Rain gutters are widely installed along the rooftop eaves of millions of homes and sloped-roof buildings in North America, Europe, and other parts of the world. These rain gutters serve an important role in properly channeling water runoff to appropriate destinations such as storm water mains or drainage ponds. By diverting roof runoff away from the walls of a building, rain gutters also reduce structural damage that would otherwise be caused by the flow of rainwater onto the walls. In addition to rainwater, substantial amounts of debris (such as leaves, tree branches, silt runoff from roof shingles, and the like) tend to accumulate in rain gutters over time, which can eventually constrict or prevent any rainwater from flowing properly.
Various tools have been described for facilitating rain gutter cleaning. For example, U.S. Pre-grant Appln. Pub. 2006/0289036 (incorporated herein by reference) relates to an elongated pole that emits compressed gas to blow leaves out of a gutter. Similarly, U.S. Pat. No. 6,471,271 (incorporated herein by reference) relates to a mechanical device, also including an elongated pole, in which a pair of tongs mounted at the end of the pole are opened and closed by pulling a rope to thrash debris out of a gutter.
However, the manual tools set forth in those documents can cause the user to fatigue his or her arms from holding heavy poles up as high as twenty feet overhead when attempting to remove debris from a gutter. For example, the user must raise the manual gutter cleaning tool up to the rain gutter and keep it raised for the duration of the cleaning. Furthermore, it may not be possible for the user to ascertain whether any residual matted debris remains in the gutter after attempting a removal, because the rain gutter is typically too high above the user for any visual inspection to be feasible.
In view of the above, as well as other considerations, presently disclosed is a mobile robot for cleaning debris from rain gutters (herein referred to as a “gutter cleaning robot”). The gutter cleaning robot includes a debris auger at a front end of the main body of the gutter cleaning robot, and moves forward along the gutter while motivating the debris auger to clear debris from the gutter being traversed. Accordingly, rain gutters may be effectively cleaned without requiring a user to manipulate strenuous overhead equipment and minimize climbing a ladder.
In accordance with a first example, a gutter cleaning robot may have a drive system for propelling the gutter cleaning robot along a rain gutter, and a debris auger detachably connected to the gutter cleaning robot for agitating debris out of the rain gutter.
The gutter cleaning robot may also have a chassis (also referred to herein as a main body) including a robot connector for mechanically driving the debris auger, and a debris auger connector disposed on the debris auger for interfacing with the robot connector.
The debris auger connector may include one or more connector concavities extending into the debris auger connector, each connector concavity being aligned substantially parallel to a longitudinal axis of the debris auger connector, in which the robot connector includes one or more tines each arranged to extend into a respective connector concavity of the debris auger connector. Also, the robot connector may further include a locking collar concavity, in which the debris auger further includes a shroud disposed around the debris auger connector, the shroud provided for enveloping the robot connector when the debris auger is attached to the main body of the gutter cleaning robot, in which the shroud includes a locking protrusion extending from an inner surface of the shroud for engaging the locking collar concavity of the robot connector.
In the gutter cleaning robot, the debris auger connector may include a hexagonal concavity extending into the debris auger connector, the hexagonal concavity aligned substantially parallel to a longitudinal axis of the debris auger connector, in which the robot connector includes a hexagonal protrusion for extending into the hexagonal concavity of the debris auger connector. The debris auger may be interchangeable with one or more alternative debris augers; and/or may include a spiral screw for drilling into debris. The alternative debris augers may include a flail-type auger, a bristle-type auger, a flap-type auger, a twisting flap-type auger, an irregular protrusion-type auger, a revolving horizontal tines-type auger, a screw-and-flap-type auger, and/or a plow-type auger; and further, the debris auger may include a pneumatic tube for blowing air onto the debris.
The drive system of the gutter cleaning robot may include a caterpillar tread for contacting an interior surface of the rain gutter; and may also include a drive motor, at least two front wheels disposed on opposite lateral sides of the main body of the gutter cleaning robot for guiding the gutter cleaning robot along the rain gutter, and two rear wheels disposed on opposite lateral sides of the main body of the gutter cleaning robot and operably connected to the drive motor.
The gutter cleaning robot may also be usable with a remote control for operating the gutter cleaning robot via a wireless signal transmitted to the gutter cleaning robot.
The gutter cleaning robot may include a light emitting diode on the remote control that blinks when the remote control transmits a signal; and/or another emitting diode on the gutter cleaning robot that blinks when the gutter cleaning robot receives a signal. The gutter cleaning robot may also have a detachable handle or a tote loop disposed on the main body of the gutter cleaning robot for hanging onto a positioning hook that can hoist the gutter cleaning robot into the rain gutter; and/or an ammeter for monitoring an auger current supplied to the debris auger motor, and a controller for receiving input from the ammeter and controlling the drive motor and the debris auger motor, in which the controller can modulate the drive motor when the auger current exceeds a threshold value.
