KR20180001477U - inundation shut off apparatus system for floating marine structure - Google Patents

Abstract

The present invention relates to a system for connecting seawater withdrawal areas provided in a hull side shell to seawater used for cooling various mechanical and electrical equipments installed in a machine / A watertight zone is selected on the passageway to allow the drainage to be automatically started when seawater is introduced due to faults in piping and piping flange connections in the seawater withdrawal area. The seawater withdrawal area and the machine / A watertight zone selected to pass through the watertight zone and a seawater intake zone; A watertight opening / closing door provided on the partition wall to pass through the seawater intake area and having a door driving part for providing a driving force for opening and closing; A control unit electrically connected to the door driving unit to control opening and closing of the watertight opening and closing door; And a water level sensor electrically connected to the control unit and installed in the watertight area to detect water flooding in the watertight area.

Description

[0001] The present invention relates to an inundation shut-off apparatus for floating marine structures,

The present invention relates to an immersion cutoff system for a floating sea structure, and more particularly, to a flooded breakwater installation system for a floating sea structure, and more particularly, to a hull side shell for taking water from an ocean to be used for cooling various mechanical and electrical equipments installed in the machine / a watertight zone is selected on the passage between the seawater withdrawal zone provided in the shell and the mechanical / electrical chamber, and the drainage for the case where seawater is introduced due to a defect in the pipeline or the pipe flange connection portion of the seawater withdrawal zone This is done automatically.

As shown in FIGS. 1 and 2, a floating liquid natural gas production facility (FLNG) and a floating oil production storage / unloading facility (FPSO), which are a type of floating sea structure 10, And electrical equipment are mounted in the machine /

The seawater intake section 14 is provided in the hull side shell of the floating liquid natural gas production facility FLNG and the floating oil production storage and unloading facility FPSO, A seawater intake system 16 is installed so that seawater can be taken from the ocean.

As described above, the seawater taken from the seawater intake system 16 is supplied to various mechanical and electrical equipments mounted on the mechanical / electrical room 12 and used as cooling water.

The sea water intake valve 24 for taking seawater from the ocean, the seawater intake pipe connection flange 26 and the gasket 28 for the pipe connection flange, the main intake pipe A plurality of branch pipes 20 connected in a form branched from the main water intake pipe 18 to supply seawater to various machines and electrical equipments mounted on the machine / And a feed pump (22) connected to the branch piping (20) for transferring the seawater intake water and the collected seawater to various machines and electric equipment.

The seawater intake valve 24, the seawater intake pipe connection flange 26, and the gasket 28 for the pipe connection flange located in the seawater intake system 16 are parts where the possibility of leakage is higher than the other areas.

In this case, since the seawater intake section 14 is disposed at the bottom of the floating sea structure 10 for stable intake of seawater, it takes a lot of time for the operator in the control room to go to the seawater intake section 14, There is a problem in that it can not cope with flooding of the seawater intake area 14 due to leakage of the water.

In addition, when the seawater intake area 14 is submerged due to the above problem, the seawater in the seawater intake area 14 is connected to the mechanical / electrical room 12 provided on the upper side and adjacent to the connection path of the seawater intake area 14 Various mechanical and electrical equipments installed in the machine / electric room 12 are flooded.

When various mechanical and electrical equipments mounted in the machine / electric room 12 are submerged in the seawater as described above, a shutdown state occurs. Thus, when the various mechanical and electrical equipment are shut down, the floating structure 10) becomes inoperable and the risk increases.

In the figure, reference character B is a ballast tank.

Korean Patent Publication No. 10-2012-0066225

A watertight zone is selected on the passage connecting the seawater withdrawal zone and the mechanical / electrical room for the supply of cooling seawater, The present invention provides a floating flood control system for a floating sea structure that allows flooding in the room and automatic operation of drainage.

In the present invention, a watertight area is selected in a passage through which a seawater withdrawal area and a machine / electric room are connected, and a partition wall partitioned between the watertight area and the seawater intake area; A watertight opening / closing door provided on the partition wall to pass through the seawater intake area and having a door driving part for providing a driving force for opening and closing; A control unit electrically connected to the door driving unit to control opening and closing of the watertight opening and closing door; And a water level sensor connected to the control unit and installed on a partition wall of the watertight area to detect flooding of the watertight area.

In addition, a drainage line is installed in the watertight area in a state where the drainage line is connected to any one of the watertight area and the seawater intake area so that seawater can be drained when inundation occurs, and the drainage pump installed in the drainage line is electrically connected to the control part The objective can be achieved through immersion isolation system of floating floating structures connected by signals.

