阅读说明：本技术 空气和表面消毒系统 (Air and surface disinfection system ) 是由 艾伦·基维亚特 于 2021-05-24 设计创作，主要内容包括：提供了一种消毒装置,包括：a)主体；b)风扇；c)第一照射源,其放置在所述主体内部,在所述主体内部的所述照射源配置成对由所述风扇迫使进入所述主体中的空气进行消毒；d)管道,其用于使空气从所述主体的外部流动到所述主体的内部以用所述第一照射源照射,且在用所述第一照射源照射之后使空气流动到所述主体的外部；以及e)第二照射源,其配置为照射在所述主体外部的空气和/或表面；其中,空气利用由所述风扇产生的力从所述装置的外部流动到所述装置的内部以利用所述第一照射源照射,并且离开所述装置,并且其中,利用一个或多个所述第二照射源照射在所述装置外部的空气和/或装置下方的表面。提供了一种用光进行消毒的方法,a)利用一个或多个风扇产生从装置的外部到内部然后到外部的流动；b)照射在主体内部流动的空气；c)使经照射的空气随着空气的流动而移动到外部；以及d)用放置在所述主体外部的一个或多个第二照射源照射在所述装置外部的空气和/或表面。(There is provided a disinfection device comprising: a) a main body; b) a fan; c) a first irradiation source placed inside the body, the irradiation source inside the body configured to disinfect air forced into the body by the fan; d) a conduit for flowing air from outside the body to inside the body for irradiation with the first irradiation source and flowing air to outside the body after irradiation with the first irradiation source; and e) a second illumination source configured to illuminate air and/or surfaces external to the body; wherein air flows from outside the device to inside the device with the force generated by the fan to irradiate with the first irradiation source and exits the device, and wherein air outside the device and/or a surface below the device is irradiated with the one or more second irradiation sources. A method of disinfection with light is provided, a) a flow is generated from the outside to the inside and then to the outside of the device using one or more fans; b) irradiating air flowing inside the main body; c) moving the irradiated air to the outside along with the flow of the air; and d) irradiating air and/or surfaces external to the apparatus with one or more second irradiation sources placed external to the body.)

1. A disinfection device comprising:

a) a main body;

b) a fan;

c) a first irradiation source placed inside the body, the irradiation source inside the body configured to disinfect air forced into the body by the fan;

d) a conduit for flowing air from outside the body to inside the body for irradiation with the first irradiation source and flowing air to outside the body after irradiation with the first irradiation source; and

e) a second illumination source configured to illuminate an exterior of the body;

wherein air flows from outside the apparatus to inside the apparatus with the force generated by the fan to illuminate with the first illumination source and exits the apparatus, and the second illumination source illuminates outside the apparatus.

2. The sanitizing device of claim 1, further comprising a door attached to the body for accessing the interior of the body.

3. The disinfection device of claim 1, further comprising one or more light sources positioned outside the body to provide illumination having at least non-UV light wavelengths.

4. The disinfection device of claim 1, further comprising a door attached to the body, the door comprising one or more light sources for illuminating outside the device.

5. The sanitizing device according to claim 1, further comprising one or more openings placed on the body for air flow.

6. A disinfecting device as claimed in claim 1, in which the edge of the second source of irradiation is placed from zero to five inches from the closest point at which air enters the duct from the outside.

7. A disinfecting device as claimed in claim 1, in which the second source of irradiation irradiates a portion of the air entering the device.

8. A disinfecting device as claimed in claim 1, in which the second source of irradiation irradiates a portion of the air exiting the device.

9. A disinfecting device as claimed in claim 1, in which the second source of irradiation is in the form of a module.

10. A disinfecting device as claimed in claim 1, in which the second source of irradiation is placed in one or more corners of the device.

11. A disinfecting device as recited in claim 1, wherein radiation from the first source of radiation remains inside the body.

12. A disinfecting device as claimed in claim 1, in which the first source of irradiation is placed in the cavity behind a removable panel.

13. A disinfection device as claimed in claim 12, wherein said chamber has an air baffle preventing UV light from escaping from said body.

14. A fumigation arrangement as defined in claim 12, in which said air baffle is curved.

15. A disinfection device as claimed in claim 12, wherein said chamber has an air riser for directing air into said illumination chamber.

