EP1660367A1

EP1660367A1 - Container ship

Info

Publication number: EP1660367A1
Application number: EP04739124A
Authority: EP
Inventors: Thomas KÜHMSTEDT
Original assignee: Aker MTW Werft GmbH
Current assignee: Wadan Yards MTW GmbH
Priority date: 2003-09-04
Filing date: 2004-05-03
Publication date: 2006-05-31
Also published as: WO2005032927A1; DE10340715A1; JP2007504051A; KR20060057003A; RU2006109555A; CN1845845A

Abstract

Disclosed is a container ship having a limited length and width in order to be able to navigate through the Panama Canal. Said container ship comprises a hold (4) which allows twelve rows of containers (15) to be accommodated next to each other across the width of the ship and is located in a hull (2) that is provided with a double shell (3). At least one three-dimensional stabilizing device (5) which connects the ship's double shell (3) on one side of the hull (2) to the ship's double shell on the other side of the hull is disposed inside the hull (2).

Description

Container Ship

The invention relates to a container ship with limited dimensions in length and width for passage of the Panama Canal according to the preamble of claim 1.

Container ships that can still pass the Panama Canal have a maximum length of approximately 294 m and a maximum width of approximately 32 m. They are also known as "Panmax" container ships.

Full container ships with a maximum width of 32.2 m and a ship length of less than 200 m are already known, which for arranging twelve containers (20 'or 40' standard containers) next to each other in the cargo space one from approx. 2 m to approx. 1 m have reduced width of the ship's double hull. As a result, the width of the cargo space is increased so that twelve rows of containers can be accommodated side by side. The reduction in the width of the ship's double hull results in a reduced torsional strength. By constructive measures and limiting the length of the ship to less than 200 m, however, sufficient torsional strength could be achieved and excessive arching of the hull was largely prevented.

When using the maximum possible ship length for the passage of the Panama Canal, this is no longer possible, so that the arrangement of twelve containers next to each other on ships of greater length while maintaining the maximum width has so far failed due to the then too low torsional rigidity of the cargo area. The extension of the existing transverse cover strips in the area of the cargo hold bulkheads would be associated with a disproportionately large loss of parking space capacity for these ships.

A key competitive advantage in shipbuilding, however, is the increase in the storage space capacity of containers using the maximum possible ship length for the passage of the Panama Canal.

The invention has for its object to provide a container ship suitable for the passage of the Panama Canal with an increased number of parking spaces for containers.

The object is achieved by a container ship with the features of claim 1. Advantageous configurations of the container ship are specified in the subclaims.

The container ship according to the invention with limited dimensions in length and width for the passage of the Panama Canal and a loading space in a hull comprising a ship's double hull, which allows the inclusion of twelve rows of containers in the ship's width, is characterized in that in the hull at least one, the ship's double hull on the one Side of the hull with the ship's double hull on the other side of the hull connecting spatial stabilization device is arranged.

According to the invention, to accommodate the twelfth row of containers in the width of the ship in the hull of the ship, a spatial stabilizing device connecting the ship's double hull is arranged for torsion-related curvature obstruction. The fact that the ship's double hull from one side to the other side of the ship is bridged by the stabilizing device, the torsional rigidity of the fuselage is increased and the curvature-related curvature is reduced. As a result, Panmax container ships with a ship's double hull of reduced width and a sufficiently wide cargo space for the accommodation of twelve rows of containers can be made side by side more torsionally rigid than in the prior art. The increased torsional rigidity can be used to build ships with lengths of less than 200 m to improve seaworthiness or to reduce the use of materials. Adequate torsional rigidity is also achieved with ship lengths of 200 m and above. According to a preferred embodiment, the container ship therefore has a length in the range of approximately 200 to 294 m, particularly preferably a length of approximately 240 to 294 m. With Panmax container ships of conventional design of appropriate length, adequate torsional rigidity was only achieved through the wider double hull, which however prevented the twelfth row of containers from being accommodated. According to the invention, Panmax container ships are thus made possible, the storage space capacity of which exceeds both that of conventional container ships with a wide ship's double hull and lengths of 200 m and above and also that of conventional container ships with a reduced width of the ship's double hull and lengths of less than 200 m.

According to a preferred embodiment, the width of the container ship is approximately 32 m. According to a preferred embodiment, the width of the ship's double hull is approximately 1 m.

According to one embodiment, the stabilization device in the fuselage separates two areas of the cargo space from one another. The hull of the container ship is particularly soft in the cargo area. The arrangement of the stabilizing device in the cargo hold so that two areas of the cargo hold are separated from one another, the torsional rigidity of the container ship is particularly increased. According to a preferred embodiment, the stabilization device is arranged approximately at half the length of the loading space. According to a further embodiment, the stabilization device is arranged approximately half the length of the loading space in front of the ship propulsion system. This particularly promotes torsional rigidity. Any additional cargo space located behind the ship propulsion system is less critical because of the stiffening of the hull that is already present in the area of the ship propulsion system.

