The present invention generally relates to floor cleaning machines and, more particularly, to a debris collection system of a floor cleaning machine.
Floor cleaning in public, commercial, institutional and industrial buildings have led to the development of various specialized floor cleaning machines. These machines include dedicated floor sweeping machines, dedicated floor scrubbing machines and combination floor sweeping and scrubbing machines.
A debris tray 322 of the cleaner 300 is positioned on the trailing side 314 of the head 306 and the tray 322 collects wet and dry waste that is discharged from the head 306. Liquid can be removed from the tray 322 through a vacuumized de-watering system. The de-watering system includes a perforated separator 324 in the tray 306 that is connected to the waste recovery tank 316 through tubing 326. During cleaning operations, liquid in the tray 322 is extracted through the perforated separator 324 and the tubing 326 and is deposited into the waste recovery tank 316 in response to the suction generated by the vacuum fan 320.
The tray 322 must be manually dumped by the operator. The tray 322 is accessed by pivoting an end of the vacuum squeegee 312 away from the rear end 328 of the cleaner 300 and then pivoting a carriage 330, in which the tray 322 is supported, toward the rear end 328 and out from behind the wheel 332. One or more operators must directly handle the tray 322 to dump its contents. For example, the operator must grab the tray 322 directly by hand to remove the tray 322 from the carriage 330, move the tray 322 to the desired dumping location, dump the tray 322, and reinstall the tray 322 in the carriage 330. Since the tray 322 lacks wheels, it must either be carried or dragged to the desired dumping location.
As a result, one or more individuals are forced to interact/touch the collected waste material or waste material that has adhered to the tray 322. Additionally, the individuals must bend over to move and dump the tray 322, which can weigh as much as 150 pounds depending on the amount of waste collected and the amount of liquid present in the waste. The maneuvering of the tray 322 is further hampered by the necessity to drag it across the ground or carry it.
The tubing 326 connecting the perforated separator 324 to the waste recovery tank 316 includes a main tubing section 334 having an end coupled to the waste recovery tank 316 and a tray tubing section 336 having an end coupled to the perforated separator 324. The other ends of the main and tray tubing sections 334 and 336 must be manually coupled and decoupled during installation and removal of the tray 322 from the carriage 330 of the cleaner 300. Such a procedure requires the operator to get on the floor and reach underneath the cleaner 300 to locate and couple the two tubing sections together. Occasionally, this step in the process of reinstalling the tray 322 in the carriage 330 is overlooked thereby leaving the main and tray tubing sections 334 and 336 disconnected. When this occurs, the de-watering system becomes inactive and liquid can overflow the tray and contaminate the surface being cleaned. The tubing of the de-watering system must also have enough slack to allow the operator to make the necessary connection, which can also cause problems.
There exists a continuous demand for improvements to combination floor cleaning machines including, for example, simplifying waste removal operations, improving maintenance access to components of the machine, providing features that prevent or reduce the likelihood of damaging the machine, and other improvements.
One embodiment of the invention relates to a debris collection system for a floor cleaning machine that includes a motorized cleaning head attached to a frame of the floor cleaning machine, a carriage attached to the frame, a debris tray, and a de-watering system. The debris tray is removably receivable within the carriage and is positioned to receive debris thrown from the motorized cleaning head. The de-watering system includes a liquid extracting component, a tray tubing section, a main tubing section, a waste recovery tank supported on the frame and a vacuum in vacuum communication with the main tubing section. The liquid extracting component is attached to the debris tray and is configured to extract liquid from within the debris tray. The tray tubing section has a first end that is coupled to the liquid extracting component and a second end that is mounted in fixed relation to the debris tray. The main tubing section has a first end that is connected to the waste collection tank and a second end that is positioned to automatically couple to the second end of the tray tubing section upon installation of the debris tray.
Additional embodiments of the invention relate to a floor cleaning machine that includes the debris collection system described above, and a method of coupling the second end of the tray tubing section to the second end of the main tubing section during installation of the debris tray into the carriage.
This Summary is provided to introduce a selection of concepts in a simplified form that are further described below in the Detailed Description. This Summary is not intended to identify key features or essential features of the claimed subject matter, nor is it intended to be used as an aid in determining the scope of the claimed subject matter. The claimed subject matter is not limited to implementations that solve any or all disadvantages noted in the Background.
