Elevated tank with integrated tank stand

Abstract

An elevated fuel delivery assembly utilizing integrated legs within sleeves attached to a tank provides a gravity flow dispensation of stored liquids within the tank, primarily fuel, by providing the tank with attached at least two parallel sleeves defining sleeve channels slidably engaging at least two parallel upright legs extending from a common base member, providing the tank with a lowered position and a raised position, locking the integrated upright legs at a selected height, suspending the tank at a chosen height using locking bolts and set screws to secure the integrated legs within the respective sleeve channels, stabilizing the tank and contained stored liquids in remote locations for subsequent dispensing of the contents.

Claims

1. An elevated fuel delivery assembly providing remote storage and dispensing of fuel or other bulk liquids at remote locations, comprising: a tank defining a floor, ceiling, at least two side panels, at least two end panels providing a fuel cavity, with a lower bung hole located in at least on or said at least two end panels, and an upper fill cap within the ceiling; at least two vertically oriented sleeves attached to each said at least two end panels, each said sleeve defining an inner channel, an upper end, a lower end, a front surface, and a rear surface attaching to an external surface of each said at least two end panels; at least two integrated leg assemblies, each said leg assembly defining a lower base member, at least two upwardly extending legs defining an upper end and base end attached to said flat base member and further defining a plurality of vertically spaced axial bores; and a hose having a dispensing spigot attached within said at least one bung hole, wherein each said upper end of each said leg is slidably engaged within each respective said inner channel of each said sleeve to raise said tank from a lowered position to a selected raised position with a locking bolt inserted through a selected axial bore within each said leg to secure said tank at a selected raised position providing the elevated fuel tank with gravity flow dispensing of the contained fuel or other liquid content.

2. The elevated fuel delivery assembly of claim 1, further comprising: a threaded bore through the front surface of each said sleeve receiving a set screw tightened against each said leg inserted within said inner cavity of said sleeve, said set screw applied against said leg subsequent to the insertion of each said locking bolt; and each said locking bolt secured in place by a locking nut to further stabilize the tank upon the leg assemblies while in said raised position.

3. The elevated fuel delivery assembly of claim 1, further comprising said tank capacity is between 100 and 1000 gallons.

4. The elevated fuel delivery assembly of claim 1, wherein each said integrated leg assembly and said sleeve are made from square tubular steel and said tank is also made of steel with said sleeves attached to each said end panel by welding said rear surface of each said sleeve to said external surface of each said end panel.

Description

III. DESCRIPTION OF THE DRAWINGS

(1) The following drawings are submitted with this utility patent application.

(2) FIG. 1 is a perspective view of the elevated fuel delivery assembly in an elevated position.

(3) FIG. 2 is a perspective view of the elevated fuel delivery assembly in a lowered position.

(4) FIG. 3 is an exploded view of a side perspective of the elevated fuel delivery assembly, showing the sockets with the set screws, the tank side, the upper ends of the leg members, and the leg cap, with the fuel cap and the tank bung hole shown.

(5) FIG. 4 is a side cross sectional view of a tank end, socket and upper end of a leg in the elevated position with the set screw engaged against the outer surface of the leg.

(6) FIG. 5 is a perspective view of FIG. 1 including a hose and a spigot for dispensing fuel.

IV. DESCRIPTION OF THE PREFERRED EMBODIMENT

(7) An elevated fuel delivery assembly 10, providing for gravity flow dispensing of fuel as shown in FIGS. 1-5, comprises a liquid tank 20, having a capacity between 100 gallons and 1000 gallons, with at least a pair of integrated leg assemblies 60 slidably engaging two sets of parallel vertical sleeves 40 attached to opposing end panels 28 of the liquid tank 20, enabling the tank 20 placed in a lowered position for transport, loading and unloading, and a raised position for dispensing the contents of the liquid tank. The purpose of the elevated fuel delivery assembly 10 is to provide for a bulk capacity fuel delivery system in remote locations for vehicles and equipment in agricultural, construction and mining operations, as well as other practical uses.