The spatial stabilization device extends in the longitudinal direction and in the transverse direction of the ship. It preferably has a box-like structure. The stabilization device preferably has an essentially closed spatial structure. Essentially closed structures are particularly rigid. They are based on the use of sheets or plates and, if necessary, frames made of steel. These are e.g. arranged in the longitudinal direction of the ship and connect the stabilization device closing front and rear transverse bulkhead, the ship's double bottom and the belt deck. The term “frame” includes the execution of these stiffening structures by means of sheets or plates. The implementation of the spatial stabilization device as an essentially closed spatial structure includes both largely closed structures with openings and completely closed structures.

According to one embodiment, the stabilization device is essentially closed on the transverse sides. This is particularly advantageous for the stiffening of the trunk. According to one embodiment, the stabilization device is enclosed by transverse bulkheads. According to a further embodiment, which increases the torsional rigidity of the hull, the stabilization device is connected to the double floor of the double floor hull. According to one embodiment, the upper belt deck of the stabilization device is essentially closed and connected to the main deck at the same level. This particularly improves the stiffening of the fuselage.

According to one embodiment, the stabilization device is integrally connected to the surrounding structure of the fuselage and / or by means of fastening means. This applies in particular to lateral plating and / or the upper belt deck of the stabilization device. The integral connection is preferably a welded connection and the additional fastening means are rivets.

Due to the smaller width of the ship's double hull due to the design of the loading space for twelve rows of containers arranged side by side, the capacity of tanks housed in the ship's double hull is reduced. According to one embodiment, the stabilization device and / or a space above it comprises a tank and / or at least one storage device for liquid and / or solid and / or other media and / or at least one storage room for goods and / or at least one crew room. By using the volume of the stabilization device and / or the space above it as a tank space, the disadvantage of the reduced tank capacity in the area of the ship's double hull is more than offset. At the same time, there is the possibility of arranging the fuel supply separately from the outer skin protected by the ship's double hull. This avoids the risk of fuel leakage due to damage to the outer skin. The tank arranged in the stabilization device forms a high tank with the known advantages with regard to trim and longitudinal strength of the ship. The removal of the fuel supply near the center of gravity from the tank leads to a noticeable reduction in trim while at the same time reducing the longitudinal bending moments of the ship and thus to increased ship safety. According to a further embodiment, these advantageous effects are promoted by ballast water tanks in the ship's double hull.

Finally, according to one embodiment, a deck house is arranged above the stabilization device. This is particularly advantageous since the area below the deck house is no longer required as a loading space for containers. Furthermore, if the deckhouse is arranged above the stabilization device compared to ships with a deckhouse arranged above the propulsion system, additional parking spaces are gained above the main deck, because the skipper has a more favorable view of the water surface in front of the bow of the ship. As a result, the proper visibility of the water surface in accordance with the applicable regulations (e.g. two ship lengths ahead according to IMO) is guaranteed even when the containers are stacked in front of the deck house. In addition, the arrangement of the deck house at a greater distance from the ship propulsion system leads to less stress on the crew from engine noise and vibrations.

The invention is explained in more detail below with reference to the attached drawings of an exemplary embodiment. The drawings show:

Figure 1 shows a container ship with stabilizing device in a roughly schematic perspective view obliquely from above. Figure 2 shows the same ship in a cross section through the stabilization device.

3 shows a detail of the ship's hull with the stabilization device;

Fig. 4 container arrangement in the hold in a conventional container ship in a roughly schematic cross section (Fig. 4a) and in a container ship according to the invention in a roughly schematic cross section (Fig. 4b);

Fig. 5 container arrangement in a conventional container ship in a longitudinal section (Fig. 5a) and in a container ship according to the invention in a longitudinal section (Fig. 5b).

The container ship 1 shown in FIG. 1 has a hull 2 which has a double ship hull 3. It has a section 3.1 on the port side of the container ship 1 and a section 3.2 on the starboard side. It also includes a double floor 3.3.

A cargo space 4 is provided inside the fuselage 2. A stabilization device 5 is arranged in the hull 2 and extends transversely to the center line of the container ship 1 and is connected on both sides to the ship's double hull 3.1, 3.2 and below to the ship's double floor 3.3. The stabilizing device 5 is provided at the most effective point for increasing the torsional rigidity and curvature obstruction. This is preferably in the region of half the length of the cargo space 4. Thus, it has an area 4.1 in front of the stabilization device 5 and an area 4.2 behind it. FIG. 2 shows the arrangement of the stabilization device 5 between the sections 3.1, 3.2 and the ship's double floor 3.3 of the ship's double hull. The ship's double hull 3 is formed by the outer skin 6 and the inner longitudinal bulkhead 7 of the hull 2. The dotted lines symbolize a subdivided inner structure of the stabilization device 5 (for example by tanks, storage rooms). An advantageous embodiment is the design as a stabilization device 5 in the ship's hull 2 as a tank 8 for liquids (for example fuel) or for use and storage of other media. Furthermore, the space above the stabilization device 5 can advantageously be used for the arrangement of a storage device for liquid or solid media. A deck house 9 is preferably arranged there.

