The present invention relates generally to floor cleaning devices having collapsible handles.
Electric vacuum cleaners are in widespread use in homes, offices and other places where quick and efficient floor cleaning is desired. Such vacuum cleaners are provided in various configurations, such as upright, canister, “stick,” and “powerhead” designs.
Upright vacuums are typically provided having a relatively large floor-engaging, wheeled nozzle base to which a pivoting rear housing/handle is attached. The base includes a suction nozzle directed towards the floor, and the rear housing includes a dirt storage receptacle (such as a cyclonic or non-cyclonic dirt separation chamber or a vacuum bag chamber), and a grip for manipulating the device. A vacuum fan and motor assembly (fan/motor) is located in either the base or the rear housing to provide a suction airflow that either draws air through the nozzle and dirt receptacle, or draws air into the nozzle and pushes it through the dirt receptacle. The base may also include an agitator driven by either the fan/motor, a separate motor, or an air turbine. Upright vacuums are also known to include a flexible hose and various cleaning tools for cleaning above the floor or in hard to reach areas.
Canister vacuums operate in the same manner as uprights with respect to generating a working air flow and separating dirt, but typically include a floor-cleaning nozzle base that is attached to a canister by way of a flexible vacuum hose. Like an upright, the nozzle base has a nozzle directed towards the floor, and may include an agitator driven by a motor in the base. The canister contains the fan/motor and dirt receptacle (again, of a bag, cyclonic or non-cyclonic bagless design).
Stick vacuums are, essentially, compact upright vacuums in which the size of the nozzle base has been minimized. These vacuums typically have a relatively small base, which may or may not have an agitator disposed in or near the air inlet. The fan/motor and dirt receptacle are typically located in a stacked arrangement in a narrow rear housing to provide the device with a slender, easily-stored profile. It can generally be said that stick vacuums are designed to locate as many of the working parts as possible in the rear housing, and in as compact a manner as practicable. Stick vacuums often use battery power, but some are corded.
Powerhead-type vacuums are the opposite of stick vacuums in that they are typically designed to locate most or all of the working parts in the nozzle base, and minimize the number of size of any parts that are located in the rear housing/handle. However, such vacuums often share the stick vacuum objective of being smaller or more compact than typical uprights and canisters. Examples of powerhead vacuums include those in U.S. Pat. Nos. 6,574,831; 6,317,920; 6,012,200; 5,829,090; 5,500,979; 5,319,828; 4,519,113; 3,618,158; and 1,829,582, all of which are incorporated herein by reference. In such devices, the nozzle base typically houses the nozzle, dirt receptacle and fan/motor, and may also include an agitator and an agitator motor (if it is not driven by the fan/motor). It is also known to power such devices using conventional electrical cords or batteries, which may be located in the base or the rear housing/handle. The rear housing includes a hand grip and serves the primary (and often the only) function of being a handle with which to guide the nozzle base. However, in some cases the rear housing has been provided with accessory tool storage areas, or has been adapted to serve as an accessory vacuum hose or wand.
While the known powerhead-type vacuum cleaners have been somewhat successful, there still exists a need to provide an improved powerhead-type vacuum cleaner.
In a first aspect, the present invention provides a vacuum cleaner having a base adapted to be moved on a surface to be cleaned, an inlet nozzle disposed on a lower surface of the base, a vacuum source operatively associated with the vacuum cleaner and adapted to draw a working airflow into the inlet nozzle, and a dirt receptacle operatively associated with the vacuum cleaner and adapted to remove dirt from the working airflow. A lower handle is pivotally attached to the base at a lower pivot, and an upper handle is pivotally attached to the lower handle at an upper pivot. The vacuum cleaner includes an automatically-operated lower pivot lock having a first position in which it restricts relative rotation between the lower handle and the base, and a second position in which it does not restrict relative rotation between the lower handle and the base. The vacuum cleaner also has a manually-operated upper pivot lock having a first position in which it restricts relative rotation between the upper handle and the lower handle, and a second position in which it does not restrict relative rotation between the upper handle and the lower handle.
