AIR STERILISATION UNIT

Abstract

An air sterilisation unit comprising a housing providing an air inlet and an air outlet and containing a filter module located between the air inlet and the air outlet, a UV-C treatment chamber located between the air inlet and the air outlet and containing at least one UV-C radiation source, and a ventilation system located between the air inlet, through the filter module and the UV-C treatment chamber and out of the housing through the air outlet, wherein the UV-C treatment chamber comprises an inlet end, an outlet end and a wall there between and the inlet end is closed with a first expanded polytetrafluoroethylene filter, the outlet end is closed with a second expanded polytetrafluoroethylene and the wall is provided with an expanded polytetrafluoroethylene liner, such that the UV-C radiation source is surrounded with expanded polytetrafluoroethylene for reflection of UV-C radiation within the chamber for destruction of pathogens in the air.

Claims

1. An air sterilisation unit comprising: a housing providing an air inlet and an air outlet and containing: a filter module located between the air inlet and the air outlet, a UV-C treatment chamber located between the air inlet and the air outlet and containing at least one UV-C radiation source, and a ventilation system located between the air inlet and the air outlet, configured to cause air flow into the housing through the air inlet, through the filter module and the UV-C treatment chamber and out of the housing through the air outlet, wherein the UV-C treatment chamber comprises an inlet end, an outlet end and a wall therebetween and the inlet end is closed with a first expanded polytetrafluoroethylene filter, the outlet end is closed with a second expanded polytetrafluoroethylene and the wall is provided with an expanded polytetrafluoroethylene liner, such that the UV-C radiation source is surrounded with expanded polytetrafluoroethylene for reflection of UV-C radiation within the chamber for destruction of pathogens in the air.

2. An air sterilisation unit according to claim 1 in which the average UV-C radiation fluence within the UV-C treatment chamber is greater than 30000 J/cm.sup.2.

3. An air sterilisation unit according to claim 1 in which the filter module is located outside the UV-C treatment chamber.

4. An air sterilisation unit according to claim 3 in which the filter module is located between the air inlet of the housing and the inlet end of the UV-C treatment chamber.

5. An air sterilisation unit according to in which the filter module comprises a plurality of filters.

6. An air sterilisation unit according to claim 5 in which the plurality of filters comprises at least one mesh filter, which traps contaminants in the air of a size in the range of 3-10 microns.

7. An air sterilisation unit according to claim 5 in which the plurality of filters comprises at least one high efficiency particulate air filter, doped with silver ions, which traps contaminants in the air of a size up to 0.3 microns.

8. An air sterilisation unit according to claim 5 in which the plurality of filters comprises at least one activated carbon filter.

9. An air sterilisation unit according to claim 1 in which the filter module comprises a UV-A treatment chamber.

10. An air sterilisation unit according to claim 9 in which the UV-A treatment chamber comprises at least one photocatalytic (POC) filter and one or more UV-A radiation sources for activation of the POC filter.

11. An air sterilisation unit according to claim 10 in which the POC filter comprises a block of aluminium having a honeycomb-shaped interior provided with a POC coating of titanium dioxide.

12. An air sterilisation unit according to claim 10 in which the or each UV-A radiation source comprises a UV-A light emitting diode (LED).

13. An air sterilisation unit according to claim 12 in which the or each UV-A LED provides a beam of UV-A radiation which is focused by a lens to be incident on the POC filter.

14. An air sterilisation unit according to claim in which the or each UV-A LED provides a total UV-A radiation power of approximately 30 W.

15. An air sterilisation unit configured to achieve an 8 log reduction of pathogens in the air.

16. A method of sterilising air using the air sterilisation unit of claim 1.

Description

BRIEF DESCRIPTION OF THE DRAWING

[0026] A preferred embodiment of the invention will now be described, by way of example only, with reference to the accompanying drawing which shows a cross sectional view from the front of an air sterilisation unit according to the invention.

DETAILED DESCRIPTION

[0027] Referring to the drawing, a sterilisation unit 1 is provided, which draws air into the unit from the surrounding environment, treats the air and passes the treated air back into surrounding environment.

[0028] The sterilisation unit 1 comprises a housing 3. In this embodiment, the housing 3 is shown as having a rectangular shape, approximately 1250 mm long, 400 mm wide and 200 mm deep. It will be appreciated that the housing 3 can have any desired shape, for example cylindrical or triangular, and dimensions. A control panel (not shown) is provided on the outside of the housing 3 and a connecting cord (not shown) is provided for connecting the housing 3 to a mains power supply. It will be appreciated that the housing could alternatively or additionally comprise a battery.

[0029] The housing 3 provides an air inlet 5 at a top thereof and an air outlet 7 at a bottom thereof. It will be appreciated that the housing 3 could be oriented differently and the air inlet and outlet provided at sides of the housing.

[0030] The housing 3 contains a ventilation system 9, a dispersion chamber 11, a UV-C treatment chamber 13 and a filter module 15, each located between the air inlet 5 and the air outlet 7. The filter module 15 is adjacent the air inlet 5 at the top of the housing 3, the UV-C treatment chamber 13 is adjacent the filter module 15, the ventilation system 9 is adjacent the UV-C treatment chamber 13 and the dispersion chamber 11 is adjacent the outlet 7 at the bottom of the housing 3.

