KR20010042100A - Ship with a protection system making it unsinkable - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a ship provided with a sinking prevention system. For example, a deck is provided with a buoyancy chamber on a ship such as a small passenger ship, a medium passenger ship, or a dangerous goods transport ship, and the air in the buoyancy chamber is operated in a first driving state. Is supplied, and the buoyancy chamber in the second operating state is characterized in that the closed cell is filled with a foam in a cohesive state, in which the cell volume is large and the shape is stable.

Description

Ship with a protection system making it unsinkable}

Such vessels are well known in the art. Known vessels, in particular large vessels, are equipped with at least one deck and a buoyancy chamber on the deck. In the first operation state, which is the normal operation, the vessel calculates a buoyancy chamber corresponding to the required buoyancy to fill the surrounding air. The buoyancy chamber generally has various functions as well as the buoyancy function of the ship. The buoyancy chamber can be played by limited empty space in all vessels, such as cabins, storage warehouses, cargo rooms or cabins. The buoyancy chamber has other features besides the role of filling the surrounding air.

In emergency situations, such as water entering the lower hull, water will penetrate through the leak. In this case, the submerged water will push the surrounding air out of the buoyancy chamber. This results in a buoyancy loss until the ship is completely sunk.

The present invention relates to a passenger ship, a regular ferry, a dangerous goods freighter provided with a buoyancy chamber on which air is supplied in a first operating state, and a dangerous goods freighter. It is about the same water vessel.

1 is a side view of a passenger ship according to the present invention;

Figure 2 is a side view of the passenger ship of Figure 1 with a buoyancy chamber installed foam according to the invention,

3 is a front view of a passenger ship equipped with a space according to the present invention;

Figure 4 is a front view of the passenger ship of Figure 2 with a buoyancy chamber installed foam according to the invention,

5 is a view showing a control device for installing a foam in the buoyancy chamber of the passenger ship according to the present invention,

It is an object of the present invention to provide a vessel of this kind which can stabilize the buoyancy when a buoyancy loss occurs.

The above object is to be achieved by filling a closed cell with a closed cell in a second operating state and filling the foam with a stable, cohesive state.

Expressed as a buoyancy chamber in the specification and claims of the present invention means a space of a ship serving as a stable buoyancy chamber in the second operating state.

In the specification and claims of the present invention, the term "cell volume" means a space that can accommodate air by many small cells or very few large cells.

When one or more buoyancy chambers are filled with cell bulky and stable foam, when water penetrates into the buoyancy chamber in an emergency situation, the buoyancy chamber of the vessel is not filled with water. Thereby, each buoyancy chamber is characterized by being able to maintain the buoyancy function.

If the room is to be used as a buoyancy room, the room should be surrounded by foam and protected from damage or loss.

An advantage according to claim 2 is to install a discharge device in the buoyancy chamber so that the foam is released in an unstable agglomerated state during the transition from the first operating state to the second operating state. This simplifies the process of filling and emptying each buoyancy chamber. The foam can be blown or sprayed into the buoyancy chamber in the form of agglomerates of liquid, which is hardened by ambient air and formed into a stable aggregate in a short time.

An advantage according to claim 3 is to install a control device for controlling the discharge device. By controlling the release device of each buoyancy chamber, the foam can be released to the target release device and the foam can be selected as required. In this way it is possible to stabilize the buoyancy for various positions of the vessel.

An advantage according to claim 4 is that the control device can be operated manually according to the value of the buoyancy loss. As above, the cabin can also be used as a buoyancy room in the second operating state. Manual operation allows the cabin to be closely inspected before operation and the passengers no longer in the cabin.

Another advantage according to claim 5 is that the control device can be used to select a deck with buoyancy chambers according to the locality of the buoyancy losses. As described above, the buoyancy can be stabilized according to the deck and the buoyancy loss.

Another advantage according to claim 6 is that the control device can be used to select the buoyancy chamber on the deck depending on the locality of the buoyancy loss. As described above, the buoyancy can be stabilized according to the buoyancy loss as well as the deck.

An advantage according to claim 7 is that it is possible to predefine each buoyancy chamber in each selected space by installing multiple decks with multiple spaces. In this way it is possible to very accurately control the buoyancy of the entire ship.

An advantage according to claim 8 is that each buoyancy chamber can be selected as a group consisting of cabins, reception rooms, warehouses, leading warehouses, stern warehouses, cargo, and the bottom of the stern and the key actuating machine. All function spaces are used as buoyancy chambers to ensure optimal buoyancy stability in emergencies.

Another advantage according to claim 9 is that the foam is resistant to pressure in a stable state of aggregation. As a result, the buoyancy chamber is kept stable even when the external pressure is increased.

An advantage according to claim 10 is that the foam consists of a plastic foam with a foam stabilizer. In the existing art, plastic foams containing foam stabilizers with high cell volume, compressive strength and form stability are well known, and thus have the advantage of being easy to select.

Features according to the present invention will be described in more detail with reference to the following embodiments the drawings.