In another aspect, the present invention provides a vacuum cleaner having a base adapted to be moved on a surface to be cleaned, an inlet nozzle disposed on a lower surface of the base, a dirt receptacle mounted in the base and in fluid communication with the vacuum inlet, and a vacuum source mounted in the base and adapted to generate a working flow of air into the vacuum inlet and through the dirt receptacle. The vacuum cleaner has a handle pivotally attached to the base. The handle includes a lower handle pivotally attached to the base at a lower pivot, and an upper handle pivotally attached to the lower handle at an upper pivot. The upper handle includes a lower section, an upper section telescopically mated to the lower section, and an adjustment mechanism adapted to selectively allow and prevent telescopic movement between the upper section and the lower section. The vacuum cleaner also has at least one electrical control attached to the upper section of the upper handle, and adapted to control at least one electrical device in the base.
In still another aspect, the present invention provides a vacuum cleaner having a base adapted to be moved on a surface to be cleaned, an inlet nozzle disposed on a lower surface of the base, a dirt receptacle mounted in the base and in fluid communication with the vacuum inlet, and a vacuum source mounted in the base and adapted to generate a working flow of air into the vacuum inlet and through the dirt receptacle. A handle is pivotally attached to the base. The handle includes a lower handle pivotally attached to the base at a lower pivot, and an upper handle pivotally attached to the lower handle at an upper pivot. The vacuum cleaner also includes an exhaust vent in fluid communication with and downstream of the dirt receptacle and the vacuum source. The exhaust vent is located on an upwardly-facing surface of the base.
Other embodiments, features and variations are also included within the scope of the invention.
The present invention generally provides a unique vacuum cleaner having a collapsible handle. While the embodiments described herein and illustrated in the accompanying figures are depicted as a vacuum cleaner, it will be understood that the invention can also be practiced as a wet or dry extractor, or as other types of special-purpose vacuum cleaners. As used herein, the expressions “vacuum cleaner” and “vacuum” are intended to include any cleaning device that uses a suction source to remove dirt or other undesirable substances from surfaces, regardless of whether it includes specialty features, such as a fluid deposition system and fluid recovery tank (as in wet extractors), and regardless of what type of dirt separation system it uses (such as cyclonic, bag, or dirt cup separation systems). These and other variations will be apparent to those of ordinary skill in the art in view of the present disclosure.
Referring now to
The handle 104 comprises a lower handle 106 and an upper handle 108, which are joined to one another at a mid-handle joint 110. A grip 112 is provided at the top of the upper handle 108, and shaped to provide ergonomic control of the device. As shown in this embodiment, the lower handle 106 comprises a yoke having two uprights. This construction has been found to be particularly useful because the bifurcated lower handle 106 can be pivoted forward to straddle the base 102, providing a very compact folded assembly. In this embodiment, the upper handle 108 pivots backwards, and rests on or next to a carrying handle 116 on the base 102. Preferably, the upper handle rests in a groove 118 located along the top of the carrying handle 116. In this embodiment, the carrying handle 116 is remains functional to move the vacuum cleaner 100, even when the handle 104 is folded, and the vacuum cleaner 100 may even be operational in this position. A lock (not shown) may be provided on the carrying handle 116 or upper handle 108 to lock the two together to prevent inadvertent unfolding.
While the foregoing yoke and post arrangement for the lower and upper handles 106, 108 is preferred, it is also envisioned that the lower handle 106 could be replaced with a single post pivotally attached along, or offset from, the longitudinal centerline of the base 102. In such an embodiment, a compact folded shape may still be obtained, for example, by shaping the base 102 with notches or troughs into which the upper and/or lower handles fit. The upper handle may also deviate from the shown single post construction.
The mid-handle joint 110 joins the upper and lower handles 108, 106, and can lock the lower and upper handles 106, 108 together into an unfolded position, as shown in
The lower end of the lower handle 106 is pivotally attached to the base 102. This pivotal attachment preferably is on an axis concentric with the rotational axis of a pair of rear base wheels 114, but other attachment points and axes or rotation are also possible. A lower pivot lock 1374 (
Referring now more specifically to
The grip 112 is attached to one end of a telescoping tube 314 to form the upper telescoping portion 302. The grip 112 includes a main grip housing 306, an upper grip housing 308, a lower grip housing 310, and a control plate 312. The grip 112 may include one or more overmolded surfaces or textured surfaces to enhance the user's feel on the grip 112. In the shown embodiment, the main grip housing 306 slides over the end of the tube 314, and is held in place by a screw boss 316 that extends rearwardly from the control plate 312 into a corresponding hole 318 in the tube 314. A screw (not shown) is inserted through the lower grip housing 310 and engaged with the screw boss 316 to hold the parts together. In addition, the tube 314 has a non-circular profile that engages with a correspondingly-shaped opening in the bottom of the of the main grip housing 306 so that the grip 112 and tube 314 can not rotate relative to one another.
