NO143757B - PROCEDURE FOR SUBMITTING A FLOATABLE HOLE BODY, AND HOLE BODY SUBMITTED BY THE PROCEDURE - Google Patents

Description

The present invention relates to a method for submerging a buoyant hollow body, in particular a support foot for a work platform etc., in great water depths by ballasting with water, whereby the pressure difference between the external water pressure acting on the hollow body and its internal pressure is minimized by providing a gas pressure in the hollow body , as liquefied gas is evaporated in the hole body with the help of water which is led into the hole body for ballasting. The invention also relates to a hollow body for carrying out the method.

When building work and production platforms that are to be stationed at sea, it is known to build these almost completely on land, e.g. at a shipyard, and then tow these on hollow bodies, which in the next stage serve as floating bodies, to the installation site.

At the installation site, the holes are filled in such a way that the platform assumes the pre-sunk position and at the same time is lowered so deeply that it occupies a suitable height above the water surface. Especially in the case of very large platforms, the well casings are thereby lowered to such a water depth that during the immersion a pressure difference occurs between the water pressure acting on the outside of the well casing and the pressure on the inside of the not yet completely filled hole casing

that the load limit for the walls of the hollow body is exceeded.

For pressure compensation, the gas pressure in the interior of the hole body is increased corresponding to the prevailing water depth at any given time by means of known devices such as e.g. compressors. When the hollow body has reached its final position, it is usually completely filled, so that no pressure difference occurs between the inside and the outside of the hollow body. As the volume of the wells on large platforms is correspondingly large, a large amount of compressed gas must be pumped into the wells in a short time during the immersion, which requires particularly large and particularly expensive compressor systems.

Alongside such ncd sinking methods that work with compressed air for pressure compensation, a method for immersing a concrete container of large dimensions is also known from DE-OS 2 312 014, where the pressure difference between the external water pressure acting on the concrete container and the internal pressure is achieved by evaporation of liquefied gas. The liquefied gas is fed from a storage container arranged on the outside of the concrete container into an aqueous solution located in the concrete container. With this method, it is possible to avoid the use of compressors at the water surface for air pressure supply and expensive connection lines between the compressors and the container to be lowered, but it will still be necessary to use a separate storage container for liquefied gas that is connected to the container to be lowered by means of supply and introduction systems. In order to enable a sufficient sinking speed for a large hollow body, the supply line from the storage container to the hollow body must also be dimensioned for a correspondingly fast transfer of liquefied gas.

The task of the invention is to provide a method

of the type mentioned at the outset for submerging a buoyant hollow body, whereby the pressure difference between the outer and inner pressure of the hollow body can be equalized in a simple way without significant use of aids, so that one can work with significantly less equipment than previously known procedures.

According to the invention, this task is solved by filling the liquefied gas in the hollow body before immersion.

When filling liquefied gas in the wellbore before the immersion, the equipment set-up is considerably simplified compared to known methods, because one does not need either compressors with corresponding connection lines to the wellbore or a separate storage container with a connection to the wellbore via supply

and introduction systems.

If the hollow body is designed as an insulated container, which can for example be achieved in a simple way by foaming the walls of the hollow body with a foam material, such a prepared hollow body can be filled with liquid gas before it is transported out to the place of use. In contrast to filling the wellbore at sea, this saves the additional use of a liquid gas tanker.

As the walls of the hole body do not need to be absolutely gas-impermeable, the hole body can consist of concrete.

A liquid gas which can be advantageously used in the method according to the invention is liquid nitrogen, which is relatively cheap and which, due to its chemical reaction inertia, does not lead to any pollution of the sea or the atmosphere. Other liquid gases can also be used, for example helium, which has even less heat of vaporization than liquid nitrogen.

The formation of pressurized gas during the immersion can, in the method according to the invention, take place in a particularly simple way by adding water during the immersion to the liquid gas which is in the cavity during the immersion. In this way, the amount of heat required to cause the liquefied gas to undergo a phase transition from liquid to gaseous state can create an internal pressure, with the help of which the liquefied gas is vaporized at the pressure corresponding at all times to the present water depth, is mostly completely taken out of the sea water.

