TECHNICAL FIELD

The present invention relates to improved submerged cooler designs for e.g. subsea applications, such as for example in oil and gas production and in offshore wind power grid link platforms, and particularly to a unique pipe support arrangement in a submerged cooler, an improved submerged cooler frame and an improved submerged cooler.

BACKGROUND OF THE INVENTION

Due to the environment in which different subsea or submersible components, equipment and systems are being used, there are many challenges related to production of oil and gas and/or to offshore electricity production from wind power.

Several subsea or submerged coolers for cooling a well flow, such as for example a hydrocarbon flow, are known.

Passive subsea coolers are usually used, because they are more robust than active subsea coolers. In these solutions related to passive subsea coolers, the fluid to be cooled, e.g. a well flow, is led through a piping constituted of multiple pipes arranged in a large common volume exposed to a cooling fluid, i.e. seawater. The seawater passes through the common volume at a relatively slow rate due to natural convection, i.e. the seawater rises through the subsea cooler since it is heated by the fluid to be cooled. It is thus difficult to regulate or control the cooling effect of passive subsea coolers. Furthermore, longitudinal elongation of the cooler piping, due to thermal expansion, can be expected, because the fluid in the piping has a higher temperature compared to the seawater temperature, and the steel structure of the subsea cooler has a temperature close or equal to the seawater temperature.

Because of the differences in temperature and different thermal expansion

coefficients, the piping will expand relative to the steel structure when the

temperature in the fluid changes over time. This is especially an issue after shut down and/or start-up operations or procedures. The temperature variations of the seawater and/or the fluid to be cooled over time should thus be taken into account. This effect is dominant in longitudinal direction. This effect is also a challenge to known passive subsea coolers. SUMMARY OF THE INVENTION

When using a submerged or submersible cooler in shallow waters, marine bio fouling will attack the structures thereof, thus causing reduced cooling efficiency. To counteract this it is possible to use a material that largely prevents accumulation of marine fouling on the cooler pipes. Thus, the cooler pipes can be made of for example different alloys and/or metals. Some of these alloys and/or metals can show very good resistance against marine bio-fouling and general corrosion. However, the oxide layer that is built up on the surface is soft and cannot withstand abrasion as well as it can be damaged (e.g. mechanically). Sliding between component parts may remove the oxide layer and will increase corrosion rates to an unacceptable level. Furthermore, the material is prone to crevice corrosion. This issue must be

addressed in the interface between the pipe support of the submerged cooler and the cooler piping.

In addition, the pipe support beams of the submerged cooler are long and structural integrity is dominated by deformations. The submerged cooler can see loading during its lifespan up to 5G. The input header of the cooler piping is stiff, as such the stiffness of the pipe support beams must be large to reduce loading on the cooler piping. Therefore, this issue must also be addressed.

It is an object of the invention to provide longitudinal elongation of the cooler piping due to thermal expansion over time.

Another object of the invention is to counteract corrosion of the structure and the piping of the submerged cooler as a consequence of abrasion of the oxide layer thereon.

Yet another object of the invention is to enable unobstructed inflow of cold seawater through the submerged cooler or to improve the inflow amount of cold sea water through the submerged cooler.

Yet another object of the invention is to ensure sufficient structural integrity of the submerged cooler.

Yet another object of the invention is to ensure sufficient protection of the submerged cooler and particularly its piping against vibration and shock loads. Yet another object of the invention is to use pipe support beams that are not welded to the frame of the submerged cooler, which in turn will change and ease the fabrication method.

According to a first aspect of the invention, this is achieved with submerged cooler designs and/or arrangements which alleviate at least some of the dis advantages of the prior art subsea or submersible coolers.

According to a second aspect of the invention, this is achieved with a unique pipe support of a submerged cooler.

According to a third aspect of the invention, this is achieved with an improved submerged cooler frame.

According to a fourth aspect of the invention, this is achieved with an improved submerged cooler.

The main features of this invention are given in the independent claims.

Additional features of the present invention are given in the dependent claims.

The present invention concerns a pipe support arrangement of a structural frame for a submerged cooler. The pipe support arrangement comprises at least one pipe support beam and at least one structural beam of the structural frame. Said at least one pipe support beam is configured for carrying approximately perpendicularly arranged cooler piping for the submerged cooler. Each structural beam comprises at least one first bracket and at least one second bracket. The first and second brackets are firmly arranged onto the structural beam. The first and second brackets are configured for receiving inbetween the pipe support beam. The pipe support beam is supported and hold by the brackets. The pipe support beam is approximately perpendicular to the structural beam. The pipe support beam is also moveably arranged inbetween the brackets. The pipe support arrangement further comprises limitation means. The limitation means is/are configured for securing a predetermined limited translation of the pipe support beam in longitudinal direction with respect to the cooler piping.

