Abstract:
A vacuum cleaner having a reduced velocity chamber with a high velocity air inlet, an electric motor, a rotary mechanism driven by the motor for creating a vacuum in the chamber, an outlet for exhausting air from the chamber, which air flows in a selected path from the air inlet, through the chamber and out the air exhaust outlet and a disposable porous sheet filter layer in the chamber for removing large solid particles from the air. The vacuum cleaner also has an improved filter, wherein the improved filter includes a layer of material to remove very fine air particles and a layer of material to remove odors from the air.

Description:
This patent application is a continuation of application Ser. No. 09,032,589 filed on Feb. 27, 1998, now U.S. Pat. No. 6,090,184, and incorporated herein by reference. 
    
    
     The present invention relates to the art of air filter systems and more particularly to an improved vacuum cleaner employing a novel filter element. The invention is particularly applicable for a canister type vacuum cleaner and it will be described with particular reference thereto; however, the invention has much broader applications and may be used to filter air by employing the novel filter element and filtering method as contemplated by the present invention. 
     INCORPORATION BY REFERENCE 
     Frey U.S. Pat. No. 5,593,479 and Stevenson U.S. Pat. No. 5,248,323 are incorporated herein as background information regarding the type of vacuum cleaner to which the present invention is particularly applicable. These two patents illustrate a canister type vacuum cleaner with a low velocity receptacle or chamber into which is placed a conical filter sheet formed from non-woven cellulose fiber and over a downwardly extending support structure for the purpose of removing particulate material from the air being processed through the vacuum cleaner. The rigid perforated conical support structure or member holds the filter sheet in its conical configuration. The support member and filter sheet are mounted together with the layer covering the rigid support member. Within the conical support member there is provided a generally flat disc shaped cellulose filter sheet for further removal of particulate solids as the solids pass with the air from the canister through the conical filter sheet and through the disc to the outlet or exhaust of the vacuum cleaner. 
     BACKGROUND OF INVENTION 
     A canister type vacuum cleaner is illustrated in the patents incorporated by reference herein and includes a reduced velocity chamber with a high velocity air inlet. Air is drawn into the chamber by an electric motor which drives a rotary means, or fan, for creating vacuum in the chamber to draw air laden with particulate material through the chamber and to force it from the outlet as exhausted clean air. Canister type vacuum cleaners normally include a conical filter extending downwardly into the canister or low velocity chamber and is formed of a porous mat to remove the dirt and debris carried by the air coming into the canister. The high velocity air drawn into the chamber has a tendency to entrain large solid particles which are brought into the low velocity chamber where the air is then swirled or vortexed in a centrifuge configuration with convolutions so that large particles carried into the chamber with the inlet air are extracted by the vortexed or cyclonic action of the air in the canister. Thereafter, the air is pulled upwardly through the conical filter toward an upper motor that drives a fan for creating a vacuum in the canister, or reduced velocity chamber, so that the air flowing upwardly through the conical filter passes through a filter disc and outwardly through an exhaust passage, or passages, above the canister. Stevenson U.S. Pat. No. 5,248,323 discloses an improvement to filters for vacuum cleaners by developing an activated charcoal containing filter which efficiently remove gaseous impurities, such as paint fumes and other odor creating gases which are in the air. 
     The canister type vacuum cleaner, as so far described, only removes the relatively large particles entrained in the air. Air particles of a size less than 10 microns pass freely through the filter medium and are recirculated in the room. Many of these small particles can act as irritants to an individual and the recirculation of such particles can increase the irritation to an individual. High density filters must be employed to filter out very small particles in the air; however, high density filters cause large pressure drops through the filter and thus cannot be used in standard vacuum cleaners or other air filtering systems. Frey U.S. Pat. No. 5,593,479 addressed this problem by disclosing a multi layer filter which included at least one layer of electrically charged fiber material incapuslated between at least two layers of support material. The multi-layer filter effectively removed very small particles from the air which penetrated the cellulose fiber layer. The patent also disclosed that a spongy non-woven polyester mat impregnated with activated charcoal could be used with the cellulose filter and multi-layer filter to remove odors from the air. 
