NO329391B1 - Collection device and system for handling an uncontrolled blowout - Google Patents

Abstract

A collecting device is provided for collecting liquid hydrocarbons and / or water in an underground activity area (10) and a system for handling liquid fluids, such as hydrocarbons and / or water entering the underground activity area (10). The system comprises at least one collection shaft (14) for collecting liquid fluids, such as liquid hydrocarbons and / or water, which extends into the bottom (12) and comprises an opening (13) which opens into the activity area (10). The system further comprises at least one pump shaft (19) which is protected against the flow of liquid hydrocarbons and / or water from the activity area (10), wherein at least one pump (26, 26 ') is provided for pumping out liquid hydrocarbons and water through at least one a drainage channel (30), a connection tunnel (16) between a lower portion of the collection shaft (14) and a lower portion of the pump shaft (19) such that there is fluid communication between the collection shaft (14) and the pump shaft (19), and at least one superstructure (20) , 22) covering the at least one collection shaft opening (13), and the superstructure (20, 22) being provided with fluid flow openings having a size dimensioned so that loose objects above a given size cannot pass through the at least one the openings of the superstructure (20, 22).

Description

The present patent application relates to a collection device for the collection of hydrocarbons and possibly water, as well as a system for handling liquid hydrocarbons in the event of an uncontrolled blowout in an underground activity area. It also relates to an application of the collection device and an application of the system for handling liquid hydrocarbons in connection with an underground activity area where extraction of hydrocarbons takes place.

In connection with the extraction of hydrocarbons, it is common for this to take place from the surface of the earth or from platforms or floating production vessels at sea. An alternative to this is to extract the hydrocarbons from a work area below the earth's surface by creating a work area below the earth's surface and a tunnel connection between the work area and the earth's surface.

As the extraction of hydrocarbons is associated with the risk of fire and explosion, it is necessary to carry out preliminary measures to limit the scope of a possible accident. In an underground working area, which is an excavation below the earth's surface, an accident involving the blowout of hydrocarbons will have an additional consequence in relation to the extraction of hydrocarbons that takes place at sea or at the surface of the earth, in that the liquid hydrocarbons will quickly fill up the working area and thereby being very dangerous for people in the work area.

In the American patent US 4,463,987, an extensive tunnel system is shown in connection with the extraction of hydrocarbons. A chamber is shown where the extraction of hydrocarbons takes place, a tunnel leading from the chamber to a second chamber. From the second chamber, a tunnel is arranged to a pump chamber where a pump is arranged which pumps hydrocarbons to an ordinary outlet for hydrocarbons in the system. The problem with this system is that it must be made very large and extensive to avoid that rock and other loose material that is dragged with the hydrocarbons into the tunnel and the second chamber during a blowout will quickly fill up and close the openings to the pump chamber and/or the tunnel from the tunnel into the other chamber. As the system of tunnels and chambers must be made large, it is also expensive to make.

It is therefore an aim of the present invention to produce a device which can take care of liquid hydrocarbons and water in an underground activity area which is not burdened with the disadvantages of known technology in the area.

This purpose is achieved with a collection device as defined in claim 1 and a system for handling liquid hydrocarbons and water as defined in claim 6, as well as an application of the collection device as defined in claim 16 and an application of the system for handling liquid hydrocarbons and water which defined in claim 17. Preferred embodiments of the collection device and the system for handling liquid hydrocarbons and water are defined in the independent claims 2-5 and 7-15.

A collection device is thus provided for the collection of liquid hydrocarbons and/or water in an underground activity area, where the collection device comprises at least one collection shaft for the collection of liquid hydrocarbons and water. The collection shaft includes an opening that opens into the activity area and extends into the ground from the opening. The at least one collection shaft further comprises at least one superstructure which is arranged above and covers the at least one collection shaft's opening towards the activity area, where the superstructure is provided with openings for fluid flow. The openings preferably have a size that is dimensioned so that loose objects above a given size cannot pass through at least one of the superstructure's openings in the event of an uncontrolled blowout.