16. The disinfection device of claim 1, wherein the device is configured to be mounted on a wall.

17. The disinfection device of claim 1, wherein the device is configured to be mounted to the ceiling.

18. The disinfection device of claim 1, wherein the second irradiation source is 0 to 5 inches from an edge of any entry or exit point of air entering to exit the device.

19. The disinfection device of claim 1, further comprising one or more light sources disposed outside the body, the light sources producing different colors of light.

20. A method for disinfecting air or a surface, comprising:

a) generating a flow from the outside to the inside and then to the outside of the device using a fan;

b) irradiating air flowing inside the main body;

c) moving the irradiated air to the outside along with the flow of the air; and

d) irradiating air or a surface external to the device with a second illumination source placed external to the body.

Technical Field

The invention discloses an ultraviolet light, antibacterial and antiviral ambient air and surface disinfection system and device system.

Background

The UV-C system combines an ultraviolet germicidal irradiation (UVGI) chamber and an air circulation fan. The system uses UV-C light and filtration to suck and treat ambient air on one side and return the air to the room on the other side by exhaust, reducing microbial and fungal populations in the treated air and reducing settled bacteria, viruses and fungi from the treated air. A problem with such a system is that additional disinfection is required, which is not possible with existing systems.

Disclosure of Invention

Embodiments provide a disinfection device configured to be attached to a ceiling, the device comprising: a) a main body; b) a fan or fan array; c) a first source of irradiation inside the body configured to disinfect air forced into the body by the fan; d) a second illumination source configured to illuminate (air or surface of) an exterior of the body; e) a door attached to the body for accessing an interior of the body; f) optionally, one or more light sources for providing illumination. The door of any of the above embodiments is pivotally attached to the long sides of the generally rectangular body. In any of the above embodiments, the end, bottom of the main body may have one or more grills or integral louvers (openings) for air flow and one or more UV modules (secondary sources). In any of the above embodiments, the grille or integrated shutter and UV module may be placed in a location other than the door at the end of the bottom of the main body. In any of the above embodiments, one UV module may be placed at each corner of the body. In any of the above embodiments, the end of the main body may have an inlet/outlet for air, the air being forced into the interior of the main body by one or more fans. In any of the above embodiments, the device comprises an air passage/conduit for air from the exterior to the first source of irradiation, for example through openings/grills/louvers and/or filters 20, and for the irradiated and/or filtered air to the exterior of the body. In any of the above embodiments, light (first source) from the UV lamp inside the body is maintained inside the body. In any of the embodiments described above, the UV lamp inside the body may be placed behind a removable panel above the door. The panel must be opened to access the UV light cavity. In any of the embodiments described above, the chamber may have an air baffle at the top to prevent UV light from escaping through the grille or integral louvers and creating turbulence in the illumination chamber. In any of the above embodiments, the cavity may have an air riser that directs air into the illumination cavity and reduces reflections. In any of the above embodiments, one or more light sources providing illumination may be placed under the door. In any of the above embodiments, the light source, e.g. LED or OLED, may be coupled with a suitable diffuser/lens and/or reflective back sheet/paper.

In any of the above embodiments, the sterilising medium may be a wall-mounted device comprising a) a body; b) a fan; c) a first source of irradiation inside the body, the source of irradiation inside the body configured to disinfect air forced into the body by the fan; d) optionally one or more second illumination sources configured to illuminate the exterior of the body; e) optionally, one or more light sources for providing illumination. In wall-mounted embodiments, the wall-mounted device may have a vertical orientation with a horizontal grille or integral louvers on the top and/or bottom of the front of the device, a mounting mechanism on the rear or both sides, and optional light sources, for example in a horizontal orientation. The wall mounted unit may be without a pivoting door. The wall mounted unit can access the UV chamber inside the unit from the front of the unit. The wall mount unit may have any of the embodiments described above, including one or more external UV lamps, illumination chambers, diffuser lamps, UV illumination modules, air grills, motion sensors and other optional sensors and electronic components.

Drawings

Fig. 1 shows a bottom view of an embodiment with a lamp panel open, e.g. for maintenance or lamp or filter replacement.

