Vacuum cleaners can include a wiper blade or strip brush mounted adjacent to a suction nozzle opening for collecting dirt and debris, in addition to a main agitator, such as a rotatable brushroll. In some cases, the wiper blade or strip brush can be pivotally mounted to the nozzle housing for pivotal movement relative to the nozzle housing. Some vacuum cleaners can also include a mechanism for raising or lowering the agitator relative to the surface to be cleaned, which can simultaneously raise or lower the wiper blade or strip brush relative to the surface to be cleaned.
According to one embodiment of the invention, a vacuum cleaner comprises a housing adapted to be moved across a surface to be cleaned in at least a forward stroke and a rearward stroke, and having a suction nozzle opening, a suction source in fluid communication with the suction nozzle opening for generating a working air stream through the housing, a debris collection blade adjacent to a rear of the suction nozzle opening, and a multiply-adjustable coupling between the debris collection blade and the housing and comprising a hinged linkage assembly that hingedly couples the debris collection blade to the housing for automatic compound adjustment of the debris collecting blade relative to the suction nozzle opening and surface to be cleaned to collect debris on the forward stroke of the vacuum cleaner and to float over debris on the rearward stroke.
In the drawings:
The invention relates to vacuum cleaners and in particular to vacuum cleaners having an agitator assembly and a suction nozzle. In one of its aspects, the invention relates to an improved suction nozzle that houses an agitator and further comprises a debris collecting blade provided along the rearward edge of the suction nozzle and rearwardly of the agitator for collecting debris (which may include dirt, dust, soil, hair, and other debris). For purposes of description related to the figures, the terms “upper,” “lower,” “right,” “left,” “rear,” “front,” “vertical,” “horizontal,” and derivatives thereof shall relate to the invention as oriented in
As illustrated, the vacuum cleaner 10 comprises an upper housing 12 pivotally mounted to a lower base 14. The upper housing 12 generally comprises a main support section 16 for supporting and receiving a collection system 18 for separating and collecting debris from a working airstream for later disposal. In one conventional arrangement illustrated herein, the collection system 18 can include an integrally formed separation/collection module 20 comprising a separator 22 and debris cup 24, with the debris cup 24 provided with a bottom-opening debris door for disposal of the collected debris. The separator 22 can comprise a cyclone separator with a single cyclonic separation stage, or multiple stages. In another conventional arrangement, the collection system 18 can include a cyclone separator for separating debris from a working airstream and a separately removable debris cup for receiving and collecting the separated debris from the cyclone separator. It is understood that other types of collection systems 18 can be used, such as centrifugal separators or bulk separators. In yet another conventional arrangement, the collection system 18 can include a filter bag. The vacuum cleaner 10 can also be provided with one or more additional filters upstream or downstream of the collection system 18.
The upper housing 12 is pivotally mounted to the base 14 for movement between an upright storage position, shown in
The upper housing 12 also has an elongated handle 28 extending upwardly from the main support section 16 that is provided with a hand grip 30 at one end that can be used for maneuvering the vacuum cleaner 10 over a surface to be cleaned. A motor cavity 32 is formed at a lower end of the support section 16 and contains a conventional suction source such as a motor/fan assembly (not shown) positioned therein in fluid communication with the collection system 18. The vacuum cleaner 10 can also be provided with one or more additional filters upstream or downstream of motor/fan assembly.
The agitator 40 comprises a generally cylindrical brush dowel 42 with a bearing 46 on both ends and a belt engagement surface 48 around the circumference of the dowel 42 near one end that communicates with the belt 44. A plurality of bristle tufts 50 project or extend from the outer circumference of the brush dowel 42. Each bristle tuft 50 can include a plurality of flexible bristles, which may be made from a durable polymer material such as nylon or polyester, for example. The tufts 50 can be arranged in a generally helix pattern in rows along the outer circumference of the brush dowel 42, although other tuft configurations are possible.