Embodiments of the present invention relate to a debris collection system of a hard floor cleaner. Although embodiments of the invention will be described below with respect to a combination floor sweeping and scrubbing machine, it will be apparent that embodiments of the invention are also useful with other hard floor cleaners, such as dedicated floor sweeping machines and dedicated floor scrubbing machines. Accordingly, embodiments of the debris collection system of the present invention include using the debris collection system with other types floor cleaning machines.
Embodiments of the machine 100 include components that are supported on a motorized mobile body 110. The mobile body 110 comprises a frame 112 supported on wheels 114 for travel over a surface 116, on which a cleaning operation is to be performed. The components that are supported on the mobile body 110 include, for example, a motorized cleaning head 118 and components of the debris collection system 102. Embodiments of the machine 100 can also include a fluid recovery system 122, a cleaning liquid or water dispensing system 124, a waste recovery tank 126, and other components.
The cleaning head 118 can include one or more brushes 128 that are configured for sweeping and/or scrubbing operations on the surface 116. In accordance with one embodiment of the invention, the cleaning head 118 is configured as a sweep/scrub head that is adapted to perform wet and/or dry sweeping operations, and scrubbing operations on the surface 116.
One embodiment of the cleaning head 118, shown in
During a dry sweeping operation, waste material 138 is swept by brushes 128 into the debris tray 136. During wet scrubbing and sweeping operations, water or a cleaning liquid contained in a tank 140 is sprayed to the surface 116 in front of the cleaning head 118. The wetted debris on the surface 116 is swept into the debris tray 136 by the brushes 128 while they also scrub the surface 116. The soiled cleaning liquid that is not swept into the tray 136 is then collected by the fluid recovery system 122 and deposited in the waste recovery tank 126.
One embodiment of the fluid recovery system 122 of the machine 100 includes a vacuum squeegee 142 mounted adjacent the rear end 144 of the machine 100, as shown in
Embodiments of the debris collection system 102 of the present invention include the motorized scrub head 118, a carriage 156 (
As mentioned above, the tray 136 is positioned to receive debris removed from the surface 116 and thrown by the motorized cleaning head 118. In one embodiment, the carriage 156 and the debris tray 136 are located on a trailing side 160 of the cleaning head 118, as shown in
One embodiment of the tray 136 includes two or more wheels 176 attached to the tray body 164. The wheels 176 facilitate easy movement of the tray 136 across a surface by supporting at least one end of the tray 136 above the surface. The wheels 176 can be mounted to the tray 136 in any conventional manner. In accordance with one embodiment of the invention, the wheels 176 are mounted to the side walls 172 and 174 of the tray 136 such that the bottom of each wheel extends slightly below the bottom surface of the tray 136. In accordance with one embodiment of the invention, the wheels 176 are mounted adjacent a rear end 178 of the tray 136. Other, more forward locations for the wheels can be used as well. Additional wheels can be mounted to the tray 136, if full wheel support of the tray 136 is desired.
Another embodiment of the tray 136 includes a handle 180 that generally allows the operator to maneuver the tray from a standing position while minimizing direct contact with the tray 136 and, thus, the debris on and in the tray 136.
In accordance embodiments of the invention, the pivotal connection of the first end 182 of the handle 180 to the tray 136 allows the handle 180 to pivot in a vertical plane and/or a horizontal plane, as respectively indicted by arrows 186 and 188 (
In accordance with one embodiment of the invention, the handle 180 is mounted to the tray 136 at a central location at the first end wall 168. The central location is preferably aligned with the anticipated center of gravity of the tray 136 when it is loaded. This alignment of the handle 180 reduces undesired torque that could be applied to the tray 136 by the handle 180 during tray removal, installation or maneuvering operations.
In accordance with one embodiment of the invention, the handle 180 is detachable from the tray 136 when not in use, such as when the tray 136 is fully installed in the carriage 156 of the cleaner 100. The handle 180 can then be manually attached to the tray 136 when the operator needs to remove and dump the tray 136.
The handle 180 can also be placed in a stowed position, in which it is received within a handle receiving channel 194 of the tray 136, as shown in
The handle 180 can be extended to an operating position (
In accordance with another embodiment of the invention, the handle 180 is configured for removal from the channel 194 by positioning the end 182 in a predefined orientation relative to the slot 198. In general, the end 182 has a shape that is slightly smaller than the slot 198 when it is oriented in the proper manner. Thus, when the end 182 has a cross bar 200, the slot 198 can be an elongated slot, as shown in
The slot 198 can also include a rubber skirt or other component that surrounds the member 196 of the handle 180 and prevents debris from entering the channel 194 through the slot 198.