The at least one superstructure can, for example, be designed with a solid structure made of steel or similar, which is dimensioned for powerful explosions that can be expected in the worst case if a blowout of hydrocarbons or an explosion were to occur. A strong grid or netting is arranged above the structure, which are also sized to withstand a blowout or an explosion in the activity area. However, the openings must be large enough that the hydrocarbons can be released through the superstructure and collected in the collection shaft. The superstructure can of course also be designed in other ways if desired.

In one embodiment of the invention, the collection device comprises two superstructures, an inner superstructure and an outer superstructure, where the outer superstructure is arranged on the outside of the inner superstructure with a distance between the inner superstructure and the outer superstructure. This provides two barriers and thus additional safety in the event of an accident.

The superstructures can, as mentioned above, comprise a grid or a mesh through which liquid hydrocarbons and water can flow, but which stops loose objects above a given size that follow or are dragged along with the fluid flow.

The openings for fluid flow in the outer superstructure are preferably larger than the openings for fluid flow in the inner superstructure. In other words, if a lattice or mesh is used in the construction of the superstructures, then the lattice or mesh in the inner superstructure is more finely meshed than the lattice or mesh in the outer superstructure.

By arranging the superstructures with grids of different mesh widths where the mesh width of the grid of the inner superstructure is the smallest and that the mesh width of the grids increases successively from the inner superstructure and outwards to the outer superstructure, the coarser-mesh outer superstructure will stop larger stones, blocks and other large objects such as drilling equipment and the like, and let through smaller rock and hydrocarbons and water. The smaller openings in the inner superstructure will in turn stop most of the rock that escapes through the outer superstructure and let through liquid hydrocarbons and water that are collected in the collection shaft.

A system is also provided for handling liquid hydrocarbons in the event of a blowout in an underground activity area as well as handling water that penetrates into the underground activity area where the system includes

- at least one collection shaft for the collection of liquid hydrocarbons and water, where the collection shaft comprises an opening that opens into the activity area, and where the collection shaft extends into the ground from the collection shaft

opening;

- at least one pump shaft that is protected against the inflow of liquid hydrocarbons and water from the activity area, where at least one pump is arranged in the pump shaft for pumping out liquid hydrocarbons and water

through at least one drainage channel; - a connecting tunnel between the collection shaft and the pump shaft so that there is fluid communication between the collection shaft and the pump shaft; - at least one superstructure covering the opening of the at least one collection shaft, where the superstructure is provided with openings for fluid flow, where the openings have a size that is dimensioned so that loose objects over a given size cannot pass through the at least one superstructure's openings.

A connecting tunnel can be arranged between a lower part of the collection shaft and the pump shaft.

In one embodiment of the invention, the system comprises two superstructures above the collection shaft, an inner superstructure and an outer superstructure, where the outer superstructure is arranged on the outside of and at a distance from the inner superstructure. This distance must be so large that between the two superstructures there is at least room for some stone and other loose material of such a size that the stone and/or loose material can pass through the opening on the outer superstructure in the event of an accident.

The openings for fluid flow in the outer superstructure are preferably larger than the openings for fluid flow in the inner superstructure. Thereby, the outer superstructure stops the largest stones and other large loose objects in the event of an accident, while the inner superstructure stops most of the stones and loose material that escape through the outer superstructure.

In one embodiment of the invention, the at least one superstructure comprises a grid or a mesh through which liquid hydrocarbons and water can flow.

In a further embodiment, the system is arranged with two or more superstructures where the superstructures are arranged with grids of different mesh widths where the mesh width of the grid of the inner superstructure is the smallest and where the mesh width of the grids increases successively from the inner superstructure and outwards to the outer superstructure. Again, such an increasing mesh size of the grids from the innermost superstructure onwards will mean that the largest boulders and stones are stopped by the outer superstructure, while progressively smaller stones will be stopped by internal superstructures which are equipped with grids that have a progressively smaller mesh size.

