Patent Grant
8209815
The present disclosure relates to suction type surface cleaning appliances and more particularly to such appliances with cyclonic cleaning action for suction type cleaners having a dual stage cyclonic dust collector for suctioning dirt and debris from carpeted surfaces, other floor surfaces like hard floor surfaces, and surfaces of furniture and the like.
Floor care appliances of the suction action cleaning type are well known in the art. Such cleaners commonly referred to as vacuum cleaners are available in a variety of forms such as upright, canister, hand-held or stationary, or built into a house. Moreover, cyclonic designs have also been used on such floor care appliances as carpet extractors and “shop” type vacuum cleaners. In a typical suction or vacuum cleaner, a suction source generates the suction required to pull dirt from the carpet or floor being vacuumed through a suction opening and into a filter bag or a dust cup housed within the vacuum cleaner. After multiple uses of the vacuum cleaner, the filter bag must be replaced or the dust cup emptied.
To avoid the need for vacuum filter bags, and the associated expense and inconvenience of replacing the filter bag, another type of vacuum cleaner utilizes cyclonic air flow and perhaps one or more multi-use filters, rather than a replaceable filter bag, to separate the dirt and other particulates from the suction air stream. If filters are used, they would need infrequent replacement.
While some currently available cyclonic air flow vacuum cleaner designs and constructions are acceptable for many common types of dust and dirt materials in many situations, the need exists for continued improvements and alternative designs for such vacuum cleaners for improvement on cleaning efficiency for more of the various types of debris that need cleaned. Also it is desirable to simplify assembly and improve filtering and dirt removal. The cyclonic air flow can be generated from a single stage cyclonic separator or a multi-stage cyclonic separator. One challenge regarding the design of a multi-stage cyclonic separator unit is the dust collector, which needs to be compact and easily serviceable by the user. The dust collector generally includes a first cyclonic separator, a plurality of second cyclonic separators and at least one particle collector. The position of the second or plurality of second stage cyclonic separators poses additional design concerns. For instance, the second stage cyclones can be positioned above the first cyclone. However, this can increase the overall height of the dust collector, which is especially disadvantageous for canister vacuum cleaners. Alternatively, the second stage cyclones can be positioned around the first cyclone to form a separate, second particle collector. However, this can increase the overall width of the particle collector, which is especially disadvantageous for upright vacuum cleaners. Also, with such a design, the diameter of the first particle collector remains relatively small, which is disadvantageous from the standpoint of separation efficiency. As another alternative, the second stage cyclones can be positioned inside and at least partially below a top wall of the first cyclone. However with such a design, the second cyclones are hidden and difficult to service due to lack of access.
Therefore, while some prior art cyclonic air flow suction type cleaner designs and constructions are acceptable for cleaning many types of common dirt and dust in many instances, the need exists for continued improvements and alternative designs for such vacuum cleaners. For example, it would be desirable to simplify assembly, improve filtering and dirt removal, and allow easier maintenance of such suction type surface cleaners.
Accordingly, the present disclosure provides an improved dual stage cyclonic air flow design which overcomes certain difficulties with the prior art designs while providing better and more advantageous overall results.
In accordance with one aspect of the present disclosure, a dual stage cyclone dust collector for a suction type surface cleaner comprises a first upstream cyclonic In accordance with the present invention, a dual stage cyclone dust collector for a vacuum cleaner comprises a first upstream cyclonic separator for separating dust from dust-laden air and a plurality of downstream second cyclonic separators for separating remaining dust particles from air which has been partially cleaned by the first separator. Adjacent ones of the downstream separators have differing lengths. A first particle collector communicates with the first separator for collecting coarse dust particles. A second particle collector communicates with the second separators for collecting fine dust particles. The two particle collectors can be individually emptied.
Still other aspects of the invention will become apparent from a reading and understanding of the detailed description of the several embodiments described hereinbelow.
