NO334394B1 - Multi-way valve with detachable center supply and method for using the multi-way valve - Google Patents

Abstract

Multi-way valve (1) comprising a female portion (2) and a detachable male portion (3), the male portion (3) forming a first end portion (31) and a second end portion (32), the male portion (3) being provided at its center with an axial channel (34), channel (34) has an inlet (35) in the first end portion (31) of the male part (31) and the channel (34) opens into an outlet portion (36) in the outer sheath (33) of the male part (3) between the (3) first end portion (31) and second end portion (32); the female part (2) comprises a housing (20) with a circular inner space (25), the longitudinal axis of the inner space (25) is parallel to the axis (200), the housing (20) is provided with a plurality of bores (26) from the outer surface (23) of the housing (20) to the inner surface (24) of the housing (20), the axis (260) of the bore (26) being substantially radial on the axis (200) of the housing (20), the housing (20) further comprises in its inner space (25) a rotatable sleeve (4) forming a first end portion (41) and a second end portion (42), and having an outer casing surface (43) and an inner casing surface (44), the rotatable sleeve ( 4) axis is coincident with the longitudinal axis of the compartment (25); the sleeve (4) is provided in its wall (45) with one continuous bore (46); the sleeve (4) is adapted to accommodate the male part (3), and the through-bore (46) of the sleeve (4) opens into a spherical portion (48) peripherally surrounding the outer casing surface (43) of the sleeve (4). 4) first end portion (41) and second end portion (42) of sleeve.

Description

MULTI-WAY VALVE WITH REMOVABLE CENTER SUPPLY AND PROCEDURE FOR USING THE MULTI-WAY VALVE

The invention relates to a multi-way valve or a manifold. The invention relates in particular to a manifold for use in underwater operations and which is designed to be operated by a so-called ROV (Remote Operated Vehicle). More particularly, the invention relates to a manifold for use on, or in connection with, the installation and operation of a pipeline on a seabed.

When laying pipelines for the transport of petroleum products on the seabed, it is common for the pipe at its end to be equipped with a removable cap or a sending station for a "pig" ("Pipeline Inspection Gauge"), possibly a receiving station, so-called PLR equipment ("Pig Launcher and Receiver"). This ensures that the pipe is not accidentally filled or emptied during laying and that any "pigs" are ready for use when the pipe has been laid, or that "pigs" can be inserted into or removed from the pipe afterwards. The PLR is usually removed from the end of the pipe after the pipe has been checked and before the pipe is joined with, for example, a riser. Such joining is done with a so-called "spool" as is known in the art.

"Pigs" are driven forward in the pipe by means of a driving medium which is introduced with an excess pressure behind the "pig" to be driven forward. When checking a pipe, there may be several "pigs". For example, the first "pig" may comprise a circular metal disk with a diameter equal to the inner diameter of the pipe. This will record the internal roundness of the pipe. A second "pig" can expel water, and a third "pig" can push a water-absorbing desiccant in front of it.

The propellant, whether gas or liquid, is usually supplied from a surface vessel through a line to the PLR. The PLR usually comprises several pipe branches that open into the end of the pipe at the back of the various "pigs" that lie ready for use. The pipe branches are usually fitted with valves that are opened using an ROV. These valves are located on the side of the pipe and are usually operated by the ROV positioning itself radially in relation to the pipe. This means that the ROV, from a position axially in relation to the pipe, must first set the correct pipe branch on the manifold in the PLR at the end of the pipe, then move along the pipe branch and to the valve and then open it.

When laying the pipe, it cannot always be controlled how the end will "spin" or bend before it comes to rest on the seabed. This means that one or more of the radially oriented valves will be inaccessible to an ROV, as they face down towards the seabed and may be buried in mud. The PLR can therefore often be fitted with a double set of pipe branches to ensure that at least one valve is accessible to an ROV.

Another disadvantage of the known technical solutions for such PLRs is that they have a relatively large diameter in relation to the pipe to which they are attached. The PLR often has to be provided with a protective cover, which helps to increase the diameter. A pipe-laying vessel is equipped with equipment that prevents the pipe from running freely from the deck. Such equipment can be rotating clamping rollers or belts with clamps, so-called "caterpillar tensioners". This equipment will limit the maximum diameter of equipment that can be attached to the pipe or to the end of the pipe and that can pass through the equipment. The size of the PLR can therefore in many cases complicate the last phase when laying a pipe equipped with a PLR in the end section.

