KR20180121237A - System for dual pumping onboard high expansion foam - Google Patents

Abstract

According to the present invention, a fire extinguishing system of a ship using high expansion foam comprises: a foam generator (20) installed at a downstream side of a suction line (21) of the stern of the ship; a foam pump (23) installed at an upstream side of the foam generator (20); and a fresh water tank (30) connected by interposing a fresh water line (31) at the upstream side of the foam generator (20). Therefore, a pipe line in an LNG ship or the like is reduced, and high capacity equipment is excluded to promote simplification. Moreover, in case of fire, high expansion foam is generated in a short time to be supplied with high operation reliability to satisfy ship classification regulations.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a system for dual pumping onboard high expansion foam,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fire extinguishing system for a ship, and more particularly, to a high expansion foaming double pumping system for a ship to extinguish a fire based on a high expansion foam on an LNG carrier or the like.

Typically, ME-GI LNGC, LNGC, and other vessels use a high expansion foam system for total fire fighting of the engine room. This is a principle to prevent fire by generating foam when engine room fire occurs and to cut off oxygen supply. In the case of existing ships, sea water is supplied to the foam system by using a fire pump located on the aft side. However, there is a lot of restriction because the capacity of the fire pump must be increased for the operation of the foam system and the piping of 300 ~ 400m length from the bow to the stern must be arranged. Especially, when the fire pump is used for washing the deck due to the large capacity of the fire pump, the risk of unnecessarily high pressure is also increased.

With respect to the foam fire extinguishing system of a ship, reference can be made to prior art documents (prior patents) such as Korean Utility Model Publication No. 2016-0001569 and Korean Patent Laid-Open Publication No. 2009-0020200.

The former is a foam tank for storing a foam extinguishing agent; A fresh water supply pipe for supplying fresh water to the foam tank; A common pump generating pressure to spray clear water or seawater; A seawater inlet pipe for introducing seawater into the inlet of the common pump; And a clean water inflow pipe connecting the fresh water tank and the inlet side of the common pump. Therefore, it is expected that the fire extinguishing system will be simplified and the work cost and cost will be reduced.

In the latter, the injection nozzle and the foam generating plate are installed in the air supply duct installed in the engine room, and the pressurized air supplied to the engine room air supply blower is used while the foam solution injected from the injection nozzle passes through the foam generation plate Thereby generating a foam. Therefore, it is expected that the extinguishing performance will be secured and the expense will be reduced by simplifying the related facilities by taking only the merits of external supply type and internal supply type digestion.

However, according to the above-mentioned prior patents, there is a lot of room for improvement in terms of optimization in terms of simplifying the high expansion foam system in the LNG carrier and maintaining the operating reliability.

1. Korean Utility Model No.2001-691569 "Combined Extinguishing System for Ship" (Published on 2015.05.13.) 2. Korean Patent Laid-Open Publication No. 2009-0020200 entitled " Pressurized high expansion foam fire extinguisher for marine engine room "(Open date: Feb. 26, 2009).

SUMMARY OF THE INVENTION It is an object of the present invention to solve the above-mentioned problems of the prior art by providing a simple structure in which a pump for a high expansion foam is installed in a region adjacent to an engine room of a stern, And to provide a high expansion foam double pumping system of a ship which enhances operational reliability.

To achieve the above object, the present invention provides a fire extinguishing system for a ship using a high expansion foam, comprising: a foam generator installed on a downstream side of a suction line of the ship; A foam pump installed upstream of the foam generator; And a fresh water tank connected to the upstream side of the foam generator through a fresh water line.

As a detailed configuration of the present invention, the suction line is installed in a path from the SG room or the engine room of the stern to the seed chest.

In a detailed configuration of the present invention, the suction line is covered with an arcing member at an exposed portion when passing through the engine room.

As a detailed configuration of the present invention, the suction line includes a main valve for interrupting the flow of seawater, and a check valve for preventing dryness of the foam pump.

In the detailed construction of the present invention, the main valve is connected to be actuated by an electric or pneumatic signal, and switches the suction line to an open state upon abnormally interrupting the signal.

In the detailed construction of the present invention, the fresh water line is provided with a sub-valve for interrupting the flow of fresh water, and a check valve for preventing reverse flow of seawater to the fresh water tank.

In the detailed construction of the present invention, the main valve of the suction line is connected to the controller to perform the opening and closing of the flow path linked to the condition of the ship and the operation of the foam pump.

In the detailed construction of the present invention, the sub-valve of the fresh water line is connected to the controller to perform the water level condition of the fresh water line, the operation of the foam pump, and the opening and closing of the channel linked to the operation of the main valve.

In a detailed configuration of the present invention, the controller maintains a set time difference from a time point when the main valve opens to a time point when the sub-valve is closed.

As described above, according to the present invention, it is effective to reduce the piping line in an LNG ship or the like and to simplify the structure by eliminating high-capacity equipment, and to increase the reliability of operation to generate and supply high expansion foam within a short time in case of fire, .

