Abstract
A system for decontaminating/neutralizing breathable air and surfaces in an occupied enclosed space, i.e., hydroponic greenhouses, aircraft, rail and road vehicles, in building ducts, or rooms, includes mounting an atmospheric hydroxyl radical generator along an inside surface of an occupied space having respective air inlets and air outlets. The hydroxyl radical generator includes a polygonal housing supporting a plurality of spaced crystal-spliced UV optics medical grade pure quartz, which emit/irradiate ultraviolet in the nanometer wavelength/ultraviolet spectrum of between 100 and 400 nanometers for deactivating and neutralizing atmospheric chemicals and pathogens in breathable air and surfaces. The hydroxyl radicals contact the walls of the reaction chamber housing. The hydroxyl radicals become created and excited to react quickly with impurities including VOC, virus, bacteria and fungi, rendering them inactivated and neutral. The breathable air passes through the polygonal housing and is decontaminated and neutralized of impurities before entering the occupied enclosed space.
Claims
1. Apparatus for cleaning breathable air within an enclosed space of a room in a structure comprising: a portable unit supported on casters within said occupied enclosed space for treating said breathable air; said portable unit enclosing a hydroxyl generator for generating and delivering hydroxyl radicals into said breathable air; said hydroxyl generator containing a plurality of spaced crystal-spliced UV lamps within a housing, said UV lamps being tubular, medical grade pure quartz optics designed to emit/irradiate ultraviolet in the nanometer wavelength/ultraviolet spectrum of between 100 and 400 nanometers for exposing ambient water vapor to the spaced crystal-spliced UV lamps, to generate the hydroxyl radicals, for deactivating chemicals and pathogens in said breathable air; said housing having an air inlet to said hydroxyl generator on one side thereof and an air outlet on an opposite side of said housing; said portable unit having grated openings opposite said air inlet and outlet of said housing to allow for continuous air flow through said hydroxyl generator; said portable unit having at least one fan for circulating said breathable air through said hydroxyl generator and into said enclosed space; said hydroxyl generator creating short-lived hydroxyl radical molecules at the rate of 2.6 million per cubic centimeter of air; said portable unit being movable anywhere within said enclosed space of said room which does not interfere with user traffic; whereby said short-lived hydroxyl radicals, created and excited within said housing, becoming excited sufficiently to react quickly with impurities including VOC, viruses, bacteria and mold, rendering them inactivated; and whereby said breathable air passing through said hydroxyl generator is cleansed of said impurities before returning to said enclosed space.
2. The apparatus of claim 1 in which said housing has at least two UV lamps for creating said short-lived hydroxyl radicals for reacting quickly with breathable passing therethrough.
3. The apparatus of claim 2 in which said housing comprises a lengthwise extending hollow structure having a polygon shape in cross section, with adjoining flat walls, and configured as a clamshell having a pivotable wall for servicing said hydroxyl generator.
4. The apparatus of claim 3 in which said portable unit contains baffles adjacent said inlet and outlet for creating a diversion of incoming and outgoing airflow, said baffles being configured to block any light emanating from said housing.
5. The apparatus of claim 4 in which said baffles create an S shaped diversion of incoming and outgoing air flow.
6. The apparatus of claim 5 in which said portable unit is provided with air filters at locations of the air flow inlet and outlet within said housing to protect optics therein from contamination by airborne dirt and other particles which might accompany incoming air flow and may degrade hydroxyl activation portions of said optics.
7. The apparatus of claim 6 in which a control box is mounted adjacent said hydroxyl generator, said control box including a master events controller receiving input from sensors, for controlling operation of said optics within said hydroxyl generator.
8. The apparatus of claim 7 in which said sensors include a detector to detect that airflow is on, so that said optics will only be on when there is airflow, a proximity switch for detecting opening of said housing, a timer and voltage monitor, said master events controller sending pulse width modulation data to said fan or to stop air flow when needed for safety and maintenance situations.
9. The apparatus of claim 8 in which said master events controller has a communications output to send data via a controller area network to a visual display for user feedback, and also send digital data wirelessly as output to status feedback units.
