Submersible water lifting assembly and automatic fire fighting system for unmanned platforms having said system

Abstract

The technology relates to a submersible water lifting assembly and automatic fire fighting system for unmanned platforms having said system (1) that is efficient yet simple to install, energy saving, noise free and economical. The submersible water lifting assembly can comprise a High flow Ratio ejector Pump (30/30A) that utilizes under water arrangements of unmanned platform and enables the fire-fighting system to efficiently lift water from the sea water; using the force of existing water injection system; eliminating the requirement of diesel engine driven pump, for lifting the water. It avoids fire risk of the safety system itself, even in conditions of a large fire, unlike that of the prior art.

Claims

1. A submersible water lifting system for automatic fire-fighting system at unmanned platforms having said submersible water lifting system (1) wherein said submersible water lifting system is a High Flow Ratio Ejector Pump (HFREP) (30), and comprises: Fire detection system (2), First line for Fire signal transmission (2a), Water inlet line (3), Control Panel (4), Blow down Valve (5), Instrument control line (5a), Pressure Regulating Valve (6), High Flow Ratio Ejector Pump (30), discharge water line (8), fire water header (9), Non Return Valve (9a), Plurality of water sprinkler header (10), First water sprinkler header (10a), Second water sprinkler header (10b), Second line for Fire signal transmission (11), Pressure tapping (12), Fire water header isolation valve (13), Utility water header isolation valve (14), Utility water header (15), Plurality of deluge valve (16), First Deluge valve (16A), Second Deluge valve (16B), Plurality of Sprinklers (18), Water surface level (19), Water body (20) [sea], Supply pressure line (21), Water injection header (22), Plurality of Water Injection Wells (23), and Pre-feed Pressure tube (24), Wherein the High Flow Ratio Ejector Pump (30) comprises: Primary water inlet (31), Secondary water inlet (32), Discharge outlet (33), Suction Strainer (34), Diffuser (35), Plurality of first studs (36), Funnel (37), Mixing chamber (38), Welded Nozzle (39), Threaded Nozzle (40), Actuated nozzle (40′), Plurality of bolts & nuts (41), First tension spring (43), First movable slip ring (47), First stationary slip ring (48), Communicating hole (49), Nozzle mounted hydraulic drum (50), Cylindrical pedestal (51), Wherein the water inlet line (3) is connected with water injection header (22) to provide for pressurized water to the submersible water lifting system (1), same way as plurality of water injection wells (23) is connected; the inflow water from the water inlet line (3) is controlled by pressure regulating valve (6) and regulates pressure of the water flow; the first line for fire signal transmission (2a) transmit fire signal from fire detection system (2) to control panel (4) and further transmits from control panel (4) to plurality of deluge valve (16) through second line for fire signal transmission (11) to open first deluge valve (16A) or second deluge valve (16B) or both or more as per fire caught area; said control panel (4) is powered by water pressure taken from water inlet line (3) through supply pressure line (21) or alternatively powered by pneumatic/electric power; similarly, pre-feed pressure tube (24) is also tapped from water inlet line (3) for controlled operation of the HFREP (30); said control panel (4) opens blow down valve (5) provided in water inlet line (3), through instrument control line (5a); and permits pressurised water to enter the submersible water lifting system (1) through primary water inlet (31); the inflow of water from the water inlet line (3) is controlled by pressure regulating valve (6) provided in water inlet line (3), with the help of feedback pressure from pressure tapping (12), provided in discharge water line (8); the submersible water lifting system receives high pressure water from the water inlet line (3) through its primary water inlet (31) to utilize the energy of the same and create the suction within the HFREP (30) to suck more water from the water body (20) through its secondary water inlet (32) and thereby reduce the pressure of the primary water flow and increase the amount of the water to be flowing within the submersible water lifting system; without use of any external source of energy; the primary water flow with reduced pressure and increased water flow discharges from the HFREP (30) to fire water header (9) through non-return valve (9a), through discharge outlet (33) and discharge water line (8); wherein non-Return Valve (9a) are provided to facilitate single side flow of water for fire-fighting; the suction strainer (34) is provided on the secondary water inlet (32) to avoid the entry of marine substances; further plurality of water sprinkler header (10) sprinkle water through plurality of sprinklers (18); once it receives said mixture of water; amongst which, a first water sprinkler header (10a) is provided to sprinkle water in upper deck and a second water sprinkler header (10b) is provided to sprinkle water in lower deck area; the plurality of deluge valve (16) [first deluge valve (16A), second deluge valve (16B)] is provided for directing the water flow in area of fire; said control panel (4) is powered by water pressure taken from water inlet line (3) through supply pressure line (21); in addition, Utility Water isolation Valve (14) manually opens and fire water isolation valve (13) manually closes for directing the water flow to utility water header (15) for utility purposes including cleaning; Wherein said HFREP (30) receive high pressure primary flow of water from the water inlet line (3), through its primary water inlet (31) to utilize the energy of the flow of water and create the suction within the HFREP (30) generating secondary flow; to suck additional water from the water body (20) through its secondary water inlet (32); said welded nozzle (39) is attached to primary inlet (31) facilitates primary water to enter the HFREP (30) from said primary inlet (31); or a threaded nozzle (40) is used where adjusting height of the threaded nozzle (40) is required; or an actuated nozzle (40′) is used for adjusting the height of the actuated nozzle (40′) in increased or decreased pressure of primary flow; wherein the water enters into the enclosed space between said hydraulic drum (50) and cylindrical pedestal (51) through communicating hole (49) and exert more pressure inside this enclosed space, thus volume of this enclosure expands; whereas the actuated nozzle (40′) mounted on hydraulic drum (50) move downward by sliding over first movable slip ring (47) and first stationary slip ring (48) which increases space between mixing chamber (38) & tip of the actuated nozzle (40′); and the pressure of primary flow decreases the first tension spring (43) reduces the space between tip of the actuated nozzle (40′) and mixing chamber (38); the high flow of water induces low pressure zone in an area surrounding a tip of said welded nozzle (39) or threaded nozzle (40) or the tip of said actuated nozzle (40′) which in turn results in flow of water from water body (20) to the HFREP (30); said flow is the secondary flow of water into the HFREP (30) and the area surrounding the welded nozzle, the threaded nozzle or the actuated nozzle (39 or 40 or 40′) from where the flow enters, forms the secondary inlet (32); Said suction strainer is provided to allow only strained water to enter from the secondary inlet (32) thereby preventing entry of marine substances and in turn chocking of the HFREP (30); said funnel (37) is placed at a pre-fixed distance above the welded nozzle, the threaded nozzle or the actuated nozzle (39 or 40 or 40′) by attaching the flange of the funnel (37) with the flange of the welded nozzle, the threaded nozzle or the actuated nozzle (39 or 40 or 40′) using plurality of first studs (36) by plurality of bolts & nuts (41); wherein said funnel (37) is provided to collect the secondary flow from water body (20) as well as primary flow from primary water inlet line (31) and direct it towards the mixing chamber (38); Said pre-fixed distance is manually adjustable to achieve desired distance between the tip of the welded nozzle, the threaded nozzle or the actuated nozzle (39 or 40 or 40′) and funnel (37) for maximum discharge flow as provided by primary flow; said plurality of first studs (36) maintains said pre-fixed distance and provides support to said strainer (34) and attached as well as fixed with flange of funnel (37), by plurality of bolts & nuts (41); said mixing chamber (38) follows the funnel (37); wherein primary and secondary flow of water enters and energy transformation takes place between said two flows for maximum recovery of pressure energy, from the primary flow; diffuser (35) follows said mixing chamber (38) receives the mixture of two water flows (primary flow and secondary flow) to achieve maximum pressure in it; said discharge outlet (33) receive the water from said diffuser (35) and passes to discharge water line (8).

2. An automatic fire-fighting system for unmanned platforms having submersible water lifting system as claimed in claim 1, enabling automatic cleaning of suction strainer, wherein: said fire water header isolation valve and utility water header isolation valve are closed for purpose of automatic cleaning, which facilitates water discharge from secondary water inlet into the water body (sea), thereby enabling cleaning of the suction strainer, further ensuring there is no blockage by marine substances and allows ready infusion of water through secondary water inlet.

3. A submersible water lifting system as claimed in claim 1, wherein: the submersible water lifting system is placed under water body (20) below water surface level (19) for operational advantages and self-defense from fire.