Patent document US2002/0053354 shows an example of how an ROV can transport and transfer one or more "pigs" to a magazine for "pigs" in connection with an underwater transmission station for "pigs". The layout for valves and pipes to drive a "pig" in a pipe is also shown schematically. The patent documents US 3674123, WO 95/12464 and WO2005/108831 show alternative solutions for how a "pig" can be sent into or received from one selected pipe among several selectable pipes from one sending station or one receiving station for the "pig".

Within the petroleum industry, it is known to use multi-way valves or manifolds where lines with product flows from, for example, wells meet and are led further into one collecting line. The manifold can be provided with a diverter inside the manifold housing which can optionally connect one of the product streams with a tube for sampling the product stream, while the other product streams flow unhindered into the collection line. Patent documents WO 98/49475 and WO 2005/108831 show examples of such multi-way valves or manifolds. These have in common that a rotatable diverter creates a flow path for the product flow between an outlet in the housing of the test tube and a selected inlet in the housing. The flow direction of the product flow out of the diverter is essentially parallel, but shifted in relation to the flow direction of the product flow into the diverter. The diverter is positioned inside the valve housing and cannot be removed from this without extensive dismantling work which includes disconnecting the housing from the lines that carry product to and from the valve or manifold.

Patent document NO310942 shows a manifold which is adapted for use under water. The manifold comprises a housing which is provided with a number of radial fluid openings through the wall of the housing. The manifold also includes a detachable fluid diverter system which can be axially inserted into the housing and which is attached to it with bolts and nuts. The fluid deflector system comprises a ring element which is provided with radial fluid openings that correspond to the housing's fluid openings. The fluid diverter system further comprises a fluid diverter element inside the ring element and the fluid diverter element is rotatable about the central axis of the manifold. The fluid deflector element is provided with a radially directed inlet and an axially directed outlet. An external actuator, possibly an ROV, can turn the fluid diverter element from one axial end part of the manifold so that the inlet corresponds to one of the inlets in the ring element. The fluid diverter element's axial outlet directs fluid flow out of the manifold's other axial end portion which is opposite the outer actuator. The manifold is particularly suitable for diverting a fluid flow from a manifold in order to be able to test the fluid flow. The fluid deflector element can also be set in a blind position where the radial inlet is directed towards a part of the inner wall of the ring element which is not provided with a radially directed opening. Fluid will then flow through the manifold from one or more inlets and out through one or more outlets and past the outlet of the fluid deflector element on its outside.

Patent document WO89/03002 describes a coupling compound for use in the petroleum industry. The coupling connection consists of a male part and a female part. The wall of the female part forms a circular cavity and the wall is provided with radial bores for a fluid. The bottom part of the cavity is provided with a coupling mechanism. The wall is on the side facing the cavity of the female part, provided with a rotatable first sleeve, hereafter referred to as the female sleeve. The female sleeve forms a rotatable closing element. The female sleeve is slightly conical on the inside with the largest diameter in a part facing the open end of the female part and the smallest diameter in a part facing the bottom part of the cavity. The female sleeve is provided with radial bores. In an open position, the radial bores of the walls will match the radial bores in the female sleeve. When the female sleeve is turned to the closed position, the wall's radial bores will open towards a tight part of the female sleeve. There is also described a packing arrangement with two concentrically arranged packings that concentrically surround the radial bore and a further drop-shaped packing that will surround both the bore in the wall and the bore in the female sleeve when the female sleeve is in the closed position. Thereby, a fluid will not be able to penetrate the annulus which is formed between the wall and the female sleeve. The male part fits complementary to the female part. The male part is made up of a stem which, at one end, is provided with a coupling mechanism designed to be temporarily lockable to the female part's locking mechanism. The male part is provided with radial bores in its mantle which are connected to channels in the stem. The channels extend in part axially in the trunk. A part of the male part's stem proximal to the male part's locking mechanism is surrounded by a rotatable second sleeve, hereafter referred to as the male sleeve. The male sleeve is provided with radial bores. The male sleeve interacts with the stem in basically the same way as the female sleeve interacts with the wall of the female sleeve and can be in an open position and a closed position. Between the stem and the male sleeve, the male part is provided with the same packing arrangement as described above. Thereby, a fluid will not be able to penetrate the annulus which is formed between the stem and the male sleeve. The male sleeve is slightly conical on the outside with the smallest diameter proximal to the locking mechanism of the male part. When the male part's locking mechanism engages with the female part's locking mechanism, the outside of the male sleeve will fit complementary to the inside of the female sleeve. The coupling connection is equipped with a guide so that the radial bores of the female sleeve match the radial bores of the male sleeve. The coupling connection is further provided with ring-shaped packing elements that seal between the radial bores of the female sleeve and the male sleeve. After connecting the coupling connection, the fluid communication between the female part and the male part is opened by simultaneously turning the female sleeve and the male sleeve from a closed position to an open position. Disconnecting takes place by first turning the female sleeve and the male sleeve from an open position to a closed position and then activating the locking mechanism so that the male part can be led out of the female part.