It should, of course, be understood that the description and drawings herein are merely illustrative and that various modifications and changes can be made in the structures disclosed without departing from this disclosure. Like numerals refer to like parts throughout the several views. It will also be appreciated that the various identified components of the dual cyclonic dust collector disclosed herein are merely terms of art that may vary from one manufacturer to another and should not be deemed to limit the present invention. It should be appreciated that the dual cyclonic dust collector can be adapted for use with a variety of household cleaning appliances, such as upright cleaners, carpet extractors, bare floor cleaners, “shop” type cleaners, canister cleaners, hand-held cleaners and built-in units. Moreover, the design could also be adapted for use with robotic units, which are becoming more widespread.
Referring now to the drawings, wherein the drawings illustrate several embodiments of the present invention only and are not intended to limit same,
The dirt cup 110 includes a first dust collection chamber 112 and a second dust collection chamber 114. The cyclone main body 102 includes a first cyclone part or first cyclonic stage 118 and a second cyclone part or second cyclonic stage 120. As will be described in greater detail below, the first and second dust collection chambers are configured to independently store dirt and dust particles separated by the respective first and second cyclone parts. The dirt cup 110 and the cyclone main body 102 can be made of a transparent material so that the presence of dirt can be seen in the dust collector 100.
As shown in
The first cyclone part 118 comprises a generally frusto-conically shaped first stage cyclone separator 150. Alternatively, the separator 150 could have a generally cylindrical shape. The first stage separator includes a dirty air inlet conduit 152 (
The airflow into the first stage separator 150 is tangential which causes a vortex-type, cyclonic or swirling flow. Such vortex flow is directed downwardly in the first stage separator by the top wall 154. Cyclonic action in the first stage separator 150 removes a substantial portion of the entrained dust and dirt from the suction air stream and causes the dust and dirt to be deposited in the first dust collection chamber 112 of the dirt cup 110. As shown in
Pivotally secured to a lower portion of the dirt cup 110 can be a bottom plate or lid 170, although other emptying constructions could also be employed. For instance those shown in copending and published patent application entitled “Separately Opening Dust Containers” Ser. No. 11/607,362 filed Dec. 1, 2006 can be used. A pivotable bottom lid allows for emptying of the first and second dust collection chambers 112 and 114, respectively. A seal ring (not shown) can be fitted around the bottom lid to create a seal between the bottom lid and the dirt cup 110. A hinge assembly (not shown) can be used to mount the bottom lid 170 to a bottom portion of the dirt cup. The hinge assembly allows the bottom lid to be selectively opened so that dirt and dust particles that were separated from the air stream by the first and second stage cyclones 118 and 120, respectively, can be emptied from the first and second dust collection chambers. A latch assembly (not shown) can be located diametrically opposed from the hinge assembly 142. Normally, the latch assembly maintains the bottom lid 170 in a closed position.
It should be appreciated that the bottom lid 170 can be configured to only allow for emptying of the first dust collection chamber 112, which requires emptying more frequently than the second collection chamber 114. In this case, a separate second bottom lid (not shown) can be hingedly mounted to the bottom portion of the dirt cup 110 to allow for independent emptying of the second dust collection chamber 114. A separate hinge assembly and latch assembly can be operably connected to such a second bottom lid. The separate hinge assembly would allow the second bottom lid to be independently, selectively, opened so that remaining dirt and dust particles that were separated from the air stream by the second cyclone part 120 can be emptied from the second dust collection chamber 114. Each bottom lid can include a device to delay the opening of the bottom lid and/or moderate movement of the bottom lid, causing the bottom lid, on release from its closed position, to be opened smoothly yet steadily and slowly. This delayed or slowed movement prevents the dirt collected in each collection chamber 112, 114 from being reintroduced into ambient air. The device can include conventional damping devices, such as a spring, piston and the like, and/or a mechanism integrated in each bottom lid or the dirt cup.
With continued reference to
The perforated tube 180 can also include at least one fin (not shown) mounted to an inside surface of the cylindrical section 182 and extending generally longitudinally through the perforated tube. The at least one fin serves to reduce or eliminate cyclonic flow inside the perforated tube.
