Not Applicable.
Not Applicable.
Not Applicable.
The present invention relates to a movable supporting construction for placing on a floor. Such a supporting construction is used, for example, as a sea floor reaction mass when conducting a geotechnical survey from aboard a ship. This supporting construction is also referred to as Seabed Frame (SBF) and serves initially as reaction mass to the force needed to push a probe or sample tube into the ground. In addition, the supporting construction has several other functions such as drill-pipe guide, support for measuring, operating and control equipment for the geotechnical survey. The equipment of the supporting construction depends on the survey to be performed. Since the seabed is in general not flat or horizontal, it is important that the supporting construction be operable on a slope. If this is not possible, or only to a lesser extent, the applicability of the supporting construction becomes limited, which is undesirable.
Supporting constructions for operating on a slope exist. These constructions are usually embodied with a fixed hinge point (cardan-like) between two components, of which one has to adapt to the angle of the slope; they may also be provided with an extra device that is actively controlled by means of, for example, hydraulic cylinders. This is often realized after landing, with the aid of measurements. During positioning, also referred to as landing, these constructions are subject to internal frictions resulting from the parts being permanently coupled (cardan or hinge) so that they are either prevented from assuming the correct angle or they require active control. After landing, the components are often not fixed so as to avoid rotation in relation to one another, with the result that relatively minor external forces can cause the support construction to become unstable.
The inability to adequately compensate for the slope may have the following consequences:
An example of an existing construction is that of the Ocean Drilling Program (ODP), referred to as the “Hard Rock Base” (HRB). A description can be found on the ODP website. This is based on a cardan. Apart from the above-mentioned drawbacks of such a construction, the maximally allowable angle of incline of the ground is 20°.
GB 1503398 discloses a supporting construction for an underwater platform for a drilled well, wherein a guide frame lowers the drill-column onto a temporary base. The drill column rests on the temporary base by means of a ball-and-socket joint formed by spherical bowls fitting into each other, determining a supporting surface. With such a bearing, the size of the supporting surface changes with the angle of incline. As the angle of incline increases, the supporting surface becomes smaller. This limits the allowable angle of incline. In practice, the maximally allowable angle of incline with a construction as described in GB 1503398, will be smaller than 20°. Likewise, an increasing angle of incline makes such a support more asymmetrical. Thus as the angle of incline increases, the stability decreases.
The invention may be employed onshore but is, for example, especially suitable for landing on the seabed. Hereinafter the invention will be further elucidated by way of a description of a preferred embodiment and with reference to the appended drawings, in which:
It is an object of the invention to provide a movable supporting construction able to reliably operate on a sloping surface that has a simple construction and avoids the drawbacks of the prior art solutions while having advantages that will be elucidated hereinafter.
This object is achieved with a supporting construction according to claim 1. The lower part is able to follow the surface of the floor, irrespective of its inclination. The upper part may then be placed on the lower part such that a particular desired orientation is maintained. This may, for example, be the horizontal orientation of a platform that is an element of the upper part. Owing to the upper part's own weight, the friction between the components of the lower part and the upper part, which during support in the second position are in contact with one another, provides a firm connection between the two parts. Once the construction is in position, there is no need to carry out further measurements or to keep the platform horizontal by means of controls and adjustments.
In the second position, the upper part and the lower part of the movable supporting construction according to the invention are in line contact and the contact line forms at least a portion of a closed line, such that the upper part is supported all round, i.e. in all directions, by the lower part. This ensures that the upper part is stably supported by the lower part, even at different angles of inclination. Moreover, the stability is hardly affected by the angle of inclination so that much larger angles of inclination are allowable.
When in a preferred embodiment the closed line is a circle, an all-round symmetrical and stable support is obtained on all sides.
In a favorable embodiment, the lower part possesses a first contact surface and the upper part possesses a second contact surface, which in the second position are cooperatingly in contact, and wherein at least a portion of either the first contact surface or the second contact surface is spherical. In a very favorable embodiment, at least a portion of the contact surface cooperating with the spherical contact surface is conical. This is particularly advantageous because in the second position, a cone and a sphere will form a circular contact line at any mutual angle so that the support is stabilized by friction, providing a stable position in all directions.