Another example of a roof having a rain gutter is shown in
In accordance with a first embodiment,
The debris auger 350 is connected to a debris auger motor 160 within the main body 101 via a debris auger shaft 163. The drive motor 170 and debris auger motor 160 are preferably controlled by an electronic controller having a memory store for storing computer instructions for controlling the drive motor 170 and/or the auger motor 160. In a preferred embodiment, a microcontroller serves as the electronic controller; or, in a possible alternative embodiment, the microcontroller may be a microprocessor. As a further alternative, the electronic controller may include a PLA or FPGA device.
The gutter shown in
In each of the above-noted gutter hanging arrangements, a strap or spike crosses the trough of the gutter transversely, and presents a possible obstacle to any gutter cleaning robot 10 moving along the through of the rain gutter 51. Accordingly, in a preferred embodiment, the gutter cleaning robot 10 has an overall height profile that is low enough to afford sufficient clearance between the topmost part of the gutter cleaning robot 10 and the straps or spikes that cross over the trough of the rain gutter 51.
As illustrated in
Many rain gutters 51 have either a round trough bottom or a substantially flat trough bottom. Rain gutters for residential housing typically have a width of between four to six inches, with the typical k-style gutter being five inches wide and the typical half-round gutter being six inches wide; thus, typical widths for rain gutters 51 may range between three to seven inches. The depth of many installed rain gutters 51 is approximately 75% the width of the rain gutter, and rain gutter depths typically range between about 60% to 90% of the width of the rain gutter. drain spouts commonly installed to rain gutters typically have 2×3″, 3×4″ or 4×5″ rectangular cross-sections, and the rain gutters generally have rectangular holes of similar shape where they interface with the drain spouts.
The gutter cleaning robot 10 preferably has a width and caterpillar tread arrangement (or wheel, or other drive system) suitable to traverse rectangular hole of at least about three inches by four inches. The gutter cleaning robot 10 may alternatively have a width and drive system placement suitable to traverse holes having a width in the range of about two to five inches, and/or a length in the range of about two to six inches.
Many installed rain gutters 51 can support up to about 50 pounds per lineal foot. Accordingly, the gutter cleaning robot 10 preferably has a weight sufficiently low so as to be supported by the weight load capacity of common rain gutters, taking into account the weight of a typical load of debris 91.
In a preferred embodiment, the treads 179 or wheels 175 are disposed toward the edges of the gutter cleaning robot 10 so that they are separated horizontally by a distance of at least about 2 inches. Because drain spouts 52 often have a width in the range of about two to six inches, the wheels 175 or treads 179 are preferably disposed apart by a distance sufficient to enable the gutter cleaning robot 10 to straddle a hole while moving forward through a rain gutter 51. As an example, the horizontal distance between the wheels 175 or treads 179 may be chosen from a range extending from substantially two inches to substantially six inches.
The wheels 175 or treads 179 may be spring mounted to the chassis 101 of the gutter cleaning robot 10, to increase the traction pressure applied by the wheels 175 or treads against the side walls of the rain gutter 51. This increased traction pressure minimizes torsion caused by the action of the auger 350, and/or may further ensure that the gutter cleaning robot 10 remains within the rain gutter 51 during operation, such as when the gutter cleaning robot 10 is performing an escape behavior in response to becoming stuck.
In
A typical clearance between the bottom-most point of a common rain gutter 51 and a fastening strap is 2.75 inches. Preferably, the gutter cleaning robot 10 has a maximum height and diameter of about 2.5 inches; or, alternatively, the gutter cleaning robot 10 may have a height and/or diameter up to substantially 2.75 inches, or to another distance representing the clearance from a rain gutter bottom to a fastening strap or brace.
A typical “D” size battery has a diameter of approximately 1.3465 inches. Thus where “D” size batteries are used, the gutter cleaning robot 10 preferably has a diameter equal to or slightly larger than the diameter of a standard D cell battery. For example, the gutter cleaning robot 10 may have a height of at least 1.4 inches. Alternatively, the gutter cleaning robot 10 may have a height and/or diameter within the range of between about 1.4 inches to about 2.5 inches; or a height and/or diameter of at least 1.4 inches, inter alia.