Figure 2 shows the top of the illumination chamber.

Figure 3 shows the body assembly.

Fig. 4 shows a disinfection system with an optional UV light panel.

Fig. 5 shows a wall mounted unit.

Fig. 6 shows a wall mounted unit.

Figure 7 shows the various electronic components (plus filters) of the disinfection system.

Fig. 8 shows an LED board with LED light sources.

Figure 9 shows the placement of UV and/or non-UV lamps outside the body.

Fig. 10 shows a fan housing/filter holder.

Fig. 11 shows a top view of a closed light panel.

Detailed Description

Fig. 1 shows a bottom view of an embodiment with a lamp panel open, e.g. for maintenance or lamp or filter replacement. In fig. 1, a UV (ultraviolet) irradiation chamber 1, a main body 2, a UV irradiation chamber access door 3, a main access door 4, an optional down lamp 5 (which may also be a decorative element without a light source), a UV irradiation module 6 with a UV light source 77, an intake grill 7 and an exhaust grill 8 are shown.

The sterilization system may have two different embodiments. In one embodiment, the disinfection system is configured to disinfect/purify only air in a room. In another embodiment, the system is configured to illuminate the room by having one or more light sources in addition to disinfection/decontamination. The one or more light sources may be LED (light emitting diode) or OLED (organic light emitting diode) light sources 61.

The disinfecting system may be in the form of a device having a body 2 configured to be attached to a ceiling. The device may have a main access door 4 pivotally connected to one side of the main body 2, allowing a technician to open the door 4 from the bottom of the device and access the UV light source(s) and filter(s) inside the main body 2. In the solution with a light source providing downlighting, the light source may be placed directly on the bottom side of the main access door 4. In the case of installations without downlights, the main access door 4 may be flat or have a decorative panel.

The body 2 of the device may have one or more grilles or integral blinds (7, 8), and/or one or more illumination modules 6 placed anywhere around the periphery of the access door 4. The bottom surface of the grille or integral blinds (7, 8) and/or one or more illumination modules 6 may be flush with the bottom surface of the main body 2 or recessed from the bottom surface of the main body 2. In one embodiment, a grill or integral louver (7, 8) is placed centrally on the end of the body 2 and the illumination sources are placed at one or more or all of the corners of the body 2. Alternatively, the illumination source may be positioned along the long side(s) of the body 2.

Below the grilles or integral louvers (7, 8) are one or more fans 19 and filters 20. A fan 19 entrains air into the unit and the illumination chamber. The function of the filter 20 is to remove large dust particles and keep the illumination chamber clean. The exhaust grill 8 directs the clean air out of the unit to circulate within the room. There may be a separate filter on the exhaust grill 8 to capture the inactivated pathogens.

The UV module may comprise LEDs, low pressure mercury lamps or far UV lamps in the 207nm or 222nm range. These lamps may be krypton-bromine or krypton-chlorine excimer lamps. In this embodiment, UV irradiation modules 6 are placed at each corner of the system (e.g., 0 to 5 inches from the edge of any entry or exit point) and are mounted on the unit, primarily to provide air and surface disinfection when the room is unoccupied. They may use UV light having any wavelength of 200nm to 280 nm. The module may alternatively be provided as two tubular or longer light sources. Alternatively, one or more longer UV light sources may be placed along the edge of the cell. The surface disinfection module is integrated with an air purification system to reduce the number of pathogens that survive in the area below the system. In another embodiment, UV light, for example having a wavelength of 207nm or 222nm, may be used so that the surface disinfection module may remain on while the room is occupied. The UV module allows the system to more effectively disinfect the air in the room before it is drawn into the irradiation chamber inlet, and disinfect the surfaces below the device. In another embodiment, 253.7nm UV light can be used to provide surface disinfection and air disinfection. In other embodiments, the module may operate continuously or intermittently based on information from the sensors or based on a predetermined period. For example, the modules may be programmed to operate when the motion sensors 50 detect that a person has entered the room or alternatively when they detect that a person has entered and exited the room. In an alternative embodiment, a sound sensor 51 may be provided to detect human activity in the room, and the system is programmed to operate the modules in response to the detected sound. In one example, the system may detect the sound of a person sneezing or coughing and, in response, activate the module for a period of time to sanitize the air.