A suction nozzle opening 54 is formed in the sole plate 36 and is in fluid communication with the agitator chamber 38. A duct 56 is coupled at one end to the agitator chamber 38 and fluidly communicates the suction nozzle opening 54 with the collection system 18 (
As best shown in
The reduced height H1 of the duct inlet 58 relative to the height H2 of the agitator chamber 38 restricts or chokes off the working air that flows through the duct inlet 58 so that the working air is evenly distributed across the entire width of the duct inlet 58. The reduced height H1 can also increase the velocity of working air flowing along the entire width of the duct inlet 58 as well as the outward portions of the agitator housing 38, which can enhance entrainment and ingestion of debris and can reduce potential for re-entrainment of debris within the agitator chamber 38.
Referring to
In operation, the vacuum cleaner 10 draws in debris-laden working air through the suction nozzle opening 54, agitator chamber 38 and through the duct 56. The duct 56 funnels the working air flowing from the agitator chamber 38 through the reduced height H1 of the duct inlet 58 and evenly distributes the working air across the entire width of the duct inlet 58. The air flows through the duct 56 in the base 14 and into the downstream collection system 18 where the debris is substantially separated from the working air. The air flow then passes through the motor cavity 32 and past the suction source prior to being exhausted from the vacuum cleaner 10. The collection system 18 can be periodically emptied of debris.
Referring to
Referring to
As best shown in
The blade assembly 68 includes a left and right pivot pin 84, 86 that protrude outwardly along blade axis Y. The left and right pivot pins 84, 86 are configured to be pivotally mounted within the corresponding left and right mounting track 74, 76 so that the blade assembly 68 can pivot about axis Y. The length of the mounting tracks 74, 76 are greater than the diameter of the pivot pins 84, 86, allowing the pivot pins 84, 86 to also slide vertically within the mounting tracks 74, 76. Thus, the blade assembly 68 can automatically adjust vertically to maintain contact with the surface to be cleaned regardless of height variations between the base 14 and the surface to be cleaned. Such height variations can arise from different surface types, such as carpets with different pile heights or hard floor surfaces, for example, or from different nozzle height settings if the vacuum cleaner 10 incorporates a height adjustment mechanism. For example, the blade assembly 68 can slide downwardly in the mounting tracks 74, 76 to maintain contact with the surface to be cleaned when the vacuum cleaner 10 is used on lower pile height carpets or hard floor surfaces, or elevated nozzle height settings. Conversely, the blade assembly 68 can slide upwardly in the mounting tracks 74, 76 to accommodate higher pile height carpets or lower nozzle height settings.
In the illustrated embodiment, the blade assembly 68 comprises an elongated scoop 88 that scoops up debris on a forward stroke of the vacuum cleaner 10 and glides over the surface to be cleaned on a rearward stroke of the vacuum cleaner 10. The blade assembly 68 further includes a pair of support ends 90 formed integrally with and extending from the ends of the scoop 88. The support ends 90 comprise triangular-shaped plates and the scoop 88 is connected to a lower portion of each support end 90. The left and right pivot pins 84, 86 protrude outwardly from an upper portion of each support end 90 along blade axis Y.
Conversely, the lower surface 98 is defined by a convex glide 102 that extends from the front edge 92 to the bottom of the rear wall 96 for gliding the blade assembly 68 across the surface to be cleaned and for riding up and floating the blade assembly 68 over debris on a rearward cleaning stroke. The junction between the glide 102 and the rear wall 96 is also rounded to prevent plowing debris and to prevent catching or snagging the surface to be cleaned.
