The present invention generally relates to hand-held portable vacuum cleaners and improvements thereto.
Typically, hand-held portable vacuum cleaners employ a motor that is powered by either a main supply of electricity (i.e., a source of alternating current power) or a battery pack, which may be rechargeable, to drive an impeller. Rotation of the impeller generates an air flow which entrains therein dirt and debris which enter the vacuum cleaner via an inlet. One or more filters may be employed to retain the dirt and debris within the vacuum.
One problem with such vacuum cleaners concerns the relatively rapid rate with which the efficiency and performance of such vacuum cleaners may deteriorate. Specifically, the use of such vacuums to collect relatively small sized particles can rapidly load the filter and substantially reduce the amount of air that passes therethrough. When filter loading is encountered in the known hand vacuum configurations, the user must disassemble the vacuum, remove the filter, clean (or dispose of and replace) the filter and replace the filter. In some situations, the user may be reluctant to perform the tasks of removing and cleaning the filter due to the unwholesomeness of the material that has accumulated on the filter. In situations where the filter is heavily loaded, the vacuum will have a relatively low efficiency and consequently, vacuuming tasks will take longer, the vacuum will experience greater wear, and if battery powered, the user will be able to perform relatively fewer vacuuming tasks per charge.
In one form, the present teachings provide a hand-held portable vacuum having a housing, an impeller that is at least partially disposed in the housing, a dirt cup and a HEPA filter. The dirt cup, which is removably attached to the housing, includes an inlet and defines a container for storage of dirt and debris therein. The HEPA filter is disposed between the impeller and the inlet.
In another form, the present teachings provide provides a method for filtering a dirt and debris laden air flow. The method includes: providing a hand-held vacuum with a housing, an impeller, an inlet, a container and a primary filter, the housing including a handle that permits a user to employ the hand-held vacuum for vacuuming with a single hand, the impeller being disposed within the housing, the inlet being configured to receive the dirt and debris laden air flow therethrough, the container being configured to retain dirt and debris removed from the dirt and debris laden air flow and the primary filter being disposed between the impeller and the inlet; rotating the impeller to generate the dirt and debris laden air flow; and swirling the dirt and debris laden air flow about the interior of the container.
In yet another form, the present teachings provide a hand-held portable vacuum including a housing with a handle, a dirt cup, an impeller at least partially disposed in the housing, a filter and a filter cleaning device. The dirt cup, which is removably attached to the housing, has an inlet and defines a container for storage of dirt and debris therein. The filter, which is disposed between the impeller and the inlet, is formed with a plurality of pleats. The filter cleaning device is coupled to at least one of the housing and the dirt cup and includes at least one rib and a hub. The hub is coupled to one of the filter and the rib and configured to rotate the one of the filter and the rib about the other one of the filter to generate contact between the rib and the filter to at least partially dislodge accumulated dirt and debris from the pleats.
In a further form, the present teachings provide a hand-held portable vacuum including a housing with a handle, a dirt cup, an impeller, a filter and a means for swirling the dirt and debris laden air in the dirt cup. The dirt cup, which is removably attached to the housing, has an inlet and defining a container for storage of dirt and debris therein. The impeller is at least partially disposed in the housing and operable for generating an air flow that flows through the inlet. The filter is disposed between the impeller and the inlet.
Further areas of applicability of the present teachings will become apparent from the detailed description provided hereinafter. It should be understood that the detailed description and specific examples, while indicating the preferred embodiment of the invention, are intended for purposes of illustration only and are not intended to limit the scope of the invention.
Additional advantages and features of the present invention will become apparent from the subsequent description and the appended claims, taken in conjunction with the accompanying drawings, wherein:
With reference to
In
The inlet port 54 may have a generally rectangular cross-sectional shape that extends rearwardly from the housing structure 52 and terminates at a rearward face 60. As will be discussed in greater detail, below, the front end of the inlet port 54 may be configured to frictionally engage various components of the accessory set 10b (
With reference to
In
The battery pack 74 conventionally includes a plurality of rechargeable batteries 100, which are adapted to be electrically coupled to a source of electrical power, as through the recharging base 75 that is illustrated in
The battery pack 74 may further include a housing 120 having a pair of engagement features 122 that co-engage mating features 124 (
One suitable power switch 76 is described in detail in U.S. Pat. No. 5,544,274, which is hereby incorporated by reference as if fully set forth herein. Briefly, and with reference to
With reference to
The latch mounting structure 164 may be configured to receive therein and support the conventional latch mechanism 40 having a latch member 170 for engaging the securing aperture 56a in the housing structure 52 of the dirt cup assembly 12 and a spring (not shown) for biasing the latch member 170 upwardly relative to the housing 32.