The surfaces of the brackets in contact with the pipe support beam and the surfaces of the pipe support beam in contact with the brackets can be polished and/or treated in such a way so that the limited longitudinal translation of the pipe support is made easier. In one embodiment, the pipe support arrangement can comprise a first bracket plate, a second bracket plate, a first support plate and a second support plate. The first bracket plate can be firmly arranged onto the first bracket. The first bracket plate can have a sliding surface facing the pipe support beam. The first support plate can be firmly arranged onto one side of the pipe support beam. The first support plate can have a sliding surface facing the first bracket. The second bracket plate can be firmly arranged onto the second bracket. The second bracket plate can have a sliding surface facing the pipe support beam. The second support plate can be firmly arranged onto the other side of the pipe support beam. The second support plate can have a sliding surface facing the second bracket. The plates can be made of a material having a low coefficient of friction. Additionally and/or alternatively, the sliding surfaces of the plates can be treated to get a low coefficient of friction. Thus, the limited longitudinal translation of the pipe support will be eased.

In one embodiment, the limitation means comprises at least one lip. Each lip can be firmly arranged on each longitudinal side of each of the brackets. The lips can be configured for securing the predetermined limited translation of the pipe support beam in the longitudinal direction with respect to the cooler piping.

In another embodiment, the limitation means comprises a restraining means and a group of holes through the pipe support beam, the brackets and optional bracket and support plates. The group of holes is parallel to the structural beam.

Each of the holes of the brackets and the optional bracket plates can be a circular hole, and each of the holes of the pipe support beam and the optional support plates can be a slit hole. Alternatively, each of the holes of the pipe support beam and the optional support plates can be a circular hole, and each of the holes of the brackets and the optional bracket plates can be a slit hole. Furthermore, the restraining means can be entirely or partially arranged through the group of holes. The restraining means is configured to interact with the slit hole in order to secure the limited translation of the pipe support beam.

The restraining means can comprise one from the group consisting of:

i) at least one coupling nut and at least one restraining bolt installed through some or all of the group of holes and fastened with a respective coupling nut for interacting with the slit hole for moveably connecting together the two brackets and the pipe support beam; ii) at least one shoulder screw configured to be threaded into at least one circular hole with threads from the plurality of circular holes and to interact with the slit hole for moveably connecting together the two brackets and the pipe support beam;

iii) at least one rivet installed through some or all of the group of holes and configured for interacting with the slit hole and for moveably connecting together the two brackets and the pipe support beam;

iv) a threaded rod passing through the group of holes and connected to two coupling nuts on each side of the brackets;

v) two rods with heads inserted from each side of the brackets and welded together;

vi) at least one stud configured to interact with the slit hole and to be firmly fixed to or welded into at least one circular hole; and/or

vii) two bolts with a threaded middle part and cylindrical end like a reversed shoulder screw, the bolts being configured to be threaded into threaded circular holes of the brackets and to interact with the slit hole of the pipe support beam for moveably connecting together the two brackets and the pipe support beam.

Other suitable restraining means not listed above, but securing the limited longitudinal translation of the pipe support beam with respect to the cooler piping, shall also be included.

The limitation means can in a different embodiment comprise at least one stud firmly fixed or welded to each bracket and/or to the structural beam. Said at least one stud is also configured to interact with at least one slit arranged on the pipe support beam.

Between two parallel structural beams of the pipe support arrangement at least one pipe support beam can be approximately perpendicularly arranged in such a way so that said predetermined limited translation of said at least one pipe support beam in longitudinal direction with respect to the cooler piping will be achieved.

The pipe support arrangement can further comprise insulation. The insulation can be at least one of: electrical and/or corrosion resistant. This insulation insulates the pipes from the structural frame and/or the structural beams. The insulation can be: i) arranged between the pipes, the pipe support beams and connection U-bolts or clamps, or ii) built into the pipe support beams or their surfaces, or iii) made by selection of insulation matehal(s) or coating(s) for the plates combined with insulation of the components restricting the longitudinal movement or translation of the pipe support beams.

The invention concerns also a structural frame of a submerged or submersible cooler comprising at least one pipe support arrangement.

In addition, the invention concerns a submerged or submersible cooler comprising a structural frame comprising at least one pipe support arrangement and a cooler piping. The cooler piping comprises several pipes. The pipes in a row are running approximately perpendicularly to the pipe support beam of the structural frame. The pipes in a row are parallel to each other. The pipes can be firmly connected to the pipe support beam.

Moreover, the invention concerns a submerged or submersible cooler comprising a structural frame and a cooler piping. The structural frame comprises at least one pipe support beam and at least one structural beam. Said at least one pipe support beam is configured for carrying approximately perpendicularly arranged cooler piping. The pipe support beam is approximately perpendicular to the structural beam. The cooler piping comprises several pipes. The pipes in a row are running approximately perpendicularly to the pipe support beam. The pipes in a row are parallel to each other. The pipes can be firmly connected to the pipe support beam. Each pipe support beam comprises pipes arranged on both opposite sides thereof. For example, in one embodiment, when the pipe support beam is horizontal, one group of parallel pipes will be arranged on top of the pipe support beam, and another group of parallel pipes will be suspended under the pipe support beam. Thus, the pipe support beam will prevent longitudinal seawater flow between those two pipe rows / groups at the pipe support beam location, but the area between two pipe rows / groups arranged respectively on neighboring pipe support beams will be fully open for seawater flow passing therethrough.

