Dynamic electrostatic filter apparatus for purifying air using electrically charged liquid droplets

TECHNICAL FIELD

The present invention relates generally to air cleaning equipment and is particularly directed to an air cleaner of the type which sprays electrically charged liquid droplets into the “dirty” air stream. The invention is specifically disclosed as an air filter that charges semiconductive liquid droplets and sprays them into a chamber in which an air flow that contains entrained dust particles is introduced. The particles are charged to one polarity, the liquid droplets are charged to an opposite polarity, and thus the particles are attracted to the droplets. The droplets are accumulated on a collecting surface, then recirculated and used again to collect further dust particles.

BACKGROUND OF THE INVENTION

Indoor air includes many small particles which, when inhaled or otherwise contacted by human beings, have a pernicious effect. Dust alone comprises dead skin, dust mite feces, pet dander, and other microscopic (less than 10 microns in size) particles which elicit a human immune response. This is exemplified by dust mite feces, which comprise a wide array of serine and cysteine protease enzymes that cause respiratory irritation and are responsible for many allergy symptoms.

While filtration systems have been used to reduce the amount of small particles present in selected locations, many of the most commonly irritating materials still exist as particles within a range of about 0.1 micron to about 10 microns in size. Filters having pore openings small enough to be effective at removing particles in this size range are known to become easily occluded and generate high backpressure, thereby requiring high power air blowers. Moreover, the ability to maintain proper air conduction through such filters requires a significant amount of electrical energy, is expensive and cumbersome.

Other types of air purifying devices, such as ionic and electrostatic devices, utilize the charge on particles to attract them to a specified collecting surface which is charged at an opposite polarity. Such devices require the collecting surface to be cleaned constantly and have met with limited success in terms of efficiency.

It will be appreciated that small particles can collect in the home and be re-breathed by the occupants without the benefit of elaborate and high power consumption filtration systems found in the public domain. One vestige of prior art systems is their size and high electrical power demand, which affects the cost of operation and the aesthetics of a sizable filtration apparatus.

With regard to the patent literature, an electrostatic scrubber is disclosed in U.S. Pat. No. 4,095,962 (by Richards) which produces highly charged liquid droplets without a concurrent production of a corona by providing a nozzle configured such that the nozzle's tip forms a substantially uniform electric field over the surface of the liquid on the tip, and this field is large enough to pull off droplets from the tip but not so large so as to create a corona discharge. Selected gas, solid particulates, and liquid mists from gaseous effluents are removed by an electrostatic collector that attracts the highly charged droplets. The droplets are caused to drift, by means of an electric field, through the gaseous effluent to a collecting electrode, thereby absorbing selected gases and aerosol particles, and carrying them to the collecting electrode. The droplet size of the charged droplets is in the range of 30-800 microns radius. One of the recommended scrubbing liquids is ammonium hydroxide, which is used when the effluent gas is sulphur dioxide.

Another patent by Richards, U.S. Pat. No. 6,156,098, also discloses a charged droplet gas scrubber apparatus, which allows scrubbing of uncharged particulates by use of a monopole-dipole attractive force between the charged liquid droplets and the electric dipoles that are induced in the uncharged particulates. The droplet production and charging produces a set of “spreading liquid sheet electrodes” in which the droplets are emitted from the edges of the liquid sheets, and these liquid sheets are interspersed with electrically conductive induction electrodes. This configuration again prevents corona discharge while charging the liquid droplets. Once the droplets are charged, they induce an electric dipole moment in the particulate particles. The droplets are collected by an impingement separator, and the liquid is then collected in a sump and strained through a strainer. In Richards '098, the liquid preferably is a conductive liquid such as tap water, and the size of the droplets is in the range of 25-250 microns diameter. An optimum size of these droplets is stated as being 140 microns. In situations where water is the liquid, the system can be an open-loop system, and the water need not be recirculated. Other liquids could be used, but they must have a minimum conductivity of 50 microSiemens per centimeter (which is 5 Ohm

−1

-meter

−1

). Richards '098 does not use the electrical charge on the droplets to “clean” the dirt particles in the air. Instead, the Richards device is merely attempping to create water droplets from a stream of water, not necessarily to retain an electrical charge on those droplets.

The two Richards patents are not directed toward room or office air cleaning systems, but are specifically directed toward scrubbing effluent gases, such as those produced in a power plant. Furthermore, the Richards patents use a conductive liquid, and this liquid is not necessarily recirculated, particularly when water is used since it is substantially inexpensive. Another feature of the two Richards patents is that the water droplets are fairly large in size, and again are directed toward removing fairly large particles from effluent gases, at a substantially high temperature in most cases. Such large droplets are not going to be substantially effective in removing particulate matter that is relatively small in particle size.

Another patent in this field is U.S. Pat. No. 3,958,959, by Cohen, which discloses a method of removing particles and fluids from a gas stream using charged droplets having a size between 60-250 microns, in which the preferred size is between 80-120 microns. The droplets are generated by ejecting a stable jet of liquid, such as water, in which the liquid jet is broken into charged droplets by applying an electric potential between the jet and the collecting walls of the scrubber. As the droplets are sprayed between two grounded wall plates, dirty inlet air flows at an angle to the liquid droplet flow direction and, once charged, the droplets are attracted to the walls. Since the droplets are moving at an angle to the direction of movement of the gas stream, this increases the relative velocity between the droplets and the particles. After the droplets impact against the grounded wall plates, they flow to the bottom of the walls and are collected in troughs below the walls, and this liquid thus contains some of the particulates from the gas stream. The resulting slurry is recirculated and the particulate matter is removed by a media filter. In this invention, the “droplet drift time” is generally less than 25 milliseconds.

The droplets in Cohen may consist of water, and in some cases there may be chemical agents added to the water that will react with the gas components that are to be removed. An example of such a chemical agent is sodium hydroxide for removing sulphur dioxide. Examples of collecting efficiency are illustrated in

FIG. 12

, which shows curves representing the specific collecting area in square feet per cfm (cubic feet per minute) of air volume movement. The curves are generated for mean particle sizes in the range of 1-10 microns, and it is clear that the smaller the particle size, the less the overall collecting efficiency. None of the curves run down to the 0.3 micron particle size, and it is clear that a fairly large specific collecting area would be required to keep efficiencies above 80-90% (and this is only an extrapolation of these curves: nothing is said in the patent document as to whether those curves can realistically be extrapolated in the lower particle size range).

Another patent document in this field is EP 1 095 705 A2, owned by ACE Lab, Inc., which discloses an air cleaning device that produces electrically charged “hyperfine liquid droplets” that are formed through an electro-hydrodynamic atomization process which applies a high voltage to capillaries that have nozzles at their tips from which the liquid is ejected in the form of the hyperfine liquid droplets. These liquid droplets “absorb” dust laden air that are flowing through a duct. In actuality, the charged liquid droplets attach themselves to the particles in the dust laden air, and these particles now receive a charge from those liquid droplets. The air flow is directed into an electrostatic dust collector (i.e., an electrostatic precipitator) which has parallel plates that are alternately charged and grounded, thereby forming an electric field that has a polarity opposite to the charge imparted by the liquid droplets. Water is used as an exemplary liquid, because it not only can carry an electrical charge a short distance, but can also humidify the discharged air. Although this EPO document states that the liquid droplets absorb the dust, in reality the opposite is true: the hyperfine liquid droplets are much smaller than the dust, and the main inventive thrust of this invention is a clever way to impart an electrical charge to the dust particles of the inlet air without causing a corona effect. The ACE Lab's patent (the EP patent) discloses a system where the water droplets are quickly attracted to the particles of dust in the incoming air, and the electrical charge is thereby transferred to the dust. Consequently, a very short relaxation time can be useful and thus water can be used as the liquid medium. This document states that “fine dust” that is smaller than 0.1 microns is “removed easily and effectively,” and also states that experimental data showed that the device could remove up to about 90% dust from the air.

One consideration of whole house air cleaners is that, if water is used for the liquid that produces the electrostatically-charged droplets, it must be remembered that microbes can grow in the water. Therefore, it may not be desirable to use water in a recirculating system. However, water is cheap, so an air cleaner could be constructed using water to create the charged droplets if desired, in which case the water could be non-recirculating in a single-pass system. It also must be remembered, however, that water does not easily retain an electrical charge for any appreciable time period, and therefore, has a very short “relaxation time” since it is fairly highly conductive. A lesser conductive liquid would have a longer relaxation time and so could retain the electrical charge for a much longer time period. Such a “semiconductive” liquid will preferably have the ability to travel several inches or more while retaining the full electrostatic charge that is imparted upon its droplets as they are ejected from the nozzles, thereby having the ability to attract particles from the inlet “dirty” air throughout their entire travel from the nozzle to a collecting plate or container. This principle is utilized in the present invention, as discussed below in greater detail.

Many whole house air cleaners are constructed as electrostatic precipitators, mainly because such air cleaning devices have a fairly low backpressure (i.e., pressure drop) characteristic, thereby enabling a furnace to blow its entire outlet air through an air cleaner without incurring an exceedingly high pressure drop (which would otherwise require a much larger motor and greater electrical power consumption). While electrostatic precipitators are quite common, their dust collecting efficiency specifications leave much to be desired.

For conventional electrostatic air cleaners that are available today, the dust collecting efficiency is typically less than 70% for particles of 0.3 microns, and for the ASHRAE “dust spot test,” the dust collecting efficiency is typically less than 78%. Moreover, electrostatic filters need to be kept clean, which is a critical characteristic having negative consequences that is often overlooked by the consumer or user of such electrostatic filters. In standard electrostatic filters, their metal plates or fiber media are easily covered by dust in rather short order, and when that occurs, the electrostatic filters become much less efficient. Furthermore, in fiber electrostatic filters that have a fairly high density of such fibers, once these fibers become covered by dust, the filter can literally become in effect a media filter (i.e., a filter that relies on mechanical means alone to prevent particles of a given size to penetrate therethrough, thus creating a greater backpressure characteristic.)

One example electrostatic air cleaner is manufactured by Honeywell, which has published a data sheet in 2000 for a model number “F300E” electronic air cleaner. In this data sheet, Honeywell stated that the “fractional efficiency” of the F300E was 70% on 0.3 micron particles at 500 feet per minute (fpm) air velocity.