Connected to a lower, closed end 188 of the perforated tube is a shroud 190 for retarding an upward flow of dirt and dust particles that have fallen below the lower end 158 of the first stage separator 150. The shroud has an outwardly flared section 192 and a flange 196 extending downwardly from the flared section. As is best illustrated in
A laminar flow member, such as one or more baffles or fins 210, is mounted to the closed lower end 188 of the perforated tube 180. At least a portion of the laminar flow member is encircled by the shroud 190. The laminar flow member extends generally along a longitudinal axis of the perforated tube and partially into the first dust collection chamber 112. The baffles 210 can be cruciform in shape and include a cross blade assembly, which can be formed of two flat blade pieces that are oriented approximately perpendicular to each other. It should be appreciated that the baffles may be formed of various shapes. For example, if a blade is employed, it can have a rectangular shape, a triangular shape or an elliptical shape, when viewed from its side. Also, in addition to a cross blade design, other designs are also contemplated. Such designs can include blades that are oriented at angles other than normal to each other or that use more than two sets of blades. The blades can be twisted along their length if so desired, as this may reduce the noise generated by the vacuum cleaner's cyclonic operation. These baffles can assist in allowing dirt and dust particles to fall out of the air stream between the perforated tube lower end and the bottom lid 170 of the first dust collection chamber 112.
With reference to
More particularly, the second stage cyclone 120 comprises a plurality of spaced apart, frusto-conical, downstream, second stage cyclonic separators 250. These are of significantly smaller diameter than the first stage cyclone. The downstream separators are arranged in parallel and are mounted radially on the air manifold 104 at least partially above of the first cyclone part 118. The separators project downwardly from the bottom wall 226 at least partially into the upper collection section 130 of the second dust collection chamber 114. As shown in
Each second stage or downstream separator 250 can have a dimensional relationship such that a diameter of its upper end can be about three times the diameter of its lower end. Further, as shown in
With reference again to
As shown in
As shown in
The top plenum 312 collects a flow of cleaned air from the filter 320 and merges the flow of cleaned air into a cleaned air outlet conduit 330 (
In operation, air entrained dirt passes into the upstream, first cyclone separator 110 through the inlet 152, which is oriented tangentially with respect to the sidewall 156 of the separator. The air then travels around the separation chamber where many of the particles entrained in the air are caused, by centrifugal force, to travel along the interior surface of the sidewall 156 of the separator 110 and drop out of the rotating air flow by gravity. However, relatively light, fine dust is less subject to a centrifugal force. Accordingly, fine dust may be contained in the airflow circulating near the bottom portion of the dirt cup. Since the cross blade 210 extends into the bottom portion of the first dust collection chamber 112 of the dirt cup 110, the circulating airflow hits the blade assembly and further rotation is stopped, thereby forming a laminar flow. In addition, if desired, extending inwardly from a bottom portion of the wall 138 of the first dust collection chamber 112 can be laminar flow members (not visible) which further prevent the rotation of air in the bottom of the dirt cup. As a result, most of the fine dust entrained in the air is also allowed to drop out.
The partially cleaned air travels through the openings 184 of the perforated tube 180. Thereafter, the partially cleaned air travels through the air manifold 104 and into the frusto-conical downstream cyclonic separators 250. There, the air cyclones or spirals down the inner surfaces of the cyclonic separators, separating out fine dust particles, before moving upward through the discharge guide tubes 300 and into the cover unit 106. The baffle 304 causes the air flowing through each discharge guide tube to have a laminar flow. Fine dirt separated in the downstream cyclonic separators collects in the second dust collection chamber 114. The cleaned air flows out of the downstream separators into the bottom plenum 310, through the filters 322 and 324, into the upper plenum 312 and into the cleaned air conduit 330. It will be appreciated that the volume of the bottom plenum can be generally the same as the volume of the upper plenum. The conduit 330 is in fluid communication with an air inlet to an electric motor and fan assembly. To empty the dirt collected in the dirt cup 110, once the dirt cup, or the entire dual cyclonic dust collector 100 is removed from the body of the vacuum cleaner, the lid 170 can be opened. At this point, the lid becomes accessible. In one embodiment, the dirt cup 110 can be selectively detached from the cyclone main body 102, to aid in emptying.