Referring to
On a rearward cleaning stroke, the blade assembly 68 can pivot forwardly and transition from a first position where the blade assembly 68 is supported on the front edge 92 to a second position where the blade assembly 68 is supported on the glide 102. However, the stop tabs 82 limit the forward blade position to maintain a minimum glide approach angle β which is defined as the angle between the glide 102 and the surface to be cleaned S on a rearward cleaning stroke. The glide approach angle β comprises an acute angle greater than 0 degrees and less than 90 degrees so that the lower surface 98 of the scoop 88 is inclined relative to the surface S so the glide 102 can ride up and float over large dirt particles or debris located rearwardly of the blade assembly 68. The glide approach angle β further defines a gap G between the bottom of the rear wall 96 and the surface to be cleaned S. The gap G provides clearance for the rear wall 96 to slide over large debris on a rearward cleaning stroke. Upon passing through the gap G the large debris can contact the glide 102 and wedge against the lower surface 98 of the blade assembly 68, which forces the blade assembly 68 to float upwardly in the flexible coupling 70 so it can pass over large debris D which can then be ingested through the suction nozzle opening 54. When the debris D clears the front edge 92, the blade assembly 68 slides downwardly in the flexible coupling 70 and the glide 102 returns into contact with the surface S and glides along the surface S. Thus, the blade assembly 68 is configured to slide up and float over debris D on the surface S on a rearward cleaning stroke so that the debris D can be ingested through the suction nozzle opening 54 rather than getting plowed rearwardly by the scoop 88.
In operation, the blade assembly 68 automatically adjusts to the surface to be cleaned S by sliding vertically within the flexible coupling member 70.
As the base 14 is pushed in a forward stroke, F, friction between the lower surface 98 of the scoop 88 and the surface to be cleaned S pivots the blade assembly 68 rearwardly, in a counterclockwise direction about axis Y. The scoop 88 swings counterclockwise about axis Y until the front edge 92 digs into the surface, S, and drags across the surface to be cleaned, S. At the same time, the agitator 40 rotates forwardly (e.g. counterclockwise as shown in
When the blade assembly 68 encounters debris D, the blade assembly 68 transitions to a third position raised above surface S, shown in
The flexible coupling members 70 may further comprise a biasing device (not shown) configured to urge the blade assembly 68 vertically downward such that the front edge 92 maintains consistent contact with the surface to be cleaned on a forward stroke. This may be achieved by adding springs or weights to the flexible coupling member 70 in register with the left and right pivot pins 84, 86 to urge the left and right pivot pins 84, 86 downwardly within the mounting tracks 74, 76, thus forcing the front edge 92 downwardly.
The scoop 206 is defined by a front edge 208, an adjoining ramp 210, which is defined by an elongate forward facing planar surface, and a glide 212, which is defined by the backside of the ramp 210. Like the blade assembly 68, the ramp 210 functions to guide debris D toward the duct 56. A portion of the back of the scoop 206 rests on a support 213, which can be formed by a rear edge of the suction nozzle opening 54 in the sole plate 36. The support 213 maintains the ramp 210 at a minimum scoop approach angle α and glide approach angle β with respect to the surface to be cleaned S, as previously described.
The linkage assembly 204 comprises a first pivot 214 formed on a first end of a link arm 216, which is pivotally mounted to a mating projection (not shown) on a top portion of the support 213. A second pivot 218 is formed on the opposite end of the link arm 216 and pivotally couples the link arm 216 to the scoop 206. The scoop 206 is configured to pivot about the second pivot 218 and can also articulate relative to the first pivot 214 when the link arm 216 rotates about the first pivot 214, which moves the interconnected second pivot 218 forwardly or rearwardly about the first pivot 214. Thus, the blade assembly 200 is automatically multiply-adjustable relative to the base 14 and nozzle opening 54. Although the schematic figure shows a single link arm 216, it is contemplated that the linkage assembly 204 can comprise a link arm 216 mounted at each end of the scoop 206, for example, or a plurality of link arms 216 mounted along the length of the scoop 206 in a configuration similar to a piano hinge, for example.