4. A submersible water lifting system for automatic fire-fighting system at unmanned platforms having said submersible water lifting system (1) wherein said submersible water lifting system is a High Flow Ratio Ejector Pump (HFREP) (30A), and comprises: Fire detection system (2), First line for Fire signal transmission (2a), Water inlet line (3), Control Panel (4), Blow down Valve (5), Instrument control line (5a), Pressure Regulating Valve (6), High Flow Ratio Ejector Pump (30A), discharge water line (8), fire water header (9), Non Return Valve (9a), Plurality of water sprinkler header (10), First water sprinkler header (10a), Second water sprinkler header (10b), Second line for Fire signal transmission (11), Pressure tapping (12), Fire water header isolation valve (13), Utility water header isolation valve (14), Utility water header (15), Plurality of deluge valve (16), First Deluge valve (16A), Second Deluge valve (16B), Plurality of Sprinklers (18), Water surface level (19), Water body (20) [sea], Supply pressure line (21), Water injection header (22), Plurality of Water Injection Wells (23), and Pre-feed Pressure tube (24), Wherein, the High Flow Ratio Ejector Pump (30A) comprises: Primary water inlet (31), Secondary water inlet (32), Discharge outlet (33), Suction Strainer (34), Diffuser (35), Plurality of second studs (36′), Funnel (37), Mixing chamber (38), Welded Nozzle (39), Threaded Nozzle (40), Plurality of bolts & nuts (41), Cylinder mounted circular plate (42), Second tension spring (43′), Drum Inlet connection (44), Hydraulic drum (45), Actuator (46), Second movable slip ring (47′), Second stationary slip ring (48′), Wherein; the water inlet line (3) is connected with water injection header (22) to provide for pressurized water to the submersible water lifting system (1), same way as plurality of water injection wells (23) is connected; the inflow water from the water inlet line (3) is controlled by pressure regulating valve (6) and regulates pressure of the water flow; the first line for fire signal transmission (2a) transmit fire signal from fire detection system (2) to control panel (4) and further transmits from control panel (4) to plurality of deluge valve (16) through second line for fire signal transmission (11) to open first deluge valve (16A) or second deluge valve (16B) or both or more as per fire caught area; said control panel (4) is powered by water pressure taken from water inlet line (3) through supply pressure line (21) or alternatively powered by pneumatic/electric power; similarly, pre-feed pressure tube (24) is also tapped from water inlet line (3) for controlled operation of the HFREP (30A); said control panel (4) opens blow down valve (5) provided in water inlet line (3), through instrument control line (5a); and permits pressurised water to enter the submersible water lifting system (1) through primary water inlet (31); the inflow of water from the water inlet line (3) is controlled by pressure regulating valve (6) provided in water inlet line (3), with the help of feedback pressure from pressure tapping (12), provided in discharge water line (8); the submersible water lifting system receives high pressure water from the water inlet line (3) through its primary water inlet (31) to utilize the energy of the same and create the suction within the HFREP (30A) to suck more water from the water body (20) through its secondary water inlet (32) and thereby reduce the pressure of the primary water flow and increase the amount of the water to be flowing within the submersible water lifting system; without use of any external source of energy; the primary water flow with reduced pressure and increased water flow discharges from the HFREP (30A) to fire water header (9) through non-return valve (9a), through discharge outlet (33) and discharge water line (8); wherein non-Return Valve (9a) are provided to facilitate single side flow of water for fire-fighting; the suction strainer (34) is provided on the secondary water inlet (32) to avoid the entry of marine substances; further plurality of water sprinkler header (10) sprinkle water through plurality of sprinklers (18); once it receives said mixture of water; amongst which, a first water sprinkler header (10a) is provided to sprinkle water in upper deck and a second water sprinkler header (10b) is provided to sprinkle water in lower deck area; the plurality of deluge valve (16) [first deluge valve (16A), second deluge valve (16B)] is provided for directing the water flow in area of fire; said control panel (4) is powered by water pressure taken from water inlet line (3) through supply pressure line (21); in addition, Utility Water isolation Valve (14) manually opens and fire water isolation valve (13) manually closes for directing the water flow to utility water header (15) for utility purposes including cleaning; Wherein, said HFREP (30A) receive high pressure primary flow of water from the water inlet line (3), through its primary water inlet (31) to utilize the energy of the flow of water and create the suction within the HFREP (30A) generating secondary flow; to suck additional water from the water body (20) through its secondary water inlet (32); said welded nozzle (39) is attached to primary inlet (31) facilitates primary water to enter the HFREP (30A) from said primary inlet (31); or a threaded nozzle (40) is used where adjusting height of the threaded nozzle (40) is required; the high flow of water induces low pressure zone in an area surrounding a tip of said welded nozzle (39) or threaded nozzle (40) which in turn results in flow of water from water body (20) to the HFREP (30A); said flow is the secondary flow of water into the HFREP (30A) and the area surrounding the welded nozzle or the threaded nozzle (39 or 40) from where the flow enters, forms the secondary inlet (32); said suction strainer (34) allows only strained water to enter from the secondary inlet (32) for preventing entry of marine substances and in turn chocking of the HFREP (30A); said funnel (37) is placed at a pre-fixed distance above the welded nozzle or the threaded nozzle (39 or 40) by attaching the flange of the funnel (37) with the flange of the welded nozzle or the threaded nozzle (39 or 40) using plurality of second studs (36′) by plurality of bolts & nuts (41); said pre-fixed distance is manually adjustable to achieve desired distance between the tip of the welded nozzle or the threaded nozzle (39 or 40) and funnel (37) for maximum discharge flow as per provided primary flow and secondary flow to direct it towards the mixing chamber (38); the plurality of second studs (36′) maintains fixed distance and provides support to said strainer (34) and top ends of the studs (36′) which are fixed with cylinder mounted circular plate (42); the flange of funnel (37) is not fixed with the plurality of second stud (36′) but allow to slip through holes in the flange thus said funnel (37) is free to move; said mixing chamber (38) allows water entry of primary and secondary flow, where energy transformation takes place for maximum recovery of pressure energy, from the primary flow; said diffuser (35) receives the mixture of water flow from mixing chamber (38) to achieve maximum pressure in it; said discharge outlet (33) receive the water and passes to discharge water line (8); said plurality of bolts & nuts (41) fixed the suction strainer (34) with flange of the welded nozzle or the threaded nozzle (39 or 40); the actuator (46) is to adjust space between the welded nozzle or the threaded nozzle (39 or 40) and mixing chamber (38); said actuator (46) is provided for resolving the pressure fluctuations in primary flow in order to achieve maximum discharge flow; Said actuator (46) is connected to flange of the welded nozzle or the threaded nozzle (39 or 40) through plurality of second studs (36′) such that cylinder mounted circular plate (42) of the actuator is attached to the mixing chamber (38) by second movable slip ring (47′) and second stationary slip ring (48′); and is further attached to the water inlet line (3) through a pre-feed pressure tube (24) to receive pressurised water from water inlet line (3) in its hydraulic drum (45) through drum inlet connection (44); said drum inlet connection (44) facilitates the pressure tubing connection between water inlet line (3) and hydraulic drum (45); the received pressure of primary flow of water from water inlet line (3) exerts pressure on cylinder mounted circular plate (42); Said hydraulic drum (45) provides mounting of second tension spring (43′) and facilitates holding of the hydraulic pressure received from primary flow through drum inlet connection (44); Said second moveable slip ring (47′) and second stationary slip ring (48′) provides slipping between mixing chamber (38) and cylinder mounted circular plate (42), as well as hydraulic drum (45) and cylinder mounted circular plate (42); said second tension spring (43′) is provided to restore the position of funnel (37) and the welded nozzle or the threaded nozzle (39 or 40) tip.

5. A submersible water lifting system as claimed in claim 4, wherein: the submersible water lifting system is placed under water body below water surface level for operational advantages and self-defense from fire.

6. An automatic fire-fighting system for unmanned platforms having submersible water lifting system as claimed in claim 4, enabling automatic cleaning of suction strainer, wherein: said fire water header isolation valve and utility water header isolation valve are both closed for purpose of automatic cleaning, which facilitates water discharge from secondary water inlet into the water body (sea), thereby enabling cleaning of the suction strainer, further ensuring there is no blockage by marine substances and allows ready infusion of water through secondary water inlet.

