SUBMERSIBLE FUEL OIL SET

Abstract

A submersible fuel oil apparatus includes a base; at least one platform supported above the base and having a top surface, an underside surface and an aperture therethrough; a submersible motor mounted on the top surface of the platform and having a motor shaft extending vertically downward through the aperture in the platform; a fuel oil pump supported underneath the platform and having a pump shaft extending vertically upward, a pump inlet into which fuel oil is adapted to be delivered, and a pump outlet from which fuel oil is adapted to be pumped, the pump positioned such that the motor shaft and the pump shaft are aligned; a coupler connecting the motor shaft and pump shaft to each other; inlet piping connected to the pump inlet; and outlet piping connected to the pump outlet.

Claims

1. Submersible fuel oil apparatus, comprising: a. a base b. at least one platform supported above said base and having (i) a top surface, (ii) an underside surface and (iii) an aperture therethrough; c. a submersible motor supported by one of said top surface and said underside surface of said platform and having a vertically oriented motor shaft; d. a fuel oil pump supported by said platform on a side of said platform opposite said motor and having a (i) a vertically oriented pump shaft, (ii) a pump inlet into which fuel oil is adapted to be delivered, and (iii) a pump outlet from which fuel oil is adapted to be pumped, said pump and motor positioned such that said motor shaft and said pump shaft are aligned, one of said motor shaft and pump shaft extending through said aperture in said platform; e. a coupler connecting said motor shaft and pump shaft to each other; f. inlet piping connected to said pump inlet; and g. outlet piping connected to said pump outlet.

2. The submersible fuel oil apparatus of claim 1 further comprising support brackets securely connecting said outlet piping to said base.

3. The submersible fuel oil apparatus of claim 1 further comprising a mounting bracket having an upper connection surface, a lower connection surface, and an interior space, wherein said upper connection surface of said mounting bracket is connected to said underside surface of said platform, wherein one of said pump and motor is positioned underneath and connected to said lower connection surface of said mounting bracket, and wherein said coupler is positioned within said interior space of said mounting bracket.

4. The submersible fuel oil apparatus of claim 3 wherein said mounting bracket is generally u-shaped, and further comprising at least one coupling guard removably mounted on said mounting bracket to isolate said coupler.

5. The submersible fuel oil apparatus of claim 4 wherein said platform is supported above said base by a plurality of legs, said plurality of legs attached to said base.

6. Submersible fuel oil apparatus, comprising: a. a base b. at least one platform supported above said base and having (i) a top surface, (ii) an underside surface and (iii) an aperture therethrough; c. a submersible motor mounted on said top surface of said platform and having a motor shaft extending vertically downward through said aperture in said platform; d. a fuel oil pump supported underneath said platform and having (i) a pump shaft extending vertically upward, (ii) a pump inlet into which fuel oil is adapted to be delivered, and (iii) a pump outlet from which fuel oil is adapted to be pumped, said pump positioned such that said motor shaft and said pump shaft are aligned; e. a coupler connecting said motor shaft and pump shaft to each other; f. inlet piping connected to said pump inlet; and g. outlet piping connected to said pump outlet.

7. The submersible fuel oil apparatus of claim 6 further comprising support brackets securely connecting said outlet piping to said base.

8. The submersible fuel oil apparatus of claim 6 wherein said fuel oil pump is supported from said platform by a mounting bracket having an upper connection surface, a lower connection surface, and an interior space, wherein said upper connection surface of said mounting bracket is connected to said underside surface of said platform, wherein said pump is positioned underneath and connected to said lower connection surface of said mounting bracket, and wherein said coupler is positioned within said interior space of said mounting bracket.

9. The submersible fuel oil apparatus of claim 8 wherein said mounting bracket is generally u-shaped, and further comprising at least one coupling guard removably mounted on said mounting bracket to isolate said coupler.

10. The submersible fuel oil apparatus of claim 9 wherein said platform is supported above said base by a plurality of legs, said plurality of legs attached to said base.