According to FIG. 3, the stabilization device 5 is formed by an essentially closed spatial structure with plating on both sides in the form of transverse bulkheads 10.1, 10.2. The transverse bulkheads 10.1, 10.2 are each connected to the outer skin 6 and the inner longitudinal bulkhead 7. The stabilization device 5 and the ship's double hull 3 thus form two interlocking double structures. An upper belt deck 11 of the stabilization device is preferably designed to be closed and is advantageously connected at the same level to a continuous main deck 12 (cf. FIG. 1).

According to FIG. 4a, in a conventional container ship with a width of the ship's double hull of approximately 2 m, eleven rows of containers 13 are arranged side by side. According to FIG. 4b, in the container ship 1 according to the invention, twelve rows of containers 13 are arranged next to one another in the cargo hold 4 due to the reduced width of the ship's double hull 3 to a width of approximately 32 m. As a result of the stabilization device 5, ship lengths of about 294 m are made possible without problems in the container ship 1 according to the invention. According to FIG. 5a, in a conventional container ship with a deck house above the ship propulsion system on the main deck in front of the deck house, the containers can only be stacked up to about the middle of the ship up to the maximum height. According to FIG. 5b, in a container ship 1 according to the invention, due to the arrangement of the deck house 9 above the stabilization device 5 far in front of the ship propulsion system 14, the visibility of the water surface prescribed for the ship's operator is given with much more extensive stacking of the containers up to the maximum height. The line of sight 15 to be observed in accordance with the applicable regulations is given when the containers are stacked up to a few container lengths behind the bow of the ship, which further increases the parking space capacity.

Claims

Expectations:

1. Container ship with limited dimensions in length and width for passage of the Panama Canal and a cargo space (4) in a hull (2) with a double hull (3) that allows the accommodation of twelve rows of containers (13) alongside the ship's width, characterized in that that at least one spatial stabilizing device (5) connecting the ship's double hull (3) on one side of the hull (2) with the ship's double hull (3) on the other side of the hull (2) is arranged in the hull (2).

2. Container ship according to claim 1, characterized in that it has a length in the range of about 200 to 294 m.

3. Container ship according to claim 1 or 2, characterized in that it has a width of about 32 m.

4. Container ship according to one of claims 1 to 3, characterized in that the width of the ship's double hull (3) is approximately 1 m.

5. Container ship according to one of claims 1 to 4, characterized in that the stabilizing device (5) in the hull (2) separates two areas (4.1, 4.2) of the cargo space (4) from each other.

6. Container ship according to claim 5, characterized in that the stabilizing device (5) is arranged approximately at half the length of the cargo space (4).

7. Container ship according to claim 6, characterized in that the stabilizing device is arranged about half the length of the cargo space (4) in front of the ship propulsion system (14).

8. Container ship according to one of claims 1 to 7, characterized in that the stabilizing device (5) has a substantially closed spatial structure.

9. Container ship according to one of claims 1 to 8, characterized in that the stabilizing device (5) is enclosed by bulkheads (10.1, 10.2).

10. Container ship according to one of claims 1 to 9, in which the stabilizing device (5) with a ship's double bottom (3.3) of the ship's double hull (3) is connected.

11. Container ship according to one of claims 1 to 10, characterized in that an upper belt deck (11) of the stabilizing device (5) is essentially closed and connected at the same level to the main deck (12).

12. Container ship according to one of claims 1 to 11, characterized in that the stabilizing device (5) with the surrounding structure of the hull (2) is integrally connected and / or by means of fastening means.

13. Container ship according to one of claims 1 to 12, characterized in that the stabilizing device (5) and / or a space above it a tank (8) and / or at least one storage device for liquid and / or solid and / or other media and / or comprises at least one storage room for goods and / or at least one team room.

14. Container ship according to one of claims 1 to 13, characterized in that the ship's double hull (3) comprises at least one ballast water tank.

15. Container ship according to one of claims 1 to 14, characterized in that a deck house (9) is arranged above the stabilizing device (5).

16. Container ship with limited dimensions in length and width for passage of the Panama Canal, in particular according to one of claims 1 to 15, characterized in that for receiving the twelfth row of containers (13) in the width of the ship in the hull (2) of the container ship (1 ) at least one spatial stabilizing device (5) connecting the ship's double hull (3, 3.1, 3.2) is arranged.