The retaining tab 42 extends outwardly from the housing 32 and defines an abutting wall 174. The retaining tab 42 may be configured to project through the securing aperture 56b when the dirt cup assembly 12 is coupled to the housing assembly 14 to permit the abutting wall 174 to cooperate with the rear edge of the securing aperture 56b to thereby limit forward movement of the dirt cup assembly 12 relative to the housing assembly 14.
In the example provided, the handle 168 is integrally formed with the housing shells 150a and 150b and may extend between the forward and rearward portions of the housing 32 and above the body of the housing 32 to define therebetween a handle aperture 180 that is sized to receive the hand of the user of the vacuum 10a. Those skilled in the art will appreciate, however, that the handle 168 may be otherwise positioned and/or a discrete component that is joined or fastened to the remainder of the housing 32 in a known manner.
Except as noted below, each of the housing shells 150a and 150b may be constructed in an identical manner so that further description of the housing shell 150a will suffice for both. With primary reference to
The motor mount 206 may include first and second mount portions 206a and 206b, respectively, that are employed to fixedly couple the motor 70 to the housing 32. The motor mount 206 may be configured to receive the motor 70 in a snap-fit manner so that discrete fasteners and the like are not required.
The hub mount 208 may include structure which, in association with the fan housing 92 in the example provided, serves to maintain the filter cleaning system 36 in a desired location along a longitudinal axis of the vacuum 10a relative to the filter system 34. In the example provided, the hub mount 208 includes first and second bearing portions 208a and 208b, respectively, which are axially spaced apart along an axis that is coincident with a rotational axis of the motor 70. The first bearing portion 208a may be semi-circular in shape so as to form a circular aperture when the housing shells 150a, 150b are coupled to one another. The second bearing portion 208b may include a rear wall 210 that may be generally transverse to the rotational axis of the motor 70.
As is apparent from the discussion above, the fan housing 92 may form the inlet aperture 94 and one or more discharge apertures 96 through which air is introduced and discharged, respectively, from the fan assembly 72. In the particular example provided, the fan housing 92 forms a volute that terminates at the discharge aperture 96. The flow channel 98 may serve as a fluid conduit which couples the discharge aperture 96 with the exhaust cavity 200.
With specific reference to
With additional reference to
Returning to
The clip structures 286 are configured to resiliently deflect in response to the application of a modest force to the exhaust deflector 154 to permit the exhaust deflector 154 to be secured to or released from the wall member 186 when the exhaust deflector 154 is moved into or out of the closed position. As will be apparent to those of ordinary skill in the art, engagement of the clip structures 286 to the wall member 186 effectively maintains the exhaust deflector 154 in the closed position. Those skilled in the art will also appreciate that features such as recesses or tabs 288 may be formed into the wall member 186 to serve as points that enhance or improve the ability of the clip structures 286 to engage the wall member 186.
Returning to
With renewed reference to
In the particular example provided, the filter drive portion 306 includes a plurality of radially extending drive tabs 316 that are circumferentially spaced apart from one another and collectively oriented concentric with the bearing surface 312. Those skilled in the art will appreciate from this disclosure, however, that the filter engagement portion 308, through frictional engagement or other engagement with the primary filter 414, may also serve in whole or in part as the filter drive portion 306.
The filter engagement portion 308 may be an elongated annular structure that may extend forwardly from the wall 314 of the filter drive portion 306. The cleaning wheel 300 may also include a grille 320 which inhibits the passage of relatively large objects from passing through the cleaning wheel 300 and contacting the impeller 90.
The cleaning wheel 300 may be installed over the fan housing 92 prior to the installation of the motor 70 and fan assembly 72 to the housing 32, thereby permitting these components to be collectively assembled to one of the housing shells (e.g., housing shell 150a) substantially simultaneously. The cleaning wheel 300 may be positioned relative to the housing 32 such that gripping portion 302 partially extends through the elliptical through-holes 204 in the recessed areas 202 of the housing 32 as shown in
The first and second bearing portions 208a and 208b of the hub mount 208, however, cooperate with the bearing surface 312 to limit the movement of the cleaning wheel 300 vertically and horizontally relative to the rotational axis of the motor 70, but permit the cleaning wheel to be rotated about the rotational axis of the motor 70. The recesses 310 in the gripping portion are specifically configured to be gripped by the thumb and/or fingers of a user of the vacuum 10a to rotate the cleaning wheel 300.
In
With additional reference to
As those of ordinary skill in the art will appreciate from this disclosure, any appropriate means may be employed to removably couple the filter flange 420 to one or both of the housing 32 and the dirt cup 20. Preferably, the securing means 424 will not automatically detach from the housing 32 when the dirt cup 20 is removed from the housing 32.
In the particular example provided, the securing means 424 is illustrated in
To guard against undesired rotation of the filter flange 420 relative to the housing 32 when the dirt cup 20 has been removed from the rear housing, the securing means 424 may include a resilient finger 440c that contacts the body portion 442b of an associated peg 442 to inhibit rotation of the filter flange 420 unless a force in excess of a predetermined force has been applied to rotate the filter flange 420 in a desired rotational direction relative to the housing 32.