Description

BRIEF DESCRIPTION OF DRAWINGS

(1) TABLE-US-00001 FIG. 1A Shows diagrammatic representation of present automatic firefighting system for unmanned platforms having submersible water lifting assembly FIG. 1B Shows diagrammatic representation of present automatic firefighting system for unmanned platforms having another embodiment of submersible water lifting assembly FIG. 2A Shows perspective view of present submersible water lifting assembly of present automatic firefighting system for unmanned platforms having said assembly FIG. 2B Shows perspective view of another embodiment of the present submersible water lifting assembly of present automatic firefighting system for unmanned platforms having said assembly FIG. 3A Shows longitudinal cross sectional view of present submersible water lifting assembly of present automatic firefighting system for unmanned platforms having said assembly FIG. 3B Shows longitudinal cross sectional view of another embodiment of present submersible water lifting assembly of present automatic firefighting system for unmanned platforms having said assembly FIG. 4 Shows enlarged Cross sectional view of welded nozzle (39); a component of HFREP (30 or 30A), shown in FIG. 3A & FIG. 3B; an alternative of threaded nozzle (40) FIG. 5 Shows enlarge Cross sectional view of threaded nozzle (40); a component of HFREP (30 or 30A), shown in FIG. 3A & FIG 3B; an alternative of welded nozzle (39) FIG. 5A Shows enlarge Cross sectional view of actuated nozzle (40′); a component of HFREP (30), shown in FIG. 3A; an alternative of welded nozzle (39) & threaded nozzle (40). FIG. 6 Shows illustrative flowchart for working of the present firefighting system with respect to embodiment HFREP (30) FIG. 7 Shows illustrative flowchart for working of the present firefighting system with respect to embodiment HFREP (30A) FIG. 8 Shows graph of flow ratio M verses pressure ratio N and flow ratio M verses efficiency η; for area ratio R is 0.1 for illustration of Example 1 FIG. 9 Shows graph of flow ratio M verses pressure ratio N and flow ratio M verses efficiency η; for area ratio R is 0.06 for illustration of Example 2

MEANING OF REFERENCE NUMERALS OF SAID COMPONENT PARTS OF PRESENT INVENTION

(2) TABLE-US-00002  1 Present automatic firefighting system for unmanned platforms having submersible water lifting assembly. (Referred herein after as present invented system)  2 Fire detection system  2a First line for Fire signal transmission  3 Water Inlet line  4 Control Panel  5 Blow down Valve  5a Instrument control line  6 Pressure Regulating Valve  8 Discharge water line  9 Fire water header  9a Non Return Valve 10 Plurality of water sprinkler header 10a First water sprinkler header 10b Second water sprinkler header 11 Second line for Fire signal transmission 12 Pressure taping 13 Fire water header isolation valve 14 Utility water header isolation valve 15 Utility water header 16 Plurality of deluge valve 16A First Deluge valve 16B Second Deluge valve 18 Sprinklers 19 Sea level surface 20 Water body 21 Supply pressure line 22 Water injection header 23 Plurality of water injection well 24 Pre-feed pressure tube 30 High Flow Ratio Ejector Pump (referred herein after as HFREP) 30A Another embodiment High Flow Ratio Ejector Pump 31 Primary water inlet 32 Secondary water inlet 33 Discharge outlet 34 Suction Strainer 35 Diffuser, Work as pressure recovery unit 36 Plurality of first studs 36′ Plurality of second studs 37 Funnel 38 Mixing chamber 39 Welded Nozzle 40 Threaded Nozzle (alternative of welded nozzle (39)) 40′ Actuated Nozzle 41 Bolts & nuts 42 Cylinder mounted circular plate 43 First tension spring 43′ Second Tension spring 44 Drum inlet connection 45 Hydraulic Drum 46 Actuator 47 First movable slip ring 47′ Second movable slip ring 48 First stationary slip ring 48′ Second stationary slip ring 49 Communicating hole 50 Nozzle mounted hydraulic drum 51 Cylindrical pedestal

SUMMARY OF THE INVENTION

(3) Water injection systems described herein above is used by the applicant for the purpose of the present invention; in such a manner that overcomes the risks associated with high pressure. The applicant of the present invention has utilized the available high pressure water flow, in system, for its use in emergency situation of major fire. The system is developed such that the emergency as well as the purpose of fire extinguishing is served using the available water supply arrangement.

(4) Said water injection system has main water supply line known as water injection header (22) from which, water can be distributed to different wells through sub-lines; a water inlet line (3) is directed from said water injection header (22) at a platform to the present invented system (1) to act as a water inlet for the present invented system (1).

(5) The applicant has developed the present invention to utilize the pressurized water for present invented system (1) such that the system controls the pressure; making it utilizable for the purpose as well as it provides a mechanism of utilizing water from the water body (20) (sea) along with it; so as to get maximum benefit of the available water while eliminating wastage of pressurized water placed there for oil extraction.

DETAILED DESCRIPTION OF INVENTION

(6) The present invention relates to a submersible water lifting assembly and automatic fire fighting system for unmanned platforms having said present invented system (1) that is efficient yet simple to install, energy saving, noise free and economical.

(7) More particularly, the present submersible water lifting assembly and automatic fire fighting system for unmanned platforms having said system for automatic fire-fighting (shown diagrammatically in FIG. 1A, 1B), utilizes under water arrangements of unmanned platform for fire-fighting. Thus, the system is fire risk free, feasibly installed within available arrangements and is thus cost effective and easy to construct; yet is efficient. This eliminates requirement of space on platforms and ensuring fire safety of the system itself unlike the prior art.

(8) Present submersible water lifting assembly; for the purpose of present invention; is a High Flow Ratio Ejector Pump (30 or 30A) (referred herein after as HFREP) that utilizes under water arrangements of unmanned platform and enables the fire-fighting system to efficiently lift water from the sea water; using the force of existing water injection system; eliminating the requirement of diesel engine driven pump, for the lifting of water. Thus, said High Flow Ratio Ejector Pump (30 or 30A) enables fire safety without use of bulky engine driven fire water pump; unlike that of the prior art.

(9) Referring to FIGS. 1A, 2A, 3A, 4, 5, and 5A; shows the said High Flow Ratio Ejector Pump (30) [hereinafter referred to as HFREP (30)] of the first embodiment of the present invention. Said HFREP (30) mainly comprises of: Primary water inlet (31), Secondary water inlet (32), Discharge outlet (33), Suction Strainer (34), Diffuser (35), Plurality of first studs (36), Funnel (37), Mixing chamber (38), Welded Nozzle (39), Threaded Nozzle (40), Actuated nozzle (40′), Plurality of bolts & nuts (41), First tension spring (43), First Movable slip ring (47), First stationary slip ring (48), Communicating hole (49), Nozzle mounted hydraulic drum (50), Cylindrical pedestal (51).

(10) Wherein said HFREP (30) is provided to receive high pressure primary flow of water from the water inlet line (3), through its primary water inlet (31) to utilize the energy of the flow of water and create the suction within the HFREP (30) generating secondary flow; to suck additional water from the water body (20) through its secondary water inlet (32). Welded nozzle (39) attached to primary inlet (31) facilitates primary water to enter the HFREP (30) from said primary inlet (31). Alternatively, a threaded nozzle (40) is used where height of the threaded nozzle (40) is adjustable with use of threads provided therein or actuated nozzle (40′) is used for automatic height adjustment as per fluctuation in supply pressure (pressure of primary water flow). The high flow of water induces low pressure zone in the area surrounding the tip of said welded nozzle (39) or threaded nozzle (40) or actuated nozzle (40′). This in turn results in flow of water from water body (20) to the HFREP (30). Said flow is the secondary flow of water into the HFREP (30) and the area surrounding the nozzle (39 or 40 or 40′) from where the secondary flow enters, forms the secondary inlet (32).

(11) A suction strainer (34) is provided to allow only strained water to enter from the secondary inlet (32) thereby preventing entry of marine substances and in turn chocking of the HFREP (30). A funnel (37) is placed at a pre-fixed distance above the nozzle (39 or 40 or 40′) by attaching the flange of the funnel (37) with the flange of the nozzle (39 or 40 or 40′) using plurality of first studs (36) by plurality of bolts & nuts (41). Said funnel (37) is provided to collect the secondary flow from water body (20) as well as primary flow from primary water inlet line (31) and direct it towards the mixing chamber (38). Said plurality of first studs (36) maintains said pre-fixed distance and provides support to said strainer (34) and attached as well as fixed with flange of funnel (37), by plurality of bolts & nuts (41). Said pre-fixed distance is manually adjustable to achieve maximum flow ratio (secondary flow to primary flow) according to available supply pressure (In general practice of designing ejector, the space between nozzle and mixing chamber is generally kept same as that of the diameter of mixing chamber. This is called prefixed distance.) wherein; if the provided pressure of primary flow (supply flow) is high, then the distance between the tip of nozzle (39 or 40 or 40′) and funnel (37) should be more which can be adjusted by manual replacement of other welded nozzle (39) or by rotating the threaded nozzle (40) or by automatic adjustment of actuated nozzle (40′) and if the provided primary pressure is low then the distance between the tip of nozzle (39 or 40 or 40′) and funnel (37) should be less which can be adjusted by manual replacement of other welded nozzle (39) or by rotating the threaded nozzle (40) or by automatic adjustment of actuated nozzle (40′). A mixing chamber (38) follows the funnel (37); wherein primary and secondary flow of water enters and where energy transformation takes place between said two flows, for maximum recovery of pressure energy, from the primary flow. A diffuser (35) following said mixing chamber (38) receives the water flow, which is a mixture of two flows (primary flow and secondary flow) from mixing chamber (38) to achieve maximum pressure in it. A discharge outlet (33) receives the water from said diffuser (35) and passes to discharge water line (8).