The support 213 limits the rotation of the scoop 206 about the second pivot 218 in a counterclockwise direction; however, the scoop 206 is free to rotate away from the support 213 in a clockwise direction about the second pivot 218. The scoop 206 can rotate about the second pivot 218 between a downward position, shown in
The scoop 206 is also configured to float vertically relative to the base 14 and the surface to be cleaned S about the first pivot 214, which has been illustrated as being formed on an upper surface of the support 213, rearwardly of the suction nozzle opening 54. The link arm 216 is configured to rotate counterclockwise/forwardly and clockwise/rearwardly about the first pivot 214 to lower and raise the scoop 206 relative to the cleaning surface S to accommodate various cleaning surfaces or nozzle height settings. For example, if the vacuum cleaner 10 is placed on low pile carpet, a hard floor surface, or set at an elevated nozzle height setting, the link arm 216 can rotate counterclockwise/forwardly about the first pivot 214 to articulate the second pivot 218 and lower the scoop 206 into contact with the surface S, as shown in
The scoop 206 also comprises a shield portion 222. As illustrated, the shield portion 222 comprises an arcuate wall extending rearwardly from the ramp 210. The shield portion 222 can be an essentially continuous extension of the ramp 210, such that the shield portion 222 also acts to guide debris toward the duct 56. However, the ramp 210 and shield portion 222 are hingedly connected about the second pivot 218 so that the ramp 210 can pivot relative to the shield portion 222 about the second pivot 218. The shield portion 222 is configured to slide over the top of the stop 220 to accommodate for changes in the position of the link arm 216 and is configured to block debris from falling into an opening 224 between the link arm 216 and the stop 220 when the link arm 216 is rotated away from the stop 220.
In operation, the blade assembly 200 automatically adjusts to the surface to be cleaned S via the multiply-adjustable coupling defined by the linkage assembly 204, which hingedly couples the blade assembly 200 to the lower base 14 and permits compound adjustment for collecting debris on a forward stroke and preventing debris from being scattered past the sole plate 36 by the agitator 40. Additionally, the configuration of the blade assembly 200 and linkage assembly 204 prevent plowing debris on a rearward stroke. When the base 14 is placed on the surface to be cleaned S the scoop 206 can float vertically upwardly or downwardly relative to the surface S by pivoting about the first pivot 214 or articulating about the second pivot 218 on the link arm 216.
On a forward stroke F, as shown in
The blade assembly 200 is also configured to prevent plowing debris on a rearward stroke R. As shown in
The vacuum cleaner disclosed herein includes an improved suction nozzle configuration. An advantage that may be realized in the practice of some embodiments of the described vacuum cleaner is that debris is prevented from being scattered past the suction nozzle opening by the agitator and debris is prevented from being plowed on a rearward cleaning stroke. The blade assembly, which is coupled to the lower base 14 through a multiply-adjustable coupling, is configured to collect and guide debris D through the suction nozzle opening 54 and downstream collection system instead of allowing the debris to scatter past the nozzle opening and avoid ingestion as in prior art designs. Moreover, the multiply-adjustable coupling permits the blade assembly to slide up and float over debris on a rearward cleaning stroke so that the debris can be ingested through the suction nozzle opening rather than plowing or pushing debris away from the opening as in prior art designs. In addition, the multiply-adjustably coupled blade assembly is configured to automatically adjust to accommodate cleaning surfaces of various heights and different nozzle height settings.
While the invention has been specifically described in connection with certain specific embodiments thereof, it is to be understood that this is by way of illustration and not of limitation. Reasonable variation and modification are possible with the scope of the foregoing disclosure and drawings without departing from the spirit of the invention which, is defined in the appended claims. Hence, specific dimensions and other physical characteristics relating to the embodiments disclosed herein are not to be considered as limiting, unless the claims expressly state otherwise.
This application is a division of U.S. application Ser. No. 14/475,750, filed Sep. 3, 2014, now U.S. Pat. No. 9,962,051, issued May 8, 2018, which claims the benefit of U.S. Provisional Application No. 61/873,615, filed Sep. 4, 2013, which is incorporated herein by reference in its entirety.
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Number | Date | Country | |
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20180184863 A1 | Jul 2018 | US |
Number | Date | Country | |
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61873615 | Sep 2013 | US |
Number | Date | Country | |
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Parent | 14475750 | Sep 2014 | US |
Child | 15907349 | US |