Patent Application
20140158445
The present disclosure relates to the field of lifting devices, systems and methods. More particularly, the present disclosure relates to a hover-type lifting device, system, and method.
The usefulness of wheelbarrows is well known. Such uses are in a wide variety of applications such as by way of example construction, gardening, and other uses where loads are moved and transported form one place to another. The wheelbarrow is a unique tool in that due to its single wheel design a relatively heavy load may be balanced and moved. Wheelbarrows are also useful in that they may be used to move loads over rough and difficult terrain where other means of transport would be very difficult.
Currently, wheelbarrows by design perform their function of transporting objects of disproportional weight from one point to another using lifting and pushing techniques that are considered difficult by most individuals. The current wheelbarrow design has not changed from the original design of having a wheel or roller that is mounted forward of a container bed and handles opposite the wheel from the container. The design is to hold objects between the wheel and the handles for transporting purposes.
With a fixed wheel mounted forward of the container section, and grasping handles extending several feet behind the back of the wheelbarrow, an individual must lift upwards on the handles using leverage to lift any disproportional weight needed to be transported. The ability to lift loads is based on the individual's body strength for obtaining the objective of moving the load.
Additionally, after upward lift has been achieved the individual must then exert forward or reverse force to overcome the total weight of the objects placed within the container before the wheelbarrow will move in the desired direction. Further, physical exertion must be applied by the individual when either pushing or pulling the wheelbarrow over any objects that maybe laying in its path as obstructing movement of the wheel, thus further increasing the negativity of current use.
Moreover, under weighted conditions the wheel itself can cause divots or impressions in the ground damaging the surface which the wheelbarrow passes over should that surface be unstable.
Generally, pushing a loaded wheelbarrow typically presents challenges related to force and leverage. Force generated by a user to propel a wheelbarrow is typically transmitted from a user's shoulders, down through the user's arms and hands, to wheelbarrow handles. The user's arms therefore act as levers to amplify force required to propel the wheelbarrow, the amplified force being transmitted to the user's shoulders. Similarly, the user's lower arms can act as levers to amplify force on the user's upper arms. As a result, the user's arms, shoulders, and upper torso experience loads and concomitant stresses that are considerably greater than forces applied at the wheelbarrow handles.
Many attempts have been made to power or motorize wheelbarrows by using gasoline-powered engines in order to propel the wheelbarrow and its load. However, such wheelbarrows end up being bulky, cumbersome, and difficult to use. In some cases such wheelbarrows can be dangerous to use in many types of terrain. Further, such wheelbarrows tend to be excessively heavy and unbalanced requiring the user to shift and manipulate the load to compensate for the load and the terrain.
There exists, therefore, a need for a powered or motorized wheelbarrow solving the aforementioned problems is desired.
A feature of the present disclosure is to provide a modular transporting apparatus adapted for accepting multiple accessories.
Another feature of the present disclosure is to provide a lifting platform in connection with a rack arrangement for accepting interchangeably different containers adapted for different uses, such as by way of example, gardening, construction, beach, sports, etc.
Another feature of the present disclosure is to provide a lifting platform in connection with various interchangeable handles, such as by way of example, a two-hand handle as associated with a typical wheelbarrow, a single bar handle as associated with a lawn mower, and a pulling handle as associated with a wagon.
Another feature of the present disclosure is to provide a lifting platform in connection with various outriggers for keeping the lifting platform stable, such as by way of example, skid-type out riggers, skid outriggers with one or more wheels, tank outriggers with a continuous articulated metal track, etc.
Yet another feature of the present disclosure is to provide a lifting platform that has a locking mechanism for preventing unauthorized use, such as by way of example, a key, a keypad, etc.
Yet still another feature of the present disclosure is to provide a lifting platform that has a power device for powering a fluid mover, such as by way of example, battery, gas, electricity, etc.
Yet still another feature of the present disclosure is to provide a lifting platform that can be remotely operated as a drone.
Another feature of the present disclosure is to provide a lifting platform that is compact in design having the ability to collapse the container or carrying portion.
Another feature of the present disclosure is to provide a lifting platform that is adapted for carrying a solid load, a sludge load or a liquid load, and where needed using various and sundry liners in the container.
Yet another feature of the present disclosure is to provide a lifting platform that no longer needs leverage to lift.
Yet still another feature of the present disclosure is to provide a lifting platform that has a pivoting bucket with a pull-type handle.
Yet still another feature of the present disclosure is to provide a lifting platform that has auxiliary wheels adapted for spanning a ramp or stairs.
