NO329529B1 - Collection device and method using the same - Google Patents

Abstract

The present invention relates to a collection device (1) for solid material and fluid which is led from a first location on a seabed, on an offshore installation or on land and to a second location, where the fluid leads the solid material into through an inlet part (7) in a solid collection device ( 1') which is provided with one or more permeable parts designed to retain solid material that exceeds a predetermined size, where the collection device (1) is further provided with a fluid collection device (1'') which is designed to be able to collect in the at least a proportion of the fluid that evacuates out through the solids collection device (1'). The invention also relates to a method of using the collection device (1).

Description

COLLECTION DEVICE AND PROCEDURE WHEN USING THE SAME

The present invention relates to a collection device and a method using the same. More specifically, it concerns a collection device for solid material and fluid that is led from a first location on a seabed, on an offshore installation or on land, and to a second location, where the fluid leads the solid material into through an inlet section in a solid collection device that is provided with one or more permeable portions adapted to retain solid material exceeding a predetermined size.

When digging or drilling in the ground on a seabed or on land, mass is loosened that must be removed from the digging or drilling area. During handling, the loosened mass could represent a disadvantage as it could spread to the surrounding environment.

When drilling the top hole section of a petroleum well on the seabed, it is known from Norwegian patent document NO 320113, whose owner is the same as the applicant of the present invention, a method and collection device for removing water-containing drilling cuttings that is returned from a drill hole's top section. The drilling cuttings are pumped into a collection device which is then raised to the sea surface and aboard a vessel. The collection device is provided with draining properties so that liquid is drained from the collection device when it is hoisted aboard the vessel.

Although the collection device and the procedure have been shown to function satisfactorily, it is plagued with certain disadvantages. One of these disadvantages relates to the fact that, especially when raising the collection device from the seabed up to the vessel, the fines that are in the collection device together with the drill cuttings, could be drained out of the collection device together with the liquid. The fine matter and liquid that is drained out could represent a pollution problem. Another disadvantage relates to the capacity of the collection device. Due to the fact that the collection device must be able to be hoisted aboard a vessel, its size is limited to a typical 25 m<3>. The collection device must therefore be relatively frequently connected to and from the pump device and the lifting device that brings the collection device up to the surface. Such handling on the seabed is usually carried out using a so-called ROV (remotely operated underwater vessel) which is relatively expensive to operate. In addition, it is expensive to transport the cuttings to land for further processing and disposal.

When dredging, for example, a seabed, there is sometimes no need, or there may be a requirement, for the mass to be removed from the bottom. However, it is in the nature of the matter that the mass must be moved from a first area to a second area on the seabed. It is known that this movement of mass is carried out by pumping the mass away from the area from which the mass is removed. A significant disadvantage of this type of dredging operation is that large areas downstream of the dredging operation are covered by the mass. This mass could damage the benthic fauna. In some places, there is therefore a requirement that dredged mass, or mass that is removed in other ways, must be pumped ashore for possible cleaning and disposal in approved landfills. This is a very expensive operation.

When depositing residual waste from the mining or processing industry, it is known to place this in open landfills on land or in the sea. In cases where such residual waste includes fine particles, it turns out to be problematic to prevent the spread of the residual waste to surrounding areas. The problem is particularly great while the movement of the mass is in progress.

From Norwegian patent application NO 20076546 belonging to the present applicant, and which is fully incorporated into the present application, a collection device for solid material is known which is moved with the help of a fluid from a first location on the seabed, on an offshore installation or on land and to another place, and where the fluid leads the solid material into through an inlet part to the collection device, and where the collection device is provided with one or more permeable parts designed to hold back solid material that exceeds a predetermined size.

The collection device according to NO 20076546 has been shown to function very satisfactorily with respect to being able to collect solid material and to a large extent solves the disadvantages pointed out in the known technique represented by the aforementioned Norwegian patent NO 320113.

