Vacuum cleaners can comprise one or more agitators rotatably mounted onto a foot portion of a vacuum cleaner to dislodge or sweep dirt on the surface being cleaned. The vacuum cleaner can further comprise a suction source fluidly connected to an upstream aperture disposed near the one or more brushes to ingest the dirt into a working air flow that is fluidly connected to a downstream filtration system. The filtration system is configured to separate the entrained dirt from the working air flow and convey the dirt into a removable dirt cup or a porous filter bag for later disposal.
Some known agitator mechanisms on vacuum cleaners comprise a cylindrical, transversely oriented brush assembly rotatably mounted within a suction aperture that spans the width of the vacuum cleaner foot. Such agitators are typically configured to dislodge dirt and hair from the cleaning surface and are positioned near the suction aperture for ingesting and transporting dirt through the working air flow and collecting it in a conventional manner.
An aspect of the present disclosure relates to a vacuum cleaner comprising; a foot assembly adapted to be moved across a surface to be cleaned and having a suction inlet, an upright handle assembly pivotally mounted to the foot assembly, a dirt cup in fluid communication with the suction inlet, wherein the foot assembly further comprises a body defined by a central portion and a pair of extension arms that extend laterally outwardly from the central portion, a rotatable agitator mounted on each extension arm, the agitator on each extension arm having an axis of rotation, and a drive assembly operably interconnected with each of the agitators, wherein the drive assembly is configured to counter-rotate one of the agitators with respect to the other one of the agitators, wherein the suction inlet is positioned rearward of and between the axes of rotation of the agitators and a dirt inlet ramp forms a bottom wall of a dirt path from the suction inlet to a dirt ramp outlet and the dirt ramp outlet is fluidly coupled with the dirt cup.
In the drawings:
Aspects of the present disclosure relate generally to the foot portion of an upright, stick, or canister vacuum cleaner 10. More specifically, referring to
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
The upright handle assembly 12 is pivotally mounted to the foot assembly 40. A conventional detent mechanism (not shown) can be configured to selectively engage and lock the upright handle assembly 12 in an upright position relative to the foot assembly 40. A user can disengage the detent mechanism to recline the upright handle assembly 12 during use as is commonly known in the art.
A suction source comprises the conventional motor/fan assembly 30 mounted within a lower portion of the main body 16 that can be selectively energized via a conventional power switch 43. The motor/fan assembly 30 is configured to generate a working airflow through a working airflow path and is in fluid communication with the filtration system 18, which separates dirt from the dirt laden airflow. The filtration system 18 can be any variety of known types including, but not limited to, a conventional filter bag or at least one cyclone separator. Furthermore, the motor/fan assembly 30 can be located in the foot assembly 40 as well as the upright handle assembly 12, or in a conventional canister vacuum cleaner housing without departing from the scope of this invention. Additionally, the motor/fan assembly 30 can be located either downstream or upstream from the filtration system 18.
Referring to
The foot assembly 40 comprises a rear housing section 50 adapted to rotatably receive opposed rear wheels 46 on either side thereof. The foot assembly 40 further comprises a central housing section 48 disposed forwardly of the rear housing section 50. As will be discussed in conjunction with
A stationary strip brush 54 is disposed beneath the foot assembly 40 behind the suction aperture 52 in a generally arcuate configuration. The strip brush 54 comprises at least one row of flexible bristles 56 configured act as a sweeping element to sweep and guide dirt towards the suction aperture 52 and to catch any dirt that may be swept past the suction aperture 52 by the counter-rotating agitators 44. The suction aperture 52 is located between the counter-rotating agitators 44, beneath the apex of the two diverging arms 53 and does not span the full width of the vacuum cleaner foot assembly 40. Accordingly, the working airflow velocity at the suction aperture 52 can be higher than a larger, conventional suction aperture that typically spans the entire width of a conventional vacuum cleaner foot assembly. The higher working airflow velocity can improve ingestion of dirt particles into the suction aperture 52.
Additionally, the stationary strip brush 54 directs loose dirt on the surface to be cleaned toward the suction aperture 52 so that the dirt can be ingested effectively. For example, if the vacuum cleaner 10 is pushed rapidly on a forward stroke, some of the dirt that is swept towards the suction aperture 52 by the counter-rotating agitators 44 may not be immediately ingested into the suction aperture 52. In such a case, the stationary strip brush 54 is configured to sweep any remaining dirt until the dirt can be ingested through the suction aperture 52. Additionally, the flexible bristles 56 of the stationary strip brush 54 can also bend and flick dirt particles forwardly, effectively moving the dirt closer to the suction aperture 52 so that the dirt can be ingested through the suction aperture 52. While the stationary strip brush 54 is illustrated as having a plurality of bristles 56, the stationary brush strip 54 can also be made from one or more pieces of a semi-rigid or flexible material, such as rubber, for example, for catching any dirt swept past the suction aperture 52.
