KR20220022229A - Disinfection booth - Google Patents

Abstract

The present invention relates to a disinfection booth (100, 500), comprising: a booth tunnel (101, 501) including two walls, a floor part and a ceiling part so that a person can pass therethrough; a plurality of motion detection sensor blocks (SR1-SR7, SL1-SL7) configured to sense a person passing through the booster tunnel (101, 501) by each movement position; a plurality of UV lamp blocks (UVBR1-UVBR7, UVBL1-UVBL7) linked to the operation of the motion detection sensor blocks (SR1-SR7, SL1-SL7), including several UVLEDs which emit UV rays to a semi-circular pillar type LED light reflector (BT) with a skirt having one side extending to a predetermined length, and rotationally driven at an arbitrary angle by a driving means; a guide support rod (301, 302) installed at the entrance of the booth tunnel (101) and including a sensor for identifying the body temperature and motion of a person and a blocking door (301a, 302a) which restricts the entry and exit of the person. Accordingly, the disinfection booth (100, 500) can sterilize people. In addition, air suction devices (400, 401, 402) are installed on the two walls and ceiling part of the booth tunnel (501) so as to disinfect the surrounding air and people.

Description

Disinfection booth

The present invention relates to a disinfection booth that can disinfect the entire body by a person who may have been contaminated with a pathogen such as a virus by walking through it.

In particular, it uses UVLED light that emits Ultra Violet with strong sterilization power to illuminate the entire human body to sterilize pathogens polluted in the body.

In general, viral infectious diseases such as COVID-19 are known to be transmitted through the respiratory tract.

Therefore, droplets discharged through the mouth and nose along with the air exhaled by the infected person are the direct source of infection.

In particular, wearing a mask and maintaining a certain distance between people is one of the best ways to prevent infection from these sources of infection.

In addition, there are cases where an infected person becomes infected due to contamination of their hands or clothing contaminated by the infected person, or the body of another person who has come into contact with the infected person, as well as indirectly as well as direct contact between air and droplets exhaled by the infected person.

In addition, it is known that there is a possibility of infection by contamination of the surrounding air by breathing or droplets of an infected person.

In order to solve this problem, a person sprays the disinfectant solution directly to the surrounding space or to a person using a sprayer, - As in 1667304, etc., disinfection booths that automatically spray disinfectant solution while staying in a predetermined space for a certain period of time or walking are used.

In addition, as mentioned in the patent registration 10-1565953, using ultraviolet rays to sterilize contaminated clothes.

Sterilization by ultraviolet rays is as verified in the contents of non-patent literature, and the ultraviolet rays are divided into UV-A, UV-B, and UV-C according to wavelength, and it is known that UV-C has the best sterilization power.

Such ultraviolet rays are either naturally supplied from sunlight or artificially generated using a light source device for emitting ultraviolet rays.

A high-pressure mercury lamp or UVLED is used as a light source device.

When ultraviolet light is emitted using the high-pressure mercury lamp as described above, a lot of ozone (O ₃ ) gas is generated at the same time. The ozone gas has a sterilizing power like ultraviolet rays, but there is a problem in that it has a fatal effect on the respiratory system.

In addition, when UV LED is used, ozone gas is not generated like the high-pressure mercury lamp, but when it is irradiated directly into human eyes, it causes damage to eyesight and causes various eye diseases.

In addition, in the disinfection booth that sprays the disinfectant solution, since the liquid disinfection spray solution is directly on the human body, there is a problem that not only gives discomfort but also can be inhaled through a respiratory system, and the disinfectant solution needs to be replenished.

In addition, there is a problem in that the disinfection booth or the apparatus to which the disinfection method using the light source body emitting left ultraviolet light is applied cannot sterilize extensively contaminated ambient air.

Korean Patent Registration 10-2139341, Korean Patent Application 10-2015-0103588, Korean Patent Registration 10-1565953, Korean Patent Registration 10-1575233, Korean Patent Registration 10-1667304.

