Patent Application
20230234178
There are manual operating techniques used for sanding floors. The manual operating techniques consist of a sequence of lapping and overlapping motion.
There are also a variety of devices and/or machines for sanding wood floors. For example, devices and/or machines may be equipped with travel mechanisms engaged to assist sanding while the operator has control of the operation.
There are robotic arm devices that may be used to sand wood floors. There are large arena-type resurface machines that may be ridden. Also, there are hand-operated machines. For example, a wood floor edge having a spinning disc output. As another example, wood floor sanders may comprise a random orbital sanding tool, which may be moved in a similar direction of the manually applied motion of operation.
An angle grinder is another resurfacing device used on metallic work surfaces and stone surfaces. The output of movement may also use a coating movement of rubbing or spray application. There is also a reciprocating device for painting, sanding, or coating.
The present disclosure can be better understood with reference to the following drawings. The elements of the drawings are not necessarily to scale relative to each other, emphasis instead being placed upon clearly illustrating the principles of the disclosure. Furthermore, like reference numerals designate corresponding parts throughout the views.
An automated system for wood floor edge sanding of the present disclosure moves in a direction to control a power wood floor edge sanding tool when sanding edges of a wood floor. The motion produced by the automated system for wood floor edge sanding replicates motion commonly used in wood floor edge sanding by a trained technician.
The automated system for wood floor edge sanding of the present disclosure produces consistent output of an oval loop cycle engaging sequent transmitted travel synchronized with selectable control of velocities relative to the engaged travel sequent to a lap path, and traverses, via a slider rod that is adapted to translate an opposing guide extended in the direction of travel.
The automated system for wood floor edge sanding of the present disclosure comprises a roller chain pin. At an overlap end via the endless roller chain pin, a first articulated tool adapted to drive a plurality of sprocket wheels. Further, the automated system for wood floor edge sanding of the present disclosure comprises a lower elevation slider rod with a slider body including a second articulated tool adapted to pivot for traversing the floor in the loop motion
The automated system for wood floor edge sander further comprises a guide that translates guide wheels bias along the moving edge sanding tool at a predetermined proximity along the guide per each loop cycle. The automated system for wood floor edge sanding also comprises a collision stop switch, which is a failsafe feature to impede the operation till restart.
A guide 14 is illustrated with dash lines at the floor surface edge. In this regard, the guide 14 may be a wall. Arrow 15 indicates the direction of the automated system for wood floor edge sanding 190 as it moves unidirectionally along the guide 14.
The upper platform 102 is coupled to a motor 450. The motor 450 is coupled to and drives the drive sprocket 422 connected by a roller chain 462 to an angular deflecting sprocket 424. Further, the drive sprocket 422 is coupled via the roller chain to translating sprocket set 426a and 426b. The motor 450 comprises a tension spring 458, which relates continuous tension to the roller chain 462.
The upper platform 102 further comprises a longitudinal slot 192. The longitudinal slot 192 is elongated and widened for receiving the shaft 20. The shaft 20 of the motor 450 moves along longitudinal slot 192 relating tension and may selectively be moved in the direction of the longitudinal slot 192 elongation.
The upper platform 102 further comprises a controller 50. The controller 50 communicatively and selectively controls output.
The upper platform 102 further comprises a transmission switch 10. The transmission switch 10 is shown with a right angled dash line to share the shaft 20 using the fastener 184 below the angular deflecting sprocket 424. The transmission switch 10 engages and communicates to a transmission motor 250 for unidirectional travel.
The motor 250 and a gear 252 engages a coaxial gear 254 for driving travel engagement to coaxial rod 240. Drive wheels 210 and 212 on opposing ends of the coaxial rod 240 define a lead side.
The upper planform 102 on its translating end is in proximity with a cross slot 194. A cross frame member 104 defines a following side. A distal suspended guide wheel 112 is slanted at its base to roll along two surfaces. The slanged guide wheel 112 guide along a wall or placed guide to provide support and bias. The guide wheel 112 may be slightly curvilinear and in slight variations normal in architectural construction.
The coaxial rod 240 is not a right angle to the translating end cross frame 104. Instead, the coaxial rod 240 being steer biased to exemplify guide contiguity.
The automated system for wood floor edge sanding 190 further comprises a lower slide rail 300 and traversing slide body 302. Further, a pivot adapter 304 connects the sanding tool swivel wheel adjusting fastener stem for an oscillating shift at each end between two reciprocating paths.
The automated system for wood floor edge sanding 190 further comprises a distal horizontal guide wheel 112. The horizontal guide wheel 112 predetermined to roll along the base portion of a wall or guide equivalent.
The guide wheel 112 and slanted guide wheel 110 are affixed to the edge sanding tool 12 (
Motor pivot mount holes 180, longitudinal slot 192, tension spring adjusting holes 198 are longitudinally placed. This allows for wood floor edge sanding having different widths of un-sanded areas. The fastener shafts 184 and a nut set 182 is contrived to an engineering standard and may include additional spacers, flat washers and locking washers (not shown).
A unidirectional arrow 15 (
The tool body connector 472 may be altered to a floor edge sander body, or a handle portion (not shown). The flat portion of the upward tool body connector 472 is for the rocker arm 466 having a flat receptor portion for pivot fastener 470 relating articulation.
The tool body connector is articulated resiliently to isolate much of the roller chain chatter common with chain driven devices.
A floor edge sander 12 at its nose or forward end causes frictional force that urges leftwards when in operation. The chain 462 having an applied tension exceeding the defined friction forces to minimize deflection between sprockets having extended chain portions.
A fastener pivot 188 extends through the motor base 452 and is mounted for tension for driving the roller chain 462. The pin body 464 is in a plane for engagement with the transmission switch 10, to be engaged sequent each loop cycle relating the lap path.
On the lower left side of the automated system for wood floor edge sanding 190 is the forward horizontal guide wheel 112. Just above the horizontal guide wheel 112 is collision switch 30 for automatic stop or a failsafe feature. The right lower of the automated system for wood floor edge sanding 190 is the slanted guide 110 and is affixed to bias steering slightly towards the wall or an appropriate guide selectively placed.
The angular deflecting sprocket 424 and switch 10 are outside the reduced loop. The loop 462 would be a floor edge to the portion of a wall area parallel to the wood grain in common with plank or strip wood floors.
Path swing time is lengthened along with the angular portion of zone-4 for a feathering lap and overlap, desirable for more planer work surface results, or technical term of blending. The zone-4 arrangement is common having the angular portion as defined and may be altered via a slight sprocket diameter interchange, still maintaining angular portion of the roller chain in zone-4. The velocity over all is adjustable for limited movements within the scope of the presented device, including tool profiles, and tool output characterizations.
Wheels can be in a plurality greater or lesser than is drawn, relative for travel and support. Mass of the presented device is in proportion for motion force related to the tool, and wood floor conditions. Finished wood floor surfaces have less traction reception till the finish or coating is abrasively removed. Wheels 110 and 112 may be of a plurality of resilient wheels for additional traction stability. The motor 450 may be in offset biasing to the lead side to balance mass. The motor 450 profile may gear reduce with higher motor rating increasing mass proportioned for the presented operation. The total of the presented device can be fabricated opposite hand.