10. The apparatus of claim 9 in which the communications output includes a Wi-Fi/Bluetooth® signal output to wireless input devices for wireless user feedback during use.
11. A method for cleaning breathable air in an occupied enclosed space of a room in a structure comprising the steps of: placing a portable unit supported on casters within said occupied enclosed space for treating said breathable airs; said portable unit enclosing a hydroxyl generator for generating and delivering hydroxyl radicals into said breathable air; said hydroxyl generator containing a plurality of spaced crystal-spliced UV lamps within a housing, said UV lamps being tubular, medical grade pure quartz optics designed to emit/irradiate ultraviolet in the nanometer wavelength/ultraviolet spectrum of between 100 and 400 nanometers for exposing ambient water vapor to the spaced crystal-spliced UV lamps, to generate the hydroxyl radicals, for deactivating chemicals and pathogens in said breathable air; providing said housing with an air inlet to said hydroxyl generator on one end thereof and an air outlet on an opposite end of said housing; providing said portable unit with grated openings opposite said air inlet and outlet of said housing to allow for continuous air flow through said hydroxyl generator; providing said portable unit with at least one fan for circulating said breathable air through said hydroxyl generator and into said occupied enclosed space; moving said portable unit to a location anywhere within said enclosed space of said room which does not interfere with user traffics; whereby said hydroxyl radicals, are short-lived, created and excited within said housing, becoming excited sufficiently to react quickly with impurities including VOC, viruses, bacteria and mold, rendering them inactivated; and whereby said breathable air passing through said hydroxyl generator is cleansed of said impurities before returning to said occupied enclosed space.
12. The method of claim 11 in which said portable unit delivers hydroxyl radical molecules at the rate of 2.6 million per cubic centimeter of air.
13. The method of claim 11 in which said housing comprises a lengthwise extending hollow structure having a polygon shape in cross section, with adjoining flat walls, and configured as a clamshell having a pivotable wall for servicing said hydroxyl generator.
14. The method of claim 13 in which said portable unit is provided with baffles adjacent said inlet and outlet for creating a diversion of incoming and outgoing airflow, said baffles being configured to block any light emanating from said housing.
15. The method of claim 14 in which said baffles create an S shaped diversion of incoming and outgoing air flow.
16. The method of claim 15 in which said portable unit is provided with air filters at locations of the air flow inlet and outlet within said housing to protect said optics from contamination by airborne dirt and other particles which might accompany incoming air flow and may degrade hydroxyl activation portions of said optics.
17. The method of claim 16 in which a control box is mounted adjacent said hydroxyl generator, said control box including a master events controller receiving input from sensors, for controlling operation of said optics within said hydroxyl generator.
18. The method of claim 17 in which said sensors include a detector to detect that airflow is on, so that said optics will only be on when there is airflow, a proximity switch for detecting opening of said housing, a timer and voltage monitor, with said master events controller sending pulse width modulation data to said fan or to stop air flow when needed for safety and maintenance situations.
19. The method of claim 18 in which said master events controller is provided with a communications output to send data via a controller area network to a visual display for user feedback, and also send digital data wirelessly as output to status feedback units.
20. The method of claim 19 in which the communications output is provided with a Wi-Fi/Bluetooth® signal output to wireless input devices for wireless user feedback during use.
Description
BRIEF DESCRIPTION OF THE DRAWINGS
[0045] The present invention can best be understood in connection with the following drawings, which are not deemed to be limiting in scope.
[0046] FIG. 1 is a perspective view of a polygonal hydroxyl generator shown in a closed position.
[0047] FIG. 2 is a perspective view of the hydroxyl generator of FIG. 1 shown in partial cross section with an open view of the interior of the hydroxyl generator.
[0048] FIG. 3 is an end view in cross section of the hydroxyl generator of FIG. 1, with two UV optics for generating hydroxyl radicals.
[0049] FIG. 4 is a cross sectional end view of an alternate embodiment for a hydroxyl generator, showing four UV hydroxyl generator optics within the polygonal hydroxyl generator.