1 is a schematic diagram illustrating a ship to which a system according to the present invention is applied;
Fig. 2 is a schematic diagram showing an enlarged view of the aft portion of the ship in Fig. 1
3 is a block diagram showing a main part connection state of the system according to the present invention;

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The present invention proposes a fire extinguishing system for a ship based on a high expansion foam. Normally, in the ship, the SG room 10 and the engine room 12 are disposed at the stern, while the fire pump 16 is disposed at the athlete. The problem associated with the high-expansion foam extinguishing of the engine room 12, for example, is highlighted in the LNGC ship illustrated in FIG. In this case, a large-capacity fire extinguishing pump must be installed along with very long piping to the stern for sea water supply. The present invention is directed to, but is not necessarily limited to, a fire extinguishing system that applies a high expansion foam to an LNGC vessel having a foam generator and a fire pump.

According to the present invention, the foam generator (20) is installed on the downstream side of the suction line (21) of the ship. A suction line (21), a discharge line, and a foam generator (20) are installed around the SG room (10) at the stern of the ship. The foam generator 20 having a foam extinguishing agent and a foam multiplier produces a high foaming foam for digestion by mixing seawater (fresh water) supplied to the suction line 21. The generated foam is supplied to the engine room 12 through the injection line 22 to suppress the fire. As a result of eliminating piping from the bow to the stern, the sea water supply piping is shortened.

The present invention is characterized in that the suction line 21 is installed in a path from the stern SG room 10 or the engine room 12 to the seed chest 14. [ Referring to FIG. 2, the suction line 21 is installed as a path connecting a plurality of vertical and horizontal pipes in the seed chest 14. It is preferable that the seed chest 14 selects an area adjacent to the SG room 10 or the engine room 12. [ The pipe connection portion of the suction line 21 uses a butt welding or double sleeve method.

In a detailed configuration of the present invention, the suction line (21) is covered with an arcing member (28) at an exposed portion when passing through the engine room (12). In Fig. 3, a part of the suction line 21 passing through the engine room 12 is covered with an arcing member 28 so as not to be affected by fire. As an example of the fire-fighting member 28, A-60 insulation or a product having a physical property equal to or higher than that of the fire-proofing member 28 can be applied.

Further, according to the present invention, a foam pump 23 is installed on the upstream side of the foam generator 20. The foam pump 23 is disposed so as to be located below the aft side SG room 10, separated from the forward side. As described above, the length of the piping is reduced and the capacity optimization by the separate foam pump 23 causes the effect of reducing the cost. However, unlike the fire pump 16, the foam pump 23 requires a design that reflects a priming time.

Referring to FIG. 3, the draft condition of the loading condition of the LNGC is generally 11.5M, and the ballast condition of the light ship condition is about 9.4M. The design freedom of the SG room 10 and the engine room 12 of the LNGC ship is not high and the arrangement height of the foam pump 23 can not be lowered to only about 11 M in draft. In this case, the seawater suction of the suction line (21) is delayed much in the condition of the light ballast, and the condition of 1 minute required by the classification society can not be satisfied.

The suction line 21 is provided with a main valve 25 for interrupting the flow of the seawater and a check valve 26 for preventing the drainage of the foam pump 23 . Since the seed chute 14 is located inside the AP tank (ballast tank), the main valve 25 is installed inside the AP tank or inside the engine room 12. The main valve 25 should be attached directly to the piping of one piece at the seed chest 14 as a ship side valve. The check valve 26 is provided at the upstream side position adjacent to the foam pump 23 in the suction line 21 and is provided at the upstream side of the foam pump 23 with the drainage Prevention.

In the detailed configuration of the present invention, the main valve 25 is connected to be actuated by an electric or pneumatic signal, and switches the suction line 21 to an open state upon abnormally interrupting the signal. The electrical or pneumatic signal applied to the main valve 25 is provided through the foam generator 20, the controller 40 described below or other equipment. In any case, the main valve 25 is installed in such a manner as to open the flow path of the suction line 21 in an emergency situation in which an electric or pneumatic signal is not normally applied. Of course, during normal operation, the main valve 25 is operated so that the suction line 21 is normally closed so that the suction line 21 always keeps water in the suction line.

According to the present invention, the fresh water tank 30 is connected to the upstream side of the foam generator 20 via the fresh water line 31. Is connected to the suction line (21) through the fresh water line (31) in the fresh water tank (30) disposed in the SG room (10) to keep the priming for the initial operation of the foam pump (23) constantly filled. The seawater should be supplied to the foam generator 20 for one minute by the foam pump 23 and to be able to suppress the fire in the engine room 12 for 10 minutes and preferably to perform the continuous fire extinguishing 5 times or more Seawater or fresh water should be supplied.