And yet still another feature of the present disclosure is to provide a lifting platform that is weighted appropriately for enhancing the unloading of the load in the container.
While certain exemplary embodiments have been described in details and shown in the accompanying drawings, it is to be understood that such embodiments are merely illustrative of and not devised without departing from the basic scope thereof, which is determined by the claims that follow.
The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate an implementation of apparatus consistent with the present disclosure and, together with the detailed description, serve to explain advantages and principles consistent with the disclosure.
The above general description and the following detailed description are merely illustrative of the generic invention, and additional modes, advantages, and particulars of this invention will be readily suggested to those skilled in the art without departing from the spirit and scope of the invention.
To achieve the foregoing objects, features, and advantages and in accordance with the purpose of the invention as embodied and broadly described herein, a hoverbarrow apparatus and method are provided.
The use of an alternate method for performing the laborious task of transporting heavy material or objects can be achieved with the use of a hoverbarrow apparatus. The hoverbarrow apparatus mechanically lifts the objects to be transported using a cushion of air as the main means of lift. The air cushion method of lift drastically reduces the physical exertion necessary for forward or reverse motion required to perform the task of transporting objects.
The air cushion further improves the performance and use of the barrow by allowing the barrow to float over objects in its path significantly reducing or eliminating impressions and divots in the surface currently associated with the present wheelbarrow technology.
As illustrated in
More particularly, the barrow apparatus 10 has at least a portion of the conduit with a ring torus shape, the torus member 350. The ring torus portion 350 of the conduit has at least one aperture (not illustrated) on the ring portion of the torus shaped member 350 through which the fluid passes causing the fluid to flow around the lowest portion of the torus member 350, the surface-engaging annulus 353, thereby providing the film of fluid on which the barrow apparatus 10 rides.
Typically, the barrow apparatus 10 uses air as the fluid. However it is appreciated that additional fluids may be advantageous in specific situations.
Also, the barrow apparatus 10 can include a stabilizer member or outrigger/wheels 340. Further, the barrow apparatus 10 comprises controls for the fluid mover/fan 330 to provide varying fluid flows for maintaining the barrow apparatus 10 above the surface over which it travels. Still further, the barrow apparatus 10 has a guide member, handle, haft, grip 200 or a combination thereof.
The barrow apparatus 10 further has a plate or planar member 310 in association with the fluid mover 330, and an inlet in the plate or planar member 310 for accepting fluid from the fluid mover 330.
A donut shaped, ring torus member 350 is provided having an interior annulus 354, an exterior annulus 352 and a curved surface-engaging annulus 353 in operative association with the surface under the barrow apparatus 10. The donut shaped, ring torus member 350 is for accepting the fluid from the inlet in the plate member 310. The plate member 310 and the donut shaped, ring torus member 350 define a volume 356. At least one aperture 351 is positioned on the inner annulus 354 of the donut shaped, ring torus member 350 for allowing the fluid to egress therefrom.
The fluid mover 330 places into motion the fluid for passage through the inlet in the planar member 310 for pressurizing the volume 356 defined by the donut shaped, ring torus member 350 and the planar member 310. The only mechanism for relieving the pressure in the volume 356 created by the moving fluid is through the at least one aperture 351 positioned on the inner annulus 354 of the donut shaped, ring torus member 350. The fluid egressing the at least one aperture 351 then pressurizes a second volume 358 defined by the exterior surface of the donut shaped, ring torus member 350 and the surface-engaging annulus 353 under the barrow apparatus 10. This creates a steady state, uniform flow of fluid out of the second volume 358 via a gap between the donut shaped, ring torus member 350 and the surface under the barrow apparatus 10. The gap is caused by the steady state flow of fluid from the second volume 358 around the curved portion of the donut shaped, ring torus member 350 adjacent to the surface for dispersion of the fluid into the atmosphere.
The planar member 310 has a surface partially defining the volume 356. The surface may be configured to create turbulent flow within the volume defined by the surface of the planar member 310 and the donut shaped, ring torus member 350. Typically, the planar member 310 would be roughened to create the turbulence. However, it is appreciated that there are other ways if initiating turbulence in a flow of fluid, such as, a trip.
The torus member 3350A has apertures 1351A and the torus member 3350B has apertures 1351B.