[0050] FIG. 5 is a block diagram of the electronic controls of the hydroxyl generator of FIGS. 1-3 and 4.
[0051] FIG. 5A is a flow chart showing the electronic controls with respect to their position adjacent to the hydroxyl generator.
[0052] FIG. 5B is a block diagram of the electronic controls of the hydroxyl generator used in hydroponic greenhouse applications shown in FIGS. 6 and 6A, or in other applications requiring the electronic controls of FIG. 5B.
[0053] FIG. 5C is a block diagram of the electronic controls of the hydroxyl generator used in HVAC building duct applications, or in other applications requiring the electronic controls of FIG. 5C.
[0054] FIG. 5D is a block diagram of the electronic controls of the hydroxyl generator used in Portable Room-Sized Unit applications, or in other applications requiring the electronic controls of FIG. 5D, which include a proximity detector for safety reasons and a fan, such as a pulse width modulated fan, which regulates the air speed of the fan by regulating the voltage of the fan between on and off, to move air flow with air purifying generated hydroxyl radicals therethrough.
[0055] FIG. 6 is a perspective environmental view of a portable room size hydroxyl generator located on the floor in a room with office or residential furniture.
[0056] FIG. 6A is a perspective view of the portable room size hydroxyl generator mountable upon a wall of a room.
[0057] FIG. 6B is a cross sectional perspective view of an alternate embodiment for a portable room size hydroxyl generator, showing interior components, including an air intake grate, a directional fan for pulling the intake air and sending it in an air flow in the direction of the arrows indicated through a vertically oriented clamshell hydroxyl generator housing, having optics therein as well as interior walls to facilitate the exiting of purified air out of the portable room size hydroxyl generator to the occupied room in which the generator is located, as well as showing filters at the air intake and air exit of the airstream to capture any dirt or undesirable particles, which could compromise the quartz lamp optics. FIG. 6B further shows baffles at the air intake and air exit of the unit to promote an “S” shaped configuration of the airstream within the unit to prevent any undesirable and dangerous glare from direct exposure of persons in the room from the intense light rays of the quartz lamp optics.
[0058] FIG. 7 is a closeup perspective view of the airflow blower fan unit of the portable room size hydroxyl generator of FIGS. 6, 6A and 6B.
[0059] FIG. 7A is a side view in cross section of a preferred embodiment for a portable room-sized hydroxyl generator having a housing with “S-shaped” conducts to promote an “S-shaped” flow of the air within the hydroxyl generator The housing includes an air inlet and a filter to keep out dirt, dust and other contaminating particulates from entering and contaminating the optics within the centrally located hydroxyl generating reactor after which the air infused with hydroxyl radicals produced by contact or water vapor in the inlet air exposed to the UV light of the optics. A curved baffle type air directing conduit moves the air in the S-shaped curvature through an exit compartment and exit grille to the room in which the portable room-sized hydroxyl generator stands upon casters or wheels or is alternatively mountable upon a wall (not shown) in the room being serviced by the portable room-sized hydroxyl generator unit.
[0060] FIG. 7B is an exploded view of the portable room-sized hydroxyl generator as in FIG. 7A, showing the housing of hydroxyl generator, with caster wheels, and a filter and baffle conduct inside the air inlet of the housing. The hydroxyl generator reactor is also shown with an optic, fan and exit grille.
DETAILED DESCRIPTION OF THE DRAWINGS
[0061] As used throughout this specification, the word “may” is used in a permissive sense (i.e., meaning having the potential to, or being optional), rather than a mandatory sense (i.e., meaning must), as more than one embodiment of the invention may be disclosed herein. Similarly, the words “include”, “including”, and “includes” mean including but not limited to.
[0062] The phrases “at least one”, “one or more”, and “and/or” may be open-ended expressions that are both conjunctive and disjunctive in operation. For example, each of the expressions “at least one of A, B and C”, “one or more of A, B, and C”, and “A, B, and/or C” herein means all of the following possible combinations: A alone; or B alone; or C alone; or A and B together; or A and C together; or B and C together; or A, B and C together.