(12) Specifically, an actuated nozzle (40′) is provided to adjust the tip of nozzle as per pressure fluctuation in primary flow. Said actuated nozzle (40′) comprises first tension spring (43), communicating hole (49), nozzle mounted hydraulic drum (50), cylindrical pedestal (51), first movable slip ring (47) and first stationary slip ring (48). Wherein, said hydraulic drum (50) received pressure of primary flow of water from primary water inlet (31) and cylindrical pedestal (51). Said cylindrical pedestal (51) provides passage for primary flow and facilitate sealing & slipping arrangement for slip rings, to guide or limit movement arrangement of nozzle mounted hydraulic drum (50) and to support first tension spring (43). Said first tension spring (43) is supported by nozzle mounted hydraulic drum (50) and cylindrical pedestal (51). Said communicating hole (49) provides the entry of water into the enclosed space between said hydraulic drum (50) and cylindrical pedestal (51) and exert more pressure inside this enclosed space, thus volume of this enclosure expands. Said first movable slip ring (47) and first stationary slip ring (48) provides movement of the nozzle mounted hydraulic drum downwards through sliding down as shown in FIG. 5A. Thus said actuated nozzle (40′) also moves downward wherein it increases space between mixing chamber (38) & tip of the nozzle (40′). Said first tension spring (43) is provided to reduce the space between tip of actuated nozzle (40′) and mixing chamber (38) when it receives decreased pressure of primary flow.

(13) The submersible water lifting assembly [HFREP (30)] of present automatic fire-fighting system, is placed below water surface level (19) (see FIG. 1A and FIG. 1B); facilitating utilization of water from water body (20) (sea) for fire-fighting as well as safe guarding said assembly itself from fire risk.

(14) Referring to FIGS. 1B, 2B, 3B, 4 and 5; shows the said High Flow Ratio Ejector Pump (30A); an alternative embodiment HFREP (30A) of the present invention. Said HFREP (30A) mainly comprises of: Primary water inlet (31), Secondary water inlet (32), Discharge outlet (33), Suction Strainer (34), Diffuser (35), Plurality of second studs (36′), Funnel (37), Mixing chamber (38), Welded Nozzle (39), Threaded Nozzle (40), Plurality of bolts & nuts (41), Cylinder mounted circular plate (42), Second Tension spring (43′), Drum Inlet connection (44), Hydraulic drum (45), Actuator (46), Second movable slip ring (47′) Second stationary slip ring (48′).

(15) Wherein said HFREP (30A) is provided to receive high pressure primary flow of water from the water inlet line (3), through its primary water inlet (31) to utilize the energy of the flow of water and create the suction within the HFREP (30A) generating secondary flow; to suck additional water from the water body (20) through its secondary water inlet (32). Welded nozzle (39) is attached to primary inlet (31) facilitates primary water to enter the HFREP (30A) from said primary inlet (31). Alternatively, a threaded nozzle (40) is used where adjusting height of the nozzle (40) is required. The high flow of water induces low pressure zone in the area surrounding the tip of said welded nozzle (39) or threaded nozzle (40). This in turn results in flow of water from water body (20) to the HFREP (30A). Said flow is the secondary flow of water into the HFREP (30A) and the area surrounding the nozzle (39 or 40) from where the flow enters, forms the secondary inlet (32).

(16) A suction strainer (34) is provided to allow only strained water to enter from the secondary inlet (32) thereby preventing entry of marine substances and in turn chocking of the HFREP (30A). A funnel (37) is placed at a pre-fixed distance as per provided primary flow, above the nozzle (39 or 40) by attaching the flange of the funnel (37) with the flange of the nozzle (39 or 40) using plurality of second studs (36′) by plurality of bolts & nuts (41). Said pre-fixed distance is manually adjustable to achieve desired distance between the tip of nozzle (39 or 40) and funnel (37) for maximum discharge flow as per provided primary flow; wherein if the provided primary flow is high then the distance between the tip of nozzle (39 or 40) and funnel (37) should be more, which can be adjusted manually by replacing welded nozzle (39) or by rotating the threaded nozzle (40); further if the provided primary flow is low then the distance between the tip of nozzle (39 or 40) and funnel (37) should be less which can be adjusted manually by replacing welded nozzle (39) or by rotating the threaded nozzle (40). Said funnel (37) is provided to collect the secondary flow from water body (20) as well as primary flow from primary inlet line (31) and direct it towards the mixing chamber (38). Said plurality of second studs (36′) maintains said fixed distance and provides support to said strainer (34) and top ends of the studs (36′) are fixed with cylinder mounted circular plate (42); wherein the bottom ends of the studs (36′) are fixed with nozzle (39 or 40). Whereas, the flange of funnel (37) is not fixed with the plurality of second stud (36′) but allows to slip through holes in the flange. Hence said funnel (37) is free to move. The holes, in the flange of funnel (37), guides the plurality of studs (36′) for linear motion. A mixing chamber (38) follows the funnel (37); wherein primary and secondary flow of water enters and where energy transformation takes place between said two flows, for maximum recovery of pressure energy, from the primary flow. A diffuser (35) following said mixing chamber (38) receives the water flow, which is a mixture of two flows (primary flow and secondary flow) from mixing chamber (38) to achieve maximum pressure in it. A discharge outlet (33) receive the water from said diffuser (35) and passes to discharge water line (8). Said plurality of bolts & nuts (41) are provided for fixing of suction strainer (34) with flange of nozzle [welded nozzle (39) or threaded nozzle (40)]. The special mechanism is provided by actuator (46) to adjust space between nozzle [welded nozzle (39) or threaded nozzle (40)] and mixing chamber (38).

(17) An actuator (46) is provided for resolving the pressure fluctuations in primary flow while adjusting the distance between the tip of nozzle (39 or 40) and funnel (37) as per pressure fluctuations in primary flow; in order to achieve maximum discharge flow. Said actuator (46) is connected to flange of nozzle (39 or 40) through plurality of second studs (36′) such that cylinder mounted circular plate (42) of the actuator is attached to the mixing chamber (38) by second movable slip ring (47′) and Second stationary slip ring (48′) as shown in FIG. 3B. Said actuator (46) is further attached to the water inlet line (3) through a pre-feed pressure tube (24) to receive pressurised water from water inlet line (3).

(18) Said actuator (46) comprises of cylinder mounted circular plate (42), Second tension spring (43′), hydraulic drum (45), drum inlet connection (44), second stationary slip ring (48′) and second moveable slip ring (47′). Wherein said actuator (46) receives pressurised water from water inlet line (3) in its hydraulic drum (45) from pre-feed pressure tube (24) through drum inlet connection (44). Said drum inlet connection (44) facilitates the pressure tubing connection between water inlet line (3) and hydraulic drum (45); the received pressure of primary flow of water from water inlet line (3) exerts pressure on cylinder mounted circular plate (42). Said hydraulic drum (45) provides mounting of Second tension spring (43′) and facilitates holding of the hydraulic pressure received from primary flow through drum inlet connection (44). Said second moveable slip ring (47′) provides slipping between mixing chamber (38) and cylinder mounted circular plate (42); and second stationary slip ring (48′) provides slipping between hydraulic drum (45) and cylinder mounted circular plate (42). Said second tension spring (43′) is provided to restore the position of funnel (37) and nozzle (39 or 40) tip when supply pressure (primary pressure) is at set pressure value, to achieve maximum ratio of flow and eliminate possibility of cavity formation; resulting by creation of low pressure that is less than vapour pressure of water in mixing chamber (38) due to very high velocity of primary flow, which can be avoided by reduction of pressure of primary flow or increase of secondary pressure, or reduction in flow ratio or increasing area ratio [ratio of cross sectional area of nozzle tip (39) to cross sectional area of mixing chamber (38)] and change in pressure ratio [ratio of secondary flow pressure rise to primary flow pressure drop]; which is not desirable for fire-fighting system. (As firefighting must not be stop to make these changes in between firefighting operation)

(19) When the increased pressure is received by said hydraulic drum (45), it pushes the cylinder mounted circular plate (42) and thereby the attached funnel (37) moves downward by slipping over each other through second stationary slip ring (48′) and second moveable slip ring (47′), which increases the space between nozzle [39 or 40] and funnel (37) as per increased pressure of primary flow. And if the pressure of primary flow is decreased, the second tension spring (43′) takes action to reduce the space between nozzle (39 or 40) and funnel (37).