The control plate 312 includes any buttons, switches or other controls that are desired for operating the device. In a preferred embodiment, these controls include a first button that turns on a vacuum fan motor, a second button that turns on both the vacuum fan motor and a brushroll motor, and a third button that turns the fan motor and brushroll motor off. Pressing the any of the buttons overrides the other buttons, so, for example, if the user has pressed the second button to activate the fan and brushroll motors, but subsequently presses the first button, then the brushroll motor will turn off, and the fan motor will remain on. A control wire bundle 320 is attached these controls, and passes downward through the telescoping tube 314, with sufficient slack to allow it to remain attached even when the upper handle 108 is fully extended. The routing of the wire bundle 320 is discussed in greater detail herein.
The lower telescoping portion 304 of the upper handle 108 comprises a rear housing 322 and a front housing 324. The rear housing 322 has an internal sleeve 326 that is shaped and sized to slidingly receive the telescoping tube 314. Rotation between the tube 314 and rear housing 322 is prevented by using a pin and groove arrangement, by making the telescoping tube 314 and sleeve 326 with mating non-circular shapes, or by other known mechanisms. Examples of such arrangements are shown in U.S. Pat. Nos. 6,311,366 and 6,766,559, which are incorporated herein by reference. While the sleeve 326 is shown in the rear housing 322, it will be appreciated that it may instead be in the front housing 324, or otherwise formed therebetween.
The front and rear housings 324, 322 of the lower telescoping portion 304 include, at their bottom ends, complementary front and rear pivot surfaces 328, 330. When the front and rear housings 324, 322 are attached to one another, the pivot surfaces 328, 330 form a pair of circular rings, one on each side of the upper handle 108, that fit around corresponding cylindrical pivot surfaces 408 (
Referring now to
The back surface of the slider 338 includes a pair of protrusions 346 and a pair of slider detents 348, which are alternately located on the lock 338, and spaced apart by approximately the same distance as the space between the rollers 340. The slider 338 is movable between a locked position (shown) and an unlocked position. In the locked position, the protrusions 346 are adjacent the openings 342, and press the rollers 340 in to the openings 342 and into engagement with the tube detents 344. In this position, the engagement between the rollers 340, openings 342, and tube detents 344 prevents the telescoping tube 314 from moving relative to the internal sleeve 326. In the unlocked position, the slider 338 is moved until the slider detents 348 are adjacent the openings 342, which allows the rollers 340 to move into the slider detents 348 and out of engagement with the tube detents 344, thus allowing the tube 314 to slide within the sleeve 326. A spring 350 is provided to bias the slider 338 into the locked position.
While the foregoing embodiment is preferred, numerous variations are possible. For example, it may instead be desirable to only offer two telescopic positions, in which case tube detents 344 would be appropriately located to allow these positions. Also, the upper handle may use a lock that allows an unlimited number of different locking positions. The telescoping lock may also have any suitable alternative construction, such as those incorporated above or shown in U.S. Pat. Nos. 6,474,696, 5,941,575, 5,332,266, and 5,046,761, which are incorporated herein by reference. Still further, the upper handle 108 may instead be non-telescoping. In addition, while the upper and lower tubes are described as being “tubes,” neither is required to be round or hollow. The tubes may instead comprise adjacent colinearly sliding parts, rather than concentric sliding parts. These and other variations will be understood by those of ordinary skill in the art, and are within the scope of the present invention.
Referring now to
Referring now to
A lower pivot ring 412 is attached to the bottom end of each upright member 402, 404 by screws or other mechanisms. Each pivot ring has a cylindrical flange 442, and one or both pivot rings 412 may include one or more radially-extending catches 444. The purpose and details of the pivot rings 412 are described subsequently herein.
The upright members 402, 404 may be encased between respective inner housing shells 414 and outer housing shells 416. These may be added to provide an improved cosmetic appearance, to add structural strength, to cover internal parts, and so on. In the shown embodiment, the outer housing shells 416 are attached to the upright members 402, 404 by screws, and the inner housing shells 414 are attached by snap fitment. Of course, other attachment mechanisms may be used instead. Caps 418 are provided for each outer housing shell 416 to cover the ends of the lower handle axle 406.