     Although the filter arrangement disclosed in Frey U.S. Pat. No. 5,593,479 effectively removed fine particles from the air and could be adapted to also remove odors from the air, the use of three separate filters proved confusing to many consumers. The three filter system required the filters to be arranged in a certain order so as to maximize particle and odor removal efficiencies and to maximize the life of the three filter system. The proper arrangement for the three filter system was confusing to many consumers and resulted in the improper arrangement of these filters. In addition to problems in arranging the order of the filters, the three filters had to be correctly positioned with respect to one another so as to obtain the desired pressure drop through the three filter system to obtain the desired particle remove efficiencies. The proper arrangement of the three filters proved to be, at times, tedious, complicated and/or confusing, thus resulting, at times, in reduced filter efficiencies and operating efficiencies. Finally, the three filter system required the user to timely change each filter to maintain the air filtering efficiencies and proper operation of the cleaning system. However, due to the use of three separate filters, confusion sometimes resulted as to when and/or which filter needed to be replaced. As a result, one or more filters would not be timely replaced thereby resulting in subpar operation and filter efficiencies. 
     As a result, vacuum cleaners, in general, canister type vacuum cleaners, in specific, have not been designed to incorporate a simple filter system which can remove both odors and very small particles entrained in the air. 
     SUMMARY OF THE INVENTION 
     The present invention relates to an improved air filtering system, and more particularly to a vacuum cleaner with a novel filtering arrangement which allows a vacuum cleaner, and even more particularly to a canister type vacuum cleaner, to be modified for the purpose of handling a wide variety of particles entrained in the air being drawn through the vacuum cleaner by an electric motor. In addition, the improved filtering system is designed to remove odors from the air as the air passes through the filter system. Thus, the filtering system can be an environmental air cleaning device as well as a standard vacuum cleaner. 
     In accordance with the present invention, there is provided an improvement in a vacuum cleaner of the type comprising a reduced velocity chamber with a high velocity air inlet, an electric motor, a rotary means driven by the motor to create a vacuum in the chamber, an outlet for exhausting air from the chamber, which air flows in a selected path from the air inlet to the low velocity chamber and out the air exhaust outlet or outlets, and a disposable filter system in the chamber for removing solid particles from the air, which filter layer intersects the air path. The improvement in this type of vacuum cleaner is the provision of a changeable filter system which includes a filter which removes all sizes of particles including particles of less than ten microns in size. In this manner, the filter removes all sizes of particles entrained in the air to provide a significantly cleaner environment. Standard filter mediums filter out approximately 300,000 particles out of 20 million particles which flow into the filter medium. Particles which are ten microns or less in size pass freely through standard filter medium. Such particles include pollen, dust mites, bacteria, viruses, etc. The recirculation of these small particles can spread diseases and/or cause allergic reactions. The improved filter system of the present invention includes a filter which removes all sizes of particles which result in about a 19 million particle removal out of 20 million particles which pass into the improved filter. As a result, over 90% of the particles greater than 2 microns in size are filtered out of the air passing through the improved filter. The improved filter is also designed to remove odors from the air which pass through the filter. The improved filter includes an odor absorbing material to remove odors from the air through the air filter. 
     In accordance with another aspect of the present invention, the improved filter includes two distinct sections. One section is designed to be a high efficiency particle removing section to remove very small particles from the air passing through the filter. This section may use mechanical and/or electrostatic capture mechanisms to remove particles entrained in the air. This section may be comprised of one or more layers. The second section is designed to be a gas removal section to remove unwanted gasses from the air. This section may also be designed to remove particles from the air. This second section may use mechanical and/or chemical capture mechanisms to remove gasses and particles from the air. This section may comprise one or more layers. 
     In accordance with yet another aspect of the present invention, the two sections of the improved filter are connected together. In one preferred arrangement, the two sections are connected together by an adhesive. One such adhesive preferably used is a hot melt adhesive. 
     In accordance with still yet another feature of the present invention, the improved filter minimizes the degree of pressure drop as the air passes through the filter. The relatively low pressure drop through the improved filter enables the filter to be used in vacuum cleaners, such as canister type vacuum cleaners or for various other types of air filter systems. 
     In accordance with another feature of the present invention, the improved filter both removes small particles and odors in the air as the air passes through the filter. This dual action filter eliminates the need for a separate filter for small particle removal and a separate filter for odor removal. 
     In accordance with yet another aspect of the present invention, the two sections of the improved filter are connected together so as to maintain the integrity of the sections during operation and to minimize the degree of pressure drop through the filter. 
     In accordance with still another aspect of the present invention, a disposable filter is used in conjunction with the improved filter to remove large particles entrained in the air prior to the air entering the improved filter. The use of a disposable filter for filtering larger particles from the air enhances the life of the improved filter. The disposable filter can be a paper of cellulose type filter. The disposable filter is preferably generally coterminous to the improved filter. 