(20) The submersible water lifting assembly HFREP (30) or (30A) of present automatic fire-fighting system, is placed below water surface level (19) (see FIG. 1A and FIG. 1B); facilitating utilization of water from water body (20) (sea) for fire-fighting as well as safe guarding said assembly itself from fire risk.

(21) Referring to FIGS. 1A & 1B; which shows preferred embodiments of the present invented invention (1); wherein water injection system of a platform of oil and gas industry is utilized to provide present automatic firefighting system for offshore platforms that is easy to install and operate, yet is efficient and economical. Said present invented system (1) mainly comprises of: Fire detection system (2), First line for Fire signal transmission (2a), Water inlet line (3), Control Panel (4), Blow down Valve (5), Instrument control line (5a), Pressure Regulating Valve (6), High Flow Ratio Ejector Pump (30 or 30A) (referred herein after as HFREP), discharge water line (8), fire water header (9), Non Return Valve (9a), Plurality of water sprinkler header (10), First water sprinkler header (10a), Second water sprinkler header (10b), Second line for Fire signal transmission (11), Pressure tapping (12), Fire water header isolation valve (13), Utility water header isolation valve (14), Utility water header (15), Plurality of deluge valve (16), First Deluge valve (16A), Second Deluge valve (16B), Plurality of Sprinklers (18), Water surface level (19), Water body (20) [sea], Supply pressure line (21), Water injection header (22), Plurality of Water Injection Wells (23), Pre-feed Pressure tube (24).

(22) Fire detection system (2); is part of oil & gas operation, at platforms it is utilized for obtaining fire signal, through first line for fire signal transmission (2a) to activate the present invented system (1) for firefighting.

(23) Said fire signal is further transmitted to plurality of deluge valve (16) through second line for fire signal transmission (11) from control panel (4); to open First deluge valve (16A) or second deluge valve (16B) or both or more. The control panel (4) is preferably powered by water pressure taken from water inlet line (3) through supply pressure line (21); or otherwise it can also be powered by pneumatic/electric power as per location where system is used. Similarly, pre-feed pressure tube (24) is also tapped from water inlet line (3) for controlled operation of HFREP (30A).

(24) The water inlet line (3) is connected with water injection header (22); wherein said water inlet line (3) tapped from water injection header (22) to provide pressurized water to the present invented system (1). The plurality of water injection wells (23) is also connected with said water injection header (22); for operation of present invented system (1) where water injection header (22) is part of platform. The inflow of water from the water inlet line (3) is controlled by pressure regulating valve (6); wherein said pressure regulating valve (6) regulates pressure of the water flow. The inflow of water from the water inlet line (3) is controlled by pressure regulating valve (6) provided in water inlet line (3), with the help of feedback pressure from pressure tapping (12), provided in discharge water line (8); Said water has a high pressure and cannot be used directly for the purpose of extinguishing the fire. Thus, a mechanism of pressure control is provided in the present invented system (1) to best utilize the available source of water for fire extinguishing. Said control panel receives fire signal through first line for fire signal transmission (2a); form fire detection system (2) which activates blow down valve (5) through instrument control line (5a), and permits pressurised water to enter the present invented system (1) through water inlet line (3) and primary water inlet (31). At the same time, said control panel (4) direct the fire signal to open plurality of deluge valve (16) [First deluge valve (16A) or second deluge valve (16B) or both or more] through second line for fire signal transmission (11).

(25) The submersible water lifting system (30 or 30A) receive high pressure water from the water inlet line (3) through its primary water inlet (31) to utilize the energy of the same and create the suction within the HFREP (30 or 30A) to suck more water from the water body (20) (sea) through its secondary water inlet (32), within which the present invented system (1) is used, and thereby reduce the pressure of the primary water flow and increase the amount of the water to be flowing within the system; without use of any external source of energy. The primary water flow with reduced pressure and increased amount of water flow discharges from the HFREP (30 or 30A) to the discharge water line (8) through discharge outlet (33).

(26) A suction strainer (34) is provided on the secondary water inlet (32) to avoid the entry of marine substances. It is pertinent to note that the water suction from the water body (20) is as high as enabling suction of multiple times of water flow as compared to the originally received pressurised water flow; resulting into utilization of maximum water from the abundant and free water source and eliminating wastage of energy stored in the pressurized water. It also minimise the use of high pressure water which is required for other important purposes.

(27) Said discharge water line (8) receive water flow form the HFREP (30 or 30A) through discharge outlet (33) and passes water flow to fire water header (9) as well as non-return valve (9a); wherein non-Return Valve (9a) are provided to facilitate single side flow of water for fire-fighting. Said plurality of water sprinkler header (10) receive said water and is provided to spray water on fire area; amongst which, a first water sprinkler header (10a) is provided to sprinkle water in upper deck area and a second water sprinkler header (10b) is provided to sprinkle water in lower deck area, and also provided to spray water, over fire caught area through plurality of Sprinklers (18). The plurality of deluge valve (16) is provided to allow passing of water to said first water sprinkler header (10a) or second water sprinkler header (10b) or both or more headers; depending upon the area in which fire has taken place. This directs the water to the fire affected area only; and avoids wastage of water by blocking passage of water in other areas. Further, depending on the plurality of water sprinkler header (10) arranged in different regions of the platform; plurality of deluge valve (16) is provided to facilitate in directing the water flow in area where fire is existing.

(28) The submersible water lifting assembly of present automatic fire-fighting system is placed below water surface level (19), facilitating utilization of water from water body (20) (sea) for fire-fighting as well as safe guarding said assembly itself from fire risk.

(29) Said present invented system (1) also has provisions to allow the water to be used for other purposes including cleaning. The Fire water header isolation valve (13) is thus provided; which can be closed and utility water header isolation valve (14) can be opened so as to allow said resultant water to pass through Utility water header (15) for said purposes. Also, said fire water header isolation valve (13) and utility water header isolation valve (14); both can be closed to ensure water discharge from secondary water inlet (32) into the water body (20) (sea), for cleaning of the suction strainer (34). This ensures there is no blockage by marine substances and allows ready infusion of water through secondary water inlet (32). This makes the maintenance simple and efficient. Also, there is no requirement of rendering the platform at risk of fire, during maintenance of fire-fighting system unlike the prior arts.

(30) Wherein, modifications in the present invented system (1) for accommodating present water lifting assembly i.e. HFREP (30 and 30A) involves the modifications in terms elimination of complex arrangements of air or gas start up vessel, diesel storage vessel, diesel tank, diesel engine, gear box, multi stage centrifugal pump, vertical column casing, 40 meter length heavy duty shaft and related arrangements of its supply and usage during operation of said prior art system. The elimination of said parts results in simplified rearrangement of remaining parts to provide a simple yet efficient said system (1) as shown in FIG. 1A & FIG. 1B and as described herein. The obtained present invented system (1) utilizes novel water lifting system (30 and 30A) as described herein above; which works without requirement of external energy sources and avoids wastage of water; yet is efficient in supplying water to the present invented system (1) for extinguishing fire; even at an unmanned platform.

(31) Further, herein before disclosed are the preferred embodiments of the present invented systems (1) with reference to accompanying drawings. Here, it is to be noted that the present invention is not limited thereto and can be used for varied applications including firefighting systems for onshore and water transport systems for transporting water from lower level to higher levels. The components like flow meters drain lines tappings with drain valves, pressure gauges, blinds, plugs, isolation valve etc. are not shown in the FIG. & not described as it is understood & still in the scope of the intervention. Furthermore, the component parts described are not meant there to limit its operating, and any rearrangement of the component parts for achieving the same functionality is still within the spirit and scope of the present invention. It is to be understood that the drawings are not drawn to scale and are only for illustration purposes.