[0063] Also, the disclosures of all patents, published patent applications, and non-patent literature cited within this document are incorporated herein in their entirety by reference. However, It is noted that the citing of any reference within this disclosure, i.e., any patents, published patent applications, and non-patent literature, is not an admission regarding a determination as to its availability as prior art with respect to the herein disclosed and claimed apparatus/method.
[0064] Furthermore, any reference made throughout this specification to “one embodiment” or “an embodiment” means that a particular feature or characteristic described in connection therewith is included in at least that one particular embodiment.
[0065] Thus, the appearances of the phrases “in one embodiment” or “in an embodiment” in various places throughout this specification are not necessarily all referring to the same embodiment. Therefore, the described features, advantages, and characteristics of any particular aspect of an embodiment disclosed herein may be combined in any suitable manner with any of the other embodiments disclosed herein.
[0066] FIG. 1 shows a hydroxyl generator 1, including a polygonal-shaped housing, including a bracket brace 14 for supporting crystal-spliced UV optics 12 and 13 within respective C-shaped spring clasps 12a and 13a, which are each respectively mounted on bracket brace 14, which are mounted parallel lengthwise to each other inside the clamshell hexagon housing, but staggered so that UV optic 12 is on a different side of the bracket 14 from the side on which UV optic 13 is located, wherein the crystal spliced UV optics 12 and 13, each have a length that runs substantially the entire length of the housing of the hydroxyl generator 1. A preferred example for the crystal-spliced UV optics 12 and 13 is the GPH457T5L/4P UV Optic 4-pin Base 18″ GPH457T5 of Light Spectrum Enterprises of Southampton; these optics 12 and 13 are typically 18 inches long and are made of quartz. The tubular optics 12 and 13 are composed of pure Medical Grade quartz crystal in the portion of the optics which creates the hydroxyls. The present invention adds additional frequencies to the pure crystal optics. These tubular optics 12 and 13 generate ‘Harmonic’ bio-mimicry nonchemical process of the present invention which enables the production of desired atmospheric hydroxyls at a rate commensurate with the VOC/Bio loading in that particular space to be treated with the hydroxyls.
[0067] In contrast to the medical grade quartz tubular optics, it is noted that total glass tubes cannot be used when generating UV. The glass would simply be vaporized. Some companies use a fusion of glass and quartz crystal, which is not optimal as the glass portion creates a frequency that actually attracts contaminants. This problematic action neutralizes the desired UV action. Such a fusion lamp of glass and quartz crystal is cheaper to produce, however the poor performance of the lamp would be the end result.
[0068] Other similar Medical Grade quartz tubed UV optics can be used. The optics 12 and 13 are preferably symmetrically positioned in the housing of the hydroxyl generator 1, as shown in FIGS. 3 and 4 to operate most efficiently, but where in FIG. 3 the crystal spliced UV optics 12 and 13 are staggered so that UV optic 12 is on a different side of the bracket brace 14 from the side on which UV optic 13 is located. FIG. 4 shows an alternate embodiment where there are two pairs of UV optics, namely 112,112 and 113, 113. The UV optics 112, 112 are staggered to the right on one bottom side of the horizontal bracket brace 114, but are separated by upright bracket brace 114. Likewise, UV optics 113 and 113 are respectively staggered to the left on the opposite top side of the horizontal bracket brace 114, also separated from each other by upright bracket brace 114. Optics pairs 112, 112 and 115, 113 are supported within pairs of respective C-shaped spring clasps which pairs of optics 112, 112 and 113, 113 are each respectively mounted on bracket brace 114, and which pairs of optics 112, 112 and 113, 113 are mounted parallel lengthwise to each other inside the clamshell hexagon housing 100 of FIG. 4.
