The invention relates to a cryogenic fluid offloading system comprising:
A weathervaning LNG offloading system is known from Zubiate, Pomonic, Mostarda, Ocean Industry, November 1978, page 75–78.
The known mooring structure comprises an articulated riser tower with a buoyancy chamber that is attached to a piled base via a universal joint. The top part of the riser tower projects above water level and is connected to a triangular mooring yoke via a tri-axial swivel and universal joint. The yoke is connected in two hinges to the stern of a floating LNG regasification barge. The yoke transporting LNG vapour to the tower riser system carries two cargo pipes. The tanker vessel is moored alongside the LNG barge, which has substantially the same length as the tanker.
Even though the combined tanker and LNG regasification barge can weathervane around the mooring tower, the offloading situation during weathervaning is relatively unstable. The tanker will therefore be docked to the regasification barge for a short period of time as possible and completely transfer its LNG to LNG storage facilities. Next, the tanker is decoupled from the barge and will leave to collect a next cargo, while the LNG stored in the regasification barge storage tanks is regasified and supplied through the pipeline extending from the riser tower along the seabed to shore.
It is an object of the present invention to provide a cryogenic fluid offloading system in which a tanker can be moored to the offshore mooring structure for a longer period of time in a stable weathervaning position.
It is a further object of the present invention to provide for a cryogenic fluid offloading system, which can employ a relatively small size regasification plant.
It is again another object of the present invention to provide a cryogenic fluid offloading system that can be easily produced and installed.
Thereto, the offshore cryogenic fluid offloading system according to the present invention is characterised in that the connecting member is connected with a second end to the tanker vessel, the mooring structure being at least substantially in line with the tanker vessel to allow displacement of the tanker vessel around the vertical axis, control means being provided for opening and closing of the fluid supply means on the basis of a predetermined supply of the gaseous phase through the first duct.
By attaching a tanker vessel in line to the mooring structure, a stable weathervaning situation is obtained. Weathervaning by displacement of the connecting member around the vertical axis can be through angles of ±180° or through smaller angles such as 90° or less, and can be in a single direction or in two directions, depending on prevailing wind and current conditions. According to the invention, the tanker vessel acts as the main LNG storage structure, which unloads LNG to the regasification plant only when there is demand from onshore, for instance from a power plant. When there is no onshore demand, the tanker is not being offloaded. Hence, the regasification plant need not have large LNG storage facilities and can be of relatively small size. Small buffer storage will suffice to ensure continued gas supply to shore when the tanker has been offloaded and is exchanged with another tanker. The buffer storage on the regasification plant can be of equal volume, preferably smaller than half of the volume or ⅓ of the volume of the LNG storage tanker of the tanker. Thereby, it is possible to moor the small size regasification plant alongside or at the bow of the tanker vessel, such that the weathervaning behaviour of the combined tanker and regasification plant is not affected in a negative manner.
Furthermore, the offloading system of the present invention can be easily installed by onshore construction of the regasification plant with the connecting member, which may be a space frame, floating it to the pre-installed mooring structure and connecting the regasification plant and connection member to the mooring structure.
In one embodiment, the connection member is an arm, for instance a space frame, having a longitudinal section that is with one end connected at or near the midpoint of the tanker vessel. The arm extends in the length direction along the vessel towards the mooring structure and has a transverse section attaching to the mooring structure. The transverse arm section allows the tanker vessel to be placed in line with the mooring structure so that it can weathervane under the influence of wind and current conditions around the mooring structure. The longitudinal section of the arm preferably is at least ⅓, more preferably at least ½ of the length of the tanker vessel, such that it can be connected near the midship position. The arm supports the LNG-duct, which may be rigid or which may comprise flexible piping. By means of the arm, according to the present invention, regular tanker vessels can be employed with midship loading and offloading facilities to be moored to the offloading system of the present invention and to be used as a storage facility for the regasification plant.
In one embodiment, the longitudinal section of the mooring arm is at its end, near the midship position of the vessel, provided with a floating structure for supporting the weight of the arm. On the floating structure, the regasification plant may be placed so that it is moored along side the vessel. The dimensions of the floating structure and the regasification plant supported on the floating structure are not more than ⅔ preferably not more than ½ of the length of the tanker vessel.
The transverse part of the mooring arm may be connected to a buoy, which is provided with a turntable that is anchored to the seabed so that the buoy can weathervane around the stationary mooring lines. In one embodiment, the regasification plant is placed on said buoy. Alternatively, the mooring structure may comprise a tower, placed on the seabed, having a fender system in the form of a vertical arm and weights depending from the vertical arm above or below sea level. A buoy is connected to the fender weights via a transverse rod. The regasification plant is placed on the buoy, which is attached to the transverse section of the mooring arm.