     In accordance with yet another aspect of the present invention, the improved filter is conical in shape to maximize the surface area to provide increased particle removal. In addition, the disposable filter is preferably conical in shape. Consequently, all the filters are sandwiched together thereby minimizing the area of filtration by the filters and to ensure the filters are in the proper position in the vacuum cleaner. This construction allows the use of the filters to be easily adapted for use in a standard canister type vacuum cleaner without modification of the vacuum cleaner. 
     In accordance with another aspect of the present invention, the improved filter includes a tab, loop or the like to facilitate the ease to which the filter can be positioned in the vacuum cleaner and/or removed from the vacuum cleaner. The tab, loop, etc. may also be used as an indicator for the proper position of the improved filter and/or include information about the filter. 
     The primary object of the present invention is the provision of a novel filter system that can effectively filter out a majority of the particles entrained in the air and to remove odors in the air as the air passes through the filter without causing a large pressure drop and can be easily used in a vacuum cleaner such as a canister type vacuum cleaner. 
     Another object of the present invention is the provision of a filter system as described above, which filter system can be changed easily and can be used in a standard canister type vacuum cleaner without modification of existing vacuum cleaner structure. 
     Yet another object of the present invention is the provision of a filter system which reduces the number of filter components need to remove odors and particles from the air thereby reducing confusion as to assembly and maintenance of the filter system. 
     Still yet another object of the present invention is the provision of a filter system, as defined above, which filter system has a large area to which the air flowing from the canister toward the exhaust outlet of the vacuum cleaner has a relatively large area compared to a standard circular disc shaped filter element. 
     Yet another object of the present invention is the provision of a conical filter system adapted to be sandwiched within and held in a nested position with a standard filter element of a canister type vacuum cleaner. 
     Still a further object of the present invention is the provision of a filter system, of the type defined above, which filter system is fixedly located in the reduced air velocity chamber or area of a vacuum cleaner so that low velocity air passes through the filter system to provide resident time to contact the large surface area of the filter system so as to remove particles from the air being cleaned by the vacuum cleaner. 
     In accordance with another objective of the present invention, the improved filter and disposable filter are nested together and supported by a support structure. 
     These and other objects and advantages will become apparent from the following description taken together with the accompanying drawings. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a pictorial exploded view of a standard canister type vacuum cleaner employing the improved filter system of the present invention; 
     FIG. 2 is a top view of a flat blank of the improved filter cut into a shape for subsequent forming into the preferred embodiment of the present invention; 
     FIG. 3 is a side view of the blank shown in FIG. 2 formed into a conical filter and showing the cross-section of the improved filter partially; 
     FIG. 4 is a side view of an alternative embodiment of the improved filter shown in FIG. 3; 
     FIG. 4A is a cross-section view of the improved filter along line  4 A— 4 A of FIG. 4; 
     FIG. 5 is a side elevational view showing the geometric configuration of the preferred embodiment of the present invention illustrated in FIGS. 2 and 4; 
     FIG. 6 is a cross-sectional view of the improved filter along line  6 — 6  of FIG. 4; 
     FIG. 7 is a schematic layout view of the air flow through a two filter system; 
     FIG. 8 is a schematic layout view of the air flow through an alternative embodiment of a two filter system; and 
     FIG. 9 is a block diagram showing the filtering and operating steps of a canister type vacuum cleaner improved by incorporating the improved filter of the present invention. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENT 
     Referring now to the drawings wherein the showings are for the purpose of illustrating a preferred embodiment of the invention only and not for the purpose of limiting same, FIG. 1 shows a canister type vacuum cleaner A having a lower generally cylindrical canister  10  with a base  12  and an upper circular opening defined by rim  14 . In the illustrated embodiment, a plurality of circumferentially spaced wheels  16  support canister  10  for movement along the floor of a room being cleaned. Canister  10  includes a low velocity chamber  20  with a high velocity inlet  22 , an air deflector  24  and a lower filter rest  26 . Air flow through the vacuum cleaner is illustrated as arrows defining a path P. In chamber  20  of canister  10 , path P is in the form of a vortexed or cyclone portion C of several convolutions so that particles carried by air through chamber  20  are removed by centrifugal force and are retained in the low velocity chamber  20 . Thereafter, air flow path P is generally in an upwardly vertical direction so that the air being cleaned moves through a conical filter element, or layer,  30  formed from a flat, non-woven cellulose fiber with an outer conical surface  32  and an upper circular opening  34 . The diameter of open end  34  is X and the height of a conical filter  30  is Y, as shown in FIG.  5 . In this manner, a substantially increased amount of filtering surface is obtained through use of a conical surface. Otherwise, filtering would be through a circular area defined by the diameter of open end  34 . Filter layer  30  is preferably designed to be relatively thin since it includes small interstices to physically block the passage of solid particles. Filter layer  30  is a standard vacuum cleaner filter designed to act as a barrier to relatively large particles entrained in the air. Filter layer  30  removes approximately 300,000 out of 20 million particles from the air as the air passes through filter  30 . Very small particles pass freely through filter layer  30 . Such filtration efficiency meets standard EPC guidelines. 