This Honeywell document also has a chart called

FIG. 1

, which shows air cleaner efficiency and pressure drop at various airflow rates. This

FIG. 1

shows efficiency ratings based upon the National Bureau of Standards “initial dust spot method” using the ASHRAE (American Society of Heating, Refrigerating and Air Conditioning Engineers) standard 52.1-92. When analyzing the airflow rates for the largest filter on this chart, which is 20×25 inches, at a velocity of 500 fpm, the airflow rate would be 1736 cfm (cubic feet per minute). At this airflow rate, the air cleaning efficiency is about 84% at a pressure drop of about 0.11 inches of water column. This would provide a Pressure Adjusted Efficiency (PAE)—which is a new characteristic for air filters created by the present inventors, in which the PAE is equal to the cleaning efficiency divided by the pressure drop-value of 764 (i.e., 84 divided by 0.11).

It is important to note that the above dust spot methodology is referred to as the “initial” dust spot method. This is very important especially with respect to electrostatic air cleaners, since their efficiency drops very quickly once the air cleaning elements begin to accumulate particles. This will be discussed below in more detail.

Another catalog of prior art electrostatic air cleaners has been published by Carrier Corporation in 1999 for an electronic air cleaner sold under the Model Number Series “AIRA” in sizes 012, 014, and 020. The largest filter element in this catalog is a 24½×20¼ filter, Model AIRAAXCC0020. Using the ASHRAE dust spot test, the “performance chart” for this filter at 500 feet per minute air velocity indicates an air cleaning efficiency of about 79% at a backpressure of about 0.07 inches of water column. This would provide a PAE value of about 1128. This very low backpressure specification obviously does not include any pressure drop for ducting, or geometric configuration of the inlet and outlet spaces that bring air to and from the filter element itself.

As can be seen from the above information, particularly the information on the Honeywell F300E air cleaner specifications, it is much easier to obtain a higher cleaning efficiency using the ASHRAE dust spot method than it is for a flow of air containing a single particle size, such as 0.3 micron particles. There are two main reasons for this: in the first place, the ASHRAE dust spot test includes particles of many sizes, a large number of which are greater than 0.3 microns in size; the second reason is that the ASHRAE dust spot test uses particles that often tend to clump together, so that the effective particle size is even larger than the individual particle sizes.

A type of media air filter commonly used in rooms of offices and homes is the HEPA filter, which is specified as having a 99.97% cleaning efficiency for removing particles of 0.3 microns in diameter or larger. This is a standard industry specification, as noted in an EPA publication known as a “EPA-CICA Fact Sheet” for fabric filters of the HEPA and ULPA type. HEPA filters typically have a relatively large surface area per unit volume of air to be cleaned moving therethrough, otherwise the pressure drop (or backpressure) would be very high, and thus require a very large motor for operation. The typical pressure drop for a “clean” filter is about 1 inch of water column. As the filter is used and begins to accumulate dust or dirt particles, the pressure drop will increase, and when it reaches between 2 and 4 inches of water column, that typically indicates the end of the service life of the filter. Some HEPA filters when they are “clean” have lower pressure drops in the range of 0.25-0.5 inches of water column.

HEPA filters are typically operated under a pressure of up to four (4) inches of water column, and higher operating pressures may rupture the filter. HEPA filters are used quite often in cleaning the air of individual rooms, but are not common for a “whole home” air cleaning system. The main reason for this fact is that the air flow through a typical furnace or air conditioner of a typical home is much too large for a HEPA filter of a reasonable size. In other words, the HEPA filter would have to be huge to handle the total amount of volume of air that passes through a typical furnace or air conditioner of a home.

One example of the operating characteristics for a HEPA filter is provided at an Internet website for a company named Airclean in the United Kingdom, having an Internet website domain name of “airclean.co.uk.” According to one of the tables provided at this website, a HEPA filter having a media size 24 inches×24 inches would have a pressure drop of about 0.803 inches of water (200 Pa) at an air velocity of 60 fpm (feet per minute). For this HEPA filter, the PAE characteristic would be a value of about 124.5 (99.97%÷0.803 inches of water).

HEPA-type filters are also used in nuclear environments, although such environments typically require a much greater air cleaning efficiency specification. Consequently, the air flow running through such filter media is generally much slower, and a typical specification is an air velocity of 5 fpm (feet per minute). One paper that describes such filters in some detail is provided in excerpts from the “16

th

DOE Nuclear Air Cleaning Conference, Session 10.” On page 673 of this report, various nuclear HEPA filters running at 5 fpm media velocity exhibit initial pressure drops of between 0.92 and 1.27 inches of water column. Such filters are deemed to come to the end of their useful life when the “final” pressure drop rises to 3 inches of water column. Such nuclear installations have media filters that can literally fill a large room, since they have to handle a very large volume of air (e.g., for an entire nuclear plant office facility). Consequently, such filters are not considered useful for a home or standard office building.

The table on page 680 of the Nuclear Air Cleaning Conference excerpts is quite revealing with respect to the lifetime of the HEPA filter, as well as its change in pressure drop characteristics over time. For example, one of the filters changed in two months from a pressure drop of 1.04 to 1.37 inches of water column, which is a change of about 32% in two months. Two other filters are shown to have changed their pressure drop characteristics over a four month operating time from 1.1 to 1.5 inches of water column, which is a change of about 36% in backpressure characteristics over that four month time span. This is an increase of almost 9% per month in backpressure for this type of filter. A corresponding pressure increase can be expected in other types of HEPA filters and also ULPA filters as well.

HEPA filters require a certain amount of electrical power for fans to blow the air through the media-type filter. Such fans typically require an electric motor that requires about ½ watt to 1 watt per cfm (cubic feet per minute) of fan and air volume movement capacity. When used as a room air cleaner, a typical HEPA filter will circulate about 350 cfm of air volume, for a room about 20 feet×20 feet in area. The electrical power requirement for such a HEPA room air cleaner is typically in the range of 180-200 watts.

Some disadvantages of using HEPA filters as “room” filters are as follows: the HEPA filter is typically noisy, requires a large backpressure for operation, and allows microbes to find their way into the filter and remain there. In situations where microbes are lodged in the filter media, when the filters are changed the microbes can be released into the air. Such filters are often used in confined systems where the air is recirculated, such as in jet aircraft. The microbes will be continually recirculated or will be trapped in the filter media; however, they can still be released into the air when the filter is changed or otherwise “cleaned.”

Another characteristic that can be discussed is the “permeability” of a filter, which represents a percentage of the “void” divided by the percentage of “volume” of a filter medium. For HEPA filters, the permeability is typically less than 1%. This means that the air molecules are much more likely to “bump” into the filter media than to be able to pass through the filter media without some type of impact, thus creating a significant backpressure. In the present invention, the permeability of the filter is much greater. One consequence of the HEPA filter's backpressure characteristic is a substantial noise level generated by the fan, which can be as high as 70 dB for a 20×20 foot room air cleaner.

Accordingly, it is desirable that an apparatus and method of purifying air be developed which is capable of removing particles of a specified size (about 0.1 micron to about 10 microns) in a manner which is adaptable, non-intrusive, and ergonomically compatible. It is also desirable that a fluid, as well as the requisite attributes thereof, be determined for use with the apparatus and method of purifying air which satisfies the electrical and sprayability demands required for use as the spray. It is further desirable to provide a dynamic electrostatic air cleaning apparatus that improves both backpressure and air cleaning characteristics over those of both HEPA filters and electrostatic precipitators.

SUMMARY OF THE INVENTION

Accordingly, it is an advantage of the present invention to provide a dynamic electrostatic air cleaning apparatus that exhibits a substantially high air cleaning efficiency while also exhibiting a substantially low backpressure when air flows therethrough at useful rates for cleaning a whole home, or merely a single room.

It is another advantage of the present invention to provide a dynamic electrostatic air cleaning apparatus that exhibits a substantially high air cleaning efficiency while also exhibiting a substantially low backpressure over a substantial time period of continuous operation without either cleaning or replacing a major component of the apparatus.

It is a further advantage of the present invention to provide a dynamic electrostatic air cleaning apparatus that compares favorably to conventional electrostatic precipitators by exhibiting an air cleaning efficiency greater than 70% at a backpressure of less than 0.2 inches of water column at an air velocity of substantially 2.54 meters per second (500 fpm), when the particles in the inlet air are substantially 0.3 microns in size.

It is yet a further advantage of the present invention to provide a dynamic electrostatic air cleaning apparatus that compares favorably to conventional electrostatic precipitators by exhibiting an air cleaning efficiency greater than 85% at a backpressure of less than 0.1 inches of water column at an air velocity of substantially 2.54 meters per second (500 fpm), when the particles in the inlet air are according to the ASHRAE dust spot test.

It is still a further advantage of the present invention to provide a dynamic electrostatic air cleaning apparatus that compares favorably to conventional HEPA filters by exhibiting an air cleaning efficiency of substantially 99.97% at a backpressure of less than 0.8 inches of water column at an air velocity of substantially 0.4572 meters per second (90 fpm), when the particles in the inlet air are substantially 0.3 microns in size.

It is still another advantage of the present invention to provide an electrostatic air cleaning apparatus that quickly cleans air from an enclosed space by use of electrically charged solid beads or other-shaped particles/objects that attract sub-micron particles entrained in the inlet air, including biohazardous materials, without substantial change to the temperature and humidity of the input air; in this apparatus, the solid beads are not recirculated.

In accordance with a first aspect of the present invention, an apparatus for removing particles from air is disclosed as including at least one inlet for receiving a flow of air, a first chamber in flow (i.e., fluidic) communication with the inlet, wherein a charged spray of semiconducting fluid droplets having a first polarity is introduced to the air flow passing therethrough so that the particles are electrostatically attracted to and retained by the spray droplets, and an outlet in flow communication with the first chamber, wherein the air flow exits the apparatus substantially free of the particles. The first chamber of the apparatus further includes a collecting surface for attracting the spray droplets, a power supply, and a spray nozzle connected to the power supply for receiving fluid, producing the spray droplets therefrom, and charging the spray droplets.

In accordance with a second aspect of the present invention, the apparatus may also include a second chamber in flow communication with the inlet at a first end and the first chamber at a second end, wherein particles entrained in the air flow are charged with a second polarity opposite the first polarity prior to the air flow entering the first chamber. The second chamber of the apparatus further includes a power supply, at least one charge transfer element connected to the power supply for creating an electric field in the second chamber, and a ground element associated with the second chamber for defining and directing the electric field, wherein the air flow passes between the charge transfer element and the ground element.