The upright members 402, 404 each include a cylindrical pivot surface 408. The pivot surfaces 408 extend with their cylindrical axes oriented horizontally and colinearly. As shown in
As shown in
As shown in
Referring now to
As shown in
The locking bar 426 is released from the catch 1002 by sliding it upwards along the side of the first upright member 402. This can be accomplished in a number of ways, but in a preferred embodiment, it is performed by lifting the locking bar 426 by a loop 430 located adjacent the mid-handle joint 110. As shown in
The lifting cam 432 has lobed profile with one or more areas having a relatively large radius, and one or more flats 436 or other areas having a relatively small radius. When the upper handle 108 is in the unfolded position, the cam 432 is oriented such that the flat 436 abuts the upper end of the loop 430 and allows the locking bar 426 to drop to a relatively low position and engage with the catch 1002. A spring (not shown) may be provided to force the locking bar 426 downwards. When the upper handle 106 is rotated relative to the lower handle 106, the upper handle axle 334 rotates and turns the cam 432 such that the a portion of cam 432 having a larger radius abuts the loop 430, and thereby lifts it upwards along the first upright member 402. The change in radius of the cam 432 is sufficient to lift the locking bar 426 completely out of engagement with the catch 1002, thus allowing the lower handle 106 to rotate forward into the folded position.
While the foregoing cam and follower arrangement is preferred, other mechanisms may be used, such as a mechanical linkage, cables, and so on. Such alternatives will be readily apparent to those of ordinary skill in the art in view of the present disclosure.
The upper and lower handles 108, 106 and their respective parts may be assembled in any useful manner and made from any suitable materials. Generally plastic materials are suitable, but some parts may benefit from the increased strength of metal. Such parts include the telescoping tube 314, rollers 340, handle axles 334, 406, upright members 402, 404, pivot rings 412, and locking bar 426.
A number of variations on the illustrated handle locking mechanism may be provided with the present invention, and the invention is not limited to the shown types of locks or manner of operating them. For example, the telescoping lock 337 and mid-handle joint lock 352 may be mechanically joined and operated by a single pushbutton. As another example, the mid-handle joint lock 352 may be operated by a pushbutton located at the bottom of the internal sleeve 326 on the upper handle 108, and actuated by pressing the telescoping tube 314 against it. Such an internal operating mechanism may take the place of the existing operating button 356, or be provided as an alternate unlocking mechanism. As still another variation, the device may include a mechanism for operating the lower pivot locking bar 426 separately from the mid-handle pivot lock 352. For example one of the lower handle caps 418 may be replaced by a rotatable dial that allows the operator to manually lift the locking bar 426. In another variation, the locking bar 426 may instead be used to activate a lever or other mechanism on the base 102 to release the handle 104 to allow forward rotation. For example, the pivot ring 412 may be modified to include an additional catch 444 that contacts the lower pivot lock 1374 (
The present invention also provides a novel electrical routing system for a folding handle. While this electrical routing system is shown in use with a vacuum cleaner, it is expected to be useful in other devices in which it is desired to include an electrical control at the end of a folding handle. As previously noted, a control plate 312 is provided on vacuum cleaner grip 112, and a control wire bundle 320 is attached to the control plate 312. The wire bundle 320 extends through the telescoping tube 314, with enough slack to allow the upper handle 108 to be fully extended without unduly stretching or breaking the wire bundle 320. In a preferred embodiment, this slack is provided by forming a coil 321 in the wire bundle 320, which, by nature of its naturally coiled relaxed shape, retracts to some degree when the upper handle 108 is compressed to help prevent it from being pinched between the telescoping tube 314 and sleeve 326.