In this method, a complete heat transfer takes place between the water and the liquid gas, as the water fed into the hollow body freezes by using deep-cooled liquid gases. Nevertheless, the amount of water required for complete evaporation of the liquefied gas can be kept so small that the ice that forms in the hollow body cannot cause damage to the walls of the hollow body. In addition, the ice causes the hollow body to heat up very slowly,

so that thermal stresses in the walls of the hollow body are largely avoided.

Another particularly advantageous option for taking the required amount of heat for vaporizing the deep-cooled liquefied gas out of the water consists in filling the hole body with liquid gas only in a part of the hole body, the remaining part of the hole body being filled with water during immersion, and that at least part of the liquefied gas in liquid form is transferred to the filled water.

As water has a very high heat capacity, correspondingly large quantities of deep-cooled liquefied gases, such as e.g. liquid nitrogen. However, the hollow body should contain at least so much water that its heat capacity at the end of the immersion is sufficient to evaporate the liquid gas used without the water in the interior of the hollow body freezing completely. For this purpose, the water in the hole body during the introduction of the liquefied gas can be kept in constant motion, e.g. in that the gas is transferred from one area to another in the form of a correspondingly directed jet which sets the water in rotation.

In the case of a buoyant hollow body suitable for carrying out the method according to the invention for immersion in great water depths, a part of the hollow body is designed as a space for absorbing liquefied gas, which space is connected to the rest of the inner space through an opening.

Regardless of the design of the hollow body, it is advantageous that it

devices for supplying heat to the liquefied gas are arranged on the hole body. Such devices can e.g. be heat exchangers that heat the liquefied gas using water. Furthermore, heating devices of any type can be used, by means of which the rate of evaporation of the liquid gas can be increased in an adjustable manner within a specific area.

The method according to the invention shall be described in more detail with reference to the design example which is shown schematically in the attached drawing.

A submersible hollow body 1 is provided on the inside with an insulation layer 2 and which is partially filled with a liquid gas 4. The hollow body is arranged at the end of a platform leg 3 and is towed to the installation site in the floating position shown. For platforms whose legs are designed for sea depths of between 300 and 400 m, such hollow bodies have a volume of from 10,000 to 40,000 m 3 , depending on the weight of the complete platform and the number of hollow bodies. The water pressure at such sea depths is 30 bar and more. If the immersion is to be able to be completed in the course of one working day, it must therefore be in the course of approx. 8 hours, a quantity of compressed gas is formed and supplied to the hole body, which corresponds to approximately 1,000,000 m 3 of gas at normal pressure. According to the method according to the invention, the hollow body 1 is filled with water at the installation site through a valve 5, and at the same time so much water is introduced into the liquid gas through a valve 6 that the amount of gas that occurs by evaporation in the hollow body forms

a pressure that at least approximately compensates the water pressure

which acts on the outside of the cavity walls. An overpressure valve 7 which automatically adjusts itself according to the water pressure prevents an overpressure from occurring in the hollow body 1 which exceeds its loadability limit. Using the rudder 8 inside the rudder 3, the hole body can later be filled with gravel, sand, cement or the like.

Claims (5)

1. Procedure for submerging a buoyant hollow body, especially a support foot for a work platform etc., in great water depths by ballasting with water, whereby the pressure difference between the external water pressure acting on the hollow body and its internal pressure is minimized by providing a gas pressure in the hollow body, liquefied gas is evaporated in the hole body with the help of water which is led into the hole body for ballasting, characterized by liquid gas being filled into the hole body before immersion. 2. Method according to claim 1, characterized in that the liquid gas which is in the hollow body is introduced into the water during the immersion. 3. Method according to claim 1 or 2, characterized in that filling of the hollow body with liquid gas is carried out only in a part of the hollow body, in that the remaining part of the hollow body is filled with water during immersion, and that at least part of the liquid gas in liquid form is led over to the filled water. 4. Buoyant hollow body for immersion in great water depths, in particular a support foot for a work platform etc., for carrying out the method according to one of claims 1 - 3, characterized in that at least part of the hollow body (1) is designed as space for absorption of liquefied gas, which room is connected to the rest of the interior room through an opening. 5. Buoyant hollow body according to claim 4, characterized in that the hollow body (1) is arranged with devices for supplying heat to the liquid gas.