[0069] The clamshell hexagon housing hydroxyl generator 1 has a clamshell configuration, including a clamshell top wall 2, upper side walls 7, 8, 9 and 10, fasteners 16a, 16a, a hinge 6 for opening the polygonal clamshell housing 1 and a bottom clamshell portion, including a bottom wall 4 and angle-oriented walls 11 and 11a, whereby the polygon housing opens hinge 6 to expose the inside of the hydroxyl generator 1 for maintenance and/or repair. In addition, the polygon hydroxyl generator enclosure can be removed from the air duct wall 40A for such maintenance and repair. The hydroxyl generator also includes an adjacent electronic control box 20, which is attachable to the clamshell housing of the hydroxyl generator 1. Alternatively, as shown in FIGS. 3 and 4, the electronic control box 20 is preferably located outside of the air path, which may be a duct or other conduit. It can alternatively be attached outside of the duct. It communicates with the UV optics wirelessly. The reason for the polygon shape is that the hydroxyl generators generated by the crystal-spliced UV optics 12 and 13 are scattered upon being generated by the optics 12 and 13, but they dissipate quickly if not activated by contact with reflective non-absorbent surfaces inside the respective walls of the polygon. The purpose of the polygon shape is that when the hydroxyl radicals are generated, they are emitted radially in all directions from the UV crystal-spliced optics 12 and 13 and normally would dissipate when scattered radially from the optics. In order to permit the hydroxyl radicals to maintain their desired electron charge and ability to contact and inactivate mold, volatile organic compounds, pathogens, bacteria, virus, etc., they need to reflect and refract off of the reflective non-absorbent walls continuously, within the reaction chamber confined space. As atmospheric hydroxyls are being activated by being created and excited in back-and-forth activity, the air inside the air duct/plenum 40a will contact the activated hydroxyl radicals with the end result of the neutralization of any impurities, such as VOCs, virus, bacteria, fungi, etc., in the air and surfaces.
[0070] Furthermore, once these radicals are emitted, they can penetrate any crevices in any area, such as in hydroponic greenhouse plant media growing vessels, such as between seats of aircraft, mass transit rail and road vehicles, in building ducts and wall surfaces and other human occupied spaces, such as individual rooms with small self-contained hydroxyl generators, between the surfaces of seats and shelving, and anywhere where ultraviolet light by itself would not be capable of eradicating the undesirable VOCs, fungi, virus, bacteria, etc. In the aircraft environment, the polygon-shaped housing is strategically located within an air supply unit in an airport terminal building, or it can be located within a remote cart not located near the aircraft, on the tarmac of the airport, and preferably it may be provided in the air systems separately of an aircraft cabin, including the flight deck and the areas of the main cabin where passengers are seated. Therefore, the polygon shaped housings may also be strategically located in mass transit rail and road vehicles, in building ducts, in individual rooms, and wall surfaces and other human occupied spaces
[0071] As shown in the end view of FIG. 3, the inside of the polygon housing 1 is located below the field of vision within the sealed off plenum so that the ultraviolet (UV) crystal-spliced tubular optics 12 and 13 will not be exposed to the eyes of any observers. Therefore, while the hydroxyl radicals are being generated, the UV energy which create hydroxyl generation from optics 12 and 13 are completely sealed off so that when the optics 12 and 13 are operational, the UV light emanating therefrom will not penetrate outside of the polygonal housing. Baffles, optionally located outside of the hydroxyl generators, but in the vicinity of the hydroxyl generators, prevent the UV light from exposure to persons. Additionally, fibrous filters may be provided at input and outlet areas of the housing containing the hydroxyl generator portion with the UV optics, to capture any undesirable airborne particulates, such as dirt and dust and other particles which may compromise the sensitive quartz material of the UV optics. There is no restriction regarding the active flow of the hydroxyls inside the hydroxyl generator 1 and no interference with the excitement of the hydroxyls produced by the exposure of ambient water vapor within the polygon shaped housing with the UV optics 12 and 13 irradiating light that causes the —OH radicals to form.
