Chemical apparatus and process disinfecting – deodorizing – preser – Chemical reactor – With means applying electromagnetic wave energy or...
Reexamination Certificate
2001-01-29
2003-04-08
Mayekar, Kishor (Department: 1741)
Chemical apparatus and process disinfecting, deodorizing, preser
Chemical reactor
With means applying electromagnetic wave energy or...
C422S186120, C422S186300, C422S121000
Reexamination Certificate
active
06544485
ABSTRACT:
FIELD OF THE INVENTION
The present invention relates generally to devices that can condition the air in a room, including so-called electro-kinetic devices that output ionized air, typically accompanied by ozone (O
3
), and more specifically to providing such devices with enhanced ability to kill microorganisms, including germs, bacteria, and viruses in the room environment.
BACKGROUND OF THE INVENTION
U.S. Pat. No. 6,163,098 to Taylor et al. and U.S. Pat. No. 4,789,801 to Lee describe various devices to generate a stream of ionized air using so-called electro-kinetic techniques. In some applications, the electro-kinetic devices may be small enough to be handheld, and in other applications electro-kinetic devices may be large enough to condition the air in a room. In overview, electro-kinetic techniques use high electric fields to ionize air molecules, a process that produces ozone (O
3
) as a byproduct. Ozone is an unstable molecule of oxygen that is commonly produced as a byproduct of high voltage arcing. In safe concentrations, ozone can be a desirable and useful substance. But ozone by itself may not be effective to kill microorganisms such as germs, bacteria, and viruses in the environment surrounding the device.
FIG. 1
depicts a generic electro-kinetic device
10
to generate ozone. Device
10
includes a housing
20
that typically has at least one air input port
30
and at least one air output port
40
. Within housing
20
there is disposed an electrode assembly or system
50
comprising a first electrode array
60
having at least one electrode
70
and comprising a second electrode array
80
having at least one electrode
90
. System
10
further includes a high voltage generator
100
coupled between the first and second electrode arrays. Electrodes
70
and electrodes
90
may have a variety of shapes. For example, electrodes
70
may be thin electrical wires, and electrodes
90
may be larger wires, rods, or other shapes. Electrodes
70
may be pointed or pin-like, and electrodes
90
may be curvilinear, including ring shaped, or may comprise a conductive plate with curved or ring-like openings formed in the plate. Electrodes
90
typically are symmetrically disposed relative to electrodes
70
. For example, if there are three electrodes
70
in first electrode array
60
, there might be two electrodes
90
in second electrode array
80
, wherein electrodes
90
are staggered to be equidistant from the nearest electrodes
70
. In the pin and ring type configurations, electrodes
90
are preferably concentric with electrodes
70
.
In the various configurations, all of the electrodes are electrically conductive material, metal for example. Electrodes
90
preferably have a larger radius than electrodes
70
, with the result that a large electric field is created at or adjacent electrodes
90
upon application of high voltage (typically several kV) from generator
100
. As a result, ozone and ionized particles of air are generated within device
10
, and there is an electro-kinetic flow of air in the direction from the first electrode array
60
towards the second electrode array
80
. In
FIG. 1
, the large arrow denoted IN represents ambient air that can enter input port
30
. The small “x's” denote particulate matter that may be present in the incoming ambient air. The air movement is in the direction of the large arrows, and the output airflow, denoted OUT, exits device
10
via port
40
. An advantage of electro-kinetic devices such as device
10
is that an air flow is created without using fans or other moving parts to create the air flow.
Preferably particulate matter x in the ambient air can be electrostatically attracted to the second electrode array
80
, with the result that the outflow (OUT) of air from device
10
not only contains ozone and ionized air, but can be cleaner than the ambient air. In such devices, it can become necessary to occasionally clean the second electrode array electrodes
80
to remove particulate matter and other debris from the surface of electrodes
90
. Thus, device
10
in
FIG. 1
can function somewhat as a fan to create an output air flow, but without requiring moving parts. Ideally the outflow of air (OUT) is conditioned in that particulate matter is removed and the outflow includes safe amounts of ozone, and some ions.
But an outflow of air containing ions and ozone may not destroy or reduce microorganisms such as germs, bacteria, fungi, viruses, and the like, collectively hereinafter “microorganisms”. It is known in the art to try to destroy such microorganisms with so-called germicidal lamps. Such lamps emit ultra violet radiation having a wavelength of about 254 nm. For example, devices to condition air using mechanical fans, HEPA filters, and germicidal lamps are sold commercially by companies such as Austin Air, C.A.R.E. 2000, Amaircare, and others. Often the devices are somewhat cumbersome, and have size and bulk of a small filing cabinet. In such devices, care must be taken to ensure that ultraviolet radiation from the germicidal lamp cannot be viewed by nearby persons, to prevent eye injury. Although such fan-powered devices can reduce or destroy microorganisms, the devices tend to be bulky, and are not necessarily silent in operation.
What is needed is a device to condition air in a room that can operate relatively silently to remove particulate matter in the air, that can preferably output safe amounts of ozone, and that can also kill or reduce microorganisms such as germs, fungi, bacteria, viruses, and the like.
The present invention provides such a device.
SUMMARY OF THE PRESENT INVENTION
In a first aspect, the invention provides an electro-kinetic ionizing device with a baffle mechanism and a germicidal lamp housed within the device such that the baffle mechanism precludes lamp ultraviolet radiation from being viewed by humans. In one configuration, the germicidal lamp is disposed vertically within a somewhat tubular housing, with an array of first and second electrodes disposed axially at one lamp end. In an alternative embodiment, there is an array of first and second electrodes disposed axially at each lamp end. In the various embodiments, intake and outlet vents at each end of the housing promote flow of electro-kinetically moved air without permitting viewing of the lamp radiation.
Preferred electrode array configurations include pin-ring and elongated pin-ring electrodes, including pin electrodes formed from an arc or ring of tapered conductive material, and symmetrically disposed arrays of electrodes formed as a single component. The electrodes in an array preferably are symmetrically disposed with respect to each other, and like in the air flow path. Efficacy of the germicidal lamp in destroying bacterial, virus, germs, etc. in the air flow appears to be proportional to the length of time the airflow is subjected to radiation from the lamp. Thus the preferred embodiments of the invention dispose the longitudinal axis of the germicidal lamp parallel to the long axis of the electro-kinetic device.
If desired, moisture containing material such as Porex may be included to augment moisture content in the outflow of conditioned air. In one embodiment, a personal-sized portable device is provided that includes electro-kinetically generated airflow with ions and ozone in the output, reduced particulate matter in the output airflow, and with reduced or eliminated microorganisms as a result of ultraviolet radiation generated from a germicidal type lamp within the device. In an alternative embodiment, the electro-kinetic components may be replaced by a small battery operated fan, to yield a personal device that outputs air substantially devoid of microorganisms. A Porex type element may also be included to allow a user to augment moisture content in the air outflow.
REFERENCES:
patent: 2327588 (1943-08-01), Bennett
patent: 2590447 (1952-03-01), Nord, Jr. et al.
patent: 2949550 (1960-08-01), Brown
patent: 3793744 (1974-02-01), Saita
patent: 3910778 (1975-10-01), Shahgholi et al.
patent: 3981695 (1976-
Fliesler Dubb Meyer & Lovejoy LLP
Mayekar Kishor
Sharper Image Corporation
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