The agitator drive motor 70 can comprise any known type of electric motor including a conventional brushed, a brushless direct current, a universal, or an alternating current induction motor configuration, for example. In some applications, the agitator drive motor 70 can be energized when the motor/fan assembly 30 is energized. In other applications, an agitator drive power switch electrically connected within the agitator drive motor 70 power circuit can be adapted to selectively energize the agitator drive motor 70 while the vacuum cleaner 10 is operated.
The belt 86 can comprise an elastomeric material such as rubber, silicone, or other suitable materials commonly known in the art. The belt 86 tension can be set to allow efficient power transfer from the drive gears 78 to the counter-rotating agitators 44 without excessive slippage and wear. The perimeter of the drive gear pulley 82 and agitator drive pulley 88 can comprise a groove 91 and 93, respectively, therein for seating the belt 86 and preventing the belt 86 from slipping off of the pulleys 82 and 88. The grooves 91, 93 can include a roughened contact surface to increase the frictional coupling of the pulleys 82 and 88 to the belt 86, and thereby improve power transfer efficiency. Alternatively, the belt 86 can comprise a conventional timing belt with teeth adapted to mate with gear teeth on the perimeters of the drive gear pulley 82 and agitator drive pulley 88.
The wheels 46 are rotatably mounted to the outboard sides of the rear housing section 50 of the foot assembly 40. Each wheel 46 comprises a wheel body 47 that is preferably constructed of injection molded thermoplastic and an outer tread 49 comprising an elastomeric material with a high coefficient of static friction to promote better grip to the surface being cleaned, such as hardwood or linoleum floor. Conventional wheels comprising a uniform material are also contemplated.
The agitator hub portion 90 is configured to receive the cleaning tool 92 of the counter-rotating agitator 44 and is adapted to rotate relative to the agitator extension housing section 42. The agitator hub portion 90 can be constructed from a thermoplastic material, elastomeric material, or the like. The cleaning tool 92 can be attached to the agitator hub portion 90 either permanently or removably via known retention means such as conventional hook and loop fasteners or tacky adhesive, for example. The peripheral edge of the cleaning tool 92 extends beyond the housing sections 42, 48, and 50 of the foot assembly 40, including the rear wheels 46. In this manner, the cleaning tool 92 can contact walls, baseboards, molding, and furniture legs during use. The cleaning tool 92 can comprise assorted materials or combinations thereof, including a plurality of flexible bristles, micro-fiber pads, disposable non-woven fibrous dusting sheets, synthetic or natural chamois pads, felt, yarn, cloth rags, or other suitable soft, deformable materials. The cleaning tool 92 is adapted to attach to the agitator hub portion 90 and to deform upon encountering obstructions while simultaneously dusting and wiping the surfaces of the obstructions. Deformation of the cleaning tool 92 is advantageous, especially for cleaning baseboards and toe kicks underneath conventional kitchen cabinets.
Referring to
The removable sheet 94 can be removably secured to a bottom wall 96 of the agitator hub portion 90 via a conventional hook and loop fastening system or via tacky adhesive. Alternatively, as shown in
The removable sheet 94 is disk-shaped and comprises a plurality of uniformly spaced flexible strips 98 that extend radially from an outermost edge of the disk. Peripheral slits 97 are formed between the flexible strips 98 and are configured to receive intermittent radially spaced bristle tufts 91 therein so that the cleaning tool 92 of the counter-rotating agitator 44 comprises alternating bristle tufts 91 and flexible strips 98 around the perimeter thereof (
An assortment of interchangeable cleaning tools 92 can permit a user to select various attachments for specific cleaning tasks depending on the type of dirt and/or cleaning surface. For example, a cleaning tool 92 with coarse bristles might be advantageous for removing large dirt particles, whereas an attachment with electrostatic or micro-fiber pads can be advantageous for removing smaller dirt particles and fine dust. Additionally, chamois pads and pre-moistened pads can be advantageous for damp mopping applications. Accordingly, the user can select a suitable interchangeable cleaning tool 92 that can be selectively attached to the agitator hub portion 90 depending on the specific cleaning task. The cleaning tool 92 can be removably attached to the agitator hub portion 90 by any known means including hook-and-loop fasteners, double-sided tape, tacky adhesive, or the previously mentioned elastomeric sheet retention inserts 95.