Working of the Invention

(32) Referring to FIGS. 1A, 2A, 3A 4, 5, 5A and 6: with respect to embodiment HFREP (30) I. When fire take place in area of platform, the fire detection system (2) transmit the fire signal, through First line for Fire signal transmission (2a); which is received by control panel (4). II. Said fire signal is further transmitted to second line for Fire signal transmission (11) of area where fire took place and open plurality of deluge valve (16). III. The Control Panel (4) simultaneously send signal to open blow down valve (5) through instrument control line (5a) which provided in water inlet line (3). IV. Said blow down valve (5) is opened and allow water flow from water injection header (22), attached with plurality of water injection well (23); through the water inlet line (3); enters into pressure regulating valve (6). V. The said pressure regulating valve (6), regulate the pressure of water flow and allows water flow to enter into nozzle (39 or 40 or 40′) of HFREP (30), which is placed below water surface level (19), into water body (20) and enters through primary water inlet (31). VI. Said primary water inlet (31) allow water flow to enter into the nozzle (39 or 40 or 40′); wherein a. said nozzle (39 or 40 or 40′) converts water flow into high velocity water jet, which strikes on area of water body (20); enclosed between conical area of funnel (37) and tip of nozzle [welded nozzle (39) or threaded nozzle (40)]. b. Specifically, actuated nozzle (40′) is useful when the primary pressure increase in the space below tip of actuated nozzle (40′); wherein, when the water enters into enclosed space between hydraulic drum (50) and cylindrical pedestal (51), through communicating hole (49) and exert more pressure inside this enclosed space so, volume of enclosure expands. As a result, the actuated nozzle (40′) mounted on hydraulic drum (50) move downward by sliding over first movable slip ring (47) and first stationary slip ring (48). Hence increases space between mixing chamber (38) & tip of the actuated nozzle (40′) as shown in FIGS. 5A and 6A. And if pressure of primary flow decreases the first tension spring (43) take action to reduce the space between tip of actuated nozzle (40′) and mixing chamber (38). VII. The impact of water jetting pushes the effected water (primary water and secondary water) inside said funnel (37) and directed towards mixing chamber (38). When water from water body (20) move toward mixing chamber (38) through said funnel (37) the low pressure generated in this area; creates water flow from water body (20) to mixing chamber (38), through secondary water inlet (32) and suction strainer (34); and starts water lifting from water body. VIII. The lifted water in mixing chamber (38) along with primary water travels toward diffuser (35) and proceed to discharge outlet (33). Form said discharge outlet (33) water travels toward discharge water line (8). IX. Said lifted water, passes through pressure tapping (12), where it detects the pressure of water flow of discharge water line (8). X. The pressure tapping (12) gives the pressure feedback to pressure regulating valve (6) that regulates pressure of the water flow; as per requirement, and set into pressure regulating valve (6). It will control the pressure of discharge water line (8). XI. As the fire water header isolation valve (13) normally remains opened and utility water header isolation valve (14) normally remains closed; the pressure controlled flow in discharge water line (8) passes to fire water header (9), through non return valve (9a). Hence fire water header (9) gets filled by said water flow. XII. The water in said fire water header (9), passes to plurality of water sprinkler header (10), through plurality of deluge valve (16). XIII. Said plurality of deluge valve (16) being already opened by action II of control panel (4) as described earlier in step “II”, water flow passes to plurality of sprinklers (18); which starts sprinkling of water, over fire caught area, detected by fire detection system (2). XIV. If water is needed for other purposes like utility water for cleaning or testing of flow rate or regular maintenance etc., the utility water header (15) can be used by opening of utility water header isolation valve (14), and simultaneously closing fire water header isolation valve (13).

(33) Referring to FIGS. 1B, 2B, 3B, 4, 5 & 7: with respect to embodiment HFREP (30A) I. When fire take place in any area of platform, the fire detection system (2) transmit the fire signal, through First line for Fire signal transmission (2a), which is received by control panel (4). II. Said fire signal is further transmitted to Second line for Fire signal transmission (11) of area where fire took place and open plurality of deluge valve (16). III. The Control Panel (4) simultaneously sends signal to open blow down valve (5), provided in water inlet line (3), through instrument control line (5a). IV. Said blow down valve (5) opened and allow water to flow, from water injection header (22), attached with plurality of water injection well (23); to the water inlet line (3); and enter through primary water inlet (31). V. The pressure regulating valve (6) regulates the pressure of water flow and allows water flow to enter into nozzle (39 or 40) of HFREP (30A), which is placed below water surface level (19), into water body (20), which enters through primary water inlet (31). VI. Simultaneously, feed water from water inlet line (3) enters into actuator (46) through pre-feed pressure tube (24) which is connected through drum inlet connection (44). Said feed water enters into the hydraulic drum (45) through drum inlet connection (44) and exerts pressure on cylinder mounted circular plate (42) by slipping over each other though Second stationary slip ring (48′). VII. The pressure on said cylinder mounted circular plate (42); move the said cylinder mounted circular plate (42) downward by slipping over each other though moveable slip ring (47); the nozzle also moves downward through inter connected plurality of second studs (36′) with the cylinder mounted circular plate (42), as shown in the FIG. 3B. Hence, the space between nozzle and funnel (37) increase with the pressure. Similarly, if pressure of water inlet line (3) decreases; the pressure supplied in hydraulic drum (45) also decreases; the Second tension spring (43′) inside the hydraulic drum (45) take action to pool nozzle (39 or 40) upward in same manner as discussed above and decrease the space between nozzle (39 or 40) and funnel (37). Thus said actuator (46); provides the function of controller that adjust the space between nozzle (39 or 40) and funnel (37) to achieve maximum ratio of water flow. VIII. Said nozzle (39 or 40) converts water flow into high velocity water jet, which strike on area of water body (20); enclosed between conical area of funnel (37) and tip of nozzle (39 or 40). IX. The impact of water jetting pushes the effected water (primary water and secondary water) inside said funnel (37) and directed towards mixing chamber (38). When water from water body (20) move toward mixing chamber (38) through said funnel (37) the low pressure generated in this area; creates water flow from water body (20) to mixing chamber (38), through secondary water inlet (32) and suction strainer (34); and starts water lifting from water body. X. The lifted water in mixing chamber (38) along with primary water travels toward diffuser (35) and proceed to discharge outlet (33). Form said discharge outlet (33) water travels toward discharge water line (8). XI. Lifted water passes through pressure tapping (12), where it detects the pressure of water flow in discharge water line (8). XII. The pressure tapping (12), give the pressure feedback to pressure regulating valve (6) that regulates pressure of the water flow; that is in turn facilitated by the pressure tapping (12), as per requirement, and set into pressure regulating valve (6). It controls the pressure of discharge water line (8). XIII. As the fire water header isolation valve (13) is normally remains opened, and utility water header isolation valve (14) is normally remain closed; the pressure controlled flow in discharge water line (8), passes to fire water header (9), through non-return valve (9a). Hence fire water header (9) is get filled by this water flow. XIV. The water in said fire water header (9), passes to plurality of deluge valve (16), through plurality of water sprinkler header (10). XV. Said plurality of deluges valve (16) being already opened by II action of control panel (4) as described earlier in step “II”, water flow passes to plurality of sprinklers (18); sprinkling of water, starts over fire detected area, detected by fire detection system (2). XVI. If water is needed for other purposes like utility water for cleaning or testing of flow rate or regular maintenance etc., the utility water header (15) can use by opening of utility water header isolation valve (14), and simultaneously closing fire water header isolation valve (13).

(34) Referring to FIGS. 1B and 2B: with respect to embodiment HFREP (30) and another embodiment HFREP (30A)

(35) When fire take place in any area of platform, the fire detection system (2) transmit the fire signal, through first line for fire signal transmission line (2a); which is received by control panel (4). Said fire signal is further transmitted to plurality of deluge valve (16) through second line for fire signal transmission (11). Simultaneously control Panel (4) send signal to open blow down valve (5) through instrument control line (5a) and allows water flow from water injection header (22), attached with plurality of water injection well (23).

(36) Said pressure regulating valve (6) regulate the pressure of water flow and allows water flow to enter into nozzle (39 or 40 or 40′) of HFREP (30 or 30A), which is placed below water surface level (19), into water body (20), through primary water inlet (31). Said primary water flow with reduced pressure and increased water flow discharges from the HFREP (30 or 30A) to fire water header (9) through non-return valve (9a), through discharge outlet (33) and discharge water line (8); and passes through pressure tapping (12) which gives the pressure feedback to pressure regulating valve (6). As the fire water header isolation valve (13) normally remains opened and utility water header isolation valve (14) normally remains closed; the pressure controlled flow in discharge water line (8) passes to fire water header (9), through non-return valve (9a). Hence fire water header (9) gets filled by this water flow. The water in said fire water header (9), passes to plurality of water sprinkler header (10), through plurality of deluge valve (16). Said plurality of deluge valve (16) passes water flow to plurality of sprinklers (18); starts sprinkling of water, over fire caught area, detected by fire detection system (2).