When a spherical and a conical contacting body cooperate with one another, there is the additional advantage that during the movement from the first position to the second position, i.e. when placing the upper part on the lower part, said contact surfaces have a centering effect on one another. If the upper part is not in precise central alignment with the lower part, the forces, which are not symmetrical at first contact, will guide the upper part to the centre of the lower contact surface.
To this end it is preferred for the at least partly conical contact surface to be provided with an opening whose diameter is at least one and a half times the diameter of the contact line.
A larger diameter of the contact line increases the supporting stability between the upper part and the lower part. The diameter of the contact line is therefore preferably at least one third part of the widest dimension of the upper part.
If desired, it is of course possible to provide extra connecting means such as clamps, traction ropes, traction rods and the like between the lower part and the upper part.
The section of the cone may have many different shapes. However, with a view to manufacturing costs, the section is advantageously triangular.
In order to prevent the supporting construction from sliding, it is an advantage for the lower part to be provided with anchoring means for anchoring in the ground.
Depending on the conditions of the ground, anchoring means to be provided may be plates or pins or combinations thereof, that are sunk into the ground.
In order to prevent the supporting construction itself sinking too deeply into the ground, it may be provided with a base plate upon which the construction rests on the ground.
An important advantage of the supporting construction according to the invention is that it is suitable for different inclines and different terrains.
If the upper part is embodied so as to be hoistable, it may be placed and removed, for example, so as to be placed somewhere else.
The supporting construction is very easy to place if the lower part and the upper part are connected with one another by a flexible connection. This flexible connection may be comprised of, for example, cables. The lower part is then, as it were, suspended from the upper part. During lowering, the parts are connected via the cables so as to be separate and movable in relation to each other. Since the lower part hangs clear, without being influenced by the upper part, it will be free to adapt to the angle of the slope. After the same has landed on the floor, the upper part after further lowering reaches the lower part in the same orientation in which it was while suspended, without being affected by the lower part. During lowering, the upper part maintains a horizontal orientation such that it creates a stable horizontal plane without being influenced by the slope of the floor.
In a special embodiment, the connection is formed by one continuous cable, running over discs, of which at least one is fastened to the lower part and at least one is fastened to the upper part. In this way the wire stays continuously under tension. In the case of separate wires, the tension in one of the wires may fall off due to the lower part already having found one supporting point during positioning. If the tension in one or two wires falls off, the upper part may, owing to the tension still present in the remaining wires, tilt slightly. Depending on the weight ratio between upper part and lower part, this tilting can be controlled and kept to a minimum. Tilting need pose no problem, as it is possible to arrange for sufficient space between the parts. As soon as the lower part is completely supported by the floor, the tension in all of the wires will fall off and the upper part will tilt back to its original orientation. However, this requires sufficient space and sufficiently long wires. In the case of a continuous wire, the upper part will not tilt and the construction can be made more compact. Instead of placing the upper part on the lower part, it is in this embodiment of the invention possible to pre-stress the hoisting cables, and thus the continuous wire. This provides a flexible connection, which may be advantageous in some circumstances since it avoids, for example, that, in drilling operations a transition from the drill-pipe in the water to the drill-pipe in the frame turns out to be too stiff. In this way the upper part is able to adjust according to the position of the drill-pipe, which is influenced for example, by the current in the water. If the discs are self-adjusting, the cable will run smoothly through the discs, irrespective of the conditions.
Although by no means limited thereto, the invention will be very suitable for guiding a drill-pipe, if during operation the supporting construction is provided with an opening to allow a pipe, such as a drill-pipe, to pass through.
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Number | Date | Country | Kind |
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1027337 | Oct 2004 | NL | national |
This application is a continuation-in-part application of Patent Cooperation Treaty (PCT) Patent Application Serial No. PCT/NL2005/000694, entitled “MOVABLE SUPPORTING CONSTRUCTION”, to Furgo Engineers B.V., filed on Sep. 26, 2005, and the specification and claims thereof are incorporated herein by reference. This application claims priority to and the benefit of the filing of Netherlands Patent Application Serial No. NL 1027337, entitled “MOVABLE SUPPORTING CONSTRUCTION”, filed on Oct. 26, 2004, and the specification and claims thereof are incorporated herein by reference.
Number | Date | Country | |
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Parent | PCT/NL05/00694 | Sep 2005 | US |
Child | 11738107 | Apr 2007 | US |