11. Submersible fuel oil apparatus, comprising: a. a base b. a pair of platforms supported above said base, each of said platforms and having (i) a top surface, (ii) an underside surface and (iii) an aperture therethrough; c. a pair of submersible motors, each of said motors being mounted on an upper surface of a respective one of said platforms and having a motor shaft extending vertically downward through said aperture in said respective platform; d. a pair of fuel oil pumps each supported underneath a respective one of said platforms and each having (i) a pump shaft extending vertically upward, (ii) a pump inlet into which fuel oil is adapted to be delivered, and (iii) a pump outlet from which fuel oil is adapted to be pumped, each of said pumps positioned such that respective ones of said motor shafts and said pump shafts are aligned; e. a pair of couplers connecting respective ones of said motor shafts and pump shafts to each other; f. inlet piping connected to each of said pump inlets; g. outlet piping connected to each of said pump outlets; and h. support brackets securely connecting said outlet piping to said base.

12. The submersible fuel oil apparatus of claim 11, wherein said inlet piping comprises a common inlet port adapted to deliver fuel oil to each of said pumps, and said outlet piping comprises a common discharge port from which fuel oil is adapted to be pumped from said pair of pumps.

13. The submersible fuel oil apparatus of claim 12, wherein each of said fuel oil pumps is supported from its respective platform by a mounting bracket having an upper connection surface, a lower connection surface, and an interior space, wherein said upper connection surface of said mounting bracket is connected to said underside surface of its respective platform, wherein each of said pumps is positioned underneath and connected to said lower connection surface of its respective mounting bracket, and wherein each of said couplers is positioned within said interior space of its respective mounting bracket.

14. The submersible fuel oil apparatus of claim 13 wherein each of said mounting brackets is generally u-shaped, and further comprising at least one coupling guard removably mounted on each of said mounting brackets to isolate said coupler.

15. The submersible fuel oil apparatus of claim 14 wherein each of said platforms is supported above said base by a plurality of legs, said plurality of legs attached to said base.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0011] These and other aspects, details and objects of the invention will be described with reference to the following drawing figures of which:

[0012] FIGS. 1A-1C are front, side and top views, respectively, of a duplex submersible fuel oil set in accordance with the present invention; and

[0013] FIG. 2 is an exploded view of the motor pedestal, pump-to-pedestal mounting bracket, 2-piece coupling guard and main base for use with the present invention.

DETAILED DESCRIPTION OF THE INVENTION

[0014] As best shown in FIGS. 1A-C, two pumps 10, which in accordance with a preferred embodiment, are VIKING SG SERIES™ spur gear pumps, with cast iron casings, heat-treated gears and shafts, plain heads, Viton mechanical seals and carbon graphite bushings. The pumps 10 are powered by respective motors 12, which, in accordance with a preferred embodiment, are ABB-Baldor continuous-in-air duty, totally enclosed, non-ventilated submersible motors, supplied as standard, with oil-filled inner and outer slurry seals, built-in seal leak sensors, and up to 100-ft long removable submersible power & seal leak sensor cables. The motors 12 and pumps 10 are supported on a main base 14 by respective motor pedestals 16, details of which are shown in FIG. 2. The main base 14 is preferably formed of heavy-duty fabricated carbon steel welded-construction main base, 5/16 inches thick, with 3-inch drip Lip, (2) ¾ inch FNPT drain connections, and six anchor bolt holes as shown. The motor pedestals 16 are preferably heavy-duty fabricated carbon steel welded-construction engineered to rigidly support each motor's weight and absorb its torsional loads for vibration-free operation. The pedestals 16 include provisions for mounting the pumps 10 and coupling them to their respective motors 12, while providing full access to unit's components for ease of inspection, maintenance, and repair. A stainless-steel arrow preferably is riveted on each pedestal, allowing easy verification of motor rotation. The pedestals are preferably full fillet welded to main base.