In a preferred embodiment of the invention, the collection shaft extends further into the ground than the connecting tunnel so that a recess is formed where loose material such as loose gravel and pebbles, which escapes through the at least one superstructure, can be collected without blocking fluid flow into or out of the connecting tunnel .

In a preferred embodiment of the invention, a double barrier comprising two barriers is arranged above the pump shaft, where each individual barrier in the double barrier is individually designed to be able to withstand fire and explosions that could occur in the activity area in the event of an uncontrolled blowout of hydrocarbons.

In the double barrier, there is preferably arranged at least one pair of corresponding hatches so that the at least one pump can be introduced into or removed from the at least one pump shaft. This makes it easier to carry out maintenance work on the pumps and to replace pumps if necessary.

From the pump shaft, hydrocarbons and water are pumped, which are collected in the collection shaft and which then flow into the pump shaft, out through an outlet channel, outlet pipe or the like, which leads away from the activity area.

The at least one pump shaft can also be arranged with a level meter for recording the amount of fluid in the at least one pump shaft and a control system which, on the basis of measurement data registered by the level meter, regulates the at least one pump so that the fluid quantity in the at least one pump shaft is kept between a upper level and a lower level. By regulating the amount of fluid that is pumped at all times in this way, you avoid the pump or pumps suddenly running dry.

In a further embodiment of the invention, a solid wall is arranged around the outer superstructure to stop the largest objects. This avoids damaging the superstructures. The height of such a solid wall can correspond to the outer superstructure or possibly somewhat higher or somewhat lower than the outer superstructure.

The superstructures can be made with different shapes. The superstructure can, for example, be given a rectangular design or a curved design, for example a hemispherical shape.

In one embodiment of the invention, the connection tunnel is further equipped with a filter to prevent stones and other smaller objects from joining the flow of fluid into the pump shaft.

In what follows, two non-limiting embodiments of the invention will be described with reference to the figures, where

Figure 1 shows a sketch of a first embodiment of the invention,

Figure 2 shows a sketch of a second embodiment of the invention.

Figure 1 shows an activity area 10. This can be an area under the earth's surface where extraction of hydrocarbons takes place or in another enclosed area where there is a risk of explosions, blowouts or similar accidents that can cause major damage to people working in the activity area 10 and destruction of equipment located in the activity area 10. A blowout of hydrocarbons can also cause environmental damage even if the activity area where the extraction of the hydrocarbons is located underground, and it is therefore necessary to have a device that can collect hydrocarbons in the event of a blowout or another serious accident.

The collection device comprises a collection shaft 14 that extends down into the ground 12 from the activity area 10. The floor or ground in the activity area 10 can advantageously be designed so that it slopes somewhat in the direction of a collection shaft 14, or possibly several collection shafts 14 spread out in the activity area 10. that the floor or ground leans towards the collection shaft or shafts 14, hydrocarbons and/or water will automatically be directed towards the collection shafts 14. A superstructure 37 is arranged above the collection shaft 14. This superstructure includes openings that are of such a size that only stone and other objects underneath a given size will slip through. The superstructure 37 can be designed with a door 24 so that it is possible to enter the inside of the superstructure so that necessary maintenance work can be carried out. A sprinkler system 32 with nozzles 34 can advantageously be arranged above the superstructure 37. This sprinkler system can of course extend further than just above the superstructure 37 if desired.

The collection device further comprises a pump shaft 19 which is arranged near the collection shaft 14. The pump shaft 19 also extends into the ground from the ground/floor in the activity area 10, and can have approximately the same depth as the collection shaft 14. The pump shaft 19 is equipped with at least one, but preferably at least two pumps 26. By equipping the pump shaft with two or more pumps, one has at least one pump 26 in reserve should one of the pumps be destroyed. The pump or pumps 26 are preferably sized so that they can remove an expected amount of liquid hydrocarbons in the event of an accident. This avoids having to build large collection facilities for hydrocarbons. The pump or pumps 26 are connected to one or more outlet channels 30 through which the fluid 15 is pumped from the pump shaft 19.