(37) Inlet water flow from water inlet line (3) to the HFREP (30 or 30A), is known as primary flow and inlet water flow from water body (20) to HFREP (30 or 30A), is known as secondary flow. Whereas these both the flows mix together and travel towards fire water header (9) is known as generated flow or discharged flow. These generated flow is depends upon parameters, inlet flow rate Q.sub.p, pressure of inlet flow P.sub.p, flow ratio M (flow ratio of secondary flow rate to primary flow rate), secondary pressure P.sub.s, discharge pressure (needed pressure) P.sub.d, nozzle diameter A.sub.n, efficiency η and Pressure ratio (N)=(P.sub.5−P.sub.2)/(P.sub.1−P.sub.5).

(38) Where, P.sub.1 is pressure of primary flow (also known as supply pressure), P.sub.2 is pressure of secondary flow (also known as suction pressure), P.sub.5 is pressure of mixed flow (also known as discharged pressure).

Example 1

(39) The efficiency and flow ratio of High Flow Ratio Ejector Pump (HFREP) are depending upon parameters applied in the invented system. For example, 16 mm diameter of welded nozzle (39) or threaded nozzle (40), Or actuated nozzle (40′) area ratio R is 0.1, primary water supply flow pressure 100 kg/cm2, secondary water inlet suction pressure 2 kg/cm2 and required desired pressure 11 kg/cm2, N will be 0.1, the flow ratio M will be 2.5, the efficiency observed is 0.25, with the resultant discharged flow rate 350 m3/hr.

(40) This is better illustrated by graph shown in FIG. 8.

(41) Illustration: the graph is plotted for area ratio R=0.1 (cross section area of nozzle (39 or 40 or 40′) outlet at tip divided by cross sectional area of mixing chamber (38) it is clearly observed from the graph in FIG. 8, that flow ratio M (secondary flow or primary flow) is depends upon selected pressure ratio N (pressure difference of primary pressure & discharged pressure) divided by (difference of discharged pressure & secondary pressure), for Pressure ratio N=0.1; observed flow ratio is 2.5 and maximum efficiency will be 0.25, since this pump is used for fire-fighting where fire extinguishing much more important than efficiency, low efficiency is preferred for high flow ratio but cavitation problem can be solve by help of adjustment of space between nozzle (39 or 40 or 40′) and funnel (37) (or mixing chamber (38)); that is adjusted manually in embodiment HFREP (30), whereas it is adjusted automatically in another embodiment HFREP (30A).

Example 2

(42) The efficiency and flow ratio of High Flow Ratio Ejector Pump (HFREP) are depending upon parameters applied in the invented system. For example, 16 mm diameter of welded nozzle (39) or threaded nozzle (40), or actuated nozzle (40′), area ratio R is 0.06, primary water supply flow rate 100 m3/hr. at pressure 100 kg/cm2, secondary water inlet suction pressure 2 kg/cm2 and required desired pressure 8 kg/cm2, N will be 0.06, the flow ratio M will be 3.5, the efficiency observed is 0.25, with the resultant discharged flow rate 450 m3/hr.

(43) This is better illustrated by graph shown in FIG. 9

(44) Illustration: the graph is plotted for area ratio R=0.06 (cross section area of nozzle (39 or 40 or 40′) outlet at tip/cross sectional area of mixing chamber (38)) it is clearly observed from the graph in FIG. 9, that flow ratio M (secondary flow divided by primary flow) is depends upon selected pressure ratio N (pressure difference of primary pressure & discharged pressure) divided by (difference of discharged pressure & secondary pressure), for Pressure ratio N=0.06; observed flow ratio is 3.5 and maximum efficiency will be 0.35, since this pump is used for fire-fighting where fire extinguishing much more important than efficiency, low efficiency is preferred for high flow ratio but cavitation problem is solved by help of adjustment of space between nozzle (39 or 40 or 40′) and funnel (37) (or mixing chamber (38)). That is adjusted manually in embodiment HFREP (30), whereas it is adjusted automatically in another embodiment HFREP (30A).

Comparison of Prior Art and Present Invention

(45) The typical prior art and the present invention are hereby compared in the below table to clearly bring out the technical differences between the prior art and the present invention.

(46) A comparison is done between the prior art (traditional) ejector pumps and the submersible water lifting assembly of the present invention through the values of various parameters and its impact. This clearly depicts the disadvantages of the traditional systems; thereby establishing the need for the present invention.

(47) TABLE-US-00003 TABLE 1 Comparative analysis of traditional ejector pumps with present submersible water lifting assembly, used in present automatic fire-fighting system. HFREP (30 or Prior Art of 30A) in Disadvantages/ Ejector present differences of Sr. (Normal invention. prior arts over No. Parameters Range) (Normal range) present invention 1. Supply/ 1 Kg/cm2 to Not less than Prior arts Can't Primary 50 kg/cm2 50 kg/cm2 generate high pressure. discharge flow which is most important for fire- fighting, at this supply pressure. The present invention is designed for high flow rate. 2. Secondary/ 0 to 2 kg/cm2 Not less than 2 In prior arts cavity suction kg/cm2 formation is Pressure. possible if operated at high primary pressure, whereas this problem is solved in present invention. 3. Discharge 0 to 10 0 to 15 kg/cm2 Range of discharge Pressure. kg/cm2 pressure of HFREP is higher. 4. Primary 1 m3/hr to 10 100 m3/hr to In prior arts, it is Flow. m3/hr 200 m3/hr very small flow compared to present invention. So It is big disadvantage of prior arts, since it can't generate large discharge flow for fire-fighting. 5. Secondary 1 m3/hr to 10 200 m3/hr to In prior arts, it is Flow. m3/hr 600 m3/hr very small flow compared to present invention. So It is big disadvantage of prior arts, since it can't generate large discharge flow for fire-fighting. 6. Discharge 2 m3/hr to 20 300 m3/hr to Biggest flow m3/hr 800 m3/hr disadvantage of prior art is having very less discharge flow than the discharged flow of present invention. 7. Flow Ratio. Less the 1 Greater than 2 Serious disadvantage of prior art is having less flow ratio, compared to present invented system. 8. Primary Less than 5 Greater than 15 Cannot generate as Nozzle mm mm high flow as Diameter. generated in present invention. 9. Primary Less than 5 Greater than 15 Possibility of cavity Nozzle mm mm formation in prior Spacing arts if it used for high flow rate. Cavity problem is solved in present invention by providing flexibility to adjust space as needed for maximum flow ratio. 10. Mixing Less the 15 Greater than 45 Due to this, the Chamber mm mm capacity of flow in Diameter. prior art is less than that of present invention. 11. Mixing Less than 35 Greater than 75 Due to this, Chamber mm mm capacity of flow in Length prior art, is less than that of present invention. 12. Diffuser Less than 33 Greater than Due to this, Diameter. mm 100 mm capacity of flow in prior art, is less than that of present invention. 13. Diffuser 66 mm to 77 Greater than Due to this, Length. mm 200 mm capacity of flow in prior art, is less than that of present invention. 14. Variables Generally not Variable Cannot adjust for Nozzle variable maximum flow Spacing. ratio in prior arts. Whereas, it can be done in present invention. 15. Flexibility for Not applicable. Provided for This is big reversal of NRV is regular Strainer disadvantage of secondary provided in cleaning prior arts as such Flow. most of ejector (Marine Growth facility is not to stop reverse Removal) applicable in it. flow. Whereas this facility is provided in present invention to solve the problem of marine Growth. 16. Construction. Generally all Divided into The present ejectors are two separate invention has mono assembly parts. These advantage over with three parts can be prior arts for ports, connected by adjustment of 1, primary long studs kept spacing for inlet, with some maximum flow 2, secondary space in ratio, which is most water inlet and between these important for 3, common two parts. This maximum available outlet. space works as quantity of water secondary inlet. for fire-fighting. 17. Noise Generally all It doesn't make Producing noise is pollution. Ejectors any noise disadvantage of Make high because prior arts. noise Large suction when works at area is available high for secondary Differential flow. As it is pressure. designed for submerged condition into water; noise pollution is not possible.

(48) A further comparison is done between traditional fire-fighting system and the present automatic fire-fighting system having a submersible water lifting assembly. Table-2, Here in below shows a component wise distinction between the prior art (traditional) and the present invention.