-. Domestic literature data 1. A study on the prediction of indoor surface sterilization performance of UV sterilizer through radiation analysis J. Odor Indoor Environ. (Vol.18, No.1, pp.60-66, March 2019) -. Foreign literature data 1. 2020 COVID-19 Coronavirus Ultraviolet Susceptibility Technical Report March 2020 2. Armellino D, Walsh TJ, Petraitis V, Kowalski W. (2019). Assessment of focused multivector ultraviolet disinfection with shadowless delivery using 5-point multisided sampling of patient care equipment without manual-chemical disinfection. Am J Infect Control 47,409-414. 3. Armellino D GK, Thomas L, Walsh T, Petraitis V. (2020). Comparative evaluation of operating room terminal cleaning by two methods: Focused multivector ultraviolet (FMUV) versus manual-chemical disinfection Am J Infect Contr (Accepted). 4. ASHRAE. (2020). ASHRAE Resources Available to Address COVID-19 Concerns. (American Society of Heating, Refrigeration and Air-Conditioning Engineers, Atlanta, GA). 5. Bianco A, M Biasin, G Pareschi et al. (2020). UV-C irradiation is highly effective in inactivating and inhibiting SARS-CoV-2 replication. medRxiv preprint doi: https://doi.org/10.1101/2020.06.05.20123463 (unreviewed preprint). 6. Blatchley ER, Petri B, Sun W. (2020). SARS-CoV-2 UV Dose-Response Behavior. International Ultraviolet Association (IUVA) White Paper. PurpleSun Inc 21-21 41st Ave, Suite 5B, Long Island City, NY 11101212-500-08595 7. Darnell MER, Subbarao K, Feinstone SM, Taylor DR. (2004). Inactivation of the coronavirus that induces severe acute respiratory syndrome, SARS-CoV. J Virol Meth 121,85-91. 8. Duan SM, Zhao XS, Wen RF, Huang JJ, Pi GH, Zhang SX, Han J, Bi SL, Ruan L, Dong XP. (2003). Stability of SARS Coronavirus in Human Specimens and Environment and its Sensitivity to Heating and Environment and UV Irradiation. Biomed Environ Sci 16,246-255. 9. Eickmann M, Gravemann U, Handke W, Tolksdorf F, Reichenberg S, M€*j*uller TH, Stsam A ( 2 0 2 0 ) Inactivation of three emerging viruses - severe acute respiratory syndrome coronavirus, Crimean-Congo haemorrhagic fever virus and Nipah virus - in platelet concentrates by ultraviolet C light and in plasma by methylene blue plus visible light. Vox Sanguinis 115:146-151. 10. Fisher D, Heymann D. (2020). Q&A: The novel coronavirus outbreak causing COVID-19. BMC Med 18,57. 11. Hirano N, Hino S, Fujiwara K. (1978). Physico-chemical properties of mouse hepatitis virus (MHV-2) grown on DBT cell culture. Microbiol Immunol 22,377-90. 12. Inagaki H, A Saito, H Sugiyama, T Okabayashi, S Fujimoto. (2020). Rapid inactivation of SARSCoV-2 with Deep-UV LED irradiation. bioRxiv preprint doi: https://doi.org/10.1101/2020.06.06.138149. (unreviewed preprint). 13. Jingwen C, Li L, Hao W. (2020). Review of UVC-LED Deep Ultraviolet Killing New NCP Coronavirus Dose. In Technology Sharing. (Hubei Shenzi Technology Co., Ltd. 14. Kariwa H, Fujii N, Takashima I. (2004). Inactivation of SARS coronavirus by means of povidone-iodine, physical conditions, and chemical reagents. Jpn J Vet Res 52,105-112. 15. Kowalski W, Bahnfleth W, Raguse M, Moeller R. (2019). The Cluster Model of Ultraviolet Disinfection Explains Tailing Kinetics. J Appl Microbiol 128,1003-1014. 16. Kowalski WJ. (2009). Ultraviolet Germicidal Irradiation Handbook: UVGI for Air and Surface Disinfection. (Springer, New York). 17. Liu Y, Cai Y, Zhang X. (2003). Induction of caspase-dependent apoptosis in cultured rat oligodendrocytes by murine coronavirus is mediated during cell entry and does not require virus replication. J Virol 77,11952-63. 18. NCBI. (2020). Genome Database https://www.ncbi.nlm.nih.gov/. (18. Petraitis V PR, Schuetz AN, K. Kennedy-Norris K, Powers JH, Dalton SL, Petraityte E, Hussain KA, Kyaw ML, Walsh TJ. . (2014). Eradication of medically important multidrug resistant bacteria and fungi using PurpleSun Inc. multivector UV technology.. In IDWeek. (IDWeek, Philadelphia, PA.19. Ryan KJ. (1994). Sherris Medical Microbiology. (Appleton & Lange, Norwalk). 21. Saknimit M, Inatsuki I, Sugiyama Y, Yagami K. (1988). Virucidal efficacy of physico-chemical treatments against coronaviruses and parvoviruses of laboratory animals. Jikken Dobutsu 37,341-345. 22. Walker CM, Ko G. (2007). Effect of ultraviolet germicidal irradiation on viral aerosols. Environ Sci Technol 41,5460-5465. 23. Weiss M, Horzinek MC. (1986). Resistance of Berne virus to physical and chemical treatment. Vet Microbiol 11,41-49. 24. Zhang L, Yang Y-R, Zhang Z, Lin Z. (2020). Genomic variations of COVID-19 suggest multiple outbreak sources of transmission. medRIX (preprint). 25. Zhu N, Zhang D, Wang W, Li X, Yang B, Song J, Zhao X, Huang B, Shi W, Lu R and others. (2020). A Novel Coronavirus from Patients with Pneumonia in China, 2019. N Engl J Med 382,727-733.