In accordance with another embodiment of the invention, the handle 180 is restricted from rotating about the longitudinal axis 190 of the handle 180. For example, the channel 194 can be sized to have an interior height 202 that is slightly larger than a thickness 204 of the cross bar 200 at the end 182, and an interior width 206 that is slightly larger than a length 208 of the cross bar 200, as shown in the simplified cross-sectional view of
One advantage to having the centrally located channel 194 is that the walls of the channel 194 operate to increase the rigidity of the tray 136, which allows for a reduction in the thickness of the end walls 168 and 170 and the side walls 172 and 174 of the tray 136, as compared to debris trays of the prior art.
In one embodiment, the handle 180 can pivot to a vertical position in which a lower portion of the member 196 abuts the outside surface of the end wall 168 of the tray 136, as shown in
In accordance with one embodiment of the invention, the tray 136 includes a handle member receiver 216 (
A bottom 220 of the channel 194 can include one or more openings 222, shown in
In one embodiment, the frame 230 of the carriage 156 is mounted to the frame 112 using conventional methods such that it can pivot about a vertical axis 238 relative to the frame 112 of the cleaning machine 100 to move a tray receiving end 240 of the carriage 156 out from behind the wheel 114′, as shown in
One embodiment of the base 236 of the carriage 156 includes openings 250 (
Another embodiment of the carriage 156 includes a ramped lip 260 at the receiving end 240 that receives the tray 136. The ramped lip 260 is angled downward from the base 236 toward the floor 116 to ease the transition for the tray 136 from the floor 116 to the carriage 156. The tray also includes an angled base 262 at the rear end 178, which engages the ramped lip 260 when pushed into the receiving end 240 of the carriage 156. These features simplify installation of the tray 136 into the carriage. These features allow the operator to install the tray 136 into the carriage 156 from a standing position using the handle 180 and without having to directly lift the tray 136. The rear end 178 of the tray 136 is simply rolled in the backward direction along the surface 116 using the handle, the angled base 262 then engages and slides over the ramped lip 260, which lifts the rear end 178 off the surface 116 and into the receiving end 240 of the carriage 156. Once the rear end 178 is received in the carriage 156, the remainder of the tray 136 can be rolled into the carriage on the wheels 176.
The vacuumized de-watering system 158 generally includes tubing 270 connecting the waste recovery tank 126 to a liquid extracting component 272 (e.g., perforated separator) that is configured to extract liquid from the interior cavity 175 of the tray 136, as shown in
One embodiment of the invention relates to the automatic coupling and de-coupling of the main and tray tubing sections 274 and 276 of the vacuumized de-watering system 158 respectively during installation of the tray 136 into the carriage 156 and removal of the tray 136 from the carriage 156. This relieves the operator from having to locate and connect the open ends of the main and tray tubing sections 274 and 276, as is the case in prior art systems. Instead, the operator can focus on simply installing the tray 136 in the carriage 156 while the connection of the open end of the main tubing section 274 to the open end of the tray tubing section 276 occurs automatically. As a result, this embodiment of the invention not only relieves the operator of the burden of performing the tubing connection, but also avoids the problems that result when the operator forgets to perform the tubing coupling operation.
One embodiment of the de-watering system 158 includes two cooperating coupling components: a main coupling component 280 and a tray coupling component 282, as shown in
In accordance with one embodiment of the invention, the tray coupling component 282 is attached to the tray 136 in a manner that fixes its position relative to the tray 136. In one embodiment, the tray 136 includes a bracket 290 (
In one embodiment, the main coupling component 280 has a fixed position relative to the carriage 156 or otherwise is placed in a predetermined location during installation of the tray 136. In one embodiment, the carriage 156 includes a bracket 292 that supports the end 284 of the main tubing section 274 in the desired fixed position, as shown in
The placement of the main and tray coupling components 280 and 282 in predetermined positions relative to the carriage 156 and the tray 136, respectively, allows the main and tray coupling components 280 and 282 to automatically engage (or couple) to each other when the tray 136 is installed in the carriage 156. The desired fixed positions of the main and tray coupling components 280 and 282 can be at other locations than those depicted and supported using other methods, without departing from the spirit of the present invention.