In accordance with a third aspect of the present invention, the apparatus may further include a fluid recirculation system in flow communication with the first chamber for providing the fluid from the collecting surface to the spray nozzle. The fluid recirculation system includes a device in flow communication with the collecting surface, a reservoir in flow communication with the device, and a pump for providing the fluid to the spray nozzle. The fluid recirculation system may also include a filter positioned between the collecting surface and the pump for removing the particles from the fluid, as well as a device for monitoring the quality of the fluid prior to being pumped to the spray nozzle. A replaceable cartridge may be utilized to house the reservoir, where the cartridge includes an inlet in fluid communication with the collecting surface of the first chamber at a first end and the reservoir at a second end and an outlet in fluid communication with the reservoir at a first end and the pump at a second end.

In accordance with a fourth aspect of the present invention, an apparatus for removing particles from air is disclosed as including at least one defined passage having an inlet and an outlet, wherein each inlet receives a flow of air and the air flow exits the passage at each outlet, and a first area positioned between each inlet and each outlet where a charged spray of semiconducting fluid droplets having a first polarity is introduced within the passage so that particles entrained within the air flow are electrostatically attracted to and retained by the spray droplets. The apparatus further includes a collecting surface associated with the first area of the passage for attracting the spray droplets, as well as a spray nozzle associated therewith for receiving fluid, producing the spray droplets in the first area of the passage, and charging the spray droplets. The apparatus may also include a second area positioned between the inlet and the first area, wherein particles entrained in the air flow are charged with a second polarity opposite the first polarity. The second area includes at least one charge transfer element associated therewith for creating an electric field in the second area of the passage, as well as a ground element associated therewith for defining and directing the electric field in the second area of the passage.

In accordance with a fifth aspect of the present invention, a method of removing particles from air is disclosed as including the steps of introducing a flow of air having particles entrained therein into a defined area and providing a charged spray of semiconducting fluid droplets having a first polarity to the defined area, wherein the particles are electrostatically attracted to and retained by the spray droplets, and attracting the spray droplets to a collecting surface. The method further includes the steps of forming the spray droplets from the fluid and charging the spray droplets. The method preferably includes the step of providing a charge to particles in the air flow at a second polarity opposite of the first polarity. The method may further include one or more of the following steps: filtering the air flow for particles having a size greater than a specified size; monitoring quality of the air flow; filtering the particles from the spray droplets; collecting the spray droplets in an aggregate of the fluid; recirculating the fluid aggregate for use in the spray; and, monitoring quality of the recirculated liquid prior to forming the spray.

In accordance with a sixth aspect of the present invention, a cartridge for use with an air purifying apparatus, wherein a charged spray of semiconducting fluid droplets is introduced to an air flow and collected so as to form a fluid aggregate, is disclosed as including a housing having an inlet and an outlet and a reservoir for retaining the fluid aggregate in flow communication with the inlet at a first end and the outlet at a second end. The cartridge may also include a filter located between the inlet and the reservoir, as well as a pump located between the reservoir and the outlet. The cartridge is configured for the inlet to be in flow communication with the collected fluid aggregate and the outlet to be in flow communication with a device for forming the fluid droplets in the air purifying apparatus. The cartridge housing may function as a collecting surface for the air purifying apparatus and include a spray nozzle associated therewith.

In accordance with a seventh aspect of the present invention, a fluid is disclosed for use as a spray in an air purifying apparatus, wherein particles in an air flow entering the air purifying apparatus are electrostatically attracted to droplets of the spray. The fluid has physical properties which enable a sprayability factor according to a designated algorithm within a specified range, where the sprayability factor is a function of certain physical properties of the fluid which relate to spray droplet size able to be formed and coverage and effectiveness of the spray. Such physical properties of the fluid include flow rate, density, resistivity, surface tension, dielectric constant, and viscosity. The sprayability factor also may be a function of an electric field formed in the air purifying apparatus to which the fluid is introduced. The fluid preferably is semiconducting, nonaqueous, inert, non-volatile and non-toxic.

Additional advantages and other novel features of the invention will be set forth in part in the description that follows and in part will become apparent to those skilled in the art upon examination of the following or may be learned with the practice of the invention. All percentages, ratios and proportions herein are by weight, unless otherwise specified. All temperatures are in degrees Celsius (° C.) unless otherwise specified. All documents cited are in relevant part, incorporated herein by reference.

To achieve the foregoing and other advantages, and in accordance with one aspect of the present invention, an air cleaning apparatus is provided, which comprises: a chamber into which a flow of input air is directed, the input air containing a plurality of particles, the input air becoming a flow of output air after being cleaned within the chamber; at least one nozzle through which a liquid is sprayed into the chamber, the liquid being electrically charged, the liquid becoming separated into a plurality of droplets upon exiting the at least one nozzle; and the chamber being configured to cause the flow of input air and the charged liquid droplets to intermix at an intermix space, wherein the plurality of particles are attracted to the charged liquid droplets, thereby removing a portion of the plurality of particles from the input air, which thus becomes the flow of output air; wherein, when the flow of input air passes through the intermix space of the chamber at an air velocity of substantially 2.54 meters per second (500 fpm), the plurality of particles at substantially 0.3 microns in size is cleaned from the input air at a cleaning efficiency of greater than 70%, at a backpressure of less than 0.2 inches of water column, and without substantial change to a temperature and humidity of the input air.

In accordance with another aspect of the present invention, an air cleaning apparatus is provided, which comprises: a chamber into which a flow of input air is directed, the input air containing a plurality of particles, the input air becoming a flow of output air after being cleaned within the chamber; at least one nozzle through which a liquid is sprayed into the chamber, the liquid being electrically charged, the liquid becoming separated into a plurality of droplets upon exiting the at least one nozzle; and the chamber being configured to cause the flow of input air and the charged liquid droplets to intermix at an intermix space, wherein the plurality of particles are attracted to the charged liquid droplets, thereby removing a portion of the plurality of particles from the input air, which thus becomes the flow of output air; wherein, when the flow of input air passes through the intermix space of the chamber at an air velocity of substantially 2.54 meters per second (500 fpm), the plurality of particles according to the ASHRAE dust spot test is cleaned from the input air at a cleaning efficiency of greater than 85%, at a backpressure of less than 0.1 inches of water column, and without substantial change to a temperature and humidity of the input air.

In accordance with yet another aspect of the present invention, an air cleaning apparatus is provided, which comprises: a chamber into which a flow of input air is directed, the input air containing a plurality of particles, the input air becoming a flow of output air after being cleaned within the chamber; at least one nozzle through which a liquid is sprayed into the chamber, the liquid being electrically charged, the liquid becoming separated into a plurality of droplets upon exiting the at least one nozzle; and the chamber being configured to cause the flow of input air and the charged liquid droplets to intermix at an intermix space, wherein the plurality of particles are attracted to the charged liquid droplets, thereby removing a portion of the plurality of particles from the input air, which thus becomes the flow of output air; wherein, when the flow of input air passes through the intermix space of the chamber at an air velocity of substantially 0.4572 meters per second (90 fpm), the plurality of particles at substantially 0.3 microns in size is cleaned from the input air at a cleaning efficiency of substantially 99.97%, at a backpressure of less than 0.8 inches of water column, and without substantial change to a temperature and humidity of the input air.

In accordance with still another aspect of the present invention, a single-pass air cleaning apparatus is provided, which comprises: a chamber into which a flow of input air is directed, the input air containing a plurality of particles, the input air becoming a flow of output air after being cleaned within the chamber; at least one nozzle through which a plurality of small solid objects are sprayed into the chamber, the solid objects being electrically charged; and the chamber being configured to cause the flow of input air and the charged solid objects to intermix at an intermix space, wherein the plurality of particles are attracted to the charged solid objects, thereby removing a portion of the plurality of particles from the input air, which thus becomes the flow of output air; wherein, when the flow of input air passes through the intermix space of the chamber, a very large portion of the particles exhibiting a sub-micron size are cleaned from the input air without substantial change to a temperature and humidity of the input air, and wherein the solid objects are not recirculated.

In accordance with a further aspect of the present invention, an air cleaning apparatus is provided, which comprises: a chamber into which a flow of input air is directed, the input air containing a plurality of particles, the input air becoming a flow of output air after being cleaned within the chamber; at least one nozzle through which a liquid is sprayed into the chamber, the liquid being electrically charged, the liquid becoming separated into a plurality of droplets upon exiting the at least one nozzle; and the chamber being configured to cause the flow of input air and the charged liquid droplets to intermix at an intermix space, wherein the plurality of particles are attracted to the charged liquid droplets, thereby removing a portion of the plurality of particles from the input air, which thus becomes the flow of output air; wherein, when the flow of input air passes through the intermix space of the chamber, the plurality of particles is cleaned from the input air at a pressure adjusted efficiency (PAE), which represents the cleaning efficiency in percent divided by the backpressure, that does not deviate by more than 25% after two months of continuous use of the air cleaning apparatus.

To achieve the foregoing and other advantages, and in accordance with one aspect of the present invention, an air cleaning apparatus is provided, which comprises: a chamber into which a flow of input air is directed, the input air containing a plurality of particles, the input air becoming a flow of output air after being cleaned within the chamber; at least one nozzle through which a liquid is sprayed into the chamber, the liquid being electrically charged, the liquid becoming separated into a plurality of droplets upon exiting the at least one nozzle; and in which the chamber is configured to cause the flow of input air and the charged liquid droplets to intermix at an intermix space, wherein the plurality of particles are attracted to the charged liquid droplets, thereby removing a portion of the plurality of particles from the input air, which thus becomes the flow of output air; wherein, when the flow of input air passes through the intermix space of the chamber at an air velocity of substantially 2.54 meters per second (500 fpm), the plurality of particles at substantially 0.3 microns in size is cleaned from the input air at a cleaning efficiency of greater than 70%, at a backpressure of less than 0.2 inches of water column, and without substantial change to a temperature and humidity of the input air.