[0031] The ventilation system 9 comprises a fan 17 which is configured to cause air flow into the housing 3 through the air inlet 5, through the filter module 15 and the UV-C treatment chamber 13, into the dispersion chamber 11 and out of the housing 3 through the air outlet 7. The ventilation system 9 provides a negative pressure within the housing 3 to move air into the housing 3 and to decrease escape of air from the housing 3 before treatment thereof. The ventilation system 9 preferably provides a predetermined rate of air flow through the housing 3 of approximately 500 m.sup.3/hr.

[0032] The dispersion chamber 11 is located adjacent the air outlet 7 of the housing 3. The size of the dispersion chamber 11 reduces operating noise of the ventilation system 9 and reduces outlet air draughts. The dispersion chamber 11 contains a porous, sound-deadening, foam material 19 partially lining the dispersion chamber 11, as shown.

[0033] The UV-C treatment chamber 13 comprises an inlet end 21, an outlet end 23 and a wall 25 therebetween and contains a UV-C radiation source 27, which, in this embodiment, is an electrodeless magnetic induction lamp. The inlet end 21 of the UV-C treatment chamber 13 is closed with a first ePTFE filter 29. The outlet end 23 is closed with a second ePTFE filter 31. The wall 25 is provided with an ePTFE liner 33. The liner comprises ePTFE soft sheet and has a minimum thickness of 2 mm. The UV-C radiation source 27 is thus surrounded with ePTFE for reflection of UV-C radiation from the source 27 within the UV-C treatment chamber 13 for destruction of pathogens in air passing through the chamber 13.

[0034] The filter module 15 is located outside the UV-C treatment chamber 13, between the air inlet 5 of the housing 3 and the inlet end 21 of the UV-C treatment chamber 13. This separation of the filter module 15 from the UV-C treatment chamber 13 decreases UV-C radiation absorption which occurs when filters are located within the chamber 13.

[0035] The filter module 15 comprises a plurality of filters. The plurality of filters comprises a mesh filter 35. The mesh filter 35 traps contaminants in the air of a size in the range of 3-10 microns. The contaminants comprise contaminants such as hair, skin, large dust particles, large dirt particles. The mesh filter 35 is removable from the filter module 15, for example, to be washed.

[0036] The plurality of filters further comprises at least one high efficiency particulate air (HEPA) filter 37. The HEPA filter 37 is doped with silver ions. The HEPA filter 37 traps contaminants in the air of a size up to 0.3 microns. The contaminants may comprise any of pollen, smoke, dust, dirt.

[0037] The plurality of filters further comprises an activated carbon filter 39. This traps contaminants in the air such as volatile organic compounds (VOCs), formaldehydes, smells, etc.

[0038] The filter module 15 comprises a UV-A treatment chamber 40. The UV-A treatment chamber 40 comprises a POC filter 41 and a plurality of UV-A radiation sources 43 for activation of the POC filter. The POC filter 41 comprises a block of aluminium having a honeycomb-shaped interior provided with a POC coating of TiO.sub.2. On activation, the POC coating destroys air pollutants and pathogens which contact the filter. The plurality of UV-A radiation sources 43 comprise a plurality of UV-A LEDs. The UV-A LEDs 43 provide a beam of UV-A radiation. The beams of UV-A radiation are each focused by a lens to be incident on the POC filter 41. This increases penetration of UV-A radiation into the POC filter 41. The UV-A LEDs 43 provide a total UV-A radiation power of approximately 30 W. UV-A radiation has a longer wavelength than UV-C radiation. Using UV-A radiation to irradiate the POC filter provides better penetration and therefore activation of the filter.

[0039] As air flows through the filter module 15, contaminants in the air are trapped by the plurality of filters and pathogens are destroyed in the UV-A treatment chamber. The air then passes into the UV-C treatment chamber 13, through the first ePTFE filter 29 at the inlet end 21 of the chamber 13.

[0040] The air is subjected to UV-C radiation from the UV-C radiation source 27, which destroys pathogens in the air. The ePTFE surrounding the UV-C radiation source 27 in the UV-C treatment chamber 13 increases the reflection of the UV-C radiation within the chamber 13 and increases the UV-C radiation fluence within the chamber 13. The average UV-C radiation fluence within the UV-C treatment chamber 13 is preferably greater than 30000 J/cm.sup.2. The sterilisation unit 1 achieves an 8 log reduction of pathogens in the air, when tested with virus MS2, which, in most circumstances, provides a substantially complete kill of pathogens in the air in one pass of the air through the UV-C treatment chamber 13 of the unit.

[0041] The first and second ePTFE filters 29, 31 and the ePTFE liner 33 also substantially contain the UV-C radiation within the UV-C treatment chamber 13. This protects other components of the air sterilisation unit 1 from damage by the UV-C radiation.

[0042] It is to be understood that the invention is not limited to the specific details described herein which are given by way of example only and that various modifications and alterations are possible without departing from the scope of the invention as defined in the appended claims.