Accordingly, the present invention has been devised to solve the above-mentioned problems, and an object of the present invention is to provide a disinfection booth free from the problem that the disinfectant solution is directly sprayed on the body to give discomfort and the disinfectant solution must be continuously replenished.

In addition, the purpose of providing a disinfection booth capable of preventing ozone gas from being generated due to the ultraviolet light emitting device from being generated, not damaging the eyes damaged by direct ultraviolet light, and sterilizing a wide range of contaminated air There is this.

In order to solve the above problems, the disinfection booth 100 according to the present invention includes: a booster tunnel 101 having two walls, a floor and a ceiling so that a person can pass; a plurality of motion detection sensor blocks (SR1..SR7, SL1..SL7) for sensing a person passing through the booster tunnel 101 by movement position; Several UV LEDs emitting ultraviolet light to a semi-circular column-shaped LED light reflection plate (BT) interlocked with the operation of the motion detection sensor block (SR1..SR7, SL1..SL7) and having a skirt with one side extended to a predetermined length. A plurality of UV lamp blocks (UVBR1..UVBR7, UVBL1..UVBL7) installed with (UVLED) and rotated at an arbitrary angle by a driving means; Sensors 301c and 302c that are installed at the entrance of the booster tunnel 101 to detect a person's body temperature and movement are installed, and guide support rods 301 and 302 are installed with blocking doors 301a and 302a that restrict entry and exit of the person. characterized in that it is composed.

In addition, in the disinfection booth 500 according to the present invention, the two walls and the ceiling are formed of a plate of a double structure, so that the ducts 400b, 401b, and 402b through which air can flow are built-in, and at the outlet through which a person passes. Slits 400a, 401a, and 402a for discharging air through the ducts 400b, 401b, and 402b are formed in the cross-section, and air is filtered on the roof corresponding to the outer surface of the wall and the outer surface of the ceiling. It is characterized in that it has a booster tunnel 501 in which the air intake devices 400, 401, and 402 are installed to which the filters F1 and F2 are installed.

As described above, by using UVLEDs that emit ultraviolet light for the disinfection booths 100,500, the disinfectant does not stick to the body, so there is no discomfort, and there is no inconvenience of repeatedly replenishing the disinfectant solution.

In addition, due to the LED light reflection plate (BT) with the skirt and the ultraviolet lamp block (UVBR1..UVBR7, UVBL1..UVBL7) having a driving means that can be rotated at an arbitrary angle, direct light to the eyes sensitive to ultraviolet rays It is possible to disinfect the entire human body while preventing damage to the eyes by not illuminating.

And, it is possible to operate the disinfection booth 100,500 in various modes, so that many people can be continuously sterilized according to the situation, and it can be managed and sterilized one by one, and also the surrounding air of a large contaminated space can be sterilized. The air intake device ( 400, 401, 402), if the air is sterilized while flowing, the same effect as a bladeless fan can be obtained.

At the same time, a person can also sterilize while passing through the booster tunnel 501 .