In addition, the cleaning tool 92 can be disposable or reusable. For example, a disposable cleaning tool 92 can be configured to be used one or more times by the user and then disposed of after a single use or when the user desires to replace the cleaning tool 92 with an unused cleaning tool 92. In another example, the cleaning tool 92 can be configured to be periodically removed and cleaned by the user, such as by rinsing with water or washing in a laundry washing machine or dishwasher, and then replaced back onto the agitator hub portion 90 for further use.
Referring again to
The foot assembly 140 comprises a rear housing section 150 configured to rotatably mount rear wheels 146 on either side thereof. The main body 116 is pivotally mounted to the rear housing section 150 via a swivel joint (not shown). A flexible conduit (not shown) within the rear housing section 150 fluidly connects the working airflow path in the foot assembly 140 to the working airflow path in the main body 116. The foot assembly 140 further comprises a central housing section 148 positioned forwardly of the rear housing section 150. As will be discussed in reference to
The motor/fan assembly 130 enclosed within the main body 116 is configured to generate a working airflow and is fluidly connected to the filtration system 118 that is adapted to separate dirt from the dirt laden airflow. The motor/fan assembly 130 can be located in either of the foot assembly 140 as well as the upright handle assembly 112 without departing from the scope of this invention. Additionally, the motor/fan assembly can be located either downstream or upstream from the filtration system 118.
Referring to
The outer boundary of foot assembly 140 can be more compact than foot assembly 40 because the two counter-rotating agitators 144 are rotatably mounted adjacent to each other within an agitator housing section 142 having a pair of arms 153 that are obtuse relative to each other and not the V-shaped diverging arms 53 of the agitator extension housing 42 shown in
The operation of the second embodiment of the invention is substantially similar to the operation of the previous embodiment except for the drive train and agitator housing configuration. A user prepares the vacuum cleaner 110 for use by connecting it to a power supply and actuating the power switch 143. The motor/fan assembly 130 draws a working airflow through the system while the agitator drive motor 170 drives the counter-rotating agitators 144 in the direction indicated by arrows 199A via the rotating worm gear 172. Worm gear threads 174 on the shaft 176 mesh with drive gear teeth 180 on the drive gears 178 that are rotatably mounted on opposite sides of the worm gear shaft 176. The drive gears 178 engage agitator gears 184 that are fixed to the agitator hub portion 190. As the worm gear 172 rotates, each drive gear 178 rotates outwardly, as indicated by arrows 199B, and rotate the agitator gears 184 inwardly, as indicated by arrows 199C, thus inducing inward rotation of the counter-rotating agitators 144 to sweep dirt inwardly towards the suction aperture 152 within the agitator housing section 142. The dirt is ingested through the aperture 152 and entrained in the working airflow generated by the motor/fan assembly 130. The working airflow transports the dirt through the working airflow path, is separated by the filtration system 118, and is collected in the dirt cup 120 on the main body 116 of the vacuum cleaner 110. The filtered working airflow is exhausted to atmosphere through exhaust vents 155 in the main body 116.
The upright handle assembly 212 comprises a main body 216 that houses a motor/fan assembly 230 that generates a working airflow and is in fluid communication with an upstream filtration system 218 and working airflow path. The motor/fan assembly 230 mounted within a lower portion of the main body 216 and can be selectively energized via a conventional power switch 243 also mounted in the main body 216. The filtration system 218 is configured to separate dirt from a dirt-laden airflow and a removable dirt cup 220 is adapted to receive and collect the separated dirt from the filtration system 218. The dirt cup 220 has a latch mechanism 222 for selectively latching the dirt cup 220 to the main body 216. The main body 216 further comprises an upright handle 226 with a second hand grip 228 at one end for maneuvering the vacuum cleaner 210 over a surface to be cleaned. It will be understood by one skilled in the art that the motor/fan assembly 230 can be located in the foot assembly 240 or the upright handle assembly 212 and can further be positioned either upstream or downstream from the filtration system 218 without departing from the scope of this invention.