If harmful UV radiation is used in the illumination module, a motion sensor 50 may be used to ensure that the illumination module is not turned on when there is a person in the room.

Other sensors may also be used. Another sensor such as a thermal (temperature) sensor 52 may be used if the unit is installed in a hospital room or ICU (intensive care unit) room or similar area where the patient is not moving such that the surface disinfection module is not functional.

The device may have other electrical components including, but not limited to, a ballast/controller 53, a power supply (power management unit 57), a UV light measurement sensor 78, safety switches for UV access doors, wiring and controls 58 and indicators 56 for remote operation. The control system may use a system (which may be wireless 54) that will be used to operate the various unit functions (UV air system, UV floor system, downlight on/off, downlight dimming) where they may be turned on or off manually (various switches 55) or programmed to turn on or off as planned. The indicator 56 may also indicate any notifications or errors, such as: filter replacement, UV lamp replacement, fan failure, UV module replacement, UV intensity in the irradiation chamber, unit not scheduled to turn on due to motion sensor activation, unit not scheduled to turn on due to other (thermal) sensor activation, UV chamber door open, and downlight failure.

Figure 2 shows the top of the illumination chamber. In this figure there is shown a UV irradiation chamber body 9, a UV irradiation chamber reflector 10, an air baffle top 11, an air uptake 12 and UV light source(s) 13. The UV irradiation chamber reflector 10 increases the exposure of UV to air as it passes through the unit. An air baffle (top) 11 prevents UV light from escaping through the grille or integral louvers and creating turbulence in the illumination chamber. The air baffle 11 may be curved. The air uptake 12 directs air into the illumination chamber and reduces reflections. In fig. 2, the UV light source 13 is shown as a low pressure mercury lamp, but may be any UV light source, such as an LED or krypton-chlorine source.

Figure 3 shows the body 2 assembly. The main channel body 14, the front panel 15 of the channel body, the access door 16 of the UV irradiation chamber, the air baffle bottom 17 and the fan tray 18 are shown in this figure. Fig. 10 shows in detail the fan 19 and the filter 20 placed in the fan tray 18.

The front panel 15 of the troffer body may comprise louvres for air inlet and outlet. The access door 16 of the UV irradiation chamber allows access to the UV lamp for replacement. There may be a momentary disconnect switch 55 which will turn off the UV lamp if the access door is open. The air baffle bottom 17 prevents UV light from escaping through the grille or integral louvers and creating turbulence in the irradiation chamber. The fan tray 18 may mount the fan 19 in place and hold the filter 20 in place. Fig. 10 shows an exploded view of a fan comprising a fan 19 and a filter 20, there may be 1-6 fans 19 at one or both ends, for example 4 fans are used in this solution. The filter 20 may be a MERV6 filter for removing large dust particles to keep the irradiation chamber clean. There may be one or two fan trays 18. Typically a fan tray 18 is placed where air enters the device.

Figure 4 shows a UV LED panel disposed along the length of the body 2. The LED board 26 may also be used for illumination purposes only, rather than illumination purposes. In this embodiment, the width of the front access door 4 may be smaller to accommodate the placement of the LED board 26 containing the LED light sources.

Fig. 5 and 6 show a wall-mounted version of the disinfection system. As shown, the main body 70 is configured to be mounted on or recessed into a wall in an upright manner, with grills or integral louvers 71 on both the top and bottom of the main body 70. Optional lights (for illumination) 72, for example placed in a horizontal manner, may extend parallel under the front surface grille or integral louvers 71 on top of the main body. The wall-mounted solution may have a flat front and a panel 73 accessible from the front of the unit. There may be no pivoting door at all on the front of the wall mounted unit. Fig. 6 shows an arrangement of an LED board 60 and a module 69, which may be arranged on the front surface of the main body. The unit may also have a UV plate and a module placed on the front surface of the body 70 or the panel 73.