In one example, as shown in
The wheel 175 or tread 179 assembly may include a mechanical switch to determine whether the gutter cleaning robot 10 has fallen out of the rain gutter 51, or whether one of the wheels 175 is stuck in a hole. The switch is activated by a decrease in spring tension between the wheels 175 or treads 179 and the walls of the rain gutter 51. When the spring's tension is low enough to activate the mechanical switch, the gutter cleaning robot may alert the user and promptly cease powering the drive motor 170 and auger motor 160. This switch's state is preferably reset each time the gutter cleaning robot 10 is powered up, and may be ignored until after initialization. Furthermore, the switch is preferably only active when the gutter cleaning robot 10 is powered on; also, in at least one embodiment, a dip switch can be included on the gutter cleaning robot 10 to cause the gutter cleaning robot 10 to either monitor or ignore the switch.
The gutter cleaning robot 10 may be directed using a remote control 6, as shown in
The auger 350 preferably has a diameter at least equal to the diameter of the chassis 101 of the gutter cleaning robot 10, as measured tip-to-tip. In one embodiment, the auger 350 has a diameter no greater than substantially 3 inches. Alternatively, the diameter of the auger 350 may be within the range of between about 2.5 inches to about 3.5 inches. The auger 350 preferably operates at a speed in the range of between about 1000 RPM (rotations per minute) to about 1500 RPM. The auger 350 may be made of a substantially flexible material, such as a polymer or plastic, that can deform when it comes into contact with rigid objects. Because the diameter of the auger 350 may exceed the clearance between the gutter's floor and a support strap or brace, the auger 350 may come into contact with straps or braces as the gutter cleaning robot 350 travels under the straps or braces. In order to ensure mobility, the auger 350 is preferably made of a material that deforms when it comes into contact with the type of strap or brace used to support the rain gutter 51.
In
A twisting flap-type debris auger 350 is shown in
An irregular protrusion-type debris auger 350 is shown in
Although the debris augers shown in
The pneumatic-type debris auger 350 shown in
Also,
The debris auger 350 may be non-interchangeably connected to the gutter cleaning robot 10, by forming the debris auger 350 integrally with the gutter cleaning robot 10 or by permanently affixing the debris auger 350 to the gutter cleaning robot 10 by welding or using adhesives, for example. Preferably, however, the debris auger 350 is detachably and interchangeably connectable to the gutter cleaning robot 10. As shown in
When the debris auger 351 is affixed to the gutter cleaning robot 10, the protrusions of the robot connector 130 impart rotating force against the inner surfaces of the concavities of the debris auger connector 321, thus motivating the debris auger 361.
In accordance with another embodiment, a shroud 315 may be provided surrounding the debris auger connector 310. As shown in
The shroud 315 may further include an annular locking protrusion 316 extending partially inward toward the central longitudinal axis of the shroud 315, with the robot connector 130 correspondingly including a locking collar concavity 138 disposed therealong. When the debris auger 350 having the shroud 315 is attached to the gutter cleaning robot 10, the annular locking protrusion 316 flexibly extends into the locking collar concavity of the robot connector 130, thus tending to retain the debris auger 350 in connection with the gutter cleaning robot 10 until force sufficient to dislodge the annular locking protrusion 316 out of the locking collar concavity 136 is applied to separate the debris auger 350 from the gutter cleaning robot 10.
In accordance with another embodiment, the gutter cleaning robot 10 may include a debris auger shaft 163 that extends both to the front and rear end portions of the main body 101. Accordingly, as illustrated in
As shown in
The gutter cleaning robot 10 may operate entirely under the control of the user using a remote control 6; alternatively, the gutter cleaning robot 10 may operate autonomously or semi-autonomously. For example, the gutter cleaning robot 10 may include an on-board controller that executes a control routine for modulating the forward motion of the gutter cleaning robot 10 through the gutter 51. The gutter cleaning robot 10 may include sensors and monitors, such as an ammeter for monitoring the drive current provided to the drive motor 160 and/or the debris auger 350 current provided to the debris auger motor 170.
Otherwise, step 2904 determines whether the drive current exceeds a bogged threshold (that is, a threshold current value corresponding to a state in which the gutter cleaning robot 10 can proceed, but only slowly because of copious debris 91 in the gutter 51, referred to as being “bogged”). If not, the routine returns to step 2901; otherwise, step 2905 reduces the commanded drive speed of the drive motor 160.
Accordingly, the example method illustrated in
The gutter cleaning robot 10 may perform an escape behavior when triggered by appropriate sensor conditions. For example, the operating speed and/or direction of the drive motor 170 and/or the auger motor 160 may be repeatedly or cyclically shifted, in order to agitate or break free of an obstacle. Tables 1 illustrates various current sensor conditions and example escape behavior responses:
When the gutter cleaning robot 10 has already performed an escape behavior but the triggering sensor conditions have not been resolved after an appropriate length of time, the gutter cleaning robot 10 may then perform a panic behavior as a second level response. Table 1 illustrates example panic behaviors that may be performed in response to various conditions:
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