(8) The tank 20 further provides a closed vessel comprising a floor 22, a ceiling 24, side panels 26 and the two opposing end panels 28 forming a fuel cavity 25. It is most preferable that the tank is symmetrical for balance purposes, although it is not essential. The shape of the tank 20 may be rectangular, cylindrical or other, with shape not being an essential factor in the purpose or function of the elevated fuel delivery system 10. In at least one end panel 28, there is a lower bung hole 30 providing a threaded opening between the fuel cavity 25 and the end panel 28, accepting the connection of a hose 100 and controlled dispensing spigot 102, and an upper fill cap 32 with a ventilation capacity, FIG. 5.

(9) On each of the two opposing end panels 28, each of the two vertically oriented sleeves 40 define an upper end 42, a lower end 44, an inner channel 46, a front surface 47 and a rear surface 49, FIGS. 3-4. The rear surfaces 49 are welded to an external surface 29 of each end panel 28 in parallel with the front surfaces 47 including a threaded bore 48.

(10) There are at least two sets of integrated leg assemblies 60, each integrated leg assembly 60 providing a flat base member 62 extending two upright parallel legs 64. Each leg 64 further defining a base end 66, attached to the flat base member 62 and an upper end 68, which are contemporaneously inserted through respective lower ends 44 into the Timer channel 46 of each vertically oriented sleeve 40, as shown in FIG. 3. An outside circumference of each leg 64 is uniform and smaller than the inside circumference of each inner channel 46 of each sleeve 40 so that the leg 64 may slide freely within the sleeve 40, the leg 64 and inner channel 46 of each sleeve 40 additionally conforming is shape including square, circular, rectangular or other conforming shape. Additionally, the spacing of the sleeves 40 should be coordinated with the spacing of the paired legs 64 so that they are capable of engagement and integration. The drawing figures depict two legs 64 and two sleeves 40 per side, but the number of legs 64 and sleeves 40 per side may be provided in greater numbers, thereby amending the requirements to at least two sleeves 40 per side and at least two legs 64 per integrated leg assembly 60, should the capacity of the tank 20 or selection of the materials used in the construction of the elevated fuel delivery assembly 10 may require provided the above criteria are met.

(11) Additionally, each leg 64 defines a plurality of spaced axial bores 65 providing for multiple height adjustments selected by the user to determine the chosen elevation of the tank 20 along the each integrated leg assembly 60, with respective locking bolts 70 and nuts 72 inserting through the respective axial bores 65 in each leg 64 to affix the height of the tank 20 in relationship to the integrated leg assemblies 60. An upper cap 80 is affixed onto an upper end 68 of each leg 64, FIGS. 3 and 4, to prevent the legs 64 from being removed from within the sleeves 40 subsequent to the manufacturing process, thereby preventing removal of each leg 64 within each sleeve 40, with vertical adjustment limited between a fully lowered position, FIG. 2, and a fully raise position, as shown in FIG. 1. Once the height is set by the attachment of the locking bolts 70 and nuts 72, a set screw 50, inserted within each threaded bore 48 of each front surface 47 of each sleeve 40 to further stabilize each leg 64 within each sleeve 40 to prevent sway or rocking of the elevated tank 20 upon the integrated legs during use.

(12) The general use of the elevated fuel delivery system 10 would be for the user to obtain the elevated fuel delivery system 10 in the lowered position, FIG. 2, with an empty tank 20, providing the most stable and safe transport embodiment. The tank could also be delivered full of fuel, but it would increase the weight during transport and also enhance the safety risk of a full fuel tank 20 during transport.

(13) Upon delivery and location, the tank 20 would be raised, FIG. 1, upon each set of integrated leg assemblies 60 to a chosen height by available lift means, with the locking bolts 70 inserted through the selected axial bores 65 within each leg 64 and securing the nut 72 to each locking bolt 70. Each set screw 50 is then installed within each threaded bore 48 of each sleeve 40. The hose 100 and spigot 102 would then be installed within the bung hole 30 of the tank 20, FIG. 5. The tank would be filled and would then be ready for the dispensing of the tank contents, which may be gasoline, kerosine, diesel or another liquid of the user's choice by gravity flow. Most practical use would be remote locations, including farm land, harvest locations, building construction sites, mining operations, road construction locations or any other remote location where the disclosed elevated fuel delivery assembly 10 would be useful.

(14) While the elevated fuel delivery assembly 10 has been particularly shown and described with reference to a preferred embodiment thereof, it will be understood by those skilled in the art that changes in form and detail may be made therein without departing from the spirit and scope of the invention.