The purpose of the invention is to remedy or to reduce at least one of the disadvantages of known technology, or at least to provide a useful alternative to known technology.

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

The multi-way valve, or manifold, according to the invention, can be used for control, maintenance and cleaning of pipelines on a seabed, also called "pigging". The invention relates to a valve solution and a connection solution which is particularly well suited to making compact and simple PLR systems for use when laying pipes on the seabed.

In a first aspect, the invention relates to a multi-way valve comprising a female part and a detachable male part, the male part forms a first end part and a second end part, the male part is provided in its center with an axial channel, the channel has an inlet in the first end part of the male part and the channel opens firmly out into an outlet part in the male part's outer man tel between the male part's first end part and second end part; the female part comprises a housing with a circular inner space, the longitudinal axis of the inner space is parallel to the axis of the housing, the housing is provided with a plurality of continuous bores from the outer surface of the housing to the inner surface of the housing, where the axis of the drilling is essentially radial to the axis of the housing , the housing further comprises in its inner space a rotatable sleeve with a first end part and a second end part and with an outer mantle surface and an inner mantle surface, the axis of the rotatable sleeve coincides with the longitudinal axis of the room, the sleeve is provided in its wall with one through hole; the sleeve is arranged to be able to house the male part, and where the sleeve's through bore opens into a spherical part which peripherally surrounds the sleeve's outer mantle surface between the sleeve's first end part and the sleeve's second end part.

The sleeve can be 360° rotatable about the axis of the sleeve. The room can be continuous in the house. The through bores of the housing can accommodate a coupling connection, and the coupling connection can, in its part which faces the spherical part of the sleeve, be provided with an annular sealing element which rests against the spherical part of the sleeve.

The sleeve can be provided with an annular positioning collar that projects radially beyond the outer casing surface of the sleeve. The annular positioning ring may comprise a gear ring.

The housing can further comprise a maneuvering element designed to be able to turn the sleeve about the axis of the sleeve. The maneuvering element may be arranged to rotate the positioning ring. The housing can be provided with a window in one end section for reading the position and orientation of the drilling.

The channel can have an axially directed inlet in the first end part of the male part.

The invention also includes a pipeline for the transport of fluids, where the pipeline can be provided in one end section with a multi-way valve as described above. The pipeline may comprise a sending station for a "pig" and/or a receiving station for a "pig".

In a second aspect, the invention relates to a method of controlling a fluid flow from one supply line connected to one inlet to one selected pipe of several possible selectable pipes using a multi-way valve as described above. The method may comprise supplying a sending station for a "pig" and/or a receiving station for a "pig" with a drive medium.

In what follows, an example of a preferred embodiment is described which is visualized in the accompanying drawings, where: Fig. 1 shows a perspective view of a multi-way valve with a detachable male part which is inserted into the multi-way valve's female part; Fig. 2 shows, on the same scale as Fig. 1, a side view of the multi-way valve; Fig. 3 shows, on the same scale, a first section through the multi-way valve as indicated by III-III in figure 2; Fig. 4 shows, on the same scale, a second section through the multi-way valve as indicated by IV-IV in figure 2; Fig. 5 shows on a smaller scale the same as Fig. 3, and where the male part is

shown outside the female part to clarify the assembly; and

Fig. 6 shows, on the same scale as Fig. 1, a side view seen from the multi-way valve

end part.