In accordance with another aspect of the present invention, an air cleaning apparatus is provided, which comprises: a chamber into which a flow of input air is directed, the input air containing a plurality of particles, the input air becoming a flow of output air after being cleaned within the chamber; at least one nozzle through which a liquid is sprayed into the chamber, the liquid being electrically charged, the liquid becoming separated into a plurality of droplets upon exiting the at least one nozzle; and in which the chamber is configured to cause the flow of input air and the charged liquid droplets to intermix at an intermix space, wherein the plurality of particles are attracted to the charged liquid droplets, thereby removing a portion of the plurality of particles from the input air, which thus becomes the flow of output air; wherein, when the flow of input air passes through the intermix space of the chamber at an air velocity of substantially 2.54 meters per second (500 fpm), the plurality of particles according to the ASHRAE dust spot test is cleaned from the input air at a cleaning efficiency of greater than 85%, at a backpressure of less than 0.1 inches of water column, and without substantial change to a temperature and humidity of the input air.

In accordance with a further aspect of the present invention, an air cleaning apparatus is provided, which comprises: a chamber into which a flow of input air is directed, the input air containing a plurality of particles, the input air becoming a flow of output air after being cleaned within the chamber; at least one nozzle through which a liquid is sprayed into the chamber, the liquid being electrically charged, the liquid becoming separated into a plurality of droplets upon exiting the at least one nozzle; and in which the chamber is configured to cause the flow of input air and the charged liquid droplets to intermix at an intermix space, wherein the plurality of particles are attracted to the charged liquid droplets, thereby removing a portion of the plurality of particles from the input air, which thus becomes the flow of output air; wherein, when the flow of input air passes through the intermix space of the chamber at an air velocity of substantially 0.4572 meters per second (90 fpm), the plurality of particles at substantially 0.3 microns in size is cleaned from the input air at a cleaning efficiency of substantially 99.97%, at a backpressure of less than 0.8 inches of water column, and without substantial change to a temperature and humidity of the input air.

In accordance with still a further aspect of the present invention, a single-pass air cleaning apparatus is provided, which comprises: a chamber into which a flow of input air is directed, the input air containing a plurality of particles, the input air becoming a flow of output air after being cleaned within the chamber; at least one nozzle through which a plurality of small solid objects are sprayed into the chamber, the solid objects being electrically charged; and in which the chamber is configured to cause the flow of input air and the charged solid objects to intermix at an intermix space, wherein the plurality of particles are attracted to the charged solid objects, thereby removing a portion of the plurality of particles from the input air, which thus becomes the flow of output air; wherein, when the flow of input air passes through the intermix space of the chamber, a very large portion of the particles exhibiting a sub-micron size are cleaned from the input air without substantial change to a temperature and humidity of the input air, and wherein the solid objects are not recirculated.

Still other advantages of the present invention will become apparent to those skilled in this art from the following description and drawings wherein there is described and shown a preferred embodiment of this invention in one of the best modes contemplated for carrying out the invention. As will be realized, the invention is capable of other different embodiments, and its several details are capable of modification in various, obvious aspects all without departing from the invention. Accordingly, the drawings and descriptions will be regarded as illustrative in nature and not as restrictive.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings incorporated in and forming a part of the specification illustrate several aspects of the present invention, and together with the description and claims serve to explain the principles of the invention. In the drawings:

FIG. 1

is a diagrammatic view of a first embodiment for the air purification system of the present invention, where the flow of air into the system crosses the direction of the fluid spray therein;

FIG. 2

is a diagrammatic view of a second embodiment for the air purification system of the present invention, where the flow of air into the system is in substantially the same direction as the fluid spray therein;

FIG. 3

is a diagrammatic view of a third embodiment for the air purification system of the present invention, where the flow of air into the system is substantially opposite to the direction of the fluid spray therein;

FIG. 4

is a diagrammatic view of the air purification system depicted in

FIG. 1

within a defined passage;

FIG. 5

is a cross-sectional view in partial cross-section of the disposable cartridge depicted in

FIG. 4

;

FIGS. 6A

is a top view of an exemplary collecting device utilized with an axisymmetric spray nozzle in a first chamber or area of the air purification system depicted in

FIGS. 1

,

4

and

5

;

FIG. 6B

is a side view in cross-section of the collecting device depicted in

FIG. 6A

;

FIG. 7A

is a top view of an exemplary collecting device utilized with an axisymmetric spray nozzle in a first chamber or area of the air purification system depicted in

FIGS. 1

,

4

and

5

;

FIG. 7B

is a side view in cross-section of the collecting device depicted in

FIG. 7A

;

FIG. 8A

is a top view of an exemplary collecting device utilized with an axisymmetric spray nozzle in a first chamber or area of the air purification system depicted in

FIGS. 2 and 3

;

FIG. 8B

is a side view in cross-section of the collecting device depicted in

FIG. 8A

;

FIG. 9A

is a top view of an exemplary collecting device utilized with an axisymmetric spray nozzle in a first chamber or area of the air purification system depicted in

FIGS. 2 and 3

;

FIG. 9B

is a side view in cross-section of the collecting device depicted in

FIG. 9A

;

FIG. 10

is a side view in cross-section of an exemplary multi-nozzle design for a spray nozzle which may be utilized in the first chamber of the air purification system depicted in

FIGS. 1-4

;

FIGS. 11A-11H

are diagrammatic views of exemplary tube patterns for the multi-nozzle design depicted in

FIG. 10

;

FIG. 12

is a side view in cross-section of a first spray nozzle design utilized in the first chamber of the air purification system including an air assist passage in flow communication with the charging tube;

FIG. 13

is a side view in cross-section of a second spray nozzle design utilized in the first chamber of the air purification system including an air assist passage around the charging tube;

FIG. 14

is a side view in cross-section of a third spray nozzle design utilized in the first chamber of the air purification system including an air assist passage around the charging tube;

FIG. 15

is a diagrammatic perspective view of an air purification system having a plurality of defined passages therein as depicted in

FIG. 4

;

FIG. 16

is a diagrammatic side view of an air purification system where a defined passage has a plurality of collecting electrodes positioned therein;

FIG. 17

is a diagrammatic perspective view of an air purification system like that depicted in

FIG. 1

having a plurality of inlets and an outlet oriented at an angle thereto;

FIG. 18

is a diagrammatic side view of the air purification system depicted in

FIG. 17

to indicate the pattern of the fluid spray therein; and

FIG. 19

is a block diagram of the air purification system depicted in

FIGS. 1-4

, where the flow of air, fluid and charge is indicated therein.

FIG. 20

is a graph of pressure drop vs. air flow rate using computer modeling data of a 10 inch×4 inch×2 inch air cleaner constructed according to the principles of the present invention.

FIG. 21

is a graph of air cleaning efficiency vs. particle size using computer modeling data of a 10 inch×4 inch×2 inch air cleaner constructed according to the principles of the present invention.

FIG. 22

is a graph of air cleaning efficiency vs. collector droplet diameter using computer modeling data of a 10 inch×4 inch×2 inch air cleaner constructed according to the principles of the present invention.

FIG. 23

is a graph of collector liquid flow rate vs. collector droplet diameter using computer modeling data of a 10 inch×4 inch×2 inch air cleaner constructed according to the principles of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

Reference will now be made in detail to the present preferred embodiment of the invention, an example of which is illustrated in the accompanying drawings, wherein like numerals indicate the same elements throughout the views.

While particular embodiments and/or individual features of the present invention have been illustrated and described, it would be obvious to those skilled in the art that various other changes and modifications can be made without departing from the spirit and scope of the invention. Further, it should be apparent that all combinations of such embodiments and features are possible and can result in preferred executions of the invention.

As seen in

FIG. 1

, an apparatus

10

for purifying air includes a housing

12

having an inlet

14

and an outlet

16

. It will be seen that inlet

14

is configured to receive an air flow designated generally by reference numeral

18

. Air flow

18

is considered to be dirty air in the sense that it includes certain particles (identified by reference numeral

20

) therein that are within a specified size range (approximately 0.1 micron to approximately 10 microns). A filter

22

is preferably included adjacent inlet

14

in order to prevent particles greater than the specified size from entering apparatus

10

. A sensor

23

may also be located adjacent inlet

14

for monitoring the quality of air entering apparatus

10

.

More specifically, apparatus

10

includes a first chamber or defined area

24

in flow communication with inlet

14

in which a charged spray

26

of semiconducting fluid droplets

28

having a first polarity (i.e., positive or negative) is introduced to air flow

18

passing therethrough to outlet

16

. Spray droplets

28

are preferably distributed in a substantially homogenous manner within first chamber

24

so that particles

20

become electrostatically attracted to and retained by spray droplets

28

. It will be seen that first chamber

24

includes a first device (e.g., a nozzle) for forming spray droplets

28

from a semiconducting fluid

30

supplied thereto and a second device (e.g., an electrostatically-charged member) for charging such spray droplets

28

. It will be appreciated, however, that the charging device may perform its function either prior or subsequent to formation of spray droplets

28

by the first device.

Preferably, a spray nozzle

34

connected to a power supply

36

(approximately 18 kilovolts) is provided to serve the function of the first and second devices so that it receives the semiconducting fluid, produces spray droplets

28

therefrom, and charges such spray droplets

28

. A collecting surface

38

spaced a predetermined distance from spray nozzle

34

is also provided in first chamber

24

to attract spray droplets

28

, as well as particles

20

retained therewith. In this way, particles

20

are removed from air flow

18

circulating through apparatus

10

. It will be appreciated that collecting surface

38

is either grounded or charged at a second polarity opposite the first polarity of spray droplets

28

to enhance attraction thereto. In order for apparatus

10

to perform in an effective manner, the charge on spray droplets

28

is preferably maintained until striking collecting surface

38

, whereupon such charge is neutralized.

Apparatus

10

preferably includes a second chamber or defined area

40

in flow communication with inlet

14

at a first end and first chamber

24

at a second end, wherein particles

20

entrained in air flow

18

are charged with a second polarity opposite the first polarity of spray droplets

28

prior to air flow

18

entering first chamber

24

. In order to provide such charge, an electric field in second chamber

40

is preferably created by at least one charge transfer element

42

(e.g., a charging needle) connected to a power supply

44

(providing, for example, approximately 8.5 kilovolts). While charge transfer element

42

may be oriented in any number of directions, it is preferred that it be mounted within second chamber

40

so as to be substantially parallel to air flow

18

. This may be accomplished as shown in

FIG. 4

by a central support element

46

extending across second chamber

40

. It will be appreciated that central support element

46

may be configured in any number of ways so long as it provides the required support for charge transfer element

42

and permits air flow

18

to move unencumbered through second chamber

40

.

