DE102010024070A1 - Device for forming oil drilling hole under sea water, has thermal insulating layer that is formed in walls of liquid lines - Google Patents

Abstract

The device consists of a probe (1) which is constructed as a cylindrical sleeve having a double wall structure and having hollow chamber (4) in interior portion. A refrigerant storage container with highly filled cooled liquid or liquefied gas is provided. A fluid line is coupled with the inflow opening of the probe, and is coupled with a pump system (7) or directly to the reservoir (10). A thermal insulating layer is formed in the walls of the liquid lines. A valve controller is provided to control the processes in device. An independent claim is included for method for closing oil drilling hole in seal floor.

Description

The invention relates to a device and method that can reliably close oil wells both under water, as well as on land.

With population growth, the demand for energy and raw materials is increasing. In particular, the oil sources are becoming increasingly important. There are very large quantities of oil on the seabed which are carried by drilling platforms.

Through the oil drilling platforms, or otherwise called drilling rigs, drilling is carried out in the depths, transporting the oil from the seabed to the surface. The oil is then transported either by long pipelines or by tanker ships. However, as the most recent example shows, it can lead to accidents and oil spills. In the case off the Gulf of Mexico, a platform has caught fire and then sunk. The well was not closed as intended, but remained open and tens of millions of liters of oil flowed daily unhindered into the sea water.

To close the well, there are many methods and procedures. As a rule, safety valves are installed which are able to close themselves if an accident should occur. If, nevertheless, the valve remains open, an attempt is made to put over it a bell over which is to prevent the escape of the oil. In the Gulf of Mexico, two attempts have been made to close the bubbling spring with bells. But without success. It has also been tried with chemicals to make the oil harmless, but with such huge amounts of oil, this unfortunately has hardly any visible effect. Also, a so-called top-kill procedure, whereby the hole is filled with mud and additives (golf balls, tire parts and other items), unfortunately showed no effect. The pressure in the well is unfortunately unstoppable with materials that are liquid, tough, or in a fluid-like state. A source from which a flowing liquid comes out under high pressure can only be closed with liquid materials if they have the property of becoming fast and more viscous. Unfortunately, such materials are difficult to deploy in deep ocean depths. By mechanical means, however, the closing of a hole is easier to implement.

Numerous protective mechanisms are described, but ultimately the human factor must also be taken into account.

The registration DE 000004126540A1 describes a device for extinguishing and sealing a burning oil source, with which one can seal a burning oil source whose source head has been damaged. Here, a ring formation and a molten metal alloy are used, which surrounds the wellhead and then solidifies.

The registration EP 000000603181A1 also describes a system for extinguishing an oil source that is under high pressure. Here cementing processes are described.

The registration EP 000000115463A2 describes a process wherein, through cement slurry compositions, the flow into the oil well is controlled. The applications US 18 57 788, US 18 30 061, SU 15 02 811 A1 also describe methods used for these purposes.

However, all of these methods are not suitable for oil wells deep under the sea.

The problem addressed by claims 1 to 26 is that of providing a reliable method and device capable of reliably closing any oil well or oil well.

This problem is solved with the features listed in the claims 1 to 26.

• – Sehr schnelle Einsatzbereitschaft,
• – zuverlässiges und schnelles Schließen einer Bohrung nahezu unabhängig von dem Durchmesser der Bohrung
• – sehr günstiges Verfahren und Vorrichtung

Advantages of the invention are:

• - very fast operational readiness,
• - Reliable and fast closing of a bore almost independent of the diameter of the bore
• - Very cheap process and device

Embodiments of the invention will be described with reference to FIGS 1 to 4 explained. Show it:

1 a probe that is simply built,

2 a cross section of the probe,

3 a variant, wherein the probe is equipped with wings or grooves,

4 a probe equipped with a fixator.