As shown in
Referring now to
It will be appreciated that various clips, springs, tensioners or other retainers or devices may be provide at any suitable location along the wire bundle 320 to hold it in place, take up slack, and prevent chafing, rubbing, pinching, and/or the risk of being damaged by undue stretching. For example, a retaining loop 1202 (
A preferred attachment between the lower handle 106 and the base 102 is illustrated in
A retainer ring 1114 attaches to each mounting member 1104. Each retainer ring 1114 includes three generally cylindrical bushing surfaces: an inner bushing 1116, a medial bushing 1118, and an outer bushing 1120. The inner and medial bushings 1116, 1118 are joined by a radial wall 1122, from which three mounting posts 1124 protrude. The mounting posts 1124 are shaped to fit over the retainer screw bosses 1112 and screws 1204 pass through these parts to hold the retainer ring 1114 in place, as shown in
As best shown in
The retainer rings 1114 also provide bearing surfaces for the rear wheels 114. As best shown in
When the wheel 114 is installed over the retainer ring 1114, the outer wheel flange 1206 is adjacent the medial bushing 1118, and the inner wheel flange 1208 is adjacent the inner bushing 1116. In use, the wheels 114 support the vacuum cleaner 100 by a sliding contact relationship between the medial and inner bushings 1118, 1116 and the outer and inner wheel flanges 1206, 1208. As such, like the outer bushing, 1120, the medial and inner bushings 1118, 1116 are preferably made of a low friction or self-lubricating material. In addition, the retainer ring 1114 preferably also includes an axially-extending annular protrusion 1132 against which the inner surface of the wheel 114 can slide when it is fully installed. This protrusion 1132 is expected to allow the wheel 114 to be installed with a relatively small gap (or no gap) between the wheel 114 and the non-rotating parts, to thereby improve product fit and finish and reduce wheel vibration and other undesirable conditions associated with loose wheels.
As with the outer bushing 1120, the inner and medial bushings 1116, 1118 may alternatively be separate pieces, and may includes lubrication holes or fittings, dirt removing slots, bearings or other useful features to provide a rotating joint. Still other variations of the foregoing wheel and handle attachments will be apparent to those of ordinary skill in the art in view of the present disclosure.
The wheels 114 may include various additional features to improve their performance or aesthetic appearance. For example, each rear wheel 114 includes a hubcap 1134 to cover the recessed center portion 1128 and mounting screw 1210. In a preferred embodiment, each hubcap 1134 comprises a generally flat circular part having a number of axially extending snap tabs 1136 that fit into corresponding openings 1138 in the wheel 114. When attached, the hubcaps 1134 provide a smooth outer appearance, and protect the wheel attachment from dirt, hair, and other debris. The wheels 114 also may include an overmolded or otherwise attached tread surface 1140. Other features will be apparent to those of ordinary skill in the art in view of the present disclosure.
Referring now to
The base 102 comprises a lower base housing 1302 that serves as the structural platform upon which the vacuum cleaner base 102 is constructed. The lower base housing 1302 includes, at its forward end, a downwardly-facing and laterally-elongated air inlet nozzle 1306 that is adapted to face and apply suction to or near a surface that is desired to be cleaned. While it is not required, it is preferred to provide a brushroll 1304 in the inlet nozzle 1306 to agitate the surface. The brushroll 1304 is rotatably disposed within the inlet nozzle 1306, and covered by a soleplate 1314 having a number of apertures 1316 through which the brushroll's agitating members (bumps, flaps, bristles, or the like) extend to contact the surface being cleaned. The soleplate 1314 (or the bottom of the housing 1302) may also include support wheels 1318 or skids (not shown) to regulate the height of the inlet nozzle 1306 relative to the surface. The wheels 1318 or other support mechanisms may be adjustable so that the user can control the inlet nozzle 1306 height.
In the embodiment of
A brushroll motor cover 1320 may be provided to capture the brushroll motor 1312 in place in the lower base housing 1302. The brushroll motor cover 1320 may also seal around the brushroll motor 1312 and have an air outlet connected to the vacuum cleaner's dirt filtration system to filter out any carbon dust or other debris generated by the brushroll motor 1312 itself. While the brushroll motor cover 1312 is shown as a separate housing part, it may instead simply comprise tie-down straps, or be formed as part of the underside of the upper base housing 1404 (
Such brushrolls 1304, support wheels 1318, soleplates 1316, motors 1312, and variations thereof, are known in the art. Any useful combination of these and other features may be used with the present invention. Other features commonly used with vacuum cleaner inlets and brushrolls, such as downwardly-extending skirts or bristles, edge cleaning brushes, viewing windows, and the like, may also be used with the present invention.
A main circuit board chamber 1310 is located in the front portion of the lower base housing 1302, preferably behind the inlet nozzle 1306 on the opposite lateral side of the housing 1302 as the brushroll motor chamber 1308. A main circuit board (not shown) is positioned within this chamber 1310, and provides various electrical control functions for the device. For example, the main circuit board may include pressure differential sensors to determine when filters are preventing adequate airflow through the device. The main circuit board also may control electronics to operate the motor(s), shut off the device in the event of fault or safety conditions, regulate battery charging, and so on. These and other functions are known in the art, and any variations thereof may be used with the present invention.