In the following, the parts of the multi-way valve that are important for understanding the invention are discussed.

In the drawings, reference number 1 shows a multi-way valve according to the invention. The multi-way valve 1 comprises a female part 2 and a detachable male part 3. A male part 3 of this type is known in the field as a so-called "staff".

The female part 2 comprises a housing 20 with a circular inner space 25, see especially figures 3 and 5. The housing 20 is provided with a plurality of through openings 26 from the outer surface 23 of the housing 20 and to the inner surface 24 of the housing, where the axis 260 of the opening 26 in the is essentially radial on the axis 200 of the housing 20. The housing 20 further comprises a rotatable sleeve 4 with a first end part 41 and a second end part 42, with an outer mantle surface 43 and an inner mantle surface 44. The rotatable sleeve 4 is positioned in the inner space 25 The axis of the rotatable sleeve 4 coincides with the axis of the chamber 200. The rotatable sleeve 4 is provided in its wall 45 with one essentially radial, continuous bore 46 from the inner mantle surface 44 and to the outer mantle surface 43, see Figure 4. The bore 46 opens into a spherical part 48 on the outer mantle surface 43. The spherical part 48 extends peripherally around the outer mantle surface 43 between the first end part 41 and the second end part 42. The sleeve 4 is further provided with an annular positioning ring 49 which projects radially beyond the outer casing surface 43, see figures 3 and 5. The positioning ring 49 can be a gear ring 491.

The housing 20 is provided in its end part 21 with a maneuvering element 6. The maneuvering element 6 comprises a rotatable handle 68 and a turntable 62. The maneuvering element 6 is attached to the housing 20 by means of a maneuvering element housing 64. The handle 68 is arranged to turn the turntable 62 about a axis 600, and the axis 600 is essentially parallel to the axis 200 of the housing 20, see Figure 3.

The openings 26 of the housing 20 are provided with coupling connections 5 which can be threadedly attached to the opening 26. The coupling connection 5 forms a fluid-tight connection between a pipe 7 and the housing 20 as is known in the art, and this is not discussed further. The coupling connection 5 is provided with an annular sealing element 58 in its end part 51 which faces the housing 20 room 25. The sealing element 58 can be made up of an O-ring. The sealing element 58 rests against the spherical part 48 of the sleeve 4 and forms a fluid-tight connection between the spherical part 48 and the coupling connection 5 in the end part 51. The person skilled in the art will know that such a fluid-tight connection corresponds to the seal in ball valves.

The male part 3 comprises a first end part 31 and a second end part 32, an outer mantle surface 33 and an inner mantle surface 34. The male part 3 further comprises a central, axial channel 34 with an inlet 35 in the first end part 31 and an outlet 36 in the outer mantle surface 33 between the first end part 31 and the second end part 32. The outlet 36 is formed with at least one radially directed outlet opening 37 in the outer casing surface 33, see figure 5. The outlet opening 37 is formed as an elongated, axially directed opening in the wall 30 of the male part The outlet openings 37 are distributed peripherally around the wall 30, see figure 4. An annular sealing element 39 extends circumferentially around the outer casing surface 33 between the first end portion 31 and the outlet opening 37, and an annular sealing element 39' extends circumferentially around the outer casing surface 33 between the other end part 32 and the outlet opening 37. The male part 3 further comprises a handle 38 which is positioned to the side of the male part's center rack see 300 in the first end part 31, see Figures 1 and 6. The inlet 35 is shown in the figures as an axially directed inlet 35 from the first end part 31.

A supply line (not shown) can be fluid-tightly connected to the inlet 35 in a known manner. The inlet 35 may comprise a threaded part (not shown).