1 is a perspective view of the structure of the disinfection booth according to the present invention viewed from the entrance.
Figure 2 is a perspective view showing a structure in which the booster tunnel outer plate of the disinfection booth according to the present invention is removed.
Figure 3 is a perspective view of the structure of the disinfection booth according to the present invention viewed from the exit.
4 is a partial shear perspective view of the structure in which the booster tunnel is cut in the disinfection booth according to the present invention as viewed from the entrance.
5 is a partial shear perspective view of the structure in which the booster tunnel is cut and the blocking door is opened in the disinfection booth according to the present invention from the entrance side.
6 is a partial shear perspective view of a state in which a booster tunnel is cut and a person measures body temperature in the disinfection booth according to the present invention as viewed from the entrance.
7 is a partial shear perspective view of a state in which the booster tunnel is cut in the disinfection booth according to the present invention, the body temperature is measured, the blocking door is opened, and a person enters the disinfection booth from the entrance side;
8 is a partial shear perspective view showing a state in which the booster tunnel is cut in the disinfection booth according to the present invention, the body temperature is measured, the blocking door is opened, and a person enters the center of the booster tunnel of the disinfection booth according to the present invention.
9 is a perspective view showing a state in which the booster tunnel outer plate of the disinfection booth according to the present invention is removed and a person enters the booster tunnel;
10 is a perspective view of the structure of the UV LED block and the motion detection sensor block of the disinfection booth according to the present invention as viewed from the entrance.
11 is a perspective view of the structure of the UV LED block and the motion detection sensor block of the disinfection booth according to the present invention as viewed from the exit.
12 is a perspective view of the structure of the UV LED block and the motion detection sensor block rotated in the disinfection booth according to the present invention as viewed from the entrance.
13 is a perspective view of the structure of the UV LED block and the motion detection sensor block rotated in the disinfection booth according to the present invention as viewed from the exit side.
14 is a perspective view of the structure of the UV LED block and the motion detection sensor block rotated further in the disinfection booth according to the present invention as viewed from the entrance.
15 is a perspective view of the structure of the UV LED block and the motion detection sensor block rotated further in the disinfection booth according to the present invention as viewed from the exit side.
16 is a perspective view of the structure of the UV LED block and the motion detection sensor block rotated back in the disinfection booth according to the present invention as viewed from the entrance.
17 is a perspective view of the structure of the UV LED block and the motion detection sensor block rotated back in the disinfection booth according to the present invention as viewed from the exit.
18 is an exploded perspective view showing the structure of a UV LED block in the disinfection booth according to the present invention.
19 is a perspective view showing a state in which ultraviolet rays shine on the human body in the disinfection booth according to the present invention.
20 is an enlarged perspective view of a state in which ultraviolet rays shine on the human body in the disinfection booth according to the present invention.
21 is an explanatory view for explaining a state in which the light emitted by the UV LED from a reflector having a symmetrical reflection angle illuminates the human body;
22 is an explanatory view for explaining a state in which the light emitted by UV LED from a reflector having an asymmetrical reflection angle illuminates the human body;
23 is a perspective view showing the operating state of mode 1 (fixed disinfection) in the disinfection booth according to the present invention.
24 is a perspective view showing the first stage operation in mode 2 (automatic disinfection) in the disinfection booth according to the present invention.
25 is a perspective view showing a two-step operation state in mode 2 (automatic disinfection) in the disinfection booth according to the present invention.
26 is a perspective view showing a three-step operation state in mode 2 (automatic disinfection) in the disinfection booth according to the present invention.
27 is a perspective view showing a four-step operation state in mode 2 (automatic disinfection) in the disinfection booth according to the present invention.
28 is a perspective view showing a five-step operation state in mode 2 (automatic disinfection) in the disinfection booth according to the present invention.
29 is a perspective view showing a six-step operation state in mode 2 (automatic disinfection) in the disinfection booth according to the present invention.
30 is a plan view showing a state in which a person enters the disinfection booth according to the present invention.
31 is a plan view showing a state in which a person enters the disinfection booth according to the present invention and is exposed to ultraviolet rays in one step.
32 is a plan view showing a state in which a person enters the disinfection booth according to the present invention and is exposed to ultraviolet rays in two stages.
33 is a perspective view showing the structure in which the air purifying device is installed in the disinfection booth according to the present invention as viewed from the entrance.
34 is a perspective view showing the structure in which the air purifying device is installed in the disinfection booth according to the present invention as viewed from the exit.
35 is a perspective view showing the structure of a booster tunnel in which an air purifier is installed in a disinfection booth according to the present invention;
36 is a perspective view of the disinfection booth having a cross section for viewing the internal structure of the air flow duct in the air purification apparatus of the disinfection booth according to the present invention.
37 is a perspective view of a booster tunnel having a cross section for viewing the internal structure of an air flow duct in the air purification apparatus of the disinfection booth according to the present invention.
38 is a plan view showing the structure in which the air purifying device of the disinfection booth according to the present invention is installed.
39 is an exploded perspective view of the structure of an air suction device that is an air purification device for a disinfection booth according to the present invention;
40 is a state diagram showing the state of air flow in mode 3 (air purification) in the disinfection booth according to the present invention.
41 is a flowchart for explaining the operation of the disinfection booth according to the present invention.
42 is a flowchart for explaining the operation of the disinfection booth according to the present invention.
43 is a flowchart illustrating the operation of the disinfection booth according to the present invention.
44 is a flowchart for explaining the operation of the disinfection booth according to the present invention.

Hereinafter, preferred embodiments of the disinfection booth 100 and 500 according to the present invention will be described based on the accompanying drawings.

As shown in FIGS. 1 to 9, the disinfection booth 100 according to the present invention has two walls, a floor 101a, and a booster tunnel 101 having a ceiling so that a person can pass therethrough.

The bottom 101 at the entrance of the booster tunnel 101 has a base plate 201 that is extended and connected to have a predetermined length.