Second chamber

40

further includes a ground element

48

associated therewith for defining and directing the electric field created therein. It will be appreciated that air flow

18

passes between charge transfer element

42

and ground element

48

. A collecting surface may also be associated with second chamber

40

, where such collecting surface could be charged by charge transfer element

42

so as to be of opposite polarity to spray droplets

28

and thereby create an attraction. In order to better effect the charge on particles

20

, a device may be provided in second chamber

40

for creating a turbulence in air flow

18

therein.

Turning back to first chamber

24

, it will be understood that various configurations and designs may be utilized for spray nozzle

34

and collecting surface

38

, but they should be matched so as to maintain a substantially uniform electric field in first chamber

24

. Accordingly, when spray nozzle

34

is axisymmetric, collecting surface

38

preferably takes the form of a ring washer, a funnel, a perforated disk, or a cylinder of wire mesh as shown in

FIGS. 6-9

, respectively. It will be understood that collecting surface

38

preferably is a solid plate, solid bar, or perforated plate design when spray nozzle

38

is linear.

Another exemplary design for spray nozzle

34

is one where a multi-nozzle configuration is utilized. This may take the form of a Delrin body

52

with a plurality of spray tubes

54

in flow communication with such Delrin body

52

at a first end and first chamber

24

at a second end (see FIG.

10

). It will be appreciated that any number of flow patterns may be provided by spray nozzle

34

when employing a multi-nozzle design as shown, for example, in

FIGS. 11A-11H

.

It will be appreciated that spray droplets

28

may be produced in various ways from fluid

30

. Since a high relative velocity is required between fluid

30

to be atomized and the surrounding air or gas, this can be accomplished by discharging fluid

30

at high velocity into a relatively slow moving stream of air or gas or exposing a relatively slow moving fluid to a high velocity air stream. Accordingly, those skilled in the art will understand that pressure atomizers, rotary atomizers, and ultrasonic atomizers may be utilized. Another device involves a vibrating capillary to produce uniform streams of drops. As seen in

FIGS. 12-14

, the present invention contemplates the use of air-assist type atomizers. In this type of spray nozzle, semiconducting fluid

30

is exposed to a stream of air flowing at high velocity. This may occur as part of an internal mixing configuration where the gas and fluid mix within the nozzle before discharging through the outlet orifice (see

FIGS. 12 and 13

) or an external mixing configuration where the gas and fluid mix at the outlet orifice (see FIG.

14

).

While each spray nozzle configuration preferably includes a main conduit

51

through which the semiconducting fluid flows to an outlet orifice

53

, as well as a charging element

55

connected to main conduit

51

for providing the desired charge to fluid/spray droplets

28

therein, it will be seen that a passage

57

also provides air to spray nozzle

34

. In

FIG. 12

, passage

57

is in direct flow communication with main conduit

51

so as to mix fluid and air before exiting outlet orifice

53

.

FIGS. 13 and 14

depict passage

57

as being in flow communication with an internal cavity

59

, whereupon the air provided therethrough is mixed with the fluid in either a separate cavity

61

before exiting outlet orifice

53

(

FIG. 13

) or as fluid is exiting outlet orifice

53

via separate passages

63

in flow communication with internal cavity

59

and located adjacent to outlet orifice

53

(FIG.

14

). An exemplary spray nozzle utilizing air assistance is one designated as Model SW750 manufactured by Seawise Industrial Ltd.

Regardless of the configuration for spray nozzle

34

and collecting surface

38

, it will be understood that spray droplets

28

are preferably distributed in a substantially homogeneous manner within first chamber

24

. It has been determined that spray droplets

28

preferably should enter first chamber

24

at substantially the same velocity as air flow

18

. Spray nozzle

34

may also be oriented in different manners so that spray droplets

28

flow in a direction substantially the same as the direction of air flow

18

(see FIG.

2

), substantially opposite to the direction of air flow

18

(see FIG.

3

), or at an angle (e.g., substantially perpendicular) to the direction of air flow

18

(see FIG.

1

). The size of spray droplets

28

is an important parameter relative to the size of particles

20

. Accordingly, spray droplets

28

preferably have a size in a range of approximately 0.1-1000 microns, more preferably in a range of approximately 1.0-500 microns, and most preferably in a range of approximately 10-100 microns.

One design consideration should be the charge density that is imparted to the droplets: while a higher charging voltage at the nozzle

34

will likely further ensure that droplets will successfully be formed at the nozzle's exit, it normally is best to not use a voltage magnitude that will tend to cause the droplets to become very tiny (e.g., below 0.1 microns). Very tiny droplets may tend to be entrained in the air flow, and may thereby completely miss the “target” collecting surface

38

. Of course, this would have two negative consequences: (1) such droplets would remove no particulates, and (2) the operating fluid would vanish over time. Furthermore, very tiny droplets may not be able to “grab” onto particles greater than a certain size, although very small particles would almost always be removed even by very tiny droplets.

In

FIG. 1

, outlet

16

of housing

12

is in flow communication with first chamber

24

so that air flow directed therethrough (designated by arrow

56

) is substantially free of particles

20

. A filter

58

may also be provided adjacent outlet

16

in order to remove any spray droplets

28

which are not attracted by collecting surface

38

in first chamber

24

. A sensor

60

is preferably provided at outlet

16

for monitoring the quality of air flow

56

upon exiting apparatus

10

. Moreover, in order to balance efficiency of apparatus

10

with the ability to substantially remove particles

20

from air flow

18

, it will be appreciated that air flow

18

have a predetermined rate of flow through apparatus

10

. To better maintain a desired flow rate, inlet

14

and/or outlet

16

also may include a device

62

or

64

, such as a fan, to assist in pushing or drawing air flow

18

from inlet

14

through first and second chambers

24

and

32

, respectively.

A control unit

50

(see

FIG. 4

) is provided in order to operate apparatus

10

, and, more specifically, power supply

36

, power supply

44

, fan

62

, and fan

64

. Additionally, control unit

50

is connected to sensor

60

for monitoring the quality of air exiting apparatus

10

and to a sensor

76

for monitoring the quality and flow rate of fluid

30

recirculated through a fluid recirculation system

66

.

It will also be seen from

FIGS. 1-4

that a fluid recirculation system

66

is preferably in flow communication with collecting surface

38

so as to capture fluid

30

aggregated from spray droplets

28

and provide it back to spray nozzle

34

for continuous use. In particular, fluid recirculation system

66

includes a device for collecting fluid

30

from collecting surface

38

and a wall

67

, defining first chamber

24

. This fluid collection mechanism preferably is incorporated into collecting surface

38

, as exemplified by the openings in the configurations depicted in

FIGS. 6-9

. Fluid recirculation system

66

also includes a reservoir

70

in flow communication with device for storing fluid

30

(aggregated at collecting surface

38

from spray droplets

28

) and a pump mechanism

72

for providing such fluid

30

to spray nozzle

34

.

It will be appreciated that fluid recirculation system

66

also preferably includes a filter

74

positioned between collecting surface

38

and spray nozzle

34

for removing particles

20

from fluid

30

. This assists in keeping fluid

30

more pure and prevent possible occlusion in spray nozzle

34

. A device

76

may be provided in association with filter

74

to monitor the quality of fluid

30

prior to being pumped to spray nozzle

34

, whereby device

76

is able to indicate when such fluid

30

should be replaced.

In a preferred embodiment of fluid recirculation system

66

depicted in

FIG. 5

, a disposable cartridge

78

is utilized to house at least a portion thereof. This permits semiconducting fluid

30

used for spray droplets

28

to be easily replaced when desired. More specifically, cartridge

78

includes a housing

80

having an inlet

82

in flow communication with collecting surface

38

at a first end and reservoir

70

at a second end. An outlet

84

is also provided in cartridge housing

80

which is in flow communication with reservoir

70

at a first end and pump mechanism

72

at a second end. As seen in

FIG. 5

, a filter

74

may be contained within cartridge housing

80

so that fluid

30

flows therethrough prior to entering reservoir

70

. Alternatively, filter

74

may be positioned so that fluid

30

first enters reservoir

70

. It will be appreciated that monitoring device

76

may or may not be included within cartridge

78

, but should be positioned upstream of pump mechanism

72

. If provided with cartridge

78

, monitoring device

76

preferably will indicate when fluid

30

therein should be replaced. Inlet

82

and outlet

84

of cartridge housing

80

each are shown to have a cap portion

86

and

88

, respectively, which extends from housing

80

and preferably has a self-sealing membrane

90

covering a passage

92

and

94

through each respective cap portion.

Preferably, cartridge

78

is configured so that inlet

82

is in flow communication with fluid

30

aggregated by collecting surface

38

. Indeed, a portion of housing

80

may itself function as collecting surface

38

. Likewise, cartridge

78

will preferably be configured so that outlet

84

is in flow communication with spray nozzle

34

or a spray nozzle integral therewith. An opening

96

with a corresponding removable plug member

98

is preferably provided in housing

80

so that fluid

30

is permitted to be drained from reservoir

70

when considered too dirty or impure. New fluid can also be replaced in reservoir

70

by such means.

It will be appreciated that a pump (identified in phantom by reference numeral

100

in

FIG. 5

) may be positioned within cartridge

78

to assist in moving fluid

30

through outlet

84

. It is also oppional for a switch

102

to be integrated with cartridge

78

so that apparatus

10

will not operate when a cartridge is not positioned therein. Similarly, cartridge

78

may be configured in a specified way so that only cartridges having such configuration are identified as being acceptable for use.

It has been found that apparatus

10

, and particularly the size, density and charge of spray droplets

28

formed in first chamber

24

by spray nozzle

34

, is preferably designed so as to satisfy an efficiency design parameter EDP within a specified range. Present experience has found that an efficiency design parameter within a range of approximately 0.0-0.6 is acceptable, while a range of approximately 0.0-0.3 is preferred and a range of approximately 0.0-0.15 is considered optimal. This efficiency design parameter is preferably calculated as a function of several parameters. The first component is a charge dependent parameter CDP calculated by the following formula when both particles

20

and spray droplets

28

are charged (i.e., K=1):

CDP

=10

aL+bL−cL−dL+25.45

When only spray droplets

28

are charged (K=−1), then the charge dependent parameter is preferably calculated by the following:

CDP

=[(10

2*aL+2*bL−PL−dL+18.26

)

0.4

]+1

where

a=charge per unit area of the electrostatically sprayed particles

20

(units of coulombs per square centimeter)

b=charge of particles

20

to be collected (units of coulombs)

c=diameter of particles

20

to be collected (units of microns)

d=relative velocity between particles

20

and spray droplets

28

(units of meter per second)

P=diameter of spray droplets

28

(units of microns) It will be appreciated that aL, bL, cL, dL and PL are the logarithms of the aforementioned respective variables.