However, the applicant has learned that there will sometimes be a need or desire to be able to clean at least a proportion of the fluid used to guide the solid particles into the collection devices according to the above-mentioned known technique, before it is released into the environment. The need for cleaning may, for example, be due to chemicals or other components added to the fluid, as this leads the solid particles into the collection device and/or the need for cleaning may be due, for example, to the fluid itself having added components that are considered polluting or to the fact that it is contaminated by substances that is released into the fluid from the solid.

From the publication NO 173521, an underwater storage construction for the treatment and storage of drilling cuttings from drilling reoperations in a seabed is known. The construction includes a generally closed tank adapted to be placed on the seabed near the drilling site. The tank is arranged with an upper inlet for the supply of drilling cuttings, as well as an outlet to the surrounding sea for water that is displaced during the supply of drilling cuttings. The tank contains means for cleaning the drilling cuttings, as well as for storing accumulated separated oil, fluids and other components that are separated from the drilling cuttings. Furthermore, the construction includes means for removing accumulated oil, fluids and other components which are lighter than water and which will gradually be released from the deposited drill cuttings.

The purpose of the invention is to remedy or to reduce at least one of the disadvantages of known technology.

The purpose is achieved by features which are indicated in the description below and in subsequent patent claims.

In a first aspect of the present invention, a collection device for solid material and fluid is provided which is led from a first location on a seabed, on an offshore installation or on land and to a second location, where the fluid leads the solid material into through an inlet part in a solid material collection device which is provided with one or more permeable parts designed to retain solid material that exceeds a predetermined size, characterized in that the collection device is further provided with a fluid collection device that is designed to be able to collect at least a portion of the fluid that flows out through the solid material collection device , and that the fluid collection device is connected to a fluid processing facility.

In this document, offshore installation means a fixed or floating installation such as a rig, or a floating vessel such as a ship or a barge.

The fluid processing facility can, for example, but not be limited to, consist of one or a combination of a fluid sampling and analysis facility, a purification facility, or a storage facility. By taking samples of the fluid that is in the fluid collection container, it can be determined whether the fluid is clean enough to be returned to the environment, which may for example be the sea, or whether the fluid must be directed to a purification plant to undergo a purification before possibly entering -return to the surroundings. In some cases, for example if the fluid is particularly heavily contaminated, it may be appropriate to put the fluid into storage containers which can then be taken to suitable treatment facilities.

In one embodiment, the fluid processing facility, or at least parts of it, is placed adjacent to the collection device. In one embodiment, all or parts of the fluid processing facility are placed at a distance from the collection device. In the latter embodiment, the fluid is led between the collection device and the fluid processing facility by means of a line.

In one embodiment, the fluid collection device is made of an elastic material so that the fluid collection device will be able to undergo a volume change as fluid flows into it.

It is an advantage if the fluid collection device is made from a degradable material.

The fluid collection device is most preferably produced from a

material that is fluid-tight, although for some areas of use it may be acceptable if some of the fluid is able to seep through the fluid collection device. When using the fluid collection device in areas where there is a desire or requirement for so-

called "zero emissions", such as for the oil extraction industry at sea in particularly vulnerable areas, a fluid-tight collection device may be necessary.

The solids collection device can be any device suitable for holding solids that are supplied, but is preferably of the type shown in the aforementioned Norwegian patent document NO 320113 and most preferably of the type described in the aforementioned Norwegian patent application NO 20076546.

In a preferred embodiment, the solids collection device consists of a container. The container is preferably closed, at least initially, in the sense that it provides at least one space which is designed to be able to keep solid material above a predetermined size back from the surroundings outside the container.

In one embodiment, the at least one permeable part of the solid matter collection device has an increasing degree of permeability in a direction from the inlet part and towards one or more parts at a distance from the collection device's inlet part.

The increasing degree of permeability is provided in one embodiment by means of changing the size of openings in the wall part of the collection device. As an alternative or addition to said changed sizes, the increasing degree of permeability can be provided by increasing the size of the permeable wall portions.