The device consists of a probe 1 , which is preferably constructed cylindrically as a sleeve with a double wall structure and inside at least one hollow chamber 4 having. The task of Probe is it, refrigerant 2 directly into the hole 3 to transport and deliver it there. It is with double existing pressure hoses 5 or pipes coupled up to a pressure vessel 6 and a pumping system 7 range, which are placed near the hole or in a ship or platform on the surface. The pressure hoses or pipes should be covered with a thermal insulation layer. The outer diameter of the probe should be slightly smaller than that of the hole. It is simply inserted into the oil well in underwater operations. The fact that it is centrally open to the flow, allows the insertion of the probe into the oil hole 8th without much resistance, despite the enormous pressure of the flowing oil. The probe should be inserted quite deep, depending on the hole, preferably around 20-50 m. She can do her own thing 9 through which it is propelled forward despite the flow.

It can be made of metal or a flexible material. Once the probe into the hole, z. B. 50 meters deep, then it is fixed in the hole and from the reservoir 10 pumped into the surface of a refrigerant. The fixation of the probe is done by extendable claws 11 or electromagnet 12 attached to the pipe wall 13 attach the probe. In addition, you can weld the claws by strong electrical pulses with the pipe wall. The electrical energy can be through an electrical line 14 into the refrigerant hose virtually lossless (because of the superconductor effect in extremely low temperatures) are conducted. But you can also build strong capacitors in the probe, which charge and electrically welded by discharging the claws or fixing parts of the probe with the pipe wall of the bore. The refrigerant (eg liquid nitrogen) is transported through the pressure hoses to the probe. The thermo-insulation of the pipes or pressure hoses prevents the refrigerant from getting hot on the way to the probe. The probe is also thermally insulated itself. Their task is to transport the refrigerant directly into the hole and to transmit its temperature directly into the environment. The environment here is the crude oil that emanates from the oil well. The oil is in the channel 15 the probe must flow along the probe in the middle. The delivery of the refrigerant jet quickly cools the oil. The probe is not smooth inside but has grooves or lamellae 16 on. The flow is increasingly losing temperature. This also reduces the speed. The frozen oil lumps clog the hole more and more and eventually no more oil flows out of the hole. You can also pump water into the hole and let it freeze quickly by refrigerant. In the Gulf of Mexico, according to calculations, flowed out of the hole to about 150 liters of oil per second. This means that the 150 liters of oil in a hole with a diameter of approx. 20 cm cover approx. 4.7 m per second. In a small section of a hole that is 50 meters long, this amount of oil would not exit the hole until about 10 seconds later. The diameter of the probe is significantly smaller than that of the oil hole. This means that a probe inserted in 50 m has about 10 seconds to cool this amount, and so that the liquid is tough and finally frozen. The strong cooling power of the probe is easily achieved by liquid nitrogen, also because the maximum oil flow rate is reduced with the cooling. Due to the claws and fixing mechanism, the probe remains fixed against the flow. Cooling is progressive by the positive feedback control method because the flow decreases rapidly over time and the slower the oil flows, the more time the probe has to cool the mass. In this way, the cooling time would extend to 150 seconds within the first minute per liter. It must also be remembered that not all the cold must be removed from -160 ° C but only a fraction of the temperature of the oil mass in order to make the crude oil toughen or even freeze it. The liquid nitrogen is pumped to the probe with a hose or tube. Also, the hoses or other coolant lines can be inserted into the bore. For a hose with an inside diameter of 20 mm, about 470 l of liquid nitrogen are sufficient to reach the probe at a depth of 1500 m from the ship. The temperature of the nitrogen will initially drop, because it has to cool the tube while traveling, but the rest arrives very strongly cooled to the probe. It is even better if there is a chance to place the coolant tank and pumping system near the oil well. By remote control one could give the control commands from the ship. This would result in much shorter lines and time for transporting the coolant from the tank to the probe.

The coat 17 The probe can also be small pimples or thorns 18 have on the outer wall, which fix him properly in the hole. However, the mandrels can be equipped with an alloy that is similar to welding electrodes used by electrical welding equipment. By applying a strong electrical current to the wall of the bore, or the tube that is in the hole and the jacket of the probe, a high current flows through the two objects. However, the highest electrical resistance is generated at the spikes as they serve as current passage points between the probe and the bore wall. The thorns immediately melt and merge with the pipe wall of the hole. Thus, the probe is well and quickly fixed.

The probe may additionally have a shut-off valve which can shut off the channel and thereby plug the oil source. In any case, the refrigerant is not only good for slowing or stopping the flow, but rather for fusing the probe with the tube wall or fixing it there.

