| CPC F04D 29/426 (2013.01) [A62C 99/0009 (2013.01); F04F 5/461 (2013.01); F04D 29/708 (2013.01); F04F 5/10 (2013.01)] | 6 Claims |
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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).
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