[0015] Each motor 12 is mounted on the top of its respective pedestal 16, as shown in FIGS. 1A and 1B. The pumps 10 are mounted on the undersides of their respective motor pedestals 16 by respective pump-to-pedestal mounting brackets 18, each of which is connected to the underside of the pedestals by stainless-steel fasteners, as shown in FIG. 2. Although mounting the motors on the top of the pedestal, and the pumps underneath the pedestal, is the preferred configuration, the configuration can be reversed, if desired, such that the pumps are on the top of the pedestal and the motors are underneath the pedestal.

[0016] Preferably, the pump mounting brackets 18 are generally u-shaped, defining an interior space, and comprised of heavy-duty fabricated carbon steel, engineered to support each pump rigidly and independently, while allowing for easy pump-motor alignment. Each of the pumps 10 is mounted to the underside of its respective pump-to-pedestal mounting bracket 18, with the pump shaft extending vertically upward through a central aperture 23, FIG. 2, in the pump-to-pedestal mounting brackets. The shafts of the motors 12, on the other hand, extend vertically downward through central apertures 21 in the motor pedestals 16. The pump and motor shafts are connected by couplers 20, in a well-known manner, within the interior spaces of the pump-to-pedestal mounting brackets 18, as shown in FIGS. 1A and 1B. The open sides of each of the pump-to-pedestal mounting brackets 18 are covered using 2-piece OSHA compliant aluminum coupling guards 22, as best shown in FIG. 2, to isolate the couplers 20. The guards 22 are removable to provide easy access for pump-motor alignment and corrosion resistance.

[0017] In addition to the mounting of the pumps and motors, as described above, the piping, fittings, inlet and discharge ports, moisture detectors, pressure gauges, strainer, relief valves, check valves, isolation ball valves, fasteners, basin leak switch assembly, flow switch assembly, local power disconnects, and control panel are supported on the main base by supporting brackets, as shown in the drawings. Fuel oil is supplied via inlet port 24, FIG. 1C, flowing through a duplex strainer 28. The fuel oil is delivered to each pump 10 via inlet manifold 30 to thereby pump the oil to the discharge port 32, FIG. 1A, via respective lower horizontal piping 34, vertical piping 36, and common discharge manifold 38, the latter of which includes check valve 40 and isolation ball valve 42, FIG. 1C.

[0018] A discharge piping support system, including six support brackets, is preferably provided and used in conjunction with the pedestals 16 to offset, counterbalance and counterweight torsional forces and pipe stresses, especially in the common discharge manifold 38. Specifically, and as shown in the drawings, brackets 44 are provided for securing respective lower horizontal piping 34, brackets 46 are provided for securing respective vertical piping 36, and brackets 48 are provided for securing respective arms of the common discharge manifold 38. The six brackets are preferably supported by 11-Gauge Carbon Steel square tubing (one example of which, 56, is shown in FIG. 1B) designed to independently support the discharge piping and common discharge manifold, eliminating any stresses on the pumps' ports or unit components, and to provide leak-free and vibration-free operation. The pipe supports are full fillet welded to main base, while allowing for removal and/or replacement of all unit pipe sections and/or components.

[0019] Additionally, the following system components are employed, in accordance with the preferred embodiments, although various changes and substitutions may be available as will be appreciated by those skilled in the art:

[0020] Moisture Detectors [0021] AMETEK Series 8040MD NEMA 1 moisture detectors are preferably supplied as standard (one for each motor) and are available in optional NEMA 4 enclosures.

[0022] Couplings [0023] Aluminum jaw couplings with Hytrel inserts are preferably supplied, providing corrosion resistance.

[0024] Piping & Fittings [0025] Carbon steel schedule 80 seamless interconnecting threaded piping, with union breakpoints, forged steel threaded pipe fittings class 2000 #, and forged steel threaded unions class 3000 # with Viton O-rings, are preferably supplied as standard on all units.

