claim 4,
a second flange, one side of which is fastened to the upper end of the filter insertion rail formed inside the storage box, and the other side is fastened to the sterilization and purification reactor module; and
One side is fastened to the sterilization and purification reactor module, and the other side is an inline air purification and sterilization apparatus, characterized in that it comprises a third flange fastened to the first surface of the other side of the storage box.
Including the in-line air purification sterilizer of claim 5,
The in-line ventilation system comprising an in-line fan fastened to the second connector of the in-line air purifying and sterilizing device.
The in-line ventilation system according to claim 6, further comprising a control box for controlling the operation of the in-line fan or the ultraviolet lamp of the in-line air purifying and sterilizing device.
The method of claim 7, wherein the control box,
controlling the rotation direction of the in-line fan to rotate in a first direction or a second direction opposite to the first direction;
The in-line air purifying and sterilizing device moves air from a first connector to a second connector or moves air from a second connector to the first connector according to the rotation direction of the in-line fan.
The method of claim 8, wherein the control box,
In-line ventilation system, characterized in that displaying the cumulative lighting time of the UV lamp, and displaying the replacement time of the UV lamp.

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