The multi-way valve 1 can be used under water. The pipes 7 can extend from the female part 2 and to a sending station for a "pig" or a receiving station for a "pig", called PLR in an end part of a pipeline (not shown). The tubes 7 can open into different parts of the PLR as is known in the art. An ROV (not shown) holds the male part 3 in the handle 38 and guides the male part 3 into the sleeve 4. A supply line extends from the male part 3 and to, for example, a surface vessel which is equipped with a pump that can pressurize a driving fluid in the line as it is known in the field. After the male part 3 is correctly positioned in the sleeve 4, the handle 38 is released from the ROV's gripping tool (not shown). The ROV's gripping tool is moved to the handle 68 of the maneuver element 6. This distance is small so that the ROV itself does not need to move. A gripping tool turns the handle 68 and thereby turns the sleeve 4. An ROV operator can, for example, use a camera to read the rotation position of the sleeve 4 in a window 29 on the end part 21 of the housing 20. The read marking in the window 29 corresponds to the markings for each pipe 7 as indicated by the pipe number marking 72. Figures 4 and 6 show that the pipe 7 positioned at the pipe number marking 72 marked with the number "3", is in fluid communication with the channel 34 in the male part 3 in that the number "3" is displayed in the window 29, see figure 6. As shown in figure 4, the sleeve 4 is turned so that the bore 46 faces the opening 26 which houses the connecting connection 5 to the pipe 7 which is positioned at the pipe number marking 72 marked with the number "3". The annular sealing element 58 will peripherally surround the bore 46 in the outer casing surface 43 and form a fluid-tight seal between the bore 46 and the pipe 7. The bore 46 has a diameter which corresponds to the inner diameter of the coupling connection 5, which in turn may correspond to the inner diameter in the pipe 7.

The outer jacket 33 of the male part 3 shows in a part at the outlet opening 37 a smaller diameter than a diameter closer to the first end part 31 and the second end part 32, see in particular figure 5. The sleeve 4 shows on its inner jacket surface 44 a larger inner diameter in a peripheral part at the bore 46, than the inner diameter at parts closer to the first end part 41 and the second end part 42, see figures 4 and 5. When the male part 3 is correctly positioned in the sleeve 4, an annular space 80 is formed at the outlet opening 37 and the bore 46 , see figures 3 and 4. The annular space 80 is delimited axially by the sealing elements 39, 39', see figure 5. The annular space 80 has the effect that fluid flowing out of the outlet openings 37 will be led into the bore 46 and that no special radial orientation is required of the outlet openings 37 in relation to the bore 46.

When the handle 68 is turned, the turntable 62 will turn. The turntable 62 can be a toothed wheel. The turntable 62 is in engagement with the positioning ring 49, which can be a gear ring 491. Thereby, the sleeve 4 is turned with the help of the gear ring 491. The outer mantle surface of the sleeve 4 and the inner surface of the housing 20 are not in fluid-tight contact with each other. The sleeve 4 is therefore pressure-balanced positioned in the space 25 in relation to the ambient pressure so that rotation of the sleeve 4 does not require a large torque. The sealing elements 39, 39' will exert a friction between the male part 3 and the inner mantle surface 44. When the sleeve 4 is rotated, the male part 3 will completely or partially rotate together with the sleeve 4. The rotation of the male part 3 will be partially counteracted by the stiffness of the supply line. The person skilled in the art will also know that the male part 3 and the housing 20 can be provided with means (not shown) which keep the male part 3 in a fixed orientation in relation to the housing 20 when the sleeve 4 is caused to rotate. The person skilled in the art will also know that the male part 3 and the housing 20 can be provided with means (not shown) which lock the male part 3 in the axial direction after the male part 4 is correctly positioned in the sleeve 4, and so that the male part 3 is not moved axially when drive fluid flows through the male part 3, through the sleeve 4 and the housing 20 and out into the pipe 7.

In the figures, it is shown that the male part 3 is inserted into the sleeve 4 until the other end part 32 of the male part 3 protrudes past the end part 42 of the sleeve 4. Insertion of the male part 3 is thus pressure-balanced and without the use of large torque or large axial forces.

The fluid used in this type of underwater operation will be an aqueous fluid or a gas. The aqueous fluid does not contain pollutants, and it is fully miscible with seawater. There are thus no requirements for special shut-off valves in the male part 3 or the female part 2 when these are disconnected from each other.