A second component of efficiency design parameter EDP is a dimensionless parameter N

D

which is preferably calculated according to the following formula:

N

D

=P

3

Q

/(−1.910×10

12

+P

3

Q

)

where

P=diameter of spray droplets

28

(units of microns)

Q=number of spray droplets

28

(units of particles per centimeter cubed)

The efficiency design parameter EDP is then preferably determined from the following equation:

EDP

=exp[(

N

D

×CDP×W

×38100)/(

P×Z

)]

where

N

D

=dimensionless parameter

CDP=charge dependent parameter (dimensionless)

W=linear distance in direction of air flow

18

from the point the air first contacts the spray to the point where air exits the spray (units of inches)

P=diameter of spray droplets

28

(units of microns)

Z=a velocity dependent parameter (dimensionless)

It will be appreciated that velocity dependent parameter Z is equal to one when air flow

18

moves in either substantially the same direction as or substantially opposite to the flow direction of spray droplets

28

. Should the flow of spray droplets

28

be at an angle to air flow

18

, velocity dependent parameter Z is determined as:

Z

=cos [arctan (

V

2

/V

1

)].

In order to appreciate better how calculation of efficiency design parameter EDP is performed, an exemplary calculation is determined where removal of 1 micron aerosol particles from an air flow using a spray of electrostatically charged 10 micron spray droplets having a density of 500 particles/cm

3

is desired. The aerosol particles enter the spray in air that has a speed of 2.1 meters per second. The spray droplets travel to collecting surface

38

at a speed of 2 meters per second and their travel is in the same direction as air flow

18

. The aerosol particles

20

are corona charged in second chamber

40

prior to entering spray

26

and have a charge of 6×10

−17

coulomb. Electrostatically charged spray droplets

28

have a charge per unit area of 9.5×10

−9

coulomb per square centimeter and spray

26

extends over a distance of 2 inches.

With regard to the information supplied for the example above,

P = 10

PL = 1.0

Q = 500

W = 2

Z = 1

a = 1.7 × 10

−8

C/cm

2

aL = −7.77

b = 6 × 10

−17

C

bL = −16.22

c = 1 μm

cL = 0

d = 0.1 m/s

dL = −1

K = +1

CDP = 10

aL+bL−cL−dL+25.45

= 281

N

D

= −2.62 × 10

−7

EDP = exp [{(−2.62 × 10

−7

) × (281) × (2) × 38100} /

{(10) × (1)}] = 0.57

While the design in the aforementioned example is considered to be within an acceptable range, it will be seen that modifications to such example where the spray density is 2000 particles per centimeter cubed and the spray droplets are 30 microns in size enable the charge dependent parameter CDP to be 162 and the dimensionless parameter N

D

to be −2.83×10

−5

. Accordingly, the efficiency design parameter EDP is calculated as being equivalent to 9×10

−5

, which is considered to be in the optimum range.

With regard to semiconducting fluid

30

utilized with the present invention, such fluid is preferably non-aqueous in order that spray droplets

28

formed therefrom are able to sustain the applied charge for a sufficient residence time (i.e., before striking collecting surface

38

). Additionally, such fluid

30

should preferably be inert, non-volatile and non-toxic for obvious safety reasons. It has been found that such fluid should exhibit certain physical characteristics which enable it to be formed into spray droplets

28

of the desired size, provide the desired spray coverage within first chamber

24

, and function effectively in attracting and retaining particles

20

as determined by calculation of the efficiency design parameter EDP.

Taking into account the desired functionality of fluid

30

as spray droplets

28

, a formulation has been determined which measures what is known herein as a sprayability factor SF for a given fluid. First, a characteristic length CL of the fluid is determined from the following:

CL

=[{(

PFS

)

2

×(

ST

)}/{(

D

)×(1

/R

)

2

×(10

7

)}]

⅓

.

Next, a characteristic flow rate CFR of the fluid is determined from the following:

CFR

=[{(

PFS

)×(

ST

)}/{(

D

)×(1

/R

)×(10

5

)}]

and a property dependent parameter PDP is determined from the following:

PDP

=[{(

ST

)

3

×(

PFS

)

2

×(6×10

3

)}/{(

V

)

3

×(1

/R

)

2

×(

FR

)}]

⅓

.

Then, should the property dependent parameter PDP be less than 1, the sprayablility factor SF is calculated from the following equation:

SF

=[log(

CL

)+log[(1.6)×((

RDC

)−1)

⅙

×[(

FR

)/{(

CFR

)×(6×10

7

)}]

⅓

−((

RDC

)−1)

⅓

]].

If the property dependent parameter PDP is greater than

1

, the sprayability factor SF is calculated from the following equation:

SF

=−[log(

CL

)+log[(1.2)×{[(

FR

)/{(

CFR

)×(6×10

7

)}]

½

}−0.3]

It will be understood that the parameters identified in the above equations are as follows:

FR =flow rate (units of milliliters per minute)

D=density of liquid (units of kilograms per liter)

RDC=relative dielectric constant of fluid (dimensionless)

R=resistivity (units of ohm centimeters)

ST=surface tension of fluid (units Newtons per meter)

PFS=permittivity of free space (units of F/m)

V=viscosity of the liquid (units of Pascuals)

In conjunction with the above formulas, it has been found that an acceptable range for the sprayability factor SF is approximately 2.4-7.0, a preferred range for the sprayability factor SF is approximately 3.1-5.6, and an optimal range for sprayability factor SF is approximately 4.0-4.9.

In order to better appreciate the calculation of sprayability factor SF, an exemplary calculation follows for the spraying of propylene glycol (PG) at a flow rate of 0.3 mL/min. Propylene glycol has a density of 1.036 kg/L, a viscosity of 40 mPas, a surface tension of 38.3 mN/m, a resistivity of 10 Megaohm cm and a dielectric constant of 32. According to the foregoing equations, the characteristic length CL is calculated to be 3.045×10

−6

, the characteristic flow rate CFR is calculated to be 3.19×10

−11

, and the property dependent parameter PDP is calculated to be 5.03×10

−2

. Since the PDP is less than one, the first equation for the sprayability factor SF is utilized and is determined to be 4.4 (in the optimal range). It will be appreciated that if the flow rate is increased to 3 mL/min, the sprayability factor SF is calculated to be 4.0, which is still within the optimal range of values.

In accordance with the above formulation, it has been found that preferred ranges for the indicated parameters are: viscosity of the fluid (V) has a range of approximately 1-100 milliPascals; surface tension of the fluid (ST) has a range of approximately 1-100 milliNewtons per meter; resistivity of the fluid (R) has a range of approximately 10 kilohm-50 Megaohm and a preferred range of approximately 1-5 Megahom; and the electric field (E) is approximately 1-30 kilovolts per centimeter. The relative dielectric constant of fluids (RDC) preferred range is from 1.0 to 50.

Upon consideration of the above formulations and the requirements of fluid

30

to be utilized as spray

26

, it has been found that the following class of fluids may be utilized: oils, silicones, mineral oil, cooking oils, polyols, polyethers, glycols, hydrocarbons, isoparafines, polyolefins, aromatic esters, aliphatic esters, fluorosurfactants, and mixtures thereof.

Of such fluids, it is preferred that the following types be utilized in apparatus

10

: glycols, silicones, ethers, hydrocarbons and their substituted or unsubstituted oliogomers with molecular weight less than 400, and mixtures thereof. More preferred are the following: diethylene glycol monoethyl ether, triethylene glycol, tetraethylene glycol, tripropylene glycol, butylene glycol, and glycerol. It has also been found that certain mixtures containing such fluids is preferred in the following amounts: (1) 50% propylene glycol, 25% tetraethylene glycol, and 25% dipropylene glycol; (2) 50% tetraethylene glycol and 50% dipropylene glycol; (3) 80% triethylene glycol and 20% tetraethylene glycol; (4) 50% tetraethylene glycol and 20% 1,3 butylene glycol; and (5) 90% dipropylene glycol and 10% transcutol CG (diethylene glycol monomethyl ether).

In order to better appreciate the process of the present invention, the charge flow, fluid flow, and air flow within apparatus

10

are depicted in

FIG. 19

by arrows of the following convention: bold arrows indicate charge flow; solid arrows indicate fluid flow; and, expanded arrows indicate air flow. In the preferred embodiment, it will be seen that air flow

18

passes through inlet

14

into second chamber

40

, where particles

20

therein are charged at a desired polarity. Such air flow

18

is preferably filtered at inlet

14

by filter

22

so that particles therein having a size greater than about 10 microns are separated therefrom prior to entering second chamber

40

. Air flow

18

may also be caused to have a turbulence within second chamber

40

so as to enhance the charging of particles

20

. Air flow

18

then enters first chamber

24

and interfaces with spray droplets

28

therein so that particles

20

are electrostatically attracted thereto and removed from air flow

18

. Finally, air flow

56

exits first chamber

24

and flows through outlet

16

. Air flow

56

may again be filtered by filter

58

and the quality thereof is monitored by sensor

60

so as to determine the effectiveness of apparatus

10

.

With regard to charge flow, it will be seen from

FIG. 19

that a charge having a desired polarity (opposite to that of spray droplets

28

) is provided to particles

20

in second chamber

40

by means of charge transfer element

42

and power supply

44

. A charge having a polarity opposite that of the charge placed on particles

20

is provided to fluid

30

or spray droplets

28

by spray nozzle

34

and power supply

36

either before or after formation of spray droplets

28

. Particles

20

are then attracted to spray droplets

28

and carried to collecting surface

38

in first chamber

24

, whereupon the respective charges on particles

20

and spray droplets

28

are neutralized.