Referring now to
The bag chamber 1322 comprises a box-like structure having an open top 1326, an air inlet 1328, and an air outlet 1502 (
The bottom and side walls of the bag chamber 1322 preferably include a number of ribs 1344. When a filter bag (not shown) is positioned within the bag chamber 1322, the ribs 1344 hold the bag away from the walls and thereby allow the working air flow to pass through a greater portion of the bag's surface area, as known in the art. The ribs 1344 may have any useful shape that promotes increased airflow to the bag chamber outlet 1502.
In the shown embodiment, the fan/motor 1324 comprises a single unified part that combines an air impeller 1324′ and an electric motor 1324″ in a compact package. Such combined units are well-known in the art. Of course, the impeller 1324′ and motor 1324″ may optionally be provided separately, if desired. The fan/motor 1324 preferably is mounted within a motor shroud 1332 that is attached to the back of the bag chamber 1322 to ensure proper alignment between them. The motor shroud 1332 has a motor shroud inlet 1338 located adjacent the bag chamber outlet 1502, and a motor shroud outlet 1340 located vertically above the fan/motor 1324. The motor shroud inlet 1338 abuts a correspondingly-shaped outlet flange 1342 on the bag chamber 1322 to provide an air-tight passage from the bag chamber outlet 1502 to the impeller 1324′. A motor outlet grill 1508 (
The motor is suspended within the shroud 1332 by a front motor gasket 1334 and a rear motor mount 1336. As shown in
The vacuum cleaner's dirt separation system may also includes a post-motor filter 1346 (not shown in
The dust separation system may also include a bag-in-place feature that prevents operation of the vacuum cleaner when no bag (or an improper bag) has been installed in the bag chamber 1322. As shown in
The bag-in-place feature is overcome by installing the proper vacuum bag 1606 in the bag chamber 1322. The vacuum bag 1606 includes a mounting flange 1360 having an elastic seal 1362 surrounding its opening 1364. To install the bag 1606, the user presses the pivoting panel 1348 towards the bag chamber inlet 1328, and places the flange 1360 over the end 1331 of the nozzle adapter 1330. The opening 1364 through the elastic seal 1362 is smaller than the nozzle adapter 1330, and elastically grips against the nozzle adapter 1330. In doing so, the elastic seal 1362 holds the bag flange 1360 and pivoting panel 1348 in place against the spring-loaded pivot assembly 1352. In this position, the upper end 1356 of the pivoting panel 1348 fits within a slot 1608 in the bag chamber lid 1604, which allows the lid 1604 to be fully seated on the bag chamber 1322. Also in this position, the bag chamber lid 1604 engages the electrical cutoff switch 1358, and activates the vacuum cleaner's power circuit.
Various other features of dust separation systems may also be incorporated into embodiments of the present invention. Non-limiting examples of such well-known features include: pressure sensors to determine cleaning performance, air bleed ports, thermal cutoff devices, multistage separators, bag or cyclone filter cleaning features, and so on.
A vacuum cleaner of the present invention may be powered by batteries or a conventional power cord. When a power cord is used, it may be a conventional fixed external cord, or retractably mounted on a cordreel, as shown in
This arrangement of the inlet nozzle 1306, bag chamber 1322, fan/motor 1324, and vertical cordreel 1366 has been found to provide a highly compact assembly, particularly when used in conjunction with a folding handle, as described previously herein. In addition, the position and shape of the inlet nozzle 1306, nozzle adapter 1330, bag chamber 1322 and fan/motor 1324 provides a relatively straight and short air flow path, which is expected to minimize suction loss between the fan/motor 1324 and the inlet nozzle 1306. While this arrangement is preferred, alternative arrangements are also expected to provide space savings and efficient operation. For example, the cordreel 1366 and/or the fan/motor 1324 may be partially or entirely contained within a large central hub of a rear wheels. In such an embodiment, it may be desirable to orient the fan/motor 1324 with its rotating axis parallel to and approximately concentric with the rear wheel rotation axis. In such an embodiment, the air may exit the vacuum cleaner through the wheel hub itself.