[0072] FIG. 4 shows an alternate embodiment for a four optic version, where polygon hydroxyl generator enclosure 100, having top wall 102, side walls 107, 108, 109, 110 of an upper shell, as well as lower walls 105, 111a, 111b of the clamshell housing. The clamshell housing has inner walls 104 against which the hydroxyls being formed contact repeatedly during formation. FIG. 4 also shows the electronics control box 120, attached to the clamshell housing by brackets 119. The respective pairs of optics 112, 112, and 113, 113 are supported within respective pairs of C-shaped spring clasps, which are each respectively mounted on bracket brace 114, which are mounted parallel lengthwise to each other inside the clamshell hexagon housing 100. The upper half of the clamshell housing is connected to the lower half of the clamshell housing by fasteners 116, 116a. Clamshell housing 100 is openable via a hinge located near fastener 116a.
[0073] FIG. 5 is a block diagram showing the network and electronics of the control box 20. Initially AC power 23 of 110 VAC is converted by converter 22 to low voltage 12 VDC, or else a low voltage battery alternatively delivers 12 VDC to a secure Key Switch 22a, to provide power to the Master Events Controller 20, which may have a microprocessor 21. The Master Events Controller 20 also receives input from sensors, such as Air Flow Sensor 25, UV Light Sensor 26, Proximity Switch 27 (detecting opening of the enclosure), Timer 30 and Voltage Monitor Sensor 31. These sensors provide Sensor Input to the Master Events Controller 20. Power Switching in the Master Events Controller 20 sends 12V Pulse Width Modulation data to a PWM Speed Controlled Fan 34, to send air through the hydroxyl generator unit 1 or 101, or to stop the flow of air when needed for safety and maintenance situations. The Power Switching also sends data via a Large Serve Outlet (LSO) to a Relay, which controls the Ballast 32, providing power to the Crystal UV Optics 12, which creates the needed hydroxyls within the hydroxyl generators 1 or 101. The Master Events Controller 20 also has a Communications Output, which can send data via a Controller Area Network (CAN) to a Visual Display 29 for user feedback. The Communications Output of the Master Events Controller 20 also sends digital data wirelessly as output to Status Feedback Units. The Communications Output of the Master Events Controller 20 also sends Wi-Fi/Bluetooth® Signal output to Wireless input devices 28 for Wireless user feedback during use.
[0074] FIG. 5A is a diagrammatic flow chart, showing the electronic control box 20 of FIGS. 1, 2 and 3, which is also equivalent to the electronic control box 120 of FIG. 4. Adjacent to the hydroxyl generator 1 or 101, which in FIGS. 1-3, the hydroxyl generators are attached by one or more brackets 19 to the electronic control box 20. Similarly, the electronic control box 120 is attached by brackets 119 of FIG. 4.
[0075] In the diagrammatic flow chart of FIG. 5A, related to the electrical block diagram of FIG. 5, the control box 20 includes a microprocessor 21 for controlling the sensors and switches, which control the operation of the optics 12 and 13, or 112 and 113, of the hydroxyl generators 1 shown in FIGS. 1-3 and 4 respectively. There is also a power source being either a DC low-voltage battery 24, or an AC plug 23, to provide higher-voltage AC power. When the AC is used, a converter 22 can be provided to convert high-voltage AC to low-voltage DC power for operating any of the sensors and control elements within box 20. Box 25 of FIG. 5A discloses the detector 25 to detect whether airflow is on, so that the optics 12 and 13 will only be on after airflow is confirmed, so that they are not on when there is no airflow. Box 26 of the diagrammatic flow chart of FIG. 5A discloses the sensor 26 for detecting emitted light, and providing feedback to replace optics, including a secondary backup optic, which is also disclosed in box 26 of the flowchart of FIG. 5A. Box 27 of the diagrammatic flow chart of FIG. 5A discloses a detector with a proximity switch 27 detecting opening of the enclosure, and thereafter used to turn off the optics 12 and 13, to protect people from being exposed to the possible harmful UV light emitted from the optics 12 and 13. This detector with the proximity switch 27 shown in box 27 of the diagrammatic flow chart of FIG. 5A also includes a limit switch, a micro switch and sensors. Box 28 of the diagrammatic flow chart of FIG. 5A discloses the mobile phone application connection 28 for user feedback by wireless communication, such as Wi-Fi or Bluetooth® communications, between the operator, the control box 20 and hydroxyl generator 1 itself, together with a timer. The control box 20 also includes the LCD user feedback system 29, with a timer shown in box 29 of the diagrammatic flow chart of FIG. 5A with a timer, as well as a further timer 30 shown in box 30 of the diagrammatic flow chart of FIG. 5A, to provide feedback for regular maintenance. The voltage and frequency of AC main supply sensor 31 is shown in box 31 of the diagrammatic flow chart of FIG. 5A, Box 32 of the diagrammatic flow chart of FIG. 5A shows the voltage and frequency of the monitor of the ballast power outfit 32. Box 33 of the diagrammatic flow chart of FIG. 5A discloses a fire sensor 33, which detects excess heat in the system. Box 34 of the diagrammatic flow chart of FIG. 5A discloses a real time clock 34 which controls any fans providing and activating the airflow through the polygon hydroxyl generators 1.