Referring to
Rear wheel assemblies 306 are rotatably mounted at the sides of the foot assembly 240. Each rear wheel assembly 306 comprises a wheel axle 308 with a wheel pulley 310 disposed thereon and further comprising a rear wheel 246 mounted at the distal end of the wheel axle 308. The wheel pulley 310 and rear wheel 246 can be fixed to the wheel axle 308 by keying the respective components, or via ultra-sonic welding, adhesive, or other commonly known manufacturing techniques. Aligned notches 312 formed in mounting ribs 314 and sidewalls of the intermediate housing 264 and sidewalls of the upper housing 242 form axle bearings that are configured to rotatably receive the wheel axles 308 therein. The entire rear wheel assembly 306 is configured to rotate with respect to the axle bearings 312 such that rotation of the rear wheel assemblies 306 induces rotation of the wheel pulleys 310. The front of the foot assembly 240 is supported by rollers 316 that are rotatably mounted beneath the front corners of the bottom housing 300. Drive belts 286 wrap around one wheel pulley 310 and a corresponding agitator pulley 288 at both sides of the foot assembly 240. Each drive belt 286 is slidably supported by a rotating direction changing spindle 260. Each spindle 260 is transversely and rotatably mounted within a spindle holder 318 that protrudes upwardly from the bottom wall of the intermediate housing 264. The direction changing spindle 260 twists the belt 286 from a substantially vertical orientation at the wheel pulley 310 to a substantially horizontal orientation at the agitator pulley 288.
A dirt cup aperture 261 formed in the top wall of the upper housing 242 is aligned with a corresponding pocket 263 in the intermediate housing 264 and dirt cup support wall 265 in the bottom housing 300 to form a mounting recess for an intermediate dirt cup 267 therein.
The intermediate dirt cup 267 comprises an elongate L-shaped structure with a hand grip 269 formed along an upper portion and a dirt collection chamber 271 formed in a lower portion thereof. The intermediate dirt cup 267 further comprises inlet 273 formed along the lower front face and an exhaust aperture 275 along the top rear wall that fluidly connect the intermediate dirt cup 267 to the working airflow path as will be described hereinafter.
Counter-rotating agitators 244 are rotatably mounted beneath the front of the intermediate housing 264 within an agitator cavity formed between the bottom housing 300 and the intermediate housing 264. The two counter-rotating agitators 244 are mounted in a manner such that at least a portion of the counter-rotating agitators 244 extend beyond the perimeters of the upper housing 242, intermediate housing 264, and bottom housing 300. Preferably, the counter-rotating agitators 244 can be canted forwardly so that the forward most portion of the agitators 244 is in register with the surface to be cleaned whereas the rearward most portion of the agitator is not in register with the surface to be cleaned (
The agitator pulleys 288 are coupled to wheel pulleys 310 via drive belts 286. The wheel pulleys 310 are mechanically coupled to the wheels 246 and rotate with the wheel assemblies 306 rotate as previously described. Alternatively, the wheel pulley 310 or the agitator pulley 288 can comprise a conventional one-way clutch mechanism that limits rotation of the counter-rotating agitators 244 in a single rotational direction indicated by the arrows shown on
In operation, the vacuum cleaner 210 can be operated either with or without energizing the motor/fan assembly 230 via the power switch 243. When the cleaner 210 is plugged into a line power source and the power switch 243 is actuated, the motor/fan assembly 230 becomes energized and generates a working airflow through the working airflow path. A user maneuvers the cleaner 210 across the surface to be cleaned by pushing and pulling the second hand grip 228 forwards and backwards in a reciprocal motion. As a user pushes the cleaner on a forward stroke, the foot 240 moves forward, the rear wheels 246 rotate forwardly and, in turn, rotate the wheel axles 308 and wheel pulleys 310 disposed thereon, thus moving the belts 286, which induce rotation of the counter-rotating agitators 244 via the agitator pulleys 288. Accordingly, the counter-rotating agitators 244 rotate only when the wheels 246 rotate. The forward most portion of the counter-rotating agitators 244 sweep inwardly, as indicated by arrows 299A in
When the cleaner 210 is used without energizing the motor/fan assembly 230, the cleaner functions as a manual sweeper and does not generate a working airflow though the working airflow path. Instead, as a user pushes the cleaner on a forward stroke, the foot 240 moves forward, rotating the rear wheel assemblies 306 forwardly, which moves the belts 286 and induces rotation of the counter-rotating agitators 244. The counter-rotating agitators 244 sweep inwardly and direct dirt through the suction aperture 266 at the base of the dirt inlet ramp 276. The momentum of the dirt carries it up the dirt inlet ramp 276, through the intermediate dirt cup inlet 273, where it is collected in the collection chamber 271 of the intermediate dirt cup. When the intermediate dirt cup 267 becomes full, a user can grasp the hand grip 269 on the top portion to lift the intermediate dirt cup 267 from the mounting recess in the foot assembly 240. A user can then tip the intermediate dirt cup 267 forwardly to empty the dirt through the inlet aperture 273 and into a suitable container. Alternatively, a user can empty the intermediate dirt cup 267 by selectively energizing the motor/fan assembly 230 by connecting the unit to a line power source and depressing the power switch 243 while the intermediate dirt cup 267 is mounted within the mounting recess. The debris collected in the collection chamber 271 thus becomes entrained in the working airflow and is transported to the dirt cup 220 mounted to the main body 216.