Figure 7 shows various electronic components of the sterilization system. In this figure a motion sensor 50 is shown which can sense whether an individual is present in the room and accordingly a switch 55 can switch on or off an external UV lamp which is not safe for the individual. The sound sensor 51 may also be used to sense the presence of a person and may be used alone or in combination with the motion sensor 50. The device may have a temperature sensor 52 for determining the heat source in the room. The apparatus may have multiple ballasts/multiple controllers 53 and/or a power management unit 57 for managing power to the UV and white light, sensors and fans. The device may have a wireless controller 54, for example with bluetooth or Wi-Fi, to allow the user to turn the device on and off, and/or to control different functions of the device. The device may have a plurality of switches 55 that can be turned on and off manually using the wireless controller 54 or internally if the panel is turned on by a technician or the device requires maintenance. The device may have one or more indicators 56 that may indicate when a UV lamp in the chamber and/or outside of the chamber is on, and/or that maintenance is required, such as replacement of a UV lamp. The wireless controller may send information about required maintenance or system performance to an external monitor and control system such as a computer, tablet, or smartphone.

Fig. 8 shows an LED board 60 with LED light sources 61. The LEDs may be placed in one or more rows on the circuit board. The LEDs may be of one or different colors, and in some cases, one set of LEDs produces only UV light, while the other LEDs produce white light for illumination purposes.

Figure 9 shows the placement of various UV and/or non-UV lamps outside the body. One or more of the light sources shown in fig. 9 may be used, for example with lights 72, 74, 75 and 76. In this figure, a transparent diffuser 75 for the light source can be seen, placed in the main channel door. The lamps may be used in pairs. The lamp may be a dedicated UV lamp for disinfection purposes, or provide light in the visible spectrum, including white light for illumination purposes, and/or provide both visible and UV disinfection light.

Fig. 10 shows an exploded view of the assembly with the fan 19 and the filter 20. In this view four fans 19 are shown, placed in a fan housing 25. The fan tray 18 holds the fan housing 25 and the filter 20. The assembly may have a service panel 24 configured to allow replacement of the filter 20 and/or the fan 19.

Fig. 11 shows a top view of the device. Shown in fig. 11 are the UV irradiation chamber 1 and the main body 2. Shown in this view is ballast and controller 53. There may be two or more ballasts and controls 53. One set of ballasts and controllers may control the lamps, another set may control the sensors, and the others are used to control the UV light. The ballast and controller may control a UV module or lamp for illuminating the air and surfaces outside the device. The device may have a UV sensor 78 that measures the intensity of the UV light in the illumination chamber and can output a reading to monitor the effective intensity.

Methods for irradiating air and sterilizing air using the device are also provided. The method includes disinfecting the air using any of the devices described above. The method may include drawing air into the interior of the body of the device with one or more fans 19, irradiating the air within the interior of the device, and expelling the irradiated air out of the device with the same or a different fan. The method further includes irradiating air external to the body with an additional radiation source. The method may further comprise first externally irradiating the air with an external radiation source and then irradiating the air with an internal radiation source. The method may further comprise first illuminating the air inside the device with an internal illumination source and then illuminating the air outside the device with an external illumination source. The method may further comprise irradiating air outside the device, then inside the device, then outside the device.

Reference numerals

UV irradiation Chamber

2. Main body

UV irradiation chamber access door

4. Main passageway door

5. Cylinder lamp

UV irradiation Module

7. Air intake grille or shutter (opening)

8. Exhaust grilles or shutters

UV irradiation chamber body

UV irradiation Cavity Reflector

11. Air baffle top

12. Air uptake

UV light source

14. Main lamp groove main body

15. Front panel for light trough body

16. Access door for a UV irradiation chamber

17. Bottom of air baffle

18. Fan plate

19. Fan with cooling device

20. Filter

21. Door/reflector body

22. Reflector

23. Diffuser

24. Maintenance panel

25. Fan casing

LED Board

50. Motion sensor

51. Sound sensor

52. Temperature sensor

53. Multiple ballasts/multiple controllers

54. Wireless controller

55. Switch with a switch body

56. Indicator device

57. Power Management Unit (PMU)

58. Wiring and control for remote operation

59.N/A

LED board

61.LED light source

UV-C Module

70. Main body/Main body

71. Grid

72. Optional lamp

73. Panel board

74. Lamp with a light source

75. Lamp with a light source

76. Lamp with a light source

77.UV light source

78.UV sensor.