As a detailed construction of the present invention, the fresh water line 31 is provided with a sub-valve 35 for interrupting the flow of fresh water, and a check valve 33 for preventing the reverse flow of seawater to the fresh water tank 30 do. The downstream end of the fresh water line 31 in which the sub valve 35 is mounted is connected to the upstream side of the check valve 26 in the suction line 21. [ The sub valve 35 is also operated by an electric or pneumatic signal like the main valve 25. The check valve 33 is disposed adjacent to the fresh water tank 30 on the upstream side of the fresh water line 31 so that the seawater of the suction line 21 does not flow backward. Since the low load ballast condition is inadequate to satisfy the suction pressure of the foam pump 23 to meet a certain requirement, the suction line 21 is provided with fresh water of the fresh water tank 30 To maintain the filled state at all times. In this case, the main valve 25 is of the normally open type and maintains the suction line 21 in a closed state by the signal, so that the pressure for priming the foam pump 23 is sufficiently maintained.

On the other hand, unrepresented reference numeral 37 provided opposite to the sub valve 35 in the branched fresh water line 31 is a manual valve that supplies fresh water to a test use or the like.

The main valve 25 of the suction line 21 is connected to the controller 40 so as to perform the opening and closing of the flow path linked to the condition of the ship and the operation of the foam pump 23 do. The controller 40 includes a microprocessor, a memory, a microprocessor circuit mounted with an input / output interface, and includes a bar-shaped power supply unit 42, a drain sensing unit 43, and the like. Accordingly, the controller 40 operates in a sequence set in the memory only when the draft condition is 11M or less, and maintains the main valve 25 always open by interlocking at a draft condition of 11M or more by cargo shipment. When the foam pump 23 is operated in a fire, the main valve 25 is switched from the closed state to the open state.

The sub valve 35 of the fresh water line 31 is connected to the controller 40 to control the water level condition of the fresh water line 31, the operation of the foam pump 23, the operation of the main valve 25 And the opening and closing of the flow channel linked to the operation is performed. The main valve 25 closes the flow path and the sub valve 35 opens the flow path and injects the fresh water into the suction line 21 under the low ballast condition. In this case, the operation of the sub-valve 35 can be started by the signal of the water level sensor 45 provided on the suction line 21. [ The open operation of the main valve 25 and the close operation of the sub valve 35 are alternately performed when the foam pump 23 is operated in the state where fresh water is filled in the suction line 21. [

The controller 40 maintains the set time interval from the time when the main valve 25 opens to the time when the sub-valve 35 is closed. When the main valve 25 is opened due to a malfunction or the like, there is a risk that the fresh water of the fresh water tank 30 will disappear as time elapses, so that the sub valve 35 is closed after a predetermined time (for example, one minute) . The controller 40 alerts the operator of the malfunction of the main valve 25, thereby urgently correcting the operator.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention. It is therefore intended that such variations and modifications fall within the scope of the appended claims.

10: SG Room 12: Engine Room
14: Seed Chest 16: Fire Pump
20: Foam generator 21: Suction line
22: injection line 23: foam pump
25: Main valve 26: Check valve
28: fireproof member 30: fresh water tank
31: fresh water line 33: check valve
35: Sub-valve 37: Manual valve
40: Controller 42: Emergency power source
43: A-level sensor 45: Water level sensor

Claims (9)

A fire extinguishing system for a ship using a high expansion foam, comprising:
A foam generator (20) installed on the downstream side of the suction line (21) of the ship;
A foam pump (23) installed upstream of the foam generator (20); And
And a fresh water tank 30 connected to the upstream side of the foam generator 20 via a fresh water line 31. The high expansion foam double pumping system according to claim 1, The method according to claim 1,
Characterized in that the suction line (21) is installed in a path from the stern SG room (10) or engine room (12) to the sea chest (14). The method according to claim 1,
Wherein the suction line (21) is covered with an arcing member (28) at the exposed portion when passing through the engine compartment (12). The method according to claim 1,
Characterized in that the suction line (21) comprises a main valve (25) for interrupting the flow of seawater and a check valve (26) for preventing dryness of the foam pump (23) system. The method of claim 4,
Wherein the main valve (25) is connected to be operated by an electric or pneumatic signal, and switches the suction line (21) to an open state when the signal is abnormally cut off. The method according to claim 1,
Characterized in that the fresh water line (31) comprises a sub valve (35) for interrupting the flow of fresh water and a check valve (33) for preventing back flow of seawater to the fresh water tank (30) Pumping system. The method according to claim 1,
Characterized in that the main valve (25) of the suction line (21) is connected to the controller (40) to perform the opening and closing of the flow path linked to the condition of the ship and the operation of the foam pump (23) Pumping system. The method according to claim 1,
The sub valve 35 of the fresh water line 31 is connected to the controller 40 to control the water level condition of the fresh water line 31, the operation of the foam pump 23, the opening and closing of the oil linked to the operation of the main valve 25 Of the vessel. ≪ RTI ID = 0.0 > 11. < / RTI > The method according to claim 7 or 8,
Wherein the controller (40) maintains a set time difference from a time point when the main valve (25) opens to a time point when the sub valve (35) is closed.

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