     To retain the conical shape of the relatively unstable conical element  30 , there is provided a filter support  40  having a large number of perforations  42  and an upper circular rim  44 . When assembled, conical support  40  nests within the thin, conical filter layer  30  and rim  44  clamps the filter layer against rim  14  of canister  10 . The outer conical surface  46  bears against the inner conical surface of filter layer  30  in normal practice to support this conical filter element. As so far described, air passes through the thin, non-woven conical cellulose filter  30  through perforations  42  and upwardly in a direction defined by air path P. 
     In accordance with standard practice, a motor driven fan housing  50 , of the type shown in the prior art, includes a lower inlet  52  and an air exhaust shown as a large number of peripherally spaced outlet exhaust openings  54  having a common cylindrical secondary filter  56  for removal of any solid particles reaching housing  50 . Secondary filter disc  60  is before motor  50  and is supported by a flat perforated support disc  62 . As so far described, canister vacuum cleaner A is constructed in accordance with standard practice. 
     In accordance with the invention, there is provided a novel filter  70  for removing both small particles and odors from the air passing through the filter. As best shown is FIGS. 3,  4  and  6 - 8 , filter  70  includes an odor removal section  76  and a particle removal section  78 . The two sections are connected together by any number of arrangements, i.e. bonding agent, stitching, etc. Preferably a bonding agent  80  is used to secure sections  76 ,  78  together. One such bonding agent which can be used is an adhesive, such as a hot melt adhesive. Preferably, the bonding agent is applied in a dot matrix pattern to secure sections  76 ,  78  together so as not to cause a significant increase in pressure drop or a reduction in performance of filter  70 . 
     Odor removal section  76  of filter  70  is designed to remove undesirable gases from the air such as smoke or other undesirable odors. The gas filter section  76  comprises a mat of laid fibers. The fibers extend in all directions in the mat. The fibers are generally parallel to the forming surface on which the fibers are laid. The gas filter section  76  may alternatively be a woven mat, a needled mat or a felted mat. The gas filter section  76  preferably is made up of multiple layers of fibers. 
     The fibers are preferably cellulosic fibers and/or synthetic textile fibers. The fibers of the mat may be all cellulosic fibers or all synthetic textile fibers or a mixture of cellulosic fibers and synthetic textile fibers. Alternately, one layer of the mat, or one layer may be all cellulosic fibers and another layer of the mat be all synthetic textile layer of the mat may be all cellulosic fibers and another layer of the mat be all synthetic textile fibers, with yet a further layer of the mat may be a mixture of synthetic textile fibers and cellulosic fibers. A wide variety of synthetic fibers may be used including acrylic fibers, polyester fibers, nylon fibers, olefin fibers, and vinyl fibers, and the like. The cellulosic fiber may be cellulose fibers, modified cellulose fibers, methylcellulose fibers, rayon and cotton fibers, although cellulose fibers are preferred. 
     Deposited on the fibers is a synthetic binder. The binder is designed to connect the fibers together and can be chosen from a wide variety of binders including an acrylic latex, a vinyl latex, an acrylonitrile latex, and an crylate latex. The binder substantially covers the surface area of the fibers, i.e. at least 50% of the fiber surface area, and is in an amount sufficient to bind the fibers together within the mat. 
     An absorbent powder, preferably in particle form, is disposed on the binder. The absorbent powder may be a variety of powders such as activated carbon, diatomaceous earth, fuller&#39;s earth and the like. Portions of the particles contact and are embedded into the binder, but portions of the particles protrude out of the binder and are free from and do not substantially contact the binder. Those protruding portions are, therefore, available to absorb odors as the air passes through the filter layer. 