In
In the example provided, the pleats 460 are formed such that their outer ends or peaks 464 lie along a straight line that intersects the axis of a theoretical cone (not shown) that includes the peak 464 of each pleat 460 on the filter body 450. Alternatively, the pleats 460 may be formed such that their peaks 464 are straight but skewed to the axis of the theoretical cone or generally helical in shape. For reasons that will be apparent from the discussion below, however, the pleats 460 should be formed relative to the theoretical cone in a manner that is consistent with the ribs 436 on the interior surface 438 of the filter housing 432.
The first seal portion 452, which is coupled to the smaller end of the filter body 450, may be a plate-like structure that is formed from a suitable material and is sealingly bonded to a lower end of the filter body 450. Alternatively, the first seal portion 452 may be wholly or partially formed from an appropriate filter material, such as the material from which the filter body 450 is manufactured, and bonded or otherwise sealingly coupled to the filter body 450.
The second seal portion 454 may be an annular flange that may be sealingly bonded to an upper end of the filter body 450. With additional reference to
With the primary filter 414 installed to the cleaning wheel 300 such that the primary seal 474 sealingly engages the seal engaging portion 308 and the drive tabs 316 and 478 are meshingly engaged with one another, the prefilter 412 may be positioned over the primary filter 414 such that the first portion 440a of the through-holes 204 in the filter flange 420 are aligned to the pegs 442 on the housing 32. The prefilter 412 may be urged toward the housing 32 such that the pegs 442 are fitted through the through-holes 204 and thereafter the prefilter 412 is rotated to position the pegs 442 within the second portion 440b of the through-holes 204. With the dirt cup 20 coupled to the housing assembly 14, the prefilter locating tabs 58 urge the filter flange 420 rearwardly toward the front face 188 of the housing 32 so that the secondary seal 476 sealingly engages the prefilter body 422 of the prefilter 412.
While the primary filter 414 has been illustrated and described as including first and second seal portions 452 and 454 which are bonded directly to the filter body 450, the primary filter 414 may be formed in various other manners. For example, the primary filter 414 may include a pair of discretely formed, caps 480a and 480b as illustrated in
The embodiment of
The embodiment of
With reference to
In some situations, the swirling effect may be so strong as to create centrifugal force that causes the dirt and debris to move outwardly toward and collect against the dirt cup 20. The swirling effect may also slow the collection of dirt and debris on the prefilter 412 and the primary filter 414 to thereby provide improved efficiency of the vacuum 10a. Improved efficiency is particularly important with cordless vacuums, as it permits extended operation on a given battery charge. Those of ordinary skill in the art will readily appreciate in view of this disclosure that the swirling effect may not be desirable under some circumstances and as such, the elbow 22 may be removable from the inlet port 54.
With reference to
Those skilled in the art will appreciate from this disclosure that various modifications may be made to the prefilter 412 to aid in discharging dirt and debris that are dislodged from the primary filter 414 and/or to slow the rate with which the pleats 460 of the primary filter 414 wear. For example, the prefilter 412 may be constructed with one or more apertures 5000 as shown in
Returning to
In the particular example provided, the brush tool 500 may be stored in a cavity 518 formed in the rear of the housing 32, while the crevice tool 502 may be coupled to a bottom face 520 of the housing 32. One or more resilient clips 522 may be employed to retain the particular accessory to the housing 32.
With reference to
In the particular example provided, the terminals 1004, which may be mounted to the base 1000, may extend outwardly from the base 1000 so as to contact associated ones of the mating terminals 1014 when the vacuum 10a is fully received into the base 1000. As the terminals 1014 are electrically coupled to the battery pack 74, contact between the terminals 1004 and 1014 permits electrical energy to be transmitted from the charging circuit 1002 to the batteries 100.
The key 1006 and the mating key 1016 coordinate with one another to permit the base 1000 to fully receive the vacuum 10a. In the particular example provided, the key 1006 includes a pedestal 1028, a flange 1030 and optionally one or more engagement tabs 1032, while the mating key 1016 includes a receiver 1040. The pedestal 1028 of the key 1006 may be coupled to the base 1000 in any conventional manner, including for example, threaded fasteners and/or features that are integrally formed onto and/or into the pedestal 1028 and base 1000 that permit the pedestal 1028 and the base 1000 to be engaged to one another in a snap-fit manner. The flange 1030 may be coupled to the pedestal 1028, extending upwardly therefrom so as to protrude from a corresponding aperture 1036 in the base 1000 when the key 1006 and the base 1000 are coupled to one another. If employed, the engagement tabs 1032 extend from the flange 1030 in the example provided.