On the left and right sides of the base plate 101, a motion sensor 301c that can recognize a person, a body temperature sensor 302c that detects body temperature, and a voice speaker 301b that can see and hear messages with voice and eyes, and The guide display 302b is provided with a right guide support bar 301 and a left guide support bar 302 installed at a predetermined height, respectively.

A right blocking door 301a and a left blocking door 302a are installed under the right guide support rod 301 and the left guide support rod 302, respectively, and the motion sensor 301c and the body temperature sensor 302c and It is opened and closed by the person who operates or controls it in conjunction.

In addition, the left and right guide support rods 302 and 301 and the booster tunnel 101 are connected by a right guide wall 201R and a left guide wall 201L, which are transparent plates of a certain height.

In addition, a plurality of motion detection sensor blocks (SR1..SR7, SL1..SL7) for sensing a person passing by each moving position are installed on the inner left and right walls of the booster tunnel 101 at regular intervals, and the Between the motion detection sensor blocks (SR1..SR7, SL1..SL7) and the motion detection sensor blocks (SR1..SR7, SL1..SL7), a semi-circular column-shaped LED light reflecting plate having a skirt extending to a predetermined length on one side Several UVLEDs emitting ultraviolet light are installed on the BT, and a number of ultraviolet lamp blocks (UVBR1..UVBR7, UVBL1..UVBL7) that are rotated at an arbitrary angle by a driving means are installed.

Among the UV lamp blocks (UVBR1..UVBR7, UVBL1..UVBL7), the first left UV block (UVBL1) and the first right UV block (UVBR1) are the motion detection sensor blocks (SR1..SR7, SL1..SL7). Lights on when a human movement is detected in the first left motion detection sensor block SL1 or the first right motion detection sensor block SR1.

When a human movement is detected in each of the motion detection sensor blocks SR1..SR7, SL1..SL7 in the same way as described above, the UV lamp blocks UVBR1..UVBR7, UVBL1..UVBL7 are sequentially turned on. .

In addition, as additionally described in FIGS. 10 to 17, when the left and right UV lamp blocks (UVBL1, UVBR1) No. 3 detect a moving person, the No. 3 left and right motion detection sensor blocks (not shown) Rotate at a certain angle towards the person's back.

At the same time, when the third left and right motion detection sensor blocks SL3 and SR3 detect a person, the third left and right ultraviolet lamp blocks UVBL3 and UVBR3 are turned on.

In the same way as above, the UV lamp blocks (UVBR1..UVBR7, UVBL1..UVBL7) are lit by operation on the motion detection sensor blocks (SR1..SR7, SL1..SL7) corresponding to their numbers, and at the same time, the UV light The lamp blocks (UVBR1..UVBR7, UVBL1..UVBL7) correspond to the motion detection sensor block corresponding to a number two steps higher than the number of the motion detection sensor block (SR1..SR7, SL1..SL7) corresponding to its own number. The movement of (SR1..SR7, SL1..SL7) rotates a certain angle toward the back of the moving person.

After that, when the last motion detection sensor block, No. 7 left/right motion sensor block (SL7, SR7) detects a moving person, the No. 7 left/right UV lamp block (UVBL7, UVBR7) is turned on for a certain period of time (normally 2 After 3 seconds), all the UV lamp blocks (UVBR1..UVBR7, UVBL1..UVBL7) blink and return to their original state.

The detailed structure of the UV lamp blocks (UVBR1..UVBR7, UVBL1..UVBL7) has a driving motor BAM2, which is a driving device installed in the tunnel bottom parts 101a and 501a, at the lower part as shown in FIG. , a semi-circular lower support plate BBS2 is fixed to the rotation shaft (not shown) of the driving motor BAM2.

The lower support plate BBS2 includes an LED light reflection plate BT2 that extends upwardly in a semicircular shape, and the LED light reflection plate BT2 includes a skirt SK2 with one side extended and a plurality of UV LEDs emitting ultraviolet light. It is composed of a semicircular reflector (BS2) installed with (UVLED).

※ For reference, UVLED uses a wavelength range of 250nm to 320nm.

In addition, a semi-circular upper support plate BTS2 is fixed to the upper portion of the LED light reflection plate BT2, and the upper support plate BTS2 is a support shaft bearing BSB2 and is attached to the ceiling portion (not shown) of the booster tunnels 101 and 501. supported and fixed

The skirt SK2 is positioned at the entrance of the booster tunnels 101 and 501 . As a result, direct UV light is not directly irradiated to the UV-sensitive eyes as described in comparison with FIGS. 19 to 22 .

If the above is described in detail once again, if the skirt SK2 is not provided, it can be seen that a large amount of the LED diffused light (UVDR) emitted from the UVLED is directly irradiated to the eye as shown in FIG. In the case of having the skirt SK2, as shown in FIG. 22, it can be seen that the LED diffused light UVDR emitted from the UVLED is horizontally illuminated on the side of the eye.