(49) TABLE-US-00004 TABLE 2 Component wise differences of prior art and present invention. Prior art Present Invented system Is it Disadvantage/ Is it Advantages of Sr. part of Problems/Draw part of present invention No. Components system? backs of prior art System? Over prior art  1) Fire Engine Yes Huge size diesel No HFREP is used in engine is used place of diesel with gear box, engine or pump and air/gas start-up it is located below vessels etc sea level, 1. Needs space 1. Doesn't require on platform. any space. 2. Needs regular 2. Doesn't require maintenance regular maintenance. 3. Needs flues. 3. Doesn't require fuel, as it is powered by injection water flow. 4. Needs 4. Doesn't require lubricant lubricant. 5. Needs fire 5. Doesn't need fire proof exhaust line. proof exhaust, 6. Needs complex 6. Simple start-up star-up system. system. 7. Needs fuel 7. No need of fuel tank. tank. 8. Needs start-up 8. No need of start- air or gas up air or gas storage vessel. storage vessel. 9. Large fire can 9. Large fire can't damage and damage system as fuel storage HFREP is place tank. below sea level 10. Needs fire 10. No need of fire protection protection wall as wall HFREP is placed below sea level.  2) Gear Box Yes As there is gear No As, there is no gear Assembly box in the system. box in the system. 1. Needs 1. No need of maintenance maintenance 2. Chances of 2. No Chance of failure failure.  3) Pump Yes As, there are No As, there is no Column shaft Pump Column and Pump Column and between gear shaft in the system. shaft in the system. box and 1. Difficult to lift 1. Eliminates pump these items at maintenance. deck level, for 2. Decreases the pump maintenance cost of fire- 2. Increases the fighting system. cost of fire- fighting system  4) Multi stage Yes As there is multi No As there is no multi centrifugal stage centrifugal stage centrifugal pump pump assembly pump assembly in assembly in the system the system 1. Difficult to lift 1. Eliminates pump for maintenance. maintenance 2. Increases the 2. Decreases the cost of fire- cost of fire- fighting system fighting system.  5) Fire water Yes Increases the no As there is no pump column cost of fire- column casing casing fighting system needed, it reduces the cost of fire- fighting system.  6) Fire Engine Yes As there is no No As there is no fire exhaust line fire Engine in Engine in the the system, system, 1. Increases the 1. Reduces the cost cost of fire- of fire-fighting fighting system system 2. Increase the 2. Reduces the risk risk of fire of fire hazard hazard.  7) Startup air or Yes Since there is fire No Since there is no fire gas storage Engine in the system, Engine in the system, vessel startup air or start-up air or gas vessel is gas vessel is not needed needed 1. Occupy lot of 1. Doesn't occupy space on the any space on the platform. platform 2. Increases the 2. Reduces cost of cost of firefighting fire-fighting system system. 3. Needs charging/ 3. Doesn't needs filling of air/gas charging/filling mechanism. of air/gas Like start up air mechanism. compressor/ gas pressure regulating mechanism.  8) Diesel storage Yes As fuel is used in No As fuel is not used vessel the system, in the system, storage vessel is storage vessel is not needed. needed. 1. Occupy lot of 1. Doesn't occupy space on the any space on the platform platform. 2. Increases the 2. So, reduces the cost of fire- cost of fire- fighting System fighting system  9) Fire water Yes Main assembly No Main assembly overboard fire engine is HFREP is line placed on submerged in water, platform, water and water flow is flow must be regulated as per regulated as per requirement, as well requirement, as, pressure relief is which needs over inbuilt facility in board line. this invented unit, 1. Increase 1. It don't require capital cost over board line. due to 2. Saves the material expensive cost of Cu—Ni use construction in over board line. material, Cu—Ni 3. Reduces the noise 2. Needs and vibration of pressure relief platform valve to structure. regulate line pressure and safe guard the system itself. 3. Noise and vibration of overboard line 10) Suction Yes Problem of yes Since, reverse flow Strainer Marine Growth of water at higher which can pressure is possible stop/restrict in this system, flow of water marine growth can be removed easily any time. Only 5 minutes running of reverse flow per month, is sufficient to prevent marine growth at suction Strainer. 11) Diesel storage Yes There is a Fire No As fuel is not used tank risk as it is in the system, mounted on fire storage tank is not engine and needed. there is limited So, reduces the risk area in of fire hazard on unmanned system itself. platform to locate the engine. 12) Water No Not applicable. Yes Water injection injection header is main header source of energy for working of present invention. Utilization of stored energy in this header is most advantage of present invention. 13) Pressure Yes As fire engine No As, header pressure Relief valve rotates with is automatically fixed RPM, maintain in the needed to system, there no maintain require need of this pressure in fire pressure relief valve. water header. 1. High noise 1. No noise pollution. pollution. 2. High vibration 2. No high of over board vibration. line 14) HFREP No Not applicable Yes Since, Main unit HFREP is located at subsea level, 1. No noise pollution. 2. No ice formation. 3. No vibration. 4. No need of pressure relief valve. 5. No need of pump casing 6. No marine growth problem. 7. No lubricant required. 8. No fuel consumption. 9. No frequent brake down of system. 10. Repair/ maintenance job is very simple & easy.

Advantages of the Invention

(50) 1. Present automatic fire-fighting system for offshore platform that is efficient yet simple to install, energy saving, noise free, and economical. 2. Present automatic fire-fighting system for offshore platforms utilizes high pressure water from the water injection system at offshore that is already present at offshore of oil and gas industries. This water provides the high pressure as energy source as well as water source. This eliminates the requirement of any additional system for providing pressure or energy. This also eliminates the requirement of fuel. 3. The pressure of water is used as source of energy while lifting additional water from the water body (sea; in case of oil and gas offshore platforms) to be sprinkled for fire-fighting. This enables the working of the system even in absence of fuel engine driven pump or electricity; unlike the prior arts. This makes the system energy efficient and economical. Besides, it is especially useful in cases of large fire of any type; when providing electricity for running water pumps is not feasible or advisable. It enhances its applicability at places where there is no electric connections or has limited electricity availability. So, there is no fuel consumption. 4. The mechanism of water lifting described in the present invention enables discharge of water with very high flow rate enabling water lifting to desired height for sprinkling it on fire. The discharged flow rate is in multiple of supplied flow rate. The present invented system (1) enables conversion of flow rate as well as achieving desired pressure for proper handling and requisite use; that can serve the purpose of present invention. 5. Present automatic fire-fighting system for offshore platforms that is self-cleaning and hence auto-maintenance. 6. Installation of present invented system (1) is possible by simple modification in existing offshore platform arrangement. This eliminates installation of additional multi-part arrangements thereby reduces the complexity in construction and operation. This also makes the present invention maintenance free. Moreover, it requires minimum space for installation. 7. Present invention eliminates risk of fire on main equipment of fire-fighting system itself. This is because the main equipment i.e. the HFREP remains submerged in water. 8. There are no rotating parts in the invented system, so, lubrication needed in Invented system. Thus, there is almost nil maintenance required for the system. 9. It ensures safeguard from fire; particularly to the unmanned platform and reduces the premium of insurance. 10. Present invented system (1) enables additional utility for using water for cleaning etc. 11. There is no noise pollution by the present invention unlike the prior arts (traditional arts). 12. Present invented system (1) is easy to operate and safe. 13. It is a system of lowest capital cost. 14. There is no operational cost in present invented system (1), as it does not use any fuel and it is automatic operation which does not require manpower to operate it. 15. Marine growth removal becomes easy by reversing secondary flow. 16. Over board line with pressure relief mechanism, constructed from high cost metal Cu—Ni (metal alloy, constructed by combination of copper and nickel) is not require in presently invented System. It saves the cost.

Applicability of Present Invention

(51) The Submersible water lifting system and the automatic Fire-Fighting System having the same assembly, has its main applicability in Oil and Gas Industry at offshore platforms particularly at unmanned platforms where electricity, fire engines and regular human presence are not available but high pressure water flow is available.

(52) It can also be used at onshore to lift water for fire-fighting, from low level ponds provided that high pressure water flow is available by any means like water injection lines, tanker having high pressure pump.

(53) Though present invented system (1) is mainly designed for emergency fire-fighting operations, it can also use as a utility or service water pump in all onshore and offshore installations where high pressure water flow is available. It can also be used in marine applications like stripping of blast tanks and sewage treatment plants etc. in ships.

(54) There are varies applications of the present invented system (1); which includes, but not limited to the applications listed herein below. The system as a whole or part of system can also be used in below mentioned industries. 1. Pumping of slurries. 2. Pumping fire water, where electrically driven pumps present an explosion risk. 3. Draining and dewatering with little modification in the system. 4. Blending and proportioning. 5. Flare gas recovery in Oil & Gas Industry. 6. Dozing of Chemicals, in process Industries. 7. Artificial lifting of Oil, in Oil & Gas Industry. 8. Deep water well pumping/domestic water supply. 9. For solid transfer. 10. As a vacuum pump. 11. As a thrust augmenters for dynamic positioning of ships. 12. It can be used to elevate low level water to medium level by utilising high elevated water.