The canister vacuum cleaner 410 comprises a suction wand handle assembly 502 which is coupled at a first end 503 with a hose 506, which is, in turn, fluidly connected with the canister body 416 via a hose fitting 505. The suction wand handle assembly 502 can be selectively coupled at a second, opposite end 504 with one of the foot assemblies 640, 740 and 840. The second end 504 of the suction wand handle assembly 502 can be received in a swivel conduit 510, 516 or 522 of any of the foot assemblies 640, 740 and 840, and secured therein using a detent mechanism (not shown) or any other mechanism known in the art. The swivel conduit 510, 516, 522 of each foot assembly 640, 740 and 840 comprises an outlet 512, 518 and 524, respectively, for the working airflow and entrained debris to flow through to the filtration system 418 and dirt cup 420 during operation, in a manner similar to that described above for the cleaner 10. Foot assemblies 640 and 740 also include a power socket 514 and 520, respectively, for connecting with a power connector 506 adjacent the second end 504 of the hose 502, as is known in the art. In this manner, when the canister vacuum cleaner 410 is connected with the foot assemblies 640 and 740, power can be transmitted from the canister vacuum cleaner 410 to the foot assemblies 640 and 740 for rotating the counter-rotating agitators 644 and 744, for example. Although foot assembly 840 has been disclosed as comprising a manual, friction drive agitator drive system, it too can optionally be adapted with an electric agitator drive mechanism and can be fitted with a power socket for furnishing power from the power connector 506 to the electric drive mechanism in a manner similar to foot assemblies 640 and 740.
Typical vacuum cleaners have a suction inlet located generally adjacent the front of the foot assembly that spans at least the majority of the width of the cleaning path defined by the foot assembly. The cleaners described herein utilize a reduced diameter suction inlet positioned rearwardly of counter-rotating agitators. The reduced diameter suction inlet provides for a more efficient use of suction power compared to a suction inlet that spans the entire cleaning path. The more efficient use of suction power allows for the use of a smaller vacuum motor, thus consuming less power and saving money, while not negatively impacting the overall cleaning performance of the cleaner. The use of counter-rotating agitators mounted along a vertical axis, rather than a traditional, horizontally-mounted brush roll, provides the ability to design a foot assembly with a lower profile, thus improving accessibility under cabinet toe-kicks and furniture, for example.
In addition, the use of an intermediate dirt cup and counter-rotating agitators that are coupled with the cleaner wheels for concomitant rotation as the cleaner is moved over the surface to be cleaned, provides for a multi-functional cleaner that can be used with or without electrical power, which can increase functionality and user satisfaction with the cleaner. For example, for small or quick clean-ups, the user can simply move the cleaner over the surface to be cleaned, sweeping dirt and debris on the surface into the intermediate dirt cup through the rotation of the counter-rotating agitators without the use of suction. This saves the user the time and hassle of unwinding and plugging in the power cord, and is also quieter than a cleaning process which uses a motor to generate suction. For larger or harder to clean tasks, the user can plug in the cleaner and actuate the suction motor to take advantage of the cleaning power of suction in combination with the counter-rotating agitators.
The intermediate dirt cup is configured for easy removal, emptying and re-insertion after use. This allows the user to use the cleaner multiple times without powering on the cleaner. The intermediate dirt cup is also configured to be emptied simply by actuating the suction motor, thus drawing the dirt collected within the intermediate dirt cup into the main dirt cup. The main dirt cup can then be removed and emptied as described above. In this manner, in one step, the user can empty both dirt collection chambers.