It can be seen that the intensity of ultraviolet light shining on the eyes is remarkably lowered due to the skirt SK2.

The disinfection booth 100 configured as described above may be operated in two modes: a fixed disinfection operation and an automatic disinfection operation.

The fixed disinfection operation among the two modes will be described with reference to FIGS. 23 and 41 as follows.

First, the left and right blocking doors 302a and 301a are opened, all the UV lamp blocks (UVBR1..UVBR7, UVBL1..UVBL7) are turned on and rotated in the same direction as the exit direction.

At this time, the body temperature sensor 302c, motion sensor 301c, voice speaker 301b, guide display 302b, camera (not shown) installed on the left and right guide rods 302 and 301 are monitored or required by the administrator. According to this, it is activated (POWER ON) so that a person passing through the booster tunnel 101 can measure it.

When a person continuously passes through the booster tunnel 100 in the above state, the virus contaminated on the body and clothes is sterilized.

The fixed disinfection operation is suitable when many people enter and exit at a specific time, such as a stadium, school, or theater.

In addition, the automatic disinfection operation will be described with reference to FIGS. 32 and 41 and 42 in FIG. 24 .

A person measures body temperature by the body temperature sensor 302c located on the left and right guide rods 302 and 301, and if the body temperature is abnormal, an appropriate message is sent to the person through the voice speaker 301b and the guide display 302b. and dispose of in the control room according to the prescribed procedures.

If the body temperature is normal, the left and right blocking doors 302a and 301a on the left and right guide support rods 302 and 301 are opened.

When a person passes through the open left and right blocking doors 302a and 301a, they are immediately closed, and when the person is detected by the motion detection sensor blocks SL1 and SR1, the first left and right UV lamp blocks (UVBL1, UVBR1) are closed. lights up

Afterwards, when the second motion detection sensor block SL2, SR2 detects the movement of a person, the second left and right UV lamp blocks UVBL2 and UVBR2 are turned on, and the third motion detection sensor block SL2, SR2 ) detects the movement of a person, the 3rd left and right UV lamp blocks (UVBL3, UVBR3) are turned on, and at the same time, the 1st left and right UV lamp blocks (UVBL1, UVBR1) are turned at an arbitrary angle toward the back of the person. rotate

In this state, when the motion detection sensor blocks SL4 and SR4 detect a human motion, the left and right UV lamp blocks UVBL4 and UVBR4 are turned on at the same time as the second left and right UV lamp blocks. (UVBL2, UVBR2) rotates at an arbitrary angle towards the person's back.

When the motion detection sensor blocks SL5 and SR5 consecutively detect a human motion, the left and right UV lamp blocks UVBL5 and UVBR5 are turned on at the same time as the third left and right UV lamp blocks UVBL3. ,UVBR3) rotates at an arbitrary angle towards the person's back.

Subsequently, when the motion detection sensor block No. 6 (SL6, SR6) detects a human motion, the No. 6 and 7 left and right UV lamp blocks (UVBL6, UVBR6, UVBL7, UVBR7) are turned on and at the same time, the No. 4 left .The right UV lamp block (UVBL4, UVBR4) rotates at an arbitrary angle toward the person's back.

After that, when the motion detection sensor block No. 7 (SL7, SR7) detects a human motion, the No. 4 left and right UV lamp blocks (UVBL4, UVBR4) and the No. 5 left. Right UV lamp block (UVBL5, UVBR5) After rotating at an arbitrary angle toward the person's back, after 2 to 3 seconds, the No. 6 left and right UV lamp blocks (UVBL6, UVBR6) and the No. 7 left and right UV lamp blocks (UVBL7, UVBR7) are All the UV lamp blocks (UVBR1..UVBR7, UVBL1..UVBL7) flicker and rotate at the same time as they rotate at any angle toward the back.

In addition, the other disinfection booth 500 according to the present invention has the same basic structure as the disinfection booth 100 described in the first embodiment as shown in FIGS. 33 to 38, but the booster tunnel 501 has two The wall (not shown) and the ceiling (not shown) are formed of a plate of a double structure, so that the ducts 400b, 401b, and 402b through which air can flow are built-in.

In addition, the booster tunnel 501 has slits 400a, 401a, and 402a through which air is discharged through the ducts 400b, 401b, and 402b are formed in the cross-section of the outlet through which a person passes, and the outer surface of the wall surface And on the roof corresponding to the outer surface of the ceiling, air intake devices 400, 401 and 402 in which filters F1 and F2 for filtering air are installed are installed.

As shown in FIG. 39 , the air intake devices 400, 401, and 402 are cross flow fans (CFF) having a length of 80-90% with respect to the width of the wall height or the length of the ceiling width.