It will be seen in

FIG. 19

that semiconducting fluid

30

is provided to spray nozzle

34

so that spray droplets

28

are formed and provided into first chamber

24

as spray

26

. Thereafter, spray droplets

28

are attracted to collecting surface or element

38

, where they are preferably collected to form a fluid aggregate and recirculated to spray nozzle

34

via fluid recirculation system

66

. This involves fluid

30

being collected in reservoir

70

and provided to spray nozzle

34

by pump mechanism

72

. As shown in

FIG. 19

, it is preferred that such fluid

30

have particles

20

filtered therefrom by filter

74

and the quality of such fluid

30

monitored by fluid quality monitor device

76

prior to entering pump mechanism

72

.

One of the characteristics of air filters is the permeability, which as described above represents a percentage of the void divided by the percentage of the volume of a filter medium. In the present invention, the permeability is typically greater than 97%. This compares very favorably with that of a HEPA filter, in which the permeability is less than 1%. It is thus easy to see why the present invention has a much lower backpressure characteristic than any type of HEPA filter at the same air velocity through the filter.

Another important aspect of the present invention is its very low noise which is generated by the fan blowing air therethrough. Since the backpressure is relatively insignificant in the present invention, the noise of the fan and its associated motor will typically be in the range of 30-40 dB. For small installations, this noise specification would even be less. In situations where the present invention is installed in the inlet or outlet of a furnace for a home, then there would be no separate fan/motor set required, and the blower fan for the furnace or air conditioner would be all that is required. The backpressure (or pressure drop) specification for the present invention would compare very favorably with that of conventional electrostatic air filters that are also installed in furnaces or air conditioners for homes.

The present invention can use virtually any type of nozzle, although one preferred nozzle would be the size of a capillary, in which a plurality of such nozzles would be used for the nozzle unit

34

. The droplets can be formed in various sizes, although the size of the actual capillary is not necessarily determinative of the droplet size. Once the droplets are formed with an electrostatic charge on their surface, they will tend to travel very quickly between the nozzle and the collector element

38

. If the distance between the nozzle

34

and the collector element

38

is, for example, about four inches, then it is preferred that the droplets travel the entire four inch-distance before the electrical charge is dissipated. It is best if the travel time is in the order of magnitude of several tenths of a second maximum, and therefore, the fluid used to create the droplets should have a relaxation time that is in the same order of magnitude. It would be preferred for the relaxation time specification of the fluid to be at least several tenths of a second, or even as much as one second. Thus a semiconductive fluid is preferred, as discussed above.

The present invention truly acts as a “dynamic” liquid electrostatic filter. As the liquid is recirculated, its surface (as droplets) is renewed and it will continue to attract dust or dirt particles by virtue of its electrostatic charge on the surface, even after each of the droplets has already received other dirt or dust particles from earlier operation of the unit. It will take a fairly lengthy amount of time before the semiconductive fluid is finally saturated with dirt or dust such that it would become less effective. For one of the preferred fluids, the time frame by which the filter could be continuously used before becoming saturated with dirt or dust particles is on the order of 4-6 months of continuous operation.

Another beneficial characteristic of the present invention is that its operation as an air filter does not substantially change the air temperature or the air humidity as the air is being cleaned when it passes through the filter. This is quite the opposite of some military air filters that literally incinerate the incoming air at 3000° F., after which that air has to be substantially cooled before being permitted to recirculate back into the spaces where humans are operating.

As will be seen below, the air cleaner of the present invention compares favorably with both electrostatic precipitator-type air filters and with HEPA-type filters. In fact, the present invention substantially fills the void between these two extremes of air filter types by operating successfully between the backpressure specifications and the cleaning efficiency specifications of electrostatic air filters and HEPA air filters.

While many electrostatic air filters are rated at an air velocity of about 500 fpm (feet per minute), they have a pressure drop typically greater than 0.2 inches of water column when cleaning particles at about 0.3 microns in size. As described above, the cleaning efficiency of such electrostatic air filters is typically 70% or less under these conditions. In contrast, the present invention can operate at an air velocity of 500 fpm (which is equal to about 2.54 meters per second) and will generate a backpressure of much less than 0.2 inches of water column with a cleaning efficiency that is greater than 70% when cleaning particles of 0.3 microns in size in the inlet air.

Electrostatic air filters will typically show a greater air cleaning efficiency when used with the ASHRAE dust spot test such that, at the same 500 fpm air velocity, the cleaning efficiency will typically be around 84% at a lower backpressure, as compared to using particles of 0.3 microns in size. The present invention nevertheless compares favorably, and under the conditions of an ASHRAE dust spot test, the present invention will have a cleaning efficiency much greater than 85% at a backpressure of less than 0.1 inches of water column when the air velocity is 2.54 meters per second (equal to 500 fpm).

Another important characteristic of the present invention is that its air cleaning efficiency specification will not substantially decrease for several months, which is in complete contrast to electrostatic air cleaners whose air cleaning efficiency drops off significantly under similar operating time periods, sometimes dropping off significantly after only a few days of operation. Moreover, the present invention will not increase its backpressure characteristic by a significant amount over several months of operation. Typically, the backpressure and air cleaning efficiency characteristics change by less than 10% over sixty days of continuous operation of the air cleaner of the present invention.

With regard to HEPA filters, they are typically rated at an air velocity of about 90 fpm (which is equal to 0.4572 meters per second), with a dirt or dust particle size of 0.3 microns diameter, and at a cleaning efficiency of 99.97%. Most HEPA filters at this air velocity have a backpressure that is greater than one inch of water column. In contrast, the present invention can operate at an air velocity of 90 fpm, at a cleaning efficiency of substantially 99.97% with particle sizes of 0.3 microns, and the backpressure will be less than 0.8 inches of water column. On top of this, the air moving through the filter of the present invention will not substantially change as to its temperature and humidity characteristics.

In an alternative embodiment of the present invention, solid “beads” instead of liquid droplets can be projected from a “spray” nozzle into a “mixing chamber” such as the first chamber

24

to impact or come within close proximity of particles in incoming air. These solid beads could be electrostatically charged just before they are output from some type of spray nozzle or plurality of spray nozzles, such as the element

34

in FIG.

1

. These solid beads would be of an electrically semiconductive material or an insulative material so that they could be electrostatically charged and retain that charge until the beads reach a collecting surface, or more appropriately a collecting box or trough, instead of a flat collecting surface such as the surface

38

in FIG.

1

.

When using the solid beads as the electrostatically charged material that will attract the dirt or dust particles from the incoming air, the system would not be a recirculating system, but instead would be more useful as a “one-time” use or “single-use” system for cleaning air. When the solid beads have been accumulated in a collecting trough or box (or any other type of chamber), then these solid beads could be disposed of. This would be particularly useful for removing some type of sub-micron size of dangerous microbes or biohazardous materials from the air.

It is contemplated by the inventors that such a system of cleaning biohazardous or otherwise dangerous particles from air would be very useful in hospitals or in military installations, and that sufficient numbers of solid beads would be supplied so that a particular room could be sealed off, the air cleaning system started, and then the solid beads dispensed through the nozzles

34

at a high rate (and high density) for a sufficient number of minutes until virtually all of the air in the room had been circulated at least two or three times, thereby removing the biohazard.

The present invention has been tested both in prototypical form and using computer modeling. Some of the test data from the computer modeling scenario is presented in

FIGS. 20-23

, in which a filter having dimensions of about 10 inches×4 inches×2 inches was the test subject.

FIG. 20

illustrates a graph of pressure drop in inches of water column versus airflow rate in cubic feet per minute. With a filter cross-section of 10 inches×4 inches, 100 cfm is equivalent to 360 fpm (feet per minute) air velocity, 200 cfm is equal to 720 fpm, 300 cfm is equal to 1080 fpm, and 400 cfm is equal to 1440 fpm.

In

FIG. 20

, the curve

200

shows the pressure drop at these airflow rates as indicated, and it is important to note that this computer-modeled data refers to the pressure drop across the filter element itself, and does not include any additional pressure drops due to ducting, or inlet and outlet configurations, above those of the filter itself. Of course, the use of the term “filter media” in the present invention essentially refers to the first chamber

24

, as seen on

FIG. 1

, for example. In other words, there is no solid filter media involved, but instead the filter media consists of an open chamber or volumetric space that has liquid droplets passing therethrough.

The computer modeled data of

FIG. 20

used a charged droplet size of 30 microns diameter, and a droplet density of 3,000 drops per cubic centimeter.

FIG. 21

is a chart showing the air cleaning efficiency versus particle size of the particulate matter that is entrained in the incoming air. The curve

202

indicates that the efficiency is nearly 100% using a particle size in the range of 0.1 microns through 100 microns. HEPA filters are tested at 0.3 micron particle size, while electrostatic precipitator-type filters are tested at certain particle sizes (such as 0.3 microns), or are more often tested using the ASHRAE dust spot test.

FIGS. 22 and 23

are further data from the computer modeling used with the present invention. This is an example of the present invention used as a room air cleaner, in which the air velocity through the filter (i.e., the first chamber

24

) is 2.1 meters per second (which translates to an air velocity of about 414 fpm), and a droplet velocity being discharged from the spray nozzle

34

of 2.0 meters per second (about 394 fpm). The filter size is again 10 inches×4 inches×2 inches, so at this air velocity of 2.1 meters per second, the clean air delivery rate (CADR) is approximately 110 cfm (cubic feet per minute).

Referring now to

FIG. 22

, the graphs

210

,

212

, and

214

represent different densities of droplets per cubic centimeter. Graph

210

is 1,000 droplets per cubic centimeter (cc), while graph

212

is 2,000 droplets per cc and graph

214

is 3,000 droplets per cc. The Y-axis represents the “cloud collection efficiency” (i.e., the air cleaning efficiency), while the X-axis represents the “collector droplet diameter” in microns. As can be seen from

FIG. 22

, the denser the number of droplets, the greater the efficiency when the droplet diameter is less than 30 microns. However, if the droplet diameter is greater than 30 microns, the efficiencies are essentially equal regardless of the density of droplets. Of course, the greater the density of droplets, the more liquid that must be discharged through the spray nozzle

34

per unit of time.

FIG. 23

has corresponding curves

220

,

222

, and

224

which represent different numbers of droplets per cubic centimeter. Curve

220

represents 1,000 droplets per cc, while curve

222

is for 2,000 droplets per cc and curve

224

is for 3,000 droplets per cc. The Y-axis is the “flow rate” in liters per minute of the liquid being passed through the spray nozzle

34

, while the X-axis represents the “collector droplet diameter” in microns.