In the foregoing discussion, dirt is any material that is removed from the surface to be cleaned. Dirt can include, but is not limited to, dust, debris, organic or inorganic particles, including human and animal based debris such as dead skin cells and hair. The surface to be cleaned can include any surface including floors, carpets, upholstery, drapery and rugs. However, the vacuum cleaner described is particularly suited for cleaning floors, including wood, hardwood, linoleum, laminate, plastic, ceramic, concrete, tile, textured concrete, stone, or metal floors.
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 within the scope of the foregoing disclosure and drawings without departing from the spirit of the invention which is defined in the appended claims. Although various examples of corded cleaning devices have been shown herein, it will also be understood that alternative power sources, such as rechargeable batteries, can also be used without departing from the scope of this invention to make household cleaning more convenient by not having to unstow, plug in and again stow a power cord. U.S. Pat. Nos. 6,968,593, 6,125,498 and 7,013,528 show various examples of alternative power sources and are incorporated herein in their entirety. Furthermore, the illustrated vacuum cleaner is but one example of the variety of vacuum cleaners with which this invention or some slight variant can be used.
While shown and described for use with an upright or “stick”-type vacuum cleaner, the invention described herein can be used with any type of vacuum cleaner, such as canister vacuum cleaners, robotic vacuum cleaners, hand-held vacuum cleaners, or built-in central vacuum cleaning systems. The invention can also be used with vacuum cleaners adapted to take up fluids, such as extractors and steam cleaners.
To the extent not already described, the features and structures of the various embodiments may be used in combination with each other as desired. That one feature may not be illustrated in all of the embodiments is not meant to be construed that it cannot be, but is done for brevity of descriptions. Thus, the various features of the different embodiments may be mixed and matched as desired to form new embodiments, whether or not the new embodiments are expressly described.
This application is a continuation of U.S. patent application Ser. No. 15/621,441, filed Jun. 13, 2017, now U.S. Pat. No. 9,993,127, issued Jun. 2, 2018, which is a continuation of U.S. patent application Ser. No. 14/732,185, filed Jun. 5, 2015, now U.S. Pat. No. 9,706,888, issued Jul. 18, 2017, which is a continuation of U.S. patent application Ser. No. 13/287,615, filed Nov. 2, 2011, now U.S. Pat. No. 9,072,415, issued Jul. 7, 2015, which claims the benefit of U.S. Provisional Patent Application No. 61/410,660, filed Nov. 5, 2010, all of which are incorporated herein by reference in their entirety.
Number | Name | Date | Kind |
---|---|---|---|
1677533 | Staehle | Jul 1928 | A |
2220224 | Faber | Nov 1940 | A |
2946080 | Burch | Jul 1960 | A |
3101505 | Belicka et al. | Aug 1963 | A |
3314099 | Otto | Apr 1967 | A |
3574880 | Butzen | Apr 1971 | A |
3597787 | Rosendall | Aug 1971 | A |
4512057 | Laing | Apr 1985 | A |
5463791 | Roden | Nov 1995 | A |
5784754 | Roden et al. | Jul 1998 | A |
6571423 | Lijzenga et al. | Jun 2003 | B1 |
6792648 | Lee | Sep 2004 | B2 |
6842941 | Lee | Jan 2005 | B2 |
7334291 | Song et al. | Feb 2008 | B2 |
7549190 | Oh et al. | Jun 2009 | B2 |
7578020 | Jaworski et al. | Aug 2009 | B2 |
8832902 | Kim et al. | Sep 2014 | B2 |
9706888 | Krebs | Jul 2017 | B2 |
20030221281 | Oh | Dec 2003 | A1 |
20040148731 | Damman et al. | Aug 2004 | A1 |
20070157422 | Oh et al. | Jul 2007 | A1 |
20080172822 | Oh et al. | Jul 2008 | A1 |
20120144619 | Forbes | Jun 2012 | A1 |
Number | Date | Country |
---|---|---|
1392150 | Apr 1975 | GB |
2213047 | Aug 1989 | GB |
2000342498 | Dec 2000 | JP |
2003038402 | Feb 2003 | JP |
200074549 | Dec 2000 | WO |
2006032991 | Mar 2006 | WO |
2009039622 | Apr 2009 | WO |
Number | Date | Country | |
---|---|---|---|
20180263444 A1 | Sep 2018 | US |
Number | Date | Country | |
---|---|---|---|
61410660 | Nov 2010 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 15621441 | Jun 2017 | US |
Child | 15983004 | US | |
Parent | 14732185 | Jun 2015 | US |
Child | 15621441 | US | |
Parent | 13287615 | Nov 2011 | US |
Child | 14732185 | US |