The cross-flow fan CFF is built-in to the fan main frame MC to which an electric motor (not shown) that supports and drives the rotating shaft is fixed.

The fan main frame MC has an inlet (not shown) through which air is sucked in by the rotation of the crossflow fan CFF and an outlet (not shown) through which air is discharged.

A primary filter (F1) and a secondary filter (F2) for filtering air are installed together with the filter support frame (FC) at the inlet.

In addition, the ducts 400b, 401b, and 402b extending to the slits 400a, 401a, and 402a are installed in the outlet.

In the ducts 400b, 401b, and 402b, a plurality of UVLEDs that emit ultraviolet light capable of sterilizing the air sucked in by the driving of the crossflow fan CFF are arranged and installed.

In the air suction device configured as described above (400, 401, 402), ambient air is filtered and sucked through the primary filter (F1) and the secondary filter (F2) by driving the cross flow fan (CFF), and then through the outlet The UVLEDs are discharged to the slits 400a, 401a, and 402a through the ducts 400b, 401b, and 402b arranged in an arrangement.

The operation of the disinfection booth 500 configured as described above will be described with reference to the drawings shown in FIGS. 40 to 44 .

First, it is designed to be operated in five modes. Mode 1 and Mode 2 are a fixed disinfection operation and an automatic disinfection operation, respectively, and are operated in the same manner as described in the disinfection booth 100 described above.

Mode 3 is an air purification operation, turning on all the UV lamp blocks (UVBR1..UVBR7, UVBL1..UVBL7), cameras, and air intake devices 400, 401, 402, closing the blocking doors 301a, 302a, and closing the body temperature sensor 302c. ) is turned off and the operating time is specified.

In the above state, the surrounding intake air (IAL, IAR, IAT) passes through the air flow ducts (400b, 401b, 402b) by the air intake device (400, 401, 402) and the air at the outlet end of the booster tunnel (501). The exhaust air OAR, OAL, OAT is formed through the exhaust slits 400a, 401a, and 402a.

At this time, the air is sterilized by UV LEDs emitting ultraviolet light installed in the air flow ducts 400b, 401b, and 402b.

In addition, the pressure at the outlet of the booster tunnel 501 is lowered by the exhaust air OAR, OAL, and OAT through the air exhaust slits 400a, 401a, and 402a.

※ Reference: Principle of fan without blades

Due to this, the air TIA at the inlet of the booster tunnel 501 makes air TOA discharged to the outlet to circulate the air in the predetermined space.

Also at this time, the air is disinfected by the ultraviolet rays emitted from UV LEDs in the ultraviolet lamp blocks (UVBR1..UVBR7, UVBL1..UVBL7) installed in the booster tunnel 501 .

When the specified time is reached in the above state, the air intake device is turned off, and the ultraviolet lamp blocks (UVBR1..UVBR7, UVBL1..UVBL7) are turned off at the same time.

The camera is turned on to check the status of the system, that is, the disinfection booth 500 in the control room.

Mode 4 performs a fixed disinfection operation at the same time as air purification. In the air purification operation described above, the body temperature sensor 302C is turned on and the left and right blocking doors 302a and 301a are opened.

In such a state, when a person passes through the booster tunnel 501, the surrounding air is sterilized and the person is also sterilized.

In addition, mode 5 combines the automatic disinfection operation described above in the air purification operation.

Therefore, in Mode 5 as described above, it is possible to control and sterilize individuals while sterilizing by continuously circulating the surrounding air.

100,500: disinfection booth 101,501: boosternel
101a, 501a: tunnel bottom 201: base plate
201L: Left guide wall 201R: Right guide wall
301: right guide support bar 301a: right blocking door
301b: voice speaker 301c: motion sensor
302: left guide support bar 302a: left blocking door
302b: information display 302c: body temperature sensor
UVB : Left UV lamp block UVLED : UV LED
BT: LED light reflector BBS: Lower support plate
BTS: Upper support plate BAM: Drive motor
BSB : Support shaft bearing UVBL1 : No. 1 left UV lamp block
UVBR1: No. 1 right UV lamp block UVBL7: No. 7 left UV lamp block
UVBR1: No. 7 right UV lamp block SL1: No. 1 left motion detection sensor block
SR1 : No. 1 right motion detection sensor block SL7 : No. 7 left motion detection sensor block
SR7: No. 7 left motion detection sensor block C1, C2: Caster
C3, C4 : Caster (not shown) C5, C6 : Caster (not shown)
BR1 : No. 1 right UV light block BR2 : No. 2 right UV light block
BR3: No. 3 right UV light block BR4: No. 4 right UV light block
BR6 : No. 6 right UV light block BL1 : No. 1 left UV light block
BL2: No. 2 left UV light block BL3: No. 3 left UV light block
BL4: No. 4 left UV light block UVDR: LED diffused light
UVER: LED eccentric light 400: Left air intake device
401: right air intake device 402: upper air intake device
400a: left air exhaust slit 401a: right air exhaust slit
402a: upper air exhaust slit 400b: left air flow duct
401b: right air flow duct 402b: upper air flow duct
F1 : 1st filter F2 : 2nd filter
FC : Filter support frame MC : Fan main frame
CFF : Crossflow fan TIA : Tunnel intake air
TOA: Tunnel exhaust air IAR: Right intake air
IAL: Left intake air (not shown) IAT: Upper intake air
OAR : Right exhaust air OAL : Left exhaust air
OAT: top exhaust air
500: additional disinfection booth with air purification function