[0076] In the alternate embodiment shown in block diagram FIG. 5B, there are disclosed therein shown the following differences of block diagram FIG. 5B from block diagram FIG. 5, wherein in block diagram FIG. 5B the following features are shown: [0077] 1. The key switch (22a) can alternatively be positioned before the power supply (22); [0078] 2. The key switch (22a) can alternatively be a pushbutton; [0079] 3. The power supply (22) can alternatively be included in the Master Events Controller (MEC) 20; [0080] 4. The user feedback display (29) of FIG. 5 is not needed in FIG. 5B, because the Wi-Fi/Bluetooth® communication works with a mobile application; [0081] 5. The PWM Speed controlled fan (34) of FIG. 5 is not needed, because the hydroxyl generator 1 will be located in an existing duct with moving air; and, [0082] 6. The power to the relay (not numbered) in FIG. 5 can alternatively be provided by the Master Events Controller (MEC) 20 in FIG. 5B.
EXAMPLE
Portable Room-Sized Generator Embodiment
[0083] FIGS. 6-7B show polygon hydroxyl generators 800, which are removably positioned for lower power needs in smaller confined areas, such as individual rooms in a building or schoolhouse or nursing home. FIG. 6 shows a portable room sized unit 800 which can be provided, which will have a smaller interior volume for producing the optimal number of hydroxyls generated to purify the air/surfaces and crevices/creases within the aforesaid areas. Such a portable hydroxyl generator 800 includes a generator chamber housing 801, which is mounted on a bottom wall, 819a including casters or wheels 845, 845a, 845b and 845c on the bottom for moving the hydroxyl generator 800 around in a confined space area, such as an individual room.
[0084] FIG. 5D is a block diagram of the electronic controls of the hydroxyl generator used in Portable Room-Sized Unit applications, or in other applications requiring the electronic controls of FIG. 5D, which include a proximity detector for safety reasons and a fan, such as a pulse width modulated fan, which regulates the air speed of the fan by regulating the voltage of the fan between on and off, to move air flow with air purifying generated hydroxyl radicals therethrough.
[0085] Alternatively, the unit 800 can be devoid of movable wheels or casters, but can be mounted upon a wall 890 (not shown).
[0086] Shown in FIG. 6B, the movable generator 800 also includes the housing polygon generator chamber housing 801, which houses therein a clamshell housing having a polygonal chamber 830, which has inside the UV light emitting optics 812, 813, Baffles 820 and 820a are located inside of the portable housing 801, but outside of clamshell housing chamber 830 with optics 812, 813 to limit any leaking of UV light from the crystal-spliced tubular optics 812, 813, which upon being engaged will generate the hydroxyl radicals flowing nearby. The unit 800 also includes an air intake 840 and air exit 841, as well as a partition and space for the electronics 820, an air blower 850 which blows and pressurizes air to the chamber of the hydroxyl generator 830. Front bezel 821 is provided for controls and the air intake 840 is provided on one of the walls 819c of the aluminum unit 801, enclosing the housing generator 830 housing optics 812, 813 therein. The aluminum housing 801, or other suitable material, has side walls 819a, 819c, top wall 819b and bottom wall 819d, as well as rear wall 819e and front cover (not shown). When the aluminum cover is removed, it provides easy access for optic cleaning and/or replacement of the enclosed, sealed clamshell hydroxyl generator 830, which can be taken out and opened along its clamshell hinge 806. The air is passed through the intake, blown by the blower 850, then through the polygonal generator chamber housing 830 and out through an air outlet 841. The blower 850 is mounted by a mount 851 within the housing 801.