When using the invention, an ROV can easily lead the male part 3 with the supply line into the housing 20 and lock the male part 3 firmly using known solutions and without the use of special tools and locking means. Without moving the ROV, the ROV can operate the handle 68 and the ROV operator can thus choose which pipe 7 or pipe branch is to be supplied with drive fluid. This can be done regardless of how the pipeline has spun before settling on the seabed.

It is also achieved to supply the end part of a pipeline with a PLR unit that is snappy enough so that it can more easily be led out over the deck and through the laying equipment of a pipe-laying vessel, the so-called "caterpillar tensioner" unit.

The use of the multi-way valve 1 in connection with the use of the PLR unit is described. The invention is not limited to just this purpose, as the person skilled in the art will understand that the multi-way valve 1 can be used in other contexts where there is a need to control a fluid from one line to one selected inlet for another line among several possible selectable lines with inlets. Pressurized hydraulic oil is one example of such a fluid.

Claims (14)

1. Multi-way valve (1) comprising a female part (2) and a detachable male part (3), the male part (3) forms a first end part (31) and a second end part (32), the male part (3) is provided in its center with an axial channel (34), the channel (34) has an inlet (35) in the first end part (31) of the male part (3) and the channel (34) opens into an outlet part (36) in the outer jacket (33) of the male part (3) between the first end part (31) and the second end part (32) of the male part (3); the female part (2) comprises a housing (20) with a circular inner space (25), the longitudinal axis of the inner space (25) is parallel to the axis of the housing (200), the housing (20) is provided with a plurality of through bores (26) from the outer surface (23) of the housing (20) and to the inner surface (24) of the housing (20), where the axis (260) of the bore (26) is substantially radial to the axis (200) of the housing (20), the housing (20) further comprises in its inner space (25) a rotatable sleeve (4) with a first end part (41) and a second end part (42) and with an outer mantle surface (43) and an inner mantle surface (44), the rotatable sleeve's (4 ) axis coincides with the longitudinal axis of the room (25), the sleeve (4) is provided in its wall (45) with one through bore (46); the sleeve (4) is arranged to be able to house the male part (3), characterized in that the through bore (46) of the sleeve (4) opens into a spherical part (48) which peripherally surrounds the outer mantle surface (43) of the sleeve (4) between the sleeve's ( 4) first end part (41) and the sleeve's second end part (42). 2. Multi-way valve (1) according to claim 1, where the sleeve (4) is 360° rotatable about the axis of the sleeve (4). 3. Multi-way valve (1) according to claim 1, where the space (25) is continuous in the housing (20). 4. Multi-way valve (1) according to claim 1, where the through bores (26) of the housing (20) house a coupling connection (5), and the coupling connection (5) is in its part which faces the spherical part (48) of the sleeve (4) , provided with an annular sealing element (58) which rests against the spherical part (48) of the sleeve (4). 5. Multi-way valve (1) according to claim 1, where the sleeve (4) is provided with an annular positioning ring (49) which projects radially beyond the sleeve's (4) outer mantle surface (43). 6. Multi-way valve (1) according to claim 5, where the annular positioning ring (49) comprises a gear ring (491). 7. Multi-way valve (1) according to claim 1, where the housing (20) further comprises a maneuvering element (6) arranged to be able to turn the sleeve (4) about the axis of the sleeve. 8. Multi-way valve (1) according to claims 5 and 7, where the maneuvering element (6) is arranged to turn the positioning ring (49). 9. Multi-way valve (1) according to claim 1, where the housing (20) in its one end part (21) is provided with a window (29) for reading the position of the bore (26). 10. Multi-way valve (1) according to claim 1, where the channel (34) has an axially directed inlet (35) in the first end part (31) of the male part (3). 11. Pipeline for the transport of fluids, where one end of the pipeline is equipped with a multi-way valve (1) in accordance with claim 1. 12. Pipeline according to claim 11, where the pipeline comprises a sending station for a "pig" and/or a receiving station for a "pig". 13. Method for controlling a fluid flow from one supply line connected to one inlet (35) to one selected pipe (7) of several possible selectable pipes (7), using a multi-way valve (1) according to claim 1. 14. Method according to claim 13, where the method comprises supplying a sending station for a "pig" and/or a receiving station for a "pig" with a drive medium.