Claims (10)

a booster tunnel 101 having two walls, a floor and a ceiling so that a person can pass therethrough;
a plurality of motion detection sensor blocks (SR1..SR7, SL1..SL7) for sensing a person passing through the booster tunnel 101 by movement position;
Number of emitting ultraviolet rays to the LED light reflecting plate (BT) in the shape of a semi-circular column interlocked with the operation of the motion detection sensor block (SR1..SR7, SL1..SL7) and having a skirt SK with one side extended to a predetermined length a plurality of UV lamp blocks (UVBR1..UVBR7, UVBL1..UVBL7) in which four UVLEDs are installed and rotationally driven at an arbitrary angle by a driving means;
Sensors 301c and 302c installed at the entrance of the booster tunnel 101 to detect a person's body temperature and movement, an output device for hearing or visual information of various types, and a blocking device for restricting entry and exit of the person Disinfection booth 100, characterized in that it consists of guide support rods (301, 302) installed with doors (301a, 302a). [2] The disinfection booth (100) according to claim 1, wherein the UV lamp blocks (UVBR1..UVBR7, UVBL1..UVBL7) are sequentially turned on and rotated, and returned to the origin with collective flashing. The disinfection booth (100) according to claim 1, wherein the UVLED installed in the UV lamp block (UVBR1..UVBR7, UVBL1..UVBL7) has a wavelength of 250 nm to 320 nm. The disinfection booth (100) according to claim 1, wherein a plurality of casters (C1, C2, C3, C4) are installed outside the bottom of the booster tunnel (101). The two walls and the ceiling are formed as a plate of a double structure, so that the ducts 400b, 401b, and 402b through which air can flow are built-in, and the ducts 400b, 401b, and 402b are installed in the cross-section of the outlet through which a person passes. Slits 400a, 401a, 402a through which air is discharged are formed, and filters F1 and F2 for filtering air are installed on the roof corresponding to the outer surface of the wall and the outer surface of the ceiling. a booster tunnel 501 in which 400, 401, and 402 are installed;
a plurality of motion detection sensor blocks (SR1..SR7, SL1..SL7) for sensing a person passing through the booster tunnel 501 by movement position;
Number of emitting ultraviolet rays to the LED light reflecting plate (BT) in the shape of a semi-circular column interlocked with the operation of the motion detection sensor block (SR1..SR7, SL1..SL7) and having a skirt SK with one side extended to a predetermined length a plurality of UV lamp blocks (UVBR1..UVBR7, UVBL1..UVBL7) in which four UVLEDs are installed and rotationally driven at an arbitrary angle by a driving means;
Sensors 301c and 302c installed at the entrance of the booster tunnel 501 to detect a person's body temperature and movement, an output device for hearing or visual information of various types, and a blocking device for restricting entry and exit of the person Disinfection booth 500, characterized in that it consists of guide support rods (301, 302) installed with doors (301a, 302a). [Claim 6] The disinfection booth (500) according to claim 5, wherein the UV lamp blocks (UVBR1..UVBR7, UVBL1..UVBL7) are sequentially turned on and rotated, and returned to the origin with collective flashing. The disinfection booth (500) according to claim 5, wherein the UVLED installed in the UV lamp blocks (UVBR1..UVBR7, UVBL1..UVBL7) has a wavelength of 250 nm to 320 nm. The disinfection booth (500) according to claim 5, wherein a plurality of UVLEDs are installed in the ducts (400b, 401b, 402b). Disinfection booth 100, characterized in that it is configured to operate with the fixed disinfection operation mode 1 and the automatic disinfection operation mode 2 Disinfection booth, characterized in that it is configured to be operated in fixed disinfection operation mode 1, automatic disinfection operation mode 2, air purification operation mode 3, air purification/fixed disinfection mode 4, and air purification/automatic disinfection mode 5, respectively (500)

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