In one embodiment, the at least one permeable part of the solid matter collection device is provided with openings of a first size, where at a distance from the inlet part there is at least one outlet opening which has an opening of a second size, the first size being smaller than the other size. In one embodiment, the outlet opening is constituted by an open part which is arranged to be able to evacuate or flow substantially the same fluid rate as is pumped into the solids collection device. The fluid that flows out through the solids collection device, through the outlet opening and/or the permeable parts, flows into the fluid collection device.

In one embodiment, at least one of the at least one permeable portion is provided with openings that are 100 µm or less, preferably 50 µm or less.

The above-mentioned increasing degree of permeability and/or increased size of the outlet opening(s) has the effect that the fluid which leads the solid material in through the inlet part of the solid material collection device will encounter less and less resistance to evacuation or flow out of the solid material collection device and into the fluid collection device the further away from the inlet part where the fluid is located. Thus, the fluid that leads the solid particles into the solids collection device will be able to flow the longest possible distance inside the solids collection device before it is evacuated. Consequently, the essential part of the fine matter will also be able to sediment in the solid matter collection device before the fluid flows out of it and into the fluid collection device.

Another important consequence of providing the above-mentioned increasing degree of permeability and/or outlet openings is that the collection device will be able to be placed packed together, for example folded or rolled up, at the place where it is to receive the solid material. Such packing requires that the solids collection device is made of, for example, a cloth-like material or is constructed so that it can be unfolded from a packed position to a fully unfolded position.

The fluid which is led into the above-mentioned solids collection device made of, for example, a cloth-like material, will initially flow out through the permeable part or parts which are located closest to the inlet part. Some of the solid particles retained by the permeable part will eventually clog the openings in it. Consequently, the fluid will move further away from the adjacent, but now densely permeable part(s). The result is that the fluid causes an inflation or expansion of the collection device as fluid and solid particles are introduced through the inlet section.

In one embodiment, the solids collection device is provided with at least one internal flow limiting device. The at least one flow-limiting device helps, among other things, to reduce the fluid's flow rate inside the solids collection device and thus contributes to an increased degree of sedimentation of the fluid's solids particles. The at least one flow restriction will also be able to contribute to increased dimensional stability and to increase the solids collection device's mechanical strength.

In one embodiment, at least parts of the material of the solids collection device, such as the material of the fluid collection container can also be, are produced from a biodegradable material. This has the effect that the mass that has been fed into the solid matter collection device will be exposed after a while and a natural fauna on a seabed or on land will be able to develop.

In another aspect of the present invention, a method is provided for the collection of solid material and fluid which is led from a first location on a seabed or on land and to a second location, where the method includes placing a collection device that includes a solid material collection device and a fluid collection device at said second location, where the solids collection device is provided with one or more permeable parts designed to hold back solid material above a predetermined size, and where the fluid collection device is designed to be able to collect at least a portion of the fluid that flows more out through the solids collection device and where the fluid that is collected in the fluid collection device is led to a fluid processing facility.

In the following, an example of a preferred embodiment is described which is visualized in the accompanying drawing, where: Fig. 1 shows a dredging operation that takes place on a seabed, where the mud masses are pumped via a line from a dredging machine into a collection device, where the collection device comprises a solids collection device enclosed by a fluid collection device.

In the figure, the reference number 1 denotes a collection device according to the present invention, where the collection device 1 consists of a solids collection device 1' which is enclosed by a fluid collection device 1''. The fluid collection device 1'' encloses the entire solids collection device 1'. However, it should be understood that the fluid collection device 1'' in alternative designs only encloses parts of the solids collection device 1'. The fluid collection device 1'' does not, for example, need, but may like, to enclose any dense parts of the solids collection device or parts that abut against the ground.

A line 3 protrudes between an inlet part 7 placed on an upper part of the solids collection device 1', and a per se known dredging machine 5. The line 3 projects in the embodiment shown through the wall part of the fluid collection device 1'' and down to the inlet part 7.

The mud machine 5 is provided with a suction pipe 5' which sucks mud mass and water, where the mud mass and water are pumped via the line 3 and into the collection device 1's solid matter collection device 1'. A person skilled in the art will understand that one or more pump devices (not shown) will be able to be connected to line 3.