The lower base housing 1302 also includes a lower pivot lock 1374 that is adapted to engage one or both of the pivot rings 412 that mount the lower handle 106 to the base 102. As shown in
The lower base housing 1302 may also include any other useful vacuum cleaner features. For example a light (not shown) may be provided to illuminate the surface being cleaned. The lower base housing 1302 may also have one or more displays 1380, 1382 to provide the user with status information regarding the vacuum cleaner, as known in the art. One or more windows (not shown) may be used to cover and protect the displays 1380, 1382. Of course, these displays 1380, 1382 and other features may be consolidated as a single display, or may be located elsewhere, such as in the upper base housing 1404 (
Referring now to
In a preferred embodiment, the inlet nozzle portion of the lower base housing 1302 is covered by a font bumper 1402, which may comprise a rubber or other soft, elastic material, and much of the remainder of the lower base housing 1302 is covered by an upper base housing 1404. Screws, snap engagement, or other fastening devices or methods may be used to hold these and other parts of the housing together. The upper base housing 1404 preferably includes a first opening 1406 that overlies the open top 1326 of the bag chamber 1322, and a second opening 1408 that overlies the motor shroud outlet 1340. The upper base housing 1404 also includes a forward catch 1410, and a rearward catch 1412. One or more gaskets (not shown) may be provided around one or both of the openings 1406, 1408 to provide an airtight seal against the bag chamber 1322 and motor shroud 1332.
A pair of wheel arches 1414 are provided one either side of the base 102 adjacent the wheels 114. The wheel arches 1414 provide a smooth contour between the base 102 and the wheels 114, and the bottom outer edge 1416 of one of the wheel arche 1414 forms a portion of the semi-circular slot 1102 into which the wire bundle 320 passes, as shown in
A cover assembly 1420 is provided to releasably attach to the upper base housing 1404. The cover assembly 1420 comprises an outer lid 1422, an inner lid 1424, a vent shroud 1426, and a handle 1428. The inner lid 1424 is attached to a lower, forward portion of the outer lid 1422, and the vent shroud 1426 is attached to the top of the outer lid 1422. The vent shroud 1436 covers a central air passage 1423 in the outer lid 1422 that begins at a rear opening 1425 through the bottom of the outer lid 1422, and ends at the vent shroud 1426 mounting location. The vent shroud 1426 includes a number of holes 1427 or other apertures to allow air to flow through it. In addition, a foam block or additional filter may be located in the central air passage 1423 beneath the vent shroud 1426. The handle 1428 is preferably formed by an upper handle portion 1432 and a lower handle portion 1434. One or both of the handle portions 1432, 1434 may include grip-enhancing features, such as an overmolded rubber layer, dimples, or checkering.
The cover assembly 1420 is selectively attachable to the upper base housing 1404 by inserting a forward tab 1430 on the outer lid 1422 into the forward catch 1410, and a rearward tab 1510 (
Referring now to
The use of a single cover assembly 1420 is preferred because it provides simple and simultaneous access to both the bag chamber 1322 and the post-motor filter 1346, if one is used. In addition, the shape of the cover assembly 1420 and its central air passage 1423 may contribute to noise reduction by providing a relatively circuitous path for the exiting air flow. This exit air flow path is also relatively short, which reduces pressure build-up. The location of the air holes 1427, which direct the exiting air upwards, may also help to prevent the vacuum cleaner exhaust air from scattering dirt and dust on the floor around the vacuum cleaner, and also prevents the air from striking the operator's feet and legs during operation. Despite the expected benefits of these features, alternative constructions, such as one in which two separate covers provided to separately access the bag chamber 1322 and post-motor filter 1346, may alternatively be used with embodiments of the present invention.
While the embodiments described herein are preferred, they are not intended to limit the scope of the invention. Many additional variations of the embodiments described herein will be apparent to those of ordinary skill in the art in view of the present disclosure and with practice of the invention. Furthermore, while various features of the invention have been described as being used together, it will be appreciated that many of these features have separate utility and inventiveness on their own, and are not all required to be used together in every or any embodiment of the invention. As such, the present invention includes embodiments in which the features described herein are used individually or in various other inventive combinations. Such alternative embodiments, modifications and combinations of the various features described herein are within the scope of the present invention, which is limited only by the appended claims.
This patent claims priority to U.S. Provisional Application Nos. 60/644,020, filed on Jan. 18, 2005, and 60/673,359, filed on Apr. 21, 2005, each of which is incorporated herein by reference in its entirety.
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