LIST OF REFERENCE NUMBERS

1

probe

2

refrigerant

3

drilling

4

hollow

5

pressure hoses

6

pressure vessel

7

pumping system

8th

Oil bore

9

drive

10

reservoir

11

claw

12

electromagnet

13

pipe wall

14

Electrical line

15

channel

16

slats

17

coat

18

thorns

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 000004126540 A1 [0006]
• EP 000000603181 A1 [0007]
• EP 000000115463 A2 [0008]
• SU 1502811 A1 [0008]

Claims (26)

Device capable of closing a damaged oil well, characterized in that it comprises at least: - a probe constructed like a sleeve and a double-walled construction with a hollow chamber; - a refrigerant reservoir filled with a highly cooled liquid or liquefied gas is filled, - a liquid line, which is coupled on the one hand to the inlet opening of the probe and on the other hand with a pumping system or directly coupled to the reservoir, - an insulating layer, which is installed in the walls of the liquid lines thermally insulating acts, - a valve control that controls the processes has. Apparatus according to claim 1, characterized in that the pumping system and the refrigerant reservoir are located outside the probe in the immediate vicinity or in the vessel and are coupled with high-pressure lines to the probe. Device according to claim 1 or 2, characterized in that the probe is equipped with at least one nozzle or outlet opening, which remains closable to the place of use. Device according to claim 1 or 2, characterized in that the probe has a plurality of nozzles or outlet openings. Device according to one of the preceding claims, characterized in that the probe is equipped with at least one temperature sensor and / or pressure sensor. Device according to one of the preceding claims, characterized in that the probe is provided with lamellae or grooves on the outer wall and / or inner wall. Device according to one of the preceding claims, characterized in that the probe is coupled to at least a second liquid line, is pumped through the water at high pressure. Device according to one of the preceding claims, characterized in that the probe is equipped with at least one drive nozzle. Device according to claim 8, characterized in that the drive nozzle is movable or its return direction can be changed via built-in control grooves or wings. Device according to one of the preceding claims, characterized in that the probe is equipped with an image / video camera or IR camera for an accurate introduction into the bore. Device according to one of the preceding claims, characterized in that it is equipped with a lighting or IR lighting. Device according to one of the claims 9 to 11, characterized in that the probe with one or more additional chamber, which are coupled to drive or control nozzles, which are filled with explosives / gases or gas mixture is equipped. Device according to claim 12, characterized in that the gas mixture consists of hydrogen and oxygen. Device according to one of the preceding claims, characterized in that the probe is equipped with claws or barbs, which are installed on the outer wall thereof. Device according to claim 14, characterized in that the claws, barbs or supports are extendable and coupled with a mechanism that can extend them. Device according to claim 14 or 15, characterized in that the claws or supports are installed as spreading wings of a dowel. Device according to claim 15 or 16, characterized in that the probe is equipped with an explosion drive system that extends the supports or claws. Device according to one of the preceding claims, characterized in that the probe is equipped with strong electromagnets. Device according to one of the preceding claims, characterized in that the probe is equipped with electrical lines which conduct electrical energy to a fixing device. Device according to claim 19, characterized in that the fixing device is provided at the tips with a special mass suitable for electrical welding to the pipe wall of the bore. Device according to one of the preceding claims, characterized in that the probe is equipped with at least one own drive, which consists of a drive motor or drive nozzles. Device according to one of the preceding claims, characterized in that the probe is equipped with thorns of metal or an alloy, which are installed on the outer wall. Device according to claim 22, characterized in that the spikes are made of welding electrode material or coated with such a material. A method for closing oil wells of all kinds after an accident, preferably for drilling, which is located in the seabed, characterized in that directly into the oil well or via a sub-bore, which leads to the problem hole, a probe so introduced as deeply as possible, which is coupled via at least one liquid line, with a refrigerant reservoir in a ship, wherein the refrigerant, preferably a liquefied gas is discharged directly into the oil hole via the probe, the freezing of the oil directly caused in the hole. A method according to claim 24, characterized in that the refrigerant is discharged at high pressure. A method according to claim 24 or 25, characterized in that the refrigerant is discharged via a plurality of nozzles or a sieve which generates a plurality of jets.

Images