The shown solids collection device 1' is of a type that is shown in the applicant's aforementioned patent application NO 2 0076546 which is fully included in this document, and will therefore not be discussed in any particular detail in this design example.

When the fluid from the dredging machine 5 is supplied to the collection device 1, the water that drives the mud mass will be able to evacuate or flow out through the solid material collection device 1' permeable wall sections and into the fluid collection device 1''.

In the embodiment shown, the solid matter collection device 1' is provided in an end portion distally or at a distance from the inlet portion 7 with an outlet opening 11 which is shown in an embodiment where part of the wall of the solid matter collection device 1' is provided with a recess. In an alternative embodiment (not shown), the outlet opening can be made up of one or more parts with greater permeability than all or parts of the rest of the solids collection device 1'.

A collection device 1 according to the invention can be produced in a great many different sizes according to need, material strength and any statutory limitations such as height limitations for so-called trawlability. During operations on the seabed, tests have shown that a collection device 1 with a length of 30 - 50 m and a width or diameter

of 10 - 20 m has proven suitable.

As a person skilled in the art will understand, the coarsest material is deposited below or near the inlet portion 7 of the solids collection device 1', while the material transported inside the solids collection device 1' will become finer and finer in the direction towards the outlet opening 11.

The fluid that flows out through the outlet opening 11 and or through the permeable wall parts of the solids container 1' will flow into the enclosing fluid collection device 1''.

From an outlet 18 in the fluid collection collection device 1'', a line 19, 20 projects up to a surface. The line 19, 20 is designed to be able to lead fluid to a fluid processing facility not shown. The fluid processing facility can, for example, be one of or a combination of a fluid sampling and analysis facility, a purification facility, or a storage facility. The storage facility can, for example, consist of one or more transport containers.

Samples of the fluid located in the fluid collection device 1'' can thus be taken to the fluid processing facility for analysis by means known per se.

The fluid processing facility, or parts of it, can in an alternative embodiment (not shown) be located at the collection device 1. In such an embodiment, the analysis result can be communicated in a manner known per se to, for example, a control room on an offshore installation, from where further handling of the fluid located in the fluid collection device 1'' is controlled.

If the analyzes show that the fluid in the fluid collection device 1'' is sufficiently clean to be able to be drained out into the bodies of water outside the collection device 1, such drainage is carried out through an outlet line 22 placed in connection with the fluid collection device 1''.

If the analyzes of the samples show that the fluid is not sufficiently clean to be able to be drained out into the bodies of water, for example because the fluid contains too much fine matter, or that other conditions indicate that the fluid cannot be drained out into the bodies of water, the fluid can be recycled using a pump-in - direction 20' from the fluid collection collection device 1'' outlet part 18, via line 19, 24 and 3 and back to the solid matter collection device 1' so that a further proportion of the fines can be sedimented in the solid matter collection device 1'.

It should be understood that the fluid flow to the lines 19, 20, 22, 24 is controlled by means of valves known per se which, for reasons of clarity, are not shown in the figure.

To increase the precipitation of fine matter, a binding or precipitating agent can be added to the fluid which contributes to particulate

substance that appears dispersed in the liquid phase will flocculate so that the particles are collected into larger and heavier particles which will thus cause a faster and more efficient separation and sedimentation of the solid. The binder is preferably an environmentally friendly chemical of a known nature. Most preferably, the binder is an organic binder.

The binder is injected via a line 17 into the supply line 3 upstream of the inlet opening 7. A person skilled in the art will understand that the binder can also be injected into the line 24.

If the analyzes of the samples show that the fluid is not sufficiently clean to be able to be drained out into the bodies of water, for example due to the content of an unacceptable level of environmentally harmful substances, the fluid can be directed in the line 19, 20 with the help of the pump 20' to a not shown treatment plant placed for example on an offshore installation. After cleaning at the off-shore installation, the fluid can be returned to the sea.

It is also conceivable that the fluid is led from the fluid collection collection device 1'' and to containers (not shown) in which the fluid is brought to a fluid processing facility on land.