In accordance with another embodiment of the invention, the end 284 of the main tubing section 274 and the main coupling component 280 are positioned to receive the tray coupling component 282 when the tray 136 and the carriage 156 are pivoted from the release/receive position 244 to the operating position 242 (
In another alternative embodiment, the main coupling component 280 is attached to a door of the mobile body 110 that is closed to complete the installation of the tray 136 in the operating position 242. When the tray 136 is positioned in the operating position 242 beneath the cleaner 100, the tray coupling component 282 is positioned to automatically engage or couple to the main coupling component 280 when the door is shut.
In accordance with another embodiment of the invention, at least one of the main and tray coupling components 280 and 282 is configured to be moved through mechanical means relative to the other coupling component during or after the tray 136 is installed in the carriage 156. For example, the main coupling component 280 can be moved relative to the carriage 156 to engage the tray coupling component 282, or the tray coupling component 282 can be moved relative to the tray 136 to engage the main coupling component 280. The movement of the coupling components can be motorized or manually driven by the operator through actuation of a lever arm or other means. The motorized movement of the coupling component can be automatically triggered by the full installation of the tray, the movement of the carriage to the operating position, the closing of a door, the pressing of a button by the operator, or other triggering event.
In accordance with one embodiment of the invention, the main and tray coupling components 280 and 282 are cooperating male and female members. Either the main coupling component 280 or the tray coupling component 282 is the male member and the other coupling component is the female member. In
The female coupling component is preferably conical and includes a flared opening 294 (
Other configurations for the main and tray coupling components 280 and 282 can also be used. For example, rather than being male and female cooperating components, the components can form a face seal in which abutting faces of the coupling components seal the junction to complete the vacuum circuit between the vacuum 152 and the liquid extracting component 272.
Below is a discussion of an exemplary operation of the debris collection system 102 in accordance with various embodiments of the invention. However, it is understood that embodiments of the invention include the individual embodiments of the debris collection system 102 described herein alone and in combination with other embodiments of the system.
In the event that the carriage 156 is positioned behind a wheel, such as wheel 114′ in the exemplary cleaning machine 100 discussed above, the removal of the tray 136 from the cleaner 100 can begin by pivoting the carriage 156 from the operating position 242 to the tray release/receive position 244, shown in
In one embodiment, once the tray 136 is removed from the carriage 156, at least a portion of the tray 136 is supported over the surface 116 on the wheels 176, which simplifies the maneuvering of the tray 136 to the desired dumping location as compared to trays of the prior art. With two wheels 176 at the rear end 178, the debris tray 136 is maneuvered in a similar manner as wheeled luggage. However, additional wheels can be added to the debris tray 136 to allow the tray 136 to be maneuvered like a cart with the entire base 166 being raised from the surface.
The handle 180 can be moved to the upright position (
After the contents of the tray 136 have been dumped, the rear end 178 of the tray 136 is inserted into the receiving end 240 of the carriage 156 while the operator remains standing by pushing the tray with the handle 180 in the upright position. The ramped leading edged 260 of the base 236 of the carriage 156 allows the rear end 178 of tray 136 to roll into the receiving end 240 of the carriage 156. The wheels 176 fall into the openings 256 and 258 to fully seat the tray 136 in the carriage 156. The handle 180 can then be removed from the tray 136, or recessed into the handle receiving channel 194 of the tray 136. In the event that the carriage 156 is in the release/receive position 244, the carriage 156 is pivoted back to the operating position 242 and locked in position relative to the frame 112 of the cleaning machine 100.
In accordance with one embodiment, during the installation of the tray 136 into the carriage 156 or movement of the carriage 156 to the operating position 242, the main and tray coupling components 280 and 2282 automatically engage each other to seal the junction between the main and tray tubing sections 274 and 276 of the de-watering system 158. The floor cleaning machine 100 is then ready to perform cleaning operations on the surface 116.
Although the present invention has been described with reference to preferred embodiments, workers skilled in the art will recognize that changes may be made in form and detail without departing from the spirit and scope of the invention.
The present application is based on and claims the benefit of U.S. provisional patent application Ser. No. 60/729,129, filed Oct. 21, 2005, the content of which is hereby incorporated by reference in its entirety.
Number | Name | Date | Kind |
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5901407 | Boomgaarden | May 1999 | A |
Number | Date | Country | |
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20070089260 A1 | Apr 2007 | US |
Number | Date | Country | |
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60729129 | Oct 2005 | US |