In addition, the control unit judges the level detection signal inputted from the level sensor and generates an electrical control signal for opening and closing the opening and closing door and controlling the driving of the drain pump according to the determined result. Purpose can be achieved.

When the floating flood control system of floating structure is applied, the watertight area is switched to prevent the inflow of seawater into the machine / electric room when flooding occurs in the seawater withdrawal area, and the seawater existing in the seawater withdrawal area By automatically draining, it is possible to prevent the flooding of various mechanical and electrical equipments installed in the machine / electric room even if it takes a long time for the operator to reach the seawater intake area.

In addition, the shutdown state of various mechanical and electrical equipments can be prevented through the above-mentioned effect, and it is expected that the effect of the present invention can be avoided from the risk of the inability to control and control the floating sea structure.

1 is a side view schematically showing a water intake zone of a general floating sea structure.
FIG. 2 is a plan view of the water intake section of FIG. 1 viewed from above.
FIG. 3 is a view corresponding to FIG. 2 showing the installation state of the immersion cutoff facility system of the floating sea structure according to the present invention.
4 is a front view of Fig.
FIG. 5 is a view showing an electrical signal connection relation to a flood control device system of a floating sea structure according to the present invention.

A preferred embodiment of a flooding prevention system of a floating sea structure according to the present invention will be described below with reference to FIGS. 3 to 5. FIG.

As shown in the figure, a floating liquid natural gas production facility (FLNG) and a floating oil production storage / unloading facility (FPSO), which are a type of floating sea structure (10), include various mechanical and electrical equipment Are mounted on the mechanical / electrical chamber (12).

The seawater intake section 14 is provided in the hull side shell of the floating liquid natural gas production facility FLNG and the floating oil production storage and unloading facility FPSO, A seawater intake system 16 is installed so that seawater can be taken from the ocean.

As described above, the seawater taken from the seawater intake system 16 is supplied to various mechanical and electrical equipments mounted on the mechanical / electrical room 12 and used as cooling water.

The seawater intake system 16 includes a main intake pipe 18 for taking seawater from the ocean and a main intake pipe 18 for connecting the main intake pipe 18 to the mechanical / A plurality of branch pipes 20 for supplying seawater taken by various machines and electrical equipments mounted thereon and a plurality of branch pipes 20 connected to the branch pipes 20 for transferring seawater taken in and taken out of the seawater to various mechanical and electrical equipment And a transfer pump 22.

The present invention is based on the idea that the operator is able to select a watertight zone 30 and a seawater intake 30 so that the watertight zone 30 can be provided on the connection path between the mechanical / electrical room 12 and the seawater intake zone 14, And a partition 32 for partitioning the area 14 is provided in the form of a partition.

The partition wall 32 is provided with a watertight opening / closing door 34 through which the operator can access the seawater withdrawal area 14 through the watertight area 30. The watertight opening and closing door 34 includes a door driving unit 36 composed of any one selected from a driving motor and an actuator. The opening and closing operations of the watertight opening and closing door 34 are performed according to the driving of the door driving unit 36 .

The door driving unit 36 for providing the driving force for opening and closing the watertight opening and closing door 34 is connected to the control unit 38 through the first electric signal line 40, And is connected to a water level sensor 42 provided on the partition 32 by a second electric signal line 44.

The control unit 38 is connected to the drain pump 48 of the drain line 46 connected to the seawater intake zone 14, the notification unit 50, the transfer pump 22, Respectively, through signal lines 54, 56, and 58, respectively.

The seawater taken from the ocean through the main water intake pipe 18 of the seawater intake system 16 is supplied to the corresponding various mechanical and electrical equipments along the branch pipe 20 by the drive of the transfer pump 22 And various mechanical and electrical equipments are cooled by the seawater thus supplied.

The seawater intake valve 24, the seawater intake pipe connection flange 26, and the gasket 28 for the pipe connection flange, and the welded portion located in the seawater intake system 16, to be.

4, when the flood level of the seawater is sensed by the water level sensor 42 provided on the partition wall 32 of the watertight zone 30, the water level detected by the water level sensor 42 The sensing signal is input to the controller 38 through the second electrical signal line 44.

The control unit 38 executes the pre-input program of the control unit 38 according to the level sensing signal input through the second electrical signal line 44 to generate an electrical signal corresponding thereto. The electrical signals of the control unit 38 generated in this manner are transmitted to the door driving unit 36, the drain pump 48, and the notification means 50 (see FIG. 1) through the first, third, fourth and fifth electrical signal lines 40, 54, For example, a buzzer, a lamp) and a transfer pump 22, respectively.