The receiver 1040 may be coupled to the housing 32 in any conventional manner, including for example, threaded fasteners and/or features that are integrally formed onto and/or into the receiver 1040 and housing 32 that permit the receiver 1040 and the housing 32 to be engaged to one another in a snap-fit manner. The receiver 1040 of the mating key 1016 may optionally include one or more slots 1042 for receiving the engagement tabs 1032. The engagement tabs 1032 and slots 1042 are positioned such that they must engage one another before the terminals 1020 and 1022 may contact one another. Those of ordinary skill in the art will appreciate from this disclosure that although the vacuum 10a has been described thus far as including slots 1042 for receiving engagement tabs 1032 that are associated with the recharging base 75, the slots 1042 and engagement tabs 1032 may alternatively be associated with the recharging base 75 and the vacuum 10a, respectively.
With reference to
One especially significant aspect of providing various key and mating key combinations is the ability to provide a family of similar vacuums having different batteries (i.e., different voltages) yet which utilize as many common components as possible. In this regard, the various key and mating key combinations are employed to “key” a particular vacuum to a particular recharging base so as to prevent a vacuum from being coupled to a recharging base having a charging circuit that provides a charging voltage in excess of that which the batteries of the vacuum are designed to be charged.
With reference to
As those skilled in the art will appreciate from this disclosure, the recharging bases (i.e., the keys) may be configured so that they will only engage one vacuum (i.e., mating key). However, it is permissible for a recharging base (i.e., key) to receive more than one type of vacuum (i.e., mating key) so long as the charging voltage provided by the recharging base will not exceed the design charging voltage of any vacuum that may be engaged thereto. In the particular example provided, any member of the family of vacuums 2000 may be engaged to the recharging base 2010b. Furthermore, the vacuum 2004a may also be engaged to the charging bases 2004b, 2006b, and 2008b.
While the vacuum 10a has been described thus far as employing an elbow to impart a swirling action to an incoming dirt and debris laden air flow and a manually rotatable cleaning wheel for use in dislodging particles of dirt and debris from a filter, those skilled in the art will appreciate that the invention, in its broader aspects, may be constructed somewhat differently. For example, the vacuum 10c may employ one or more vanes to swirl the incoming dirt and debris laden air flow as shown in
As those of ordinary skill in the art will appreciate from this disclosure, vanes 600d for swirling the incoming dirt and debris laden air flow may be additionally or alternatively formed on another surface, such as the exterior surface 620 of the side wall 432d of the prefilter 412d, as illustrated in
Alternatively, the vacuum 10e may be configured as is shown in
The nozzle 720 includes an outlet 730 that directs an incoming flow of dirt and debris laden air tangentially into the prefilter 412e, thereby generating a swirling effect that tends to reduce the accumulation of dirt and debris against the side wall 432e of the prefilter 412e. This configuration is highly advantageous in that it permits the user to not only perform vacuuming operations with a single hand, but also to empty the vacuum 10e of dirt and debris with a single hand. More specifically, the user need only access the latch release 38 to unlatch the nozzle 720 from the housing assembly 14e to permit the nozzle 720 to pivot into the open condition. A detent (not specifically shown) may be employed to retain the nozzle 720 in the open condition. The user need only grasp the handle 168 of the housing assembly 14e and overturn the vacuum 10e to empty the contents of the prefilter 412e.
As is apparent from the discussion above, rotation of the cleaning wheel 300 when the impeller 90 is rotating renders the cleaning action relatively less effective (as compared to when the impeller 90 is not rotating) since dirt and debris that are dislodged when the cleaning wheel 300 is rotated tends to be immediately drawn back into the primary filter 414. Accordingly, it is within the scope of the present invention to include with the vacuum 10a a device that either locks the cleaning wheel 300 or electrically disables the fan assembly 72 when the cleaning wheel 300 is rotated. In
In the embodiments of
While the invention has been described in the specification and illustrated in the drawings with reference to various embodiments, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention as defined in the claims. Furthermore, the mixing and matching of features, elements and/or functions between various embodiments is expressly contemplated herein so that one of ordinary skill in the art would appreciate from this disclosure that features, elements and/or functions of one embodiment may be incorporated into another embodiment as appropriate, unless described otherwise, above. Moreover, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from the essential scope thereof. Therefore, it is intended that the invention not be limited to the particular embodiment illustrated by the drawings and described in the specification as the best mode presently contemplated for carrying out this invention, but that the invention will include any embodiments falling within the foregoing description and the appended claims.
The present application is a divisional of U.S. application Ser. No. 10/686,506, filed Oct. 15, 2003, now pending.
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Number | Date | Country | |
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20090144931 A1 | Jun 2009 | US |
Number | Date | Country | |
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Parent | 10686506 | Oct 2003 | US |
Child | 12371043 | US |