In again another embodiment, the regasification plant is placed on a tower above water level, the transverse section of the mooring arm being attached to a buoy that is connected to the tower via a soft yoke construction or via a rotatable hinging construction. For offloading of LNG to the regasification plant, a transfer duct may be employed as shown in European patent application no. 01202973.2, filed in the name of the applicant. The hinging LNG-offloading arm, having a number of articulations allows for heave, surge, sway, yaw roll and pitch motions of the tanker vessel, while allowing safe LNG-transfer to the regasification plant.
Some embodiments of a cryogenic fluid offloading system according to the present invention will be described in detail with reference to the accompanying drawings. In the drawings:
The floating structure 12 is moored alongside the tanker 2 as can be clearly seen in
As can be seen from
Furthermore, the offloading system 1 comprises control means 30, which may be formed by a flow sensor and a computing device for determining the flow of gas through the pipe line 16 towards the shore. Alternatively, control unit 30 may have another input for determining the demand of gas flow through duct 16 such as a manual input or an electrical or radiographical input from another computing device. In response to the desired gas flow through pipe line 16, the control unit 30 controls fluid supply means 31, which may comprise one or more valves connecting or disconnecting the LNG-tanks on the vessel 2 with the regasification plant 13. Signal lines 36, 37 for providing electrical or hydraulical control signals to the control means 30 and to the fluid supply means 31 have been schematically indicated. When no demand for gas flow through pipe line 16 is present, the fluid supply means 31 will be closed whereas the control means 30 will be opening the fluid supply means 31 when gas flow through the pipe line 16 is required. Hence, the vessel 2 functions as the LNG storage facility for the regasification plant 13 and is moored to the mooring structure 3 for a longer or shorter period, depending on the demand for gas supply through pipe line 16. As no substantial additional storage facilities are required for the regasification plant 13, it can be of relatively small size so that it can be moored alongside the vessel 2 without affecting the weathervaning capacities of the tanker 2.
In the embodiments, shown in
Again, the longitudinal centreline 24 of the vessel 2 intersects the vertical axis 39 so that the vessel 2 can weathervane through about ±90° around the vertical axis 39. Upon weathervaning, the weights 41, 42 will be deflected and provide a restoring force on the vessel 2 driving it back to assume its equilibrium position. The fluid duct 14 is attached to the regasification plant 13 for supplying LNG to the plant. An outlet of the plant 13 is connected via flexible riser 46 to a vertical gas duct which is incorporated within or alongside the tower 35 and which connects at the bottom thereof to pipe line 16 for transport of gas to the shore.
In an alternative embodiment, the fluid supply means 31 may also be connected to the duct 14 at the side of the regasification plant 13.
In the embodiment shown in
In the embodiment shown in
In the embodiment in
In the embodiment shown in
The offloading system, as described above, may be easily installed by onshore construction of the mooring arm 10 and connecting it to the floating regasification plant 13 of relatively small size. Separately, the mooring structure, such as tower 35, can construct at the mooring site. The regasification plant, together with the floating arm 10, can be transported to the site of the tower together and can there be connected, during which the regasification plant can remain on the floating structure, such as shown in the embodiments of
As can be seen from
The vertical mooring arms 104, 104′ are at their upper ends connected to the support structure 102 in articulation joints 122, 122′ allowing rotation of the arms 104, 104′ around a transverse axis 123 and a longitudinal axis 124. At the coupling end part 125, the arms 105, 105′ are provided with a mechanical connector 113 (
During connecting of the mooring arms 105, 105′ to the vessel 2, the vessel 2 may be connected to the tower 35 via a hawser 144. Via a pilot line 145, the mechanical connector 113 can be lowered and placed into a receiving element 146 on deck of the vessel 2. By paying out cable 130, the horizontal arm 105 pivots in articulation joints 116, 116′ around the transverse axis 118. The vertical ducts 135, 136 can pivot around a transverse axis 123 in articulation joints 133, 134 and in articulation joints 137, 138 as shown in
The horizontal ducts 139, 140 will also pivot around a vertical axis at swivels 137′, 138′ and a transverse axis a horizontal axis and a vertical arm at the position of two sets of each three perpendicular swivels 141, 142 until the mechanical connector 113 mates with receiving element 146 as shown in
In the embodiment shown in
Number | Date | Country | Kind |
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01204865 | Dec 2001 | EP | regional |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP02/14285 | 12/12/2002 | WO | 00 | 6/14/2004 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO03/049994 | 6/19/2003 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
3311142 | Bergstrom | Mar 1967 | A |
3354479 | Dickson et al. | Nov 1967 | A |
3908576 | Van Der Gaag | Sep 1975 | A |
3969781 | Reid | Jul 1976 | A |
3999498 | Flory | Dec 1976 | A |
4098212 | Kemper et al. | Jul 1978 | A |
4494475 | Eriksen | Jan 1985 | A |
Number | Date | Country |
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1 097 058 | Jan 1968 | GB |
1 511 313 | May 1978 | GB |
Number | Date | Country | |
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20050039665 A1 | Feb 2005 | US |