Between the collection shaft 14 and the pump shaft 19, a connecting tunnel 16 is arranged which connects the collection shaft 14 and the pump shaft 19. A fluid 15 which is collected in the collection shaft 14 will therefore flow further into the pump shaft 19, as indicated by the arrows 18, and settle on essentially the same level in both shafts 14, 19 as shown in the figures.

A double barrier 27 comprising an inner barrier 41 and an outer barrier 40 is arranged above the pump shaft 19, both of which are dimensioned so that they can withstand explosions that can be expected in the event of an accident in the activity area in question 10. The outer barrier 40 is designed with a door 31 for access to the pump shaft where the pumps 26 are located, so that necessary maintenance work can be carried out on the pumps 26. The outer barrier 40 and the inner barrier 41 are further designed with an outer hatch 28 and an inner hatch 29, respectively, so that the pumps 26 can be taken out of or inserted into the pump shaft 19. This is indicated by the fact that a pump 26' is dotted and on its way out/in through the hatches 28, 29 in the figures.

Figure 2 shows an almost identical embodiment of the present invention. However, this embodiment is designed with two superstructures, an outer superstructure 37 and an inner superstructure 38. The outer superstructure 37 is thus designed with openings that are larger than the openings in the inner superstructure 38. The outer superstructure is furthermore preferably designed so that there space between the outer superstructure 37 and the inner superstructure 38 where stones and other objects that are small enough to be able to pass through the openings in the outer superstructure 37, but too large to be able to pass through the openings in the inner superstructure 38, can find space.

Apart from the fact that the embodiment shown in Figure 2 is designed with two superstructures 37, 38 instead of only one superstructure, the two embodiments shown in Figures 1 and 2 are essentially similar, and a repetition of the features of the present the invention which has already been described above in connection with the embodiment in figure 1, will not be repeated here.

At the bottom of the collection shaft, a recess 39 is arranged. This recess 39 extends from the connection tunnel 16 and further into the ground. Pebbles, loose gravel and other small objects that have passed through all the superstructures 37, 38 will sink down through the fluid 15, i.e. the hydrocarbons and the water, which are collected in the collection shaft 14 and collect in the recess 39. By means of such a recess 39 avoids man that the connecting tunnel 16 is blocked by small gravel and other loose material that is so small that it can pass through the openings in the superstructures 37, 38.

Two embodiments of the present invention with a collection shaft and a pump shaft are described above. A person skilled in the field will naturally understand that two or more collection shafts can be arranged with an associated connecting tunnel, or connecting tunnels, to one or more pump shafts. It is of course also possible to arrange the collection shaft, or possibly the collection shafts, with more than two superstructures, even though only one and two superstructures are respectively shown in the two embodiments described above.

Claims (17)