Similar to the aforementioned embodiment, a second embodiment of a dust collector for a vacuum cleaner is shown in
With reference to
As shown in
With reference now to
Pivotally secured to a lower portion of the dirt cup 510 is a bottom plate or lid 570. The pivotable bottom lid allows for emptying of the first and second dust collection chambers 512 and 514, respectively. This can occur once the dust collector 500, or at least the dirt cup 510 thereof, is removed from the body of the vacuum cleaner. A seal ring (not shown) can be fitted around the bottom lid to create a seal between the bottom lid and the dirt cup 510. A hinge assembly (not shown) can be used to mount the bottom lid 570 to a bottom portion of the dirt cup 510. The hinge assembly allows the bottom lid to be selectively opened so that dirt and dust particles that were separated from the air stream by the first and second stage cyclones 518 and 520, respectively, can be emptied from the first and second dust collection chambers. A latch assembly (not shown) can be located diametrically opposed from the hinge assembly. Normally, the latch assembly maintains the bottom lid 570 in a closed position.
Fluidly connecting the first cyclone part 518 to the second cyclone part 520 is a perforated tube 580. The perforated tube is removably disposed within the first stage separator 550 and extends longitudinally therein. In the depicted embodiment, the perforated tube has a longitudinal axis coincident with the longitudinal axis 540 of the first stage separator 550 and offset from the longitudinal axis 542 of the dirt cup 510. The perforated tube includes a generally cylindrical section 582. A plurality of openings or perforations 584 is located around the circumference of a portion of the length of the cylindrical section. The openings 584 serve as an outlet from the first stage separator 550, allowing the partially cleaned fluid to enter the second cyclone stage 520. Connected to a lower, closed end 588 of the perforated tube is a shroud 590 for retarding an upward flow of dirt and dust particles that have fallen below the lower end 558 of the first stage separator 550. A laminar flow member, such as one or more baffles or fins 610, is mounted to the closed lower end 588 of the perforated tube 580. At least a portion of the laminar flow member is encircled by the shroud 590.
An upper end or air outlet 620 of the perforated tube 580 is in fluid communication with an air inlet section 622 of the air manifold 504 positioned above the first stage separator 550. With reference to
With continued reference to
As best shown in
The cyclone cover 506 includes a bottom plenum 710 and a top plenum 712. The bottom plenum can be hinged (not visible) to provide access to the second stage separators 650 for cleaning. The bottom plenum collects a flow of cleaned air from the downstream separators 650 and directs the cleaned air through a first filter 720 and a second pleated filter 724, for filtering any fine dust remaining in the airflow exiting the downstream separators. The top plenum 712 collects a flow of cleaned air from the second filter 722 and merges the flow of cleaned air into a cleaned air outlet conduit 730. An outlet end 732 of the cleaned air outlet conduit is in fluid communication with an inlet of a vacuum cleaner electric motor and fan assembly.
With reference now to
Each downstream separator 830 includes a cylindrical upper part 870 and a frusto-conical lower part 872 and defines a longitudinal axis. At least one downstream cyclone can have an inclined longitudinal axis 876 wherein the lower part extends outwardly toward a wall 878 of the dirt cup 810. This configuration provides a more compact dust collector 800 in the vertical direction, which allows the dust collector to be more easily packaged. In other words, by angling the axes of at least some of the second stage cyclones 830 outwardly, the height of the dust collector 800 can be reduced. This is advantageous for creating a more compact dust collector. In the depicted embodiment of
Alternatively, as shown in
As shown in
Several embodiments of a dual cyclonic dust collector have been described herein. Obviously, modifications and alterations will occur to others upon reading and understanding the preceding detailed description. It is intended that the illustrated embodiments be construed as including all such modifications and alterations, insofar as they come within the scope of the appended claims or the equivalents thereof.
This application claims priority to U.S. provisional application Ser. No. 60/992,935 filed Dec. 6, 2007.
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| Number | Date | Country | |
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| 20100139033 A1 | Jun 2010 | US |
| Number | Date | Country | |
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| 60992935 | Dec 2007 | US |