     As can be appreciated, odor removal section  76  is also designed to remove particles in the air that have passed through filter layer  30 . The particle removal is by a mechanical and/or a chemical mechanism. The close spacing of the fibers making up section  76  mechanically removes particles from the air by not allowing the particles to pass through the filter section. The gas absorbing material in section  76  also can remove materials from the air by chemical attraction. Therefore, section  76  has a dual mechanism for removing particles from the air. 
     The odor removal section  76  of filter  70  is preferably designed to be resistant to mold, mildew, fungus and bacteria. The odor removal section  76  also is preferably designed to remove odors caused by Aromatic Solvents, Polynuclear Aromatics, Halogenated Aromatics, Phenolics, Aliphatic Amines, Aromatic Amines, Ketons, Esters, Ethers, Alcohols, Fuels, Halogenated Solvents, Aliphatic Acids, Aromatic Acids, etc. The odor removal section  76  may also be treated to resist damage from liquids. Preferably, section  76  has a weight of 100-300 g/m 2  and more preferably 150-225 g/m 2 , and a gas absorbent content of 25%-80% and more preferably 40%-60%. 
     The particle removal section  78  of filter  70  is designed to remove very small particles from the air. Preferably, section  78  is a high efficiency particulate air (HEPA) filter. Particle removal section  78  is preferably a multi-layer arrangement which removes particles mechanically and/or electrostatically from the air. Preferably the exterior surface layer of section  78  is made up of a relatively durable material so as to resist damage to the filter layer during operation of the air cleaner and/or during insertion on or removal of filter  70  from the air cleaner. The exterior surface is preferably a sheet of polyester, nylon or the like. The exterior surface may be woven or non-woven. Section  78  is preferably formed of materials which resist growth to mold, mildew, fungus or bacteria. The materials also preferably resist degradation over time and are able to withstand extremes in temperatures and humidity, i.e. up to 70° C. (158° F.) and 100% relative humidity. Therefore, the particle removal section  78  is preferably unaffected by normal operating temperatures and water in the air. As a result, the filter  70  can be designed to be, if desired, used in both wet and dry environments. Section  78  is designed to act as a mechanical and/or electrical barrier to prevent air particles from penetrating the fiber layer. Preferably, section  78  removes essentially all particles having a size greater than two microns. Particle removal section  78  preferably has a 99% air filtration efficiency for particles greater than two microns in size. More preferably, section  78  filters out over 99.9% of the particles 2 micron or greater in size, and even more preferably filters over 99% of the particles 0.3 micron or greater in size. For particles from 0.3-2.0 microns, particle removal section  78  has a filtration efficiency of at least 70% and more preferably at least 99.9%. As a result, out of the millions of air particles entering the fiber layer, only a relatively few extremely small particles pass through section  78  of filter  70 . The weight of the material of section  78  is 60-150 gm/m 2 , and more preferably 62-90 gm/m 2 , which results in a very nominal pressure drop as the air passes through section  78 . 
     The multiple layers of section  78  are connected together by any conventional means. Preferably, they are connected together by a binder and/or needle pointed together. The materials used to form section  78  may be similar to the materials used in section  76 . 
     The combining of odor removal section  76  and particle removal section  78  complements each of the sections of filter  70  thereby resulting in greater particle removal efficiencies. As illustrated in FIG. 7, filter layer  30  mechanically removes the large particles  90  in air stream P. The smaller particles  92  freely pass through filter layer  30 . The smaller particles  92  then encounter odor removal section  76  of filter  70 . Odor removal section removes odors such as smoke from the air by absorbing such odors as the air passes through odor removal section  76 . In addition, odor removal section  76  mechanically, and in some instances, chemically removes smaller particles from air stream P by blocking their passageway and/or absorbing such particles. Odor removal section  76  thus acts as a pre-filter of particles for particle removal section  78 . The remaining small particles  92  that pass through odor removal section  76  are mechanically and/or electrically removed from air stream P by adhesive layer  80  and particle removal section  78 . Particle removal efficiencies as high as 99.98% for particles 0.1 micron and greater in size and at air flow rates of 10-60 CFM are achievable by filter  70 . This filter arrangement has been found to also maximize the life of the filter system. 