1 shows a passenger ship as a ship. In the embodiment according to the present invention, the passenger ship is about 4000 tons (registered tonnage, NRT) and 6000 tons (total registered tonnage, BRT). In the case of a ship accident, the maximum carrying weight at the time of life or similar is approximately 4100 tonnes (total registered tonnage, BRT). There are at least 4000 tons of buoyancy chamber volume consisting of two decks (passenger deck, 3) of approximately 200 buoyancy chambers (cabinet 5) with 20 tons of buoyancy each. The buoyancy chamber volume, which consists of the buoyancy chamber at the fore and stern, adds at least 1000 tons. As above, the total buoyancy chamber volume is about 5000 tons and the reserve buoyancy is at least 900 tons.

The deck 3 is installed with a plurality of upper decks (7).

The vessel 1 shown in FIG. 1 shows a normal operating state, not an emergency. The waterline is shown at 9 and lies under the hull 11.

2 shows the vessel 1 in a rescue state, ie an emergency state. The draft line 9 lies on top of the hull 11.

Shown in the figures is a buoyancy chamber 5 of the passenger deck, in particular a buoyant chamber placed outside, filled with foam (shown in black in the figure, 13). The buoyancy chamber 15 at the head is also filled with foam like the stern 17.

3 is a view showing the front of the vessel 1. The buoyancy chamber 5 inside the ship is shown. Theoretically, all the buoyancy chambers 5 shown can be filled with foam in an emergency. In practice, some buoyancy chambers 5 are selected to suit the purpose.

4 shows the buoyancy chamber 5 as described above. In the passenger ship shown in the embodiment, the outer cab and head 15 of all (passenger) decks 3, as well as the stern key operating machine 17 serving as the buoyancy chamber 5, play the above-mentioned role.

The upper deck 7 serves as an evacuation deck.

5 shows a control device 19. The control device 19 controls the discharge devices 21 respectively installed in the buoyancy chamber 5 selected for emergencies. The discharge device 21 is a tank installed on the deck side in each buoyancy chamber 5, in which a foam is formed of aggregates of unstable shape and liquid or gaseous state. Secured by filling buoyancy chamber inexpensively and uniformly through deck installation.

An emergency switch 23 is installed in the central control room at the bridge of the passenger ship, which is connected to a line 25 in which a gas pressure generator 27 such as a pressure generator is installed. The gas pressure generator 27 is connected to the discharge device 21 in each buoyancy chamber via line systems 29 and 30 provided with a valve device 31 such as a magnet valve.

The valve device 31 is connected to the safety switch 35 via another line 31.

In an emergency situation, the emergency switch 23 is activated. Through this, the gas pressure generator 27 generates gas pressure in the line systems 29 and 30. If the selected buoyancy chamber 5 is a cabin or space that can accommodate passengers, the presence of passengers in the buoyancy chamber is examined. When it is confirmed that there is no passenger in the buoyancy chamber 5, the safety switch 35 is operated to open the valve device 31 and transmit the gas pressure placed in the line 30 to the discharge device 21. In this manner, the foam, which is unstable in shape and in a cohesive state, is discharged from the discharge device 21 and sprayed or sprayed into the buoyancy chamber 5. The foam is cured by the ambient air to the above mentioned properties and stabilizes the buoyancy function of the corresponding buoyancy chamber 5.

The control device 19 directs the particular deck 3 and the buoyancy chamber 5 via the line systems 29 and 30 according to the locality of the buoyancy losses.

The foam may be a mineral or organic natural foam or a plastic foam with or without foam stabilizer. Since the foam having the above characteristics is well known in the prior art, the present invention has not been described in detail.

When the safety device 35 is operated, the electric circuit is closed in order to operate the valve device, and the electric circuit of the buoyancy chamber corresponding to the city is opened.

Claims (10)

In floating vessels such as passenger ships, ferries, and dangerous goods cargo ships with decks provided with air in the normal operating state of the first operating state, the cell volume is large with closed cells in the second operating state. A vessel characterized in that the buoyancy chamber (5) is filled with a stable form of agglomerated form. The method of claim 1, characterized in that the discharge device 21 is installed in the buoyancy chamber 5 so that the foam is released in an unstable agglomerated state during the transition from the first operating state to the second operating state. Shipping. The ship according to claim 1 or 2, wherein a control device (19) for controlling the discharge device (21) is provided. 4. Ship according to claim 3, characterized in that the control device (19) can be operated manually according to the value of the buoyancy loss. 5. Ship according to claim 4, characterized in that the control device (19) makes it possible to select the deck (3) in which the buoyancy chamber (5) is installed in accordance with the locality of the buoyancy loss. 5. Ship according to claim 4, characterized in that the control device (19) makes it possible to select the buoyancy chamber (5) according to the locality of the buoyancy loss. Ship according to one of the preceding claims, characterized in that a plurality of decks (3) with a plurality of spaces are provided so that each buoyancy chamber (5) can be pre-determined in each selected space. Ship according to one of the preceding claims, characterized in that each buoyancy chamber (5) is selected from the group consisting of cabins, reception rooms, warehouses, leading warehouses, stern warehouses, cargo, including the bottom of the stern and the key actuating machine. The ship as claimed in claim 1, wherein the foam is resistant to pressure in a stable state of aggregation. The ship according to claim 1, wherein the foam consists of a plastic foam containing a foam stabilizer.