A subject of the invention is an articulated arm for loading and unloading products, in particular fluid products, such as for example petroleum products (liquefied natural gas . . . ).
More particularly it relates to a balanced loading arm equipped with a hydraulic coupling allowing a transfer to be carried out between two vessels moored side-by-side, between a vessel and a platform or a floating barge moored side-by-side, or also between a jetty on which the loading arm is installed and a vessel moored alongside this jetty.
Such loading arms are known, in particular from patent application FR 2 813 873. This document describes a connection-assistance system which is composed principally of a constant-tension system (winch, jack, counterweight or other), and a so-called conventional winch, installed at the connection system of the loading arm.
The aim of the invention is to eliminate the risks of impacts between the end of the manifold of the vessel and the coupling means of the loading arm. In particular it aims to permit the connection/disconnection of the loading arm to vessels in difficult meteorological conditions.
To this end, the invention relates to an assembly for loading and unloading products, comprising a balanced loading and unloading arm installed at a first location and having a compass-style duct system mounted by one of its ends on a base and provided at the other of its ends with a connection system suitable for connecting the compass-style duct system to a coupling means installed at the second location, characterized in that it comprises, in addition, a cable joined on the one hand to means integral with the base and suitable for subjecting this cable to a constant tension and suitable for being joined, on the other hand, to the second location, the loading and unloading assembly also comprising guiding means capable of co-operating with the cable so as to guide the connection system along a trajectory materialized by the said cable until the connection system is brought into a position of connection to the coupling means.
According to preferred provisions of the invention, combined where appropriate:
A subject of the invention is also a combination comprising an assembly as described previously, characterized in that it also comprises coupling means fitted with means for fixing to the second location, these coupling means being suitable for co-operating with the said connection system.
According to a preferred characteristic, the connection system comprises a female truncated conical element and the coupling means comprise a male truncated conical element, the female truncated conical element and the male truncated conical element being suitable for fitting into each other to define a relative positioning of the said assembly and said coupling means.
Other characteristics and advantages of the invention appear in the light of the description that will follow of a preferred embodiment given by way of non-limitative example, which description refers to the attached drawings in which:
The so-called “constant-tension” winch will allow a cable to be kept stretched between the vessel, for example a liquid natural gas tanker, and the loading/unloading arm throughout the phase comprising approach, connection and disconnection at the manifold of the vessel. This cable will allow, via the drive winch, the connection system for the loading arm to brought close to the manifold of the vessel.
In order to guarantee a constant tension in the cable the winch winds on and unwinds according to the movements imposed between the vessel and the location on which the loading arm is installed. When the vessel approaches the arm, the winch winds on the cable, and when it moves away from it the winch allows the cable to unwind. A specific hydraulic control system applies a constant hydraulic pressure to the winch motor.
The constant-tension winch is installed at the foot of the base of the loading arm.
The guide pulley serves to orientate the cable between the constant-tension winch and the drive winch. It is orientatable along the three axes of rotation so as to best guide the cable, whatever the direction and the angle of engagement of the latter. The pulley is situated at the upper end of the base, just above the constant-tension winch.
The orientatable alignment guide is fixed onto the drive winch and is situated just behind the latter. It moves along an axis perpendicular to the cable and orientates itself at an angle, for example ranging from −30° to +30°. Its principal functions are to correctly guide the cable before entering the winch, and to orientate the connection system in the vertical plane. This guide accompanied by the cable allows the avoidance of too-sudden vertical movements, and also the front and rear balancings of the connection system.
The so-called “drive” winch is a mechanical assembly operated by a hydraulic motor. It is fixed at the connection system close to the alignment cone described below. It is located behind the coupling and moved off-centre relative to the axis of the latter. Its functions are to permit the connection system to progressively follow the movements of the liquid natural gas tanker, and to guide the loading arm as far as the manifold of the vessel. For this, the winch winds and unwinds on the cable at constant tension. It is actually the adhesion of the cable on the drum of the winch that allows the arm to be brought close to and moved away from the manifold. During this approach phase, the arm is in “free wheel” mode. To drive the arm, the winch must overcome the forces induced by the cable, the intrinsic mass of the arm and all other outside agents (wind, ice etc.). This hydraulic winch is controlled by the operator who works a control panel; it is he who decides whether or not to bring the arm close, by working the drive winch.
The hydraulic coupling is fitted with a female cone called “alignment cone” through which the cable passes at a constant tension. Upstream from the alignment cone, the cable passes into the drive winch and downstream from the cone is found the end of the cable which is locked by the system located on the vessel. The role of this centering cone is to precisely guide the connection system and in particular the coupling. At the end of the approach, the male cone, called “reception cone”, which is located alongside the manifold of the vessel, fits inside the female cone. Thus fitting allows the coupling to be brought close to the manifold while avoiding the violent impacts which could damage the joints and the coupling itself. The cone also serves to align the coupling with the flange on board the vessel; it is situated alongside the coupling. In addition to the cone, it is possible to use an orientation device for the connection system, in order to best prepare the alignment between the two elements. This orientation device can comprise a device for rotating the connection system relative to the articulated arm.