In the another embodiment illustrated in
A planar member 1310 is provided in association with the fluid mover. Two or more inlets 1312, 1314, 1316 in the planar member 1310 are for accepting fluid from the fluid mover. Two or more concentric donut shaped, ring torus members 1350A, 1350B are provided for implementing an interior and at least one exterior concentric donut shaped, ring torus members, each having an interior annulus, an exterior annulus and a curved portion in operative association with the surface under the barrow apparatus. The donut shaped, ring torus members 1350A, 1350B are for accepting the fluid from the inlets 1312, 1314, 1316.
The planar member 1310 and the donut shaped, ring torus members 1350A, 1350B define a volume 1356A, 1356B with respect to each donut shaped, ring torus member 1350A, 1350B.
At least one aperture is positioned on the inner annulus of each donut shaped, ring torus member 1350A, 1350B for allowing the fluid to egress therefrom.
The fluid mover places into motion the fluid for passage through the two or more inlets in the planar member for pressurizing the volumes defined by the donut shaped, ring torus members 1350A, 1350B and the planar member. The only mechanism for relieving the pressure in each volume created by the moving fluid is through the at least one aperture positioned on the inner annulus of the donut shaped, ring torus members 1350A, 1350B.
The fluid egressing the at least one aperture in the interior donut shaped, ring torus member 1350A then pressurizes a first exterior volume defined by the exterior surface of the interior donut shaped, ring torus member 1350A and the surface under the barrow apparatus.
The fluid egressing the at least one aperture in the exterior donut shaped, ring torus member 1350A then pressurizes a subsequent exterior volume defined by the exterior surface of the interior ring torus member 1350B, the exterior surface of the interior ring torus member, and the surface under the barrow apparatus 1010.
The surface under the barrow apparatus 1010 creates a steady state, uniform flow of fluid out of the exterior volumes via a gap between each donut shaped, ring torus member 1350A, 1350B and the surface under the barrow apparatus 1010. The gap is caused by the steady state flow of fluid from the exterior volumes around the curved portion of the donut shaped, ring torus members 1350A, 1350B adjacent to the surface for dispersion of the fluid into the atmosphere.
Typically, the barrow apparatus 1010 uses air as the fluid. However it is appreciated that additional fluids may be advantageous in specific situations.
Also, the barrow apparatus 1010 can include a stabilizer member. Further, the barrow apparatus comprises controls for the fluid mover to provide varying fluid flows for maintaining the barrow apparatus 1010 above surface over which it travels. Still further, the barrow apparatus 1010 has a guide member, handle, haft, grip or a combination thereof
The barrow method further comprises the steps of providing a planar member in association with the fluid mover, and implementing at least one inlet in the planar member for accepting fluid from the fluid mover.
A donut shaped, ring torus member is provided having an interior annulus, an exterior annulus and a curved portion in operative association with the surface under the barrow apparatus, the donut shaped, ring torus member for accepting the fluid from the inlet. The planar member and the donut shaped, ring torus member define a volume.
The at least one aperture is positioned on the inner annulus of the donut shaped, ring torus member for allowing the fluid to egress.
The fluid mover energizes into motion the fluid for passage of the fluid through the inlet in the planar member for pressurizing the volume defined by the donut shaped, ring torus member and the planar member. The only mechanism for relieving the pressure in the volume created by the moving fluid is through the at least one aperture positioned on the inner annulus of the donut shaped, ring torus member.
The fluid egresses via the at least one aperture for pressurizing a second volume defined by the exterior surface of the donut shaped, ring torus member and the surface under the barrow apparatus.
A steady state, uniform flow of fluid out of the second volume via a gap between the donut shaped, ring torus member and the surface under the barrow apparatus is created. The gap caused by the steady state flow of fluid from the second volume around the curved portion of the donut shaped, ring torus member adjacent to the surface disperses the fluid into the atmosphere.
Typically, the barrow apparatus uses air as the fluid. However it is appreciated that additional fluids may be advantageous in specific situations.
Also, the barrow apparatus can include a stabilizer member. Further, the barrow apparatus comprises controls for the fluid mover to provide varying fluid flows for maintaining the barrow apparatus above surface over which it travels. Still further, the barrow apparatus has a guide member, handle, haft, grip or a combination thereof.
While certain exemplary embodiments have been described in details and shown in the accompanying drawings, it is to be understood that such embodiments are merely illustrative of and not devised without departing from the basic scope thereof, which is determined by the claims that follow.
The present application claims the priority and the benefit of the U.S. Provisional Patent Application of Mark Welker bearing Ser. No. 60/630,289, filed Dec. 8, 2011, the entirety of which is incorporated herein by reference.