As can be seen in

FIG. 23

, the greater the density of droplets per volume, the greater the flow rate, which of course must be true. As the collector droplet diameter decreases, then so does the flow rate, even if the density of droplets is maintained at a constant value.

Further information not found in the graphs of

FIGS. 20-23

is provided below in tabular form. In the first example, the computer modeling data for the present invention shows particle diameter (in meters), particle collection efficiency, and particle “escapees” (which in essence is “1—collection efficiency”) for a duct air velocity of 5 meters per second (about 984 feet per minute), at three different droplet densities. The 5 meter/second air velocity in a duct is typical for whole house HVAC systems. This data is provided in three different tables, referred to herein as TABLES #1 through #3, for drop densities of 1000 drops per cc, 2000 drops per cc, and 3000 drops per cc, respectively.

TABLE #1

5 m/s Air Velocity (typical home duct velocity) 1000 drops/cc

Particle diameter (m)

Efficiency

Escapees

1.00E−07

0.135700000000

0.8643

5.00E−07

0.517700000000

0.4823

1.00E−06

0.767400000000

0.2326

5.00E−06

0.999300000000

0.0007

1.00E−05

0.999999537000

4.63E−07

3.00E−05

1.000000000000

2.12E−32

TABLE #2

5 m/s Air Velocity (typical home duct velocity) 2000 drops/cc

Particle diameter (m)

Efficiency

Escapees

1.00E−07

0.253000000000

0.747

5.00E−07

0.767440000000

0.23256

1.00E−06

0.945900000000

0.0541

5.00E−06

0.999999537000

4.63E−07

1.00E−05

1.000000000000

2.19824E−14

3.00E−05

1.000000000000

0

TABLE #3

5 m/s Air Velocity (typical home duct velocity) 3000 drops/cc

Particle diameter (m)

Efficiency

Escapees

1.00E−07

0.354400000000

0.6456

5.00E−07

0.887800000000

0.1122

1.00E−06

0.987400000000

0.0126

5.00E−06

0.999999999969

3.15E−11

1.00E−05

1.000000000000

0

3.00E−05

1.000000000000

0

Tables #1 through #3 can be compared to conventional electrostatic precipitators, and it can be seen that the cleaning efficiency of the present invention is quite high in comparison to known prior art electrostatic precipitators, especially when the droplet density is at 3000 drops/cc. The cleaning efficiency of the present invention is also superior at particle sizes of one micron or larger, even when the droplet density is only at 1000 drops/cc.

As discussed above, the conductivity of the fluid used to create the charged droplets is an important property for use in the present invention. The higher the conductivity, the easier it is for the droplets to initially be charged with an electrical voltage; however, the lower the fluid conductivity, the greater the charge “lifetime,” which is technically referred to as the “relaxation time.”

If the conductivity of the fluid has a value of 10

−12

Ohm

−1

-meter

−1

, then the relaxation time is approximately 18 seconds. On the other hand, if the conductivity is increased to a value of 6.7×10

−10

Ohm

−1

-meter

−1

, then the relaxation time is reduced to approximately 3 milliseconds. For the purposes of the present invention, it is preferred that the relaxation time is at least several tenths of a second, and more preferably greater than one second.

In the example computer-modeled simulation illustrated in

FIGS. 22 and 23

, the droplet velocity was 2 meters per second, which would allow a fairly large chamber for collecting particles from inlet air if the relaxation time was at least one second. Of course, in this simulation model, the distance through the “media” was only 2 inches, so the relaxation time could of course be much less, while the charged droplet nevertheless retained its charge throughout its travel from the nozzle to the collecting plate.

As noted in a related application, the liquids used for the present invention will preferably have a relatively low viscosity, and will have a conductivity less than 10

4

Ohms

−1

m

−1

. The conductivity will preferably be even less than this 10

−4

value, and a better number would be less than 10

−10

Ohm

−1

m

−1

. This would provide a greater relaxation time, of greater than 0.1 seconds.

It will be understood that the cleaning efficiency is equal to the number of particles entrained in the inlet air minus the number of particles entrained in the outlet air, divided by the number of particles entrained in the inlet air, and this quantity is multiplied by 100%. A particle counter is typically used when measuring actual particle counts in experimental prototypes or production units.

As noted above, a new characteristic called “pressure adjusted efficiency” (PAE) is introduced herein for describing the efficiencies and pressure drop characteristics of an air cleaning filter. The PAE is measured as the cleaning efficiency (in percent) divided by the pressure drop (in inches of water), leading to a numerical result that has the units of the inverse of pressure. In this patent document, the units will always be the inverse of inches of water column.

For a “fresh” filter, the PAE will typically be at its maximum value, and as the filter is used, the cleaning efficiency will drop while the pressure drop will tend to increase, thereby lowering the PAE numeric result. HEPA filters when “fresh” will tend to have a PAE value around 100, which would be 99.97% divided by about 0.1 inches of water column of backpressure. Of course, this backpressure tends to increase rather quickly once particulate matter is accumulated in the filter media, and the PAE accordingly will drop proportionally.

Electrostatic precipitator-type air filters tend to have much greater PAE values, mainly because the pressure drop is so much smaller while the efficiency still remains relatively high, usually at least in the range of 70-80% for the ASHRAE dust spot test.

The present invention can achieve PAEs substantially larger than any HEPA filter, while nevertheless removing sub-micron particles from air at the same efficiencies (i.e., at 99.97%).

The present invention can also achieve PAE values that are substantially similar if not greater than those achieved by conventional electrostatic precipitator-type air filters. Moreover, the PAE value for the present invention will not substantially change over extended use in the range of, for example, 2 months of continuous operating time. However, conventional electrostatic precipitators will substantially lose cleaning efficiency over the same operating time, as their collecting elements begin accumulating particulate matter, which thereby decreases the likelihood that further particulate matter will be attracted to electrically charged elements. For example, the present invention will continue to operate at a PAE that does not deviate by more than 25% after two months of continuous use.

The present invention can clean air at an efficiency greater than 70% with a backpressure of less than 0.2 inches of water column for particles substantially 0.3 microns in size at an air velocity of 500 fpm (2.54 meters per second). When using the ASHRAE dust spot test, the present invention can provide a cleaning efficiency of greater than 85% at a backpressure of less than 0.1 inches of water column at the same air velocity.

When operated at air velocities substantially similar to those of HEPA filters, the present invention can achieve a cleaning efficiency of at least 99.97% at a backpressure of less than 0.8 inches of water column with the air velocity of 90 fpm (0.4572 meters per second) when the particle size is 0.3 microns.

Another example of tabular information is provided below in reference to TABLE #4. Computer modeling data of the present invention for a filter operating at an air velocity of 0.03 meters per second (about 5.9 feet per minute) is set forth in TABLE #4, which provides a direct comparison to conventional HEPA filters. Even when the droplet density is only at 1000 drops per cc, the collecting efficiency is extremely high in TABLE #4, and in fact it is so high at particle sizes above 5 microns that the precision of the measurement cannot provide a number below 100% collecting efficiency.

TABLE #4

0.03 m/s Air Velocity (HEPA comparison) 1000 drops/cc

Particle diameter (m)

Efficiency

Escapees

1.00E−07

0.999999999995

5.00E−12

5.00E−07

1.000000000000

3.45E−57

1.00E−06

1.000000000000

1.19E−113

5.00E−06

1.000000000000

0.00E+00

1.00E−05

1.000000000000

0.00E+00

3.00E−05

1.000000000000

0.00E+00

The foregoing description of a preferred embodiment of the invention has been presented for purposes of illustration and descrippion. It is not intended to be exhaustive or to limit the invention to the precise form disclosed. Obvious modifications or variations are possible in light of the above teachings. The embodiment was chosen and described in order to best illustrate the principles of the invention and its practical application to thereby enable one of ordinary skill in the art to best utilize the invention in various embodiments and with various modifications as are suited to the particular use contemplated. It is intended that the scope of the invention be defined by the claims appended hereto.

Number	Name	Date	Kind
2357354	Penney	Sep 1944	A
2525347	Gilman	Oct 1950	A
3802625	Buser et al.	Apr 1974	A
3988128	Hogg	Oct 1976	A
4095962	Richards	Jun 1978	A
4239504	Polizzotti et al.	Dec 1980	A
RE30479	Cohen et al.	Jan 1981	E
4294588	Polizzotti et al.	Oct 1981	A
4549243	Owen et al.	Oct 1985	A
4738690	Radway et al.	Apr 1988	A
4776515	Michalchik	Oct 1988	A
5290600	Ord et al.	Mar 1994	A
5310416	Borger et al.	May 1994	A
5337963	Noakes	Aug 1994	A
5503335	Noakes et al.	Apr 1996	A
5518525	Steed	May 1996	A
5843210	Paranjpe et al.	Dec 1998	A
5902380	Tomimatsu et al.	May 1999	A
5914454	Imbaro et al.	Jun 1999	A
5958361	Laine et al.	Sep 1999	A
5980614	Loreth et al.	Nov 1999	A
6156098	Richards	Dec 2000	A
6500240	Tomimatsu et al.	Dec 2002	B1

Number	Date	Country
1 095 705	May 2001	EP
10-2001-0038576	Oct 1999	KR
WO 8201481	May 1982	WO
WO 9728883	Aug 1997	WO

	Number	Date	Country
Parent	10/039854	Oct 2001	US
Child	10/282586		US
Parent	09/860288	May 2001	US
Child	10/039854		US

Dynamic electrostatic filter apparatus for purifying air using electrically charged liquid droplets

Information

Patent Number

Date Filed

Date Issued

Inventors

Original Assignees

Examiners

Agents

CPC

US Classifications

Field of Search

US

International Classifications

Abstract

Description

Claims

CROSS-REFERENCE TO RELATED APPLICATIONS

US Referenced Citations (23)

Foreign Referenced Citations (4)

Non-Patent Literature Citations (11)

Provisional Applications (1)

Continuation in Parts (2)

Entry
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Carrier Model AIRA Electronic Air Cleaner Product Data Sheet, published by Carrier Corporation (1999), pp. 1-4.
“Carrier Model AIRA Electronic Air Cleaner” advertisement, published by Carrier Corporation (1998), p. 1-2.
“EPA Air Pollution Technology Fact Sheet, Fabric Filter, HEPA and ULPA Type,” pp. 1-8.
“16th DOE Nuclear Air Cleaning Conference,” Session 10, (Oct. 21, 1980), pp. 666-707.
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