Samples of the fluid located in the fluid collection device 1'' can, for example, be obtained continuously or at fixed intervals.

When the solids collection device 1' is sufficiently filled, the lines 3 and 19 are removed, for example with the help of an ROV, from the inlet part 7 and the outlet part 18, respectively, and a new collection device is optionally connected as described in the aforementioned Norwegian patent application NO 20076546

The figure shows an embodiment of the solids collection device 1' where two cross walls 13, 13' are placed inside the collection device 1 and across its longitudinal direction between the inlet part 7 and the outlet opening 11. The cross wall 13, which is located closest to the inlet part 7, projects from the bottom part of the solids collection device 1' and about halfway up towards the summit. The transverse wall 13', which is closest to the outlet opening 11, covers the entire internal cross-section of the solids collection device 1'.

It should be understood that any number of cross walls 13, 13' can be placed inside the solids collection device 1', although two are shown in Figure 1. Furthermore, it should be understood that the cross walls 13, 13' can be placed at any desired angle in relation to said longitudinal direction. The transverse walls 13, 13' have two purposes. Firstly, the transverse walls 13, 13' will function as stiffening elements which reinforce the wall parts of the solids collection device 1'. Secondly, the transverse walls 13, 13', depending on their permeability, will be able to function as a flow restriction and thus delimit chambers in the solids collection device 1'. The chambers will be able to facilitate inflation of the collection device 1 and at the same time cause a reduced flow rate of the fluid. A reduced flow rate will result in an even longer residence time for the fluid in the solids collection device 1' and thus sedimentation of fines closer to the inlet opening 7 compared to a collection device 1 without cross walls 13, 13'.

It should be understood that the cross walls 13, 13' can cover all or only parts of a cross-sectional area of the solids collection device 1'.

It should be understood that the collection device 1 will be able to be connected to already existing systems (not shown) designed to be able to separate sand from well production, a so-called "Sub sea sand separator" (underwater sand separator).

The present invention thus provides a collection device 1 which is designed to both filter solid particles from a fluid, while also collecting the fluid before it is released into the surrounding environment, possibly after a cleaning process.

Claims (10)

1. Collection device (1) for solid material and fluid which is led from a first place on a seabed, on an offshore installation or on land and to a second place, where the fluid leads the solid material into through an inlet part (7) in a solid material collection device (1') which is provided with one or more permeable parts designed to retain solid material that exceeds a predetermined size, characterized in that the collection device (1) is further provided with a fluid collection device (1'') which is designed to be able to collect at least a proportion of the fluid that flows out through the solids collection device (1'), and that the fluid collection device (1'') is connected to a fluid processing facility. 2. Collection device according to claim 1, where the fluid processing facility consists of one or a combination of a fluid sampling and analysis facility, a purification facility or a storage facility. 3. Collection device according to claim 1 or 2, where the fluid processing facility is placed at a distance from the collection device (1) and that the fluid is led between the collection device (1) and the fluid processing facility by means of a line (19, 20). 4. Collection device according to claim 1, where the fluid collection device (1'') is made of an elastic material. 5. Collection device according to any one of the preceding claims, where the fluid collection device (1'') is made of a degradable material. 6. Collection device according to any one of the preceding claims, where the fluid collection device (1'') is fluid-tight. 7. Method for collecting solid material and fluid which is led from a first location on a seabed or on land and to a second location, characterized in that the method includes placing a collection device (1) which includes a solid material collection device (1') and a fluid collection 1ing device (1'') at said second place, where the solid matter collection device (1'') is provided with one or more permeable parts designed to hold back solid material above a predetermined size, and where the fluid collection device (1'') is designed to to be able to collect at least a portion of the fluid that flows out through the solid matter collection device (1') and where the fluid that is collected in the fluid collection device (1'') is led to a fluid processing facility. 8. Method according to claim 7, where the fluid in the fluid processing facility undergoes a purification. 9. Method according to claim 8, where the method further comprises returning the purified fluid to the environment. 10. Method according to claim 7, wherein the method further comprises recycling the fluid back to the fluid collection device (1'').