The whole of the connection system is in fact here fitted with a rotation device independent of the rest of the equipment, and permits angular orientation in the desired direction of the coupling and the system for connecting the arm (cone, drive winch, orientatable guide). This system allows the operator to centre the coupling with the manifold of the vessel during the final approach phase. It is composed of two hydraulic motors fitted with drive pinion, as well as a crown gear. This orientation system is installed at the upper-rotation level of the connection system generally called “median rotation”
An equivalent system can for example be developed from a jack and connecting rods.
The horizontal orientation (the trim) is obtained with the help of the orientatable guide and the guide rollers situated behind the female cone.
A single cable stretched at a constant tension can thus serve as a link and guide between the manifold of the vessel and the system for connecting the loading arm.
On the vessel, a guiding assembly is installed right alongside the manifold. This assembly is composed in particular of a male reception cone through which the cable passes equipped with a sleeve at its end, as well as a mechanical locking system allowing this cable under constant tension to be kept in place. This system is essentially composed of an indexable bolt fixed to an operating handle. The bolt is actually a piece having at its lower end a longitudinal rounded shape through which the cable passes. As the sleeve (crimping) has a diameter greater than that of the cable, this is “trapped” after having entered the guiding tube and after the bolt has been lowered. When at rest, the bolt is in fact in a position of flanging the sleeve of the cable. As the bolt is fitted with a return system, when the operator pulls on the rope hitched to the end of the sleeve, the latter acts on the bolt so that the latter closes as soon as the sleeve has passed completely behind it.
The guiding/locking assembly is thus capable of withstanding very strong forces.
In the event of a problem during the loading/unloading of the vessel, the connection assembly is fitted with an emergency disconnection system. This system is composed in particular of an ERS (assembly of two valves which close and separate). As this equipment is well known, it will not be described in more detail here. The emergency disconnection system also comprises a means of releasing the cable in the case of an abnormal gap between the vessel and the arm. The cable release system is here installed at the constant-tension winch. The cable is wound onto the drum of the winch and its free end is kept engaged in a cubicle, by three mechanical spring thrusters (not represented). Three additional thrusters, these being hydraulic, can also be used in parallel to the mechanical thrusters.
In the event of a major unwinding of the cable, the three hydraulic thrusters are capable of unlocking themselves. At the end of unwinding, the cable is held only by the three mechanical thrusters, which can release the cable with the help of the tractive force engendered in the latter.
The connection-assistance system is thus composed of a constant-tension winch and a drive winch, permitting movement of the loading arm, by friction, on a single cable kept stretched at a nominal tension.
To connect the loading/unloading arm, the following stages can be envisaged, independently of one another:
To disconnect the loading/unloading arm, the following steps can be envisaged, independently of one another:
Although the cones or guiding elements are used for orientation and permit the coupling to be brought close to the manifold of the vessel without impacts, in the case described above these are not aligned relative to the axes of the coupling and of the manifold. The coupling and the manifold are orientated in one direction, whereas the connection-assistance assembly is orientated in another. The orientatable guide, the drive winch and the male and female guide cones are all orientated in the same direction. Other cases can be developed, consideration being given for example to guiding tubes or frusta parallel to the axes of the coupling and of the manifold.
The invention can comprise, in particular in view of the following elements, independent of one another:
The reference signs used for the corresponding elements shown on the drawings are indicated below:
Number | Date | Country | Kind |
---|---|---|---|
03 04999 | Apr 2003 | FR | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2004/004527 | 4/20/2004 | WO | 00 | 4/30/2007 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2004/094296 | 11/4/2004 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
2660110 | Boutwell | Nov 1953 | A |
2722230 | Toussaint | Nov 1955 | A |
3032082 | Vilain | May 1962 | A |
3249121 | Bily | May 1966 | A |
3964512 | Dumas | Jun 1976 | A |
4206782 | Tuson | Jun 1980 | A |
4299261 | Talafuse | Nov 1981 | A |
4418718 | Fusy | Dec 1983 | A |
4715404 | Fusy | Dec 1987 | A |
6343620 | LeDevehat et al. | Feb 2002 | B1 |
6719008 | LeDevehat | Apr 2004 | B1 |
6886611 | Dupont et al. | May 2005 | B2 |
7147022 | Le Devehat | Dec 2006 | B2 |
20090205343 | Dupont et al. | Aug 2009 | A1 |
Number | Date | Country |
---|---|---|
1.415.279 | Nov 1964 | FR |
2 813 872 | Mar 2002 | FR |
1 591 646 | Jun 1981 | GB |
WO 0104041 | Jan 2001 | WO |
WO 0104041 | Jan 2001 | WO |
WO 0222491 | Mar 2002 | WO |
Number | Date | Country | |
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20090065078 A1 | Mar 2009 | US |