[0026] Pressure Gauge [0027] H. O. Trerice Series D80 discharge and compound suction pressure gauges 50, FIGS. 1A, and 1C, are preferably supplied as standard, with liquid-filled, stainless-steel case, bronze tube, brass socket and 4″ dial. Each gauge is supplied with 316SS full port isolation ball valve 26 as standard.

[0028] Differential Pressure Gauge [0029] Differential pressure gauge 52, FIG. 1C, is preferably provided with 316ss tubing and full port isolation ball valve 26 is supplied across the duplex strainer inlet and outlet, as standard, and is preferably Ashcroft type 1130 with 0-30 PSID range, stainless steel case, brass body, in-line in/out ports, Viton O-ring, glycerin filled, and 4″ diameter dial.

[0030] Duplex Strainer [0031] Duplex strainer 28, FIG. 1C, is preferably Eaton Ball type duplex basket strainer model 53BTX, with threaded inlet/outlet connections, cast iron body, stainless steel diverter ball and 1/32″ perforated baskets, Teflon seat, Buna N seals, is supplied as standard. Optional construction materials such as, bronze, carbon steel and stainless steel, may be utilized, if desired.

[0032] External Pressure Relief Valves [0033] Two Fulflo V-Series adjustable pressure relief valves 54, FIGS. 1A and 1B, are preferably supplied in cast iron, with threaded connections, Buna O-ring cap seal and 410SS Piston, as standard. Optional construction materials such as, brass, steel and stainless steel, may be utilized, if desired.

[0034] Check Valves [0035] Two Check-All style U3, 1500 PSIG (non-shock) check valves 40, FIG. 1C, are preferably supplied as standard, with a carbon steel body, threaded connections, Viton seat, and 316SS spring with 0.125 PSI cracking pressure. Optional construction materials such as, brass, 316SS and alloy 20, may be utilized, if desired.

[0036] Isolation Ball Valves [0037] Apollo series 76F-100-A 316SS full port, 1000 CWP ball valves 42 and 26, FIG. 1C, are preferably supplied as isolation valves for suction, discharge, suction and discharge gauges, and differential pressure gauge, as standard.

[0038] Fasteners [0039] All fasteners are preferably supplied in 316SS material as standard.

[0040] Coating [0041] Two Coats of COROTHANE® I black coal tar are preferably applied to unit's cast iron, steel & fabricated steel components, as standard. Coats are applied 24-hour apart to allow for proper curing. Motors, and stainless steel & aluminum components preferably are not coated.

[0042] Basin Leak Assembly [0043] Gems series LS-1755, 316SS basin leak switch assembly, formed of switch 58, FIG. 1B and bracket 60, FIG. 1C, is preferably supplied as standard to detect any fuel leak that collects in the main base during normal/dry operating conditions. The assembly includes an LS-1755 switch with up to 100-ft long leads enclosed in ⅜″ liquid tight flexible PVC conduit, 316SS tubing, and 316SS fittings.

[0044] Flow Switch Assembly [0045] An IFM Efector model SI5006 (SR5906 for 1½″ discharge pipe size or larger) flow switch assembly is preferably supplied as standard, for pumps' lead-lag alternating operation. This assembly will preferably include a stainless-steel flow switch, SS Adapter, 4-meter cable, 316ss isolation ball valve, and coated forged steel fittings. [0046] This component is installed above flood level.

[0047] Local Disconnects [0048] As generally required by local codes, a local power disconnect must be installed near the pumping unit, to allow for immediate shut-down for maintenance purpose or emergency.

[0049] Control Panel [0050] NEMA 12 duplex control panel is preferably supplied as standard. [0051] This component is installed above flood level.

[0052] Thus, by providing the structures and components as described, the present invention provides fully submersible operation without compromising structural integrity and allowing full access to the machinery for maintenance and repair.

[0053] While the foregoing is directed to preferred embodiments of the present invention, further changes, objects, aspects and embodiments of the present invention will be appreciated by those in the art, without departing from the scope of the invention, which will be defined by the following claims.