[0087] FIG. 6B also shows a side perspective view in cross-section of the hydroxyl generator 800 for residential home use, showing the “S-curve” diversion of the incoming and outgoing airflow “A”, which diversion is achieved by light blocking baffles 860 and 860a, where one or more staggered baffles 860a are at the air flow exit portion 840 of the hydroxyl generator housing 801 for residential rooms, and also with one or more staggered baffles 860 are at the air flow entry point 840 of the hydroxyl generator housing 801. The staggered baffles 860 and 860a are configured to block inadvertent eye damaging light emanating from the optics within the polygonal optics bearing clamshell hydroxyl generator housing 830, especially for curious short children or leased service dogs for people in need of canine assistance while visiting in a residential building room, who might tend to stare and look at the hydroxyl generator 800, located on the floor of the room.
[0088] FIG. 6B also shows dirt and particulate-capturing filters 890, 890a at the air intake 840 and air exit 841 of the airstream to capture any dirt or undesirable particles in the air, whether part of the air stream or adjacent air surrounding the portable room sized hydroxyl generator 800, which could compromise the quartz lamp optics 812, 813.
[0089] FIG. 7 shows one example of an airflow blower fan unit of the portable room size hydroxyl generator of FIGS. 6, 6A and 6B. However, any shape or configuration for an air moving fan structure can be employed.
[0090] For example, a preferred embodiment for a portable room sized hydroxyl generator is shown in drawing FIGS. 7A and 7B.
[0091] FIG. 7A is a side view in cross section of a preferred embodiment for a portable room-sized hydroxyl generator 900 having a housing 911 with “S-shaped” conducts to promote an “S-shaped” flow of the air within the hydroxyl generator 900 The housing 911 includes an air inlet 901 and a filter 902 to keep out dirt, dust and other contaminating particulates from entering and contaminating the optics 906, 907 within the centrally located hydroxyl generating reactor 905 after which the air infused with hydroxyl radicals produced by contact or water vapor in the inlet air exposed to the UV light of the optics 906, 907. A curved baffle type air directing conduit 908 moves the air in the S-shaped curvature through an exit compartment 909 and exit grille 910 to the room in which the portable room-sized hydroxyl generator 900 stands upon casters or wheels 912, 913 or is alternatively mounting upon a wall in the room being serviced by the portable room-sized hydroxyl generator unit 900.
[0092] FIG. 7B is an exploded view of the portable room-sized hydroxyl generator 900 as in FIG. 7A, showing the housing 911 of hydroxyl generator 900, with caster wheels 912, 913 and a filter 902 and baffle conduct 914 inside the air inlet of the housing 911. The hydroxyl generator reactor 905 is also shown with a cover 905a removed, an optic 906, fan 903 an exit grille 910.
CONCLUSION
[0093] The hydroxyl generator systems of the present invention are designed to neutralize and destroy virus' everywhere safely and effectively, while purifying and sanitizing breathable heated, ambient, or cooled air emanating from a source and neutralizing up to 99.9999% of tested virus, including Covid-19 virus. The present invention also helps occupants an occupied space who are afflicted with asthma and airborne allergies, including full air and surface protection, including in crevices between other surfaces.
[0094] The hydroxyl generator systems of the present invention can be placed in any environment where pristine air is required, in a state of the art technology that is chemical free, safe for people, pets and plants.
[0095] In the foregoing description, certain terms and visual depictions are used to illustrate the preferred embodiment. However, no unnecessary limitations are to be construed by the terms used or illustrations depicted, beyond what is shown in the prior art, since the terms and illustrations are exemplary only, and are not meant to limit the scope of the present invention.
[0096] It is further known that other modifications may be made to the present invention, without departing the scope of the invention, as noted in the appended Claims.