     An alternate embodiment of the invention is shown in FIG.  8 . The arrangement of the filter system is the same as shown in FIG. 7 except particle removal section  78  is first exposed to small particles  92  after such particles pass through filter layer  30 . The particle removal efficiencies of this filter system arrangement are comparable to the particle removal efficiencies of the filter system arrangement illustrated in FIG.  7 . However, it has been found that the life of filter  70  is slightly shortened by this arrangement, but, in some instances, the odor removal efficiencies are increased. 
     Referring now to FIG. 2, filter  70  is originally in a sheet form after sections  76  and  78  are connected together. This sheet form is then cut out in a particular shape as shown in FIG.  2 . The particular cut of the filter material is then formed into a cone shaped filter as illustrated in FIGS. 3 and 4. This particular shape of filter  70  maximizes the surface area of the filter for canister air cleaning systems utilizing a vortex particle removal system. The ends of the filter material are attached together to form the conical shaped filter  70 . Preferably, the ends are connected together by a bonding agent  74 , such as a hot melt adhesive. However, the ends of the filter can be connected together by other means such as stitches, staples, VELCRO, or the like. 
     Referring now to FIGS. 4 and 4A, an alternative embodiment of filter  70  is illustrated. A tab  84  is connected to the top edge  72  of filter  70 . Tab  84  is designed to facilitate in the ease of insertion and removal of filter  70  from filter support  40 . Tab  84  may also include use, installation and/or replacement information to assist in the operation of the vacuum cleaner A. Tab  84  may also function as a positional indicator to assist the user properly positioning filter  70  in vacuum cleaner A. Finally, tab  84  is preferably positioned on filter  70  to overlap bonding agent  74  which connects the ends of filter  70  together. This positioning of tab  84  helps to protect and secure the seam formed by bonding agent  74 . Tab  84  is preferably secured to both sides of filter  70  as shown in FIG.  4 A. The tab is preferably secured to filter  70  by a bonding agent such as a hot melt adhesive. However, tab  84  can be connected to filter  70  by other means such as stitching, staples, etc. If desired, tab  84  can be designed to be easily removed by the user. 
     The formed conical filter  70  preferably nests within conical filter layer  30  and is sandwiched between filter layer  30  and filter support  40 . As illustrated in FIGS. 7 and 8, layer  30  acts as a mechanical barrier to prevent large particles  90  from entering into filter  70 . The small particles  92  which penetrate the small openings in layer  30  are subsequently filtered out of the air by filter  70 . The use of layer  30  extends the life of filter  70  by filtering out the larger particles which can clog up the air passages in filter  70 . 
     Referring now to FIGS. 1 and 9, it is shown that filter  30  and filter  70  are sandwiched together so that air flowing through this filter arrangement is first intercepted by conical filter  30 . This filter removes the solid particles which have not been centrifuged out in canister  10 . The air particles passing through filter  30  engage sections  76  and  78  of filter  70 . In addition, odors and other undesired gases are simultaneously removed from the air as the air passes through section  76  of filter  70 . Thus, improved vacuum cleaner A can be used for cleaning fine particles from a room and can help sterilize a room from pollen, bacteria, viruses, microorganisms and the like, and also remove smoke and other unwanted gasses from the air. It is appreciated that the vacuum cleaner can clean the ambient air for a normal household use. 
     As shown in FIGS. 1 and 9, the air passes upwardly from the cyclone action of canister  20  through exhaust  56  by passing filter  70  positioned between conical filter layer  30  and the flat filter disc, or secondary filter  60 . FIG. 9 illustrates a novel method of processing air in a vacuum cleaner, which novel method has not been heretofore available, especially in canister type vacuum cleaners. This novel method allows the vacuum cleaner to be capable of removing ultra fine particles entrained within the air being cleaned, and also to simultaneously remove unwanted gasses from the air. 
     The dual functions of filter  70  greatly simplifies the operation of vacuum cleaner A. Only two separate filters are required to be changed during the operation of the vacuum cleaner A, i.e. filter  30  and filter  70 . The problems associated with the need for separate filters to obtain odorless clean air is solved by this filter system of the present invention. In addition, particle removal efficiencies never before obtained in portable vacuum cleaners are achieved by the filter system of the present invention. 
     The invention has been described with reference to a preferred embodiment and alternatives thereof. It is believed that many modifications and alterations to the embodiments disclosed will readily suggest themselves to those skilled in the art upon reading and understanding the detailed description of the invention. It is intended to include all such modifications and alterations insofar as they come within the scope of the present invention.