1. Collection device for the collection of liquid hydrocarbons and/or water in an underground activity area (10) comprising at least one collection shaft (14) for the collection of liquid hydrocarbons and water, characterized in that the collection shaft (14) extends into the ground (12) and comprises an opening (13) which opens into the activity area (10), and that the at least one collection shaft (14) further comprises at least one superstructure (20, 22) which is arranged above and covers the opening (13) of the at least one collection shaft towards the activity area (10), which superstructure (20, 22) is provided with openings for fluid flow, where the openings have a size that is dimensioned so that loose objects above a given size cannot pass through the openings of at least one superstructure (20, 22). 2. Collection device according to requirement 1, characterized in that the collection device comprises two superstructures, an inner superstructure (22) and an outer superstructure (20), where the outer superstructure (20) is arranged on the outside of the inner superstructure (22) with a distance between the inner superstructure and the outer overbuilt. 3. Collection device according to requirement 2, characterized in that the dimension of the openings for fluid flow in the outer superstructure (20) is larger than the dimension of the openings for fluid flow in the inner superstructure (22), whereby larger objects are stopped by the outer superstructure (20) while smaller objects are stopped by the inner superstructure ( 22). 4. Collection device according to one of the requirements 2-3, characterized in that the superstructures (20, 22) comprise a grid (37, 38) or a mesh through which fluids, such as hydrocarbons and/or water, can flow. 5. Collection device according to requirement 4, characterized in that the superstructures (20, 22) are arranged with grids or meshes (37, 38) with different mesh sizes where the mesh size of the inner grid or the inner mesh (38) of the inner superstructure (22) is the smallest and that the mesh size of the grids or the netting increases successively from the inner superstructure (22) and outwards onto the external superstructure (20). 6. System for handling liquid fluids, such as hydrocarbons and/or water penetrating into the underground activity area (10), which system comprises at least one collection shaft (14) for collecting liquid fluids, such as liquid hydrocarbons and/or water , characterized in that the collection shaft (14) extends down into the ground (12) and comprises an opening (13) which opens into the activity area (10), and that the system further comprises; - at least one pump shaft (19) which is protected against inflow of liquid hydrocarbons and/or water from the activity area (10), in which pump shaft (19) at least one pump (26, 26') is arranged for pumping out liquid hydrocarbons and water through at least one drainage channel (30); - a connecting tunnel (16) between the collection shaft (14) and the pump shaft (19) so that there is fluid communication between the collection shaft (14) and the pump shaft (19); - at least one superstructure (20, 22) which covers the opening (13) of the at least one collection shaft, which at least one superstructure (20, 22) is provided with openings for fluid flow, where the openings have a size that is dimensioned so that loose objects over a given size cannot pass through at least one of the superstructure's (20, 22) openings. 7. System according to claim 6, characterized in that the system comprises two superstructures, an inner superstructure (22) and an outer superstructure (20), which is arranged above the collection shaft (14), where the outer superstructure (20) is arranged on the outside of and at a distance from the inner superstructure (22). 8. System according to claim 7, characterized in that the openings for fluid flow in the outer superstructure (20) are larger than the openings for fluid flow in the inner superstructure (22). 9. System according to one of claims 6-8, characterized in that the at least one superstructure (20, 22) comprises a grid or a mesh (37, 38) through which liquid hydrocarbons and water can flow. 10. System according to claim 6, characterized in that the system is arranged with two or more superstructures (20, 22), where the superstructures (20, 22) are arranged with grids or meshes (37, 38) with different mesh sizes, where the mesh size of the inner grid or the inner mesh (38 ) to the inner superstructure 22) is smallest and that the mesh width of the grids or netting (37, 38) increases successively from the inner superstructure (22) and outwards to the external superstructure (20). 11. System according to one of claims 6-10, characterized in that the collection shaft (14) extends further into the ground (12) than the connecting tunnel (16) so that a recess (39) is formed so that mass such as gravel and pebbles, which escapes through the at least one superstructure (20, 22) , can be collected at the bottom of the collection shaft (14) without blocking fluid flow into or out of the connecting tunnel (16). 12. System according to one of claims 6-11, characterized in that above the pump shaft (14) a double barrier (27) comprising two barriers (40, 41) is arranged, where each individual barrier in the double barrier (27) is individually designed to be able to withstand fire and explosions that may occur in the activity area (10) by an uncontrolled blowout of hydrocarbons. 13. System according to claim 12, characterized in that the double barrier (27) is arranged with at least one pair of corresponding hatches (28, 29) through which the at least one pump (26, 26') can be introduced into or removed from the at least one pump shaft (19). 14. System according to one of claims 6-13, characterized in that the at least one pump shaft (19) is arranged with a level gauge for recording the amount of fluid in the at least one pump shaft (19) and a control system which, on the basis of measurement data registered by the level gauge, regulates the at least one pump (26, 26 ') so that the amount of fluid in the at least one pump shaft (19) is kept between a given upper level and a given lower level. 15. System according to one of claims 6-14, characterized in that the connecting tunnel (16) extends between a lower part of the collection shaft (14) and a lower part of the pump shaft (19). 16. Use of a collection device according to one of claims 1-5 in connection with an underground activity area (10) where extraction of hydrocarbons takes place. 17. Application of a system for handling liquid fluids according to one of claims 6-15 in connection with an underground activity area (10) where extraction of hydrocarbons takes place.