When the electric signal of the control unit 38 is applied to the door driving unit 36 through the first electric signal line 40, the door driving unit 36 is driven according to the electrical signal of the control unit 38. For example, when the watertight opening / closing door 34 is open, the watertight opening / closing door 34 is forcibly closed so that the space of the connecting passage to which the mechanical / electrical room 12 and the seawater intake section 14 are connected is made watertight Switch to zone 30 to delay and prevent the seawater that is submerged in the seawater intake zone 14 from leaking quickly through the watertight opening and closing door 34 and into the machine /

When the electrical signal of the control unit 38 is applied to the drain pump 48 through the third electrical signal line 54, the drain pump 48 that has been stopped is driven to pumped, Is quickly discharged to the ocean through the drainage line (46).

At the same time, an electrical signal of the control unit 38 is applied to the notification means 50 through the fourth electrical signal line 56 to inform the manager working in the cone room of the floating sea structure 10 of the watertight zone 30 I will promptly inform the immersion.

When the electric signal of the control unit 38 is applied to the transfer pump 22 through the fifth electric signal line 58, the pumping operation of the transfer pump 22 is stopped to stop the water intake and transfer .

When the water level of the watertight zone 30 is lowered from the water level sensor 42, the signal sensed by the water level sensor 42 is inputted to the controller 38, The control unit 38 applies a corresponding signal to the door driving unit 36, the drain pump 48, the notification unit 50, and the transfer pump 22, respectively.

First, the watertight opening / closing door 34 can be opened and closed, the driving constraint for closing the door driving unit 36 is released, and the drain pump 48 stops pumping driving.

When the operation of the feed pump 22 is stopped, the control unit 38 inputs the corresponding signal according to the re-operation of the feed pump 22 to the control unit 38 when the seawater intake system 16 is restarted, And the driving signal corresponding thereto is applied to the transfer pump 22 so that the seawater intake system 16 is restarted for seawater intake.

Therefore, in the present invention, when water inundation occurs in a watertight area, water is automatically drained along with a watertight area that prevents seawater from flowing into the machine / electric room, so that it takes a long time It is possible to solve the problem of flooding the various mechanical and electrical equipments mounted on the machine / electric room through the formation of the watertight zone as mentioned above. By eliminating these problems, the shutdown condition of various mechanical and electrical equipment can be prevented, thereby significantly reducing the risk of floating floating structures becoming out of control.

While the preferred embodiments of the present invention have been described above, those skilled in the art will appreciate that various modifications, additions and substitutions are possible, without departing from the scope and spirit of the invention as disclosed in the accompanying claims. For example, in the above description, the drain line 46 is directly connected to the seawater intake zone 14, but the drain line 46 installed in this way is directly connected to the water- It is included in the design. Accordingly, variations and modifications of the embodiments of the present invention will not depart from the technical scope of the present invention.

10: Floating offshore structure
12: Mechanical / electrical room
14: Seawater catchment area
16: Seawater intake system
18: Main water intake pipe
20: Branch piping
22: Feed pump
24: Seawater intake valve
26: Seawater intake pipe connection flange
28: Gasket for piping connection flange
30: Water-tight zone
32:
34: Watertight opening / closing door
36:
38:
40: first electric signal line
42: Level sensor
44: second electric signal line
46: Drain line
48: Drain pump
50: Notification means
52: Feed pump
54: third electric signal line
56: fourth electric signal line
58: fifth electric signal line

Claims (3)

A watertight area selected as a passage connecting the seawater withdrawal area and the machine / electric room, and a partition wall partitioned between the watertight area and the seawater intake area;
A watertight opening / closing door provided on the partition wall to pass through the seawater intake area and having a door driving part for providing a driving force for opening and closing;
A control unit electrically connected to the door driving unit to control opening and closing of the watertight opening and closing door;
A water level sensor connected to the control unit and installed on a partition wall of the watertight area to detect immersion of the watertight area;
Wherein the flood control system includes a flood control system.
The method according to claim 1,
A drainage line is provided in a state where the drainage line is connected to any one of the watertight zone and the seawater intake zone so that the seawater can be drained when the floodwater is generated in the watertight zone and the drainage pump installed in the drainage line is electrically connected to the control unit Wherein the floating water immersion isolation system of the floating sea structure is characterized in that: The method of claim 2,
Wherein the control unit judges a level sensing signal input from the level sensor and generates an electrical control signal for controlling opening and closing of the opening and closing door and driving control of the drain pump according to the determined result. .

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