BRIEF DESCRIPTION OF THE DRAWINGS

These and other aspects of the invention are apparent from and will be further elucidated, by way of example(s), with reference to the drawings, wherein:

Figure 1 shows a submerged cooler and a frame / support frame of the submerged cooler according to the present invention. Figures 2A - 2B illustrate a first embodiment of a pipe support arrangement of a submerged cooler frame in a submerged cooler according to the present invention.

Figures 3A - 3B illustrate a second embodiment of a pipe support arrangement of a submerged cooler frame in a submerged cooler according to the present inven tion.

Figures 4A - 4B show a third embodiment of a pipe support arrangement of a submerged cooler frame in a submerged cooler according to the present invention.

DETAILED DESCRIPTION OF THE EMBODIMENTS

Figure 1 illustrates a submerged cooler 20 comprising a structural frame 1 and a cooler piping 9. The frame 1 comprises structural beams 16 and pipe support beams 5, wherein each structural beam 16 is approximately perpendicular to respective pipe support beam(s) 5, and wherein the structural beams of the structural frame 1 are interconnected with the respective pipe support beams of the structural frame 1 as well as with other additional structural beams necessary for achieving a rigid and robust structural frame 1 of the submerged cooler 20. The cooler piping 9 is constituted of multiple pipes.

Figures 2A - 2B show a first solution for longitudinal translation of the pipe support 5 (figure 2A) and a detailed view of the sliding faces for longitudinal translation (figure 2B).

A first embodiment of a structural frame 1 of a submerged cooler 20 is shown. The structural frame 1 comprises at least one pipe support beam 5 and at least one structural beam 16. Each structural beam 16 comprises at least one first bracket 17 and at least one second bracket 18. The first and second brackets 17, 18 are firmly arranged on the structural beam 16 in such a way so that the pipe support beam 5 fits moveably inbetween them and is hold by the brackets 17, 18. At the same time, the pipe support beam 5 is approximately perpendicular to the structural beam 16. The brackets 17, 18 can be welded onto the structural beam 16. Alternatively, the brackets 17, 18 can be firmly fastened to the structural beam 16 by means of for example one or several bolts 22 and optionally nuts (see for example figures 4A-4B) and/or one or several rivets. Other fastening means for firmly connecting the brackets 17, 18 to the structural beam 16 are also possible. The pipe support beam 5 is carrying a cooler piping 9. The cooler piping 9 comprises several pipes 9. The pipes 9 are running approximately perpendicularly to the pipe support beam 5 and are firmly connected thereto, for example by means of welding, U-bolts or clamps 8 and nuts and/or other fastening means. The pipes 9 are parallel to each other. In one embodiment, the pipes 9 of the cooler piping 9 are arranged on one side of each pipe support beam 5; for example on top of each pipe support beam 5. This typical solution for subsea or submerged coolers shows that the cooler pipes are supported by one beam per row or one beam per column. In another embodiment, some pipes 9 of the cooler piping 9 are arranged on both sides of each pipe support beam 5. For example, some pipes 9 of the cooler piping 9 can be arranged on top of each pipe support beam 5, while the rest of pipes 9 of the cooler piping 9 can be suspended under each pipe support beam 5. With the last solution, the pipe support beam 5 will prevent longitudinal seawater flow between those two pipe rows at the pipe support beam location, but inbetween every second row is fully open for seawater flow that passes therethrough. In some applications, the latter solution will result in a lower longitudinal projected area of the pipe support beams compared to the first solution, thus allowing more free seawater flow through the cooler 20. The surfaces of the brackets 17, 18 in contact with the pipe support beam 5 and the surfaces of the pipe support beam 5 in contact with the brackets 17, 18 can be polished or treated in such a way so that longitudinal translation of the pipe support 5 is being eased.

Alternatively, a first bracket plate 3 with sliding surface can be firmly arranged onto the first bracket 17 facing the pipe support beam 5. A first support plate 10 with sliding surface can be firmly arranged onto the pipe support beam 5 facing the first bracket 17. A second bracket plate 2 with sliding surface can be firmly arranged onto the second bracket 18 facing the pipe support beam 5. A second support plate 11 with sliding surface can be firmly arranged onto the pipe support beam 5 facing the second bracket 18. In this case, due to material used for the plates 2, 3, 10, 11 , the sliding surfaces thereof can be easily manufactured. For example the plates 2, 3, 10,

11 can be steel plates with a coating or with such a structure that gives low

coefficient of friction.

The arrangement can further comprise electrical insulation, where the pipes 9 are insulated from the structural frame 1 and/or beams 16. The electrical insulation can be located between the pipes 9 and the clamps or U-bolts 8 and the pipe support beams 5. Alternatively, the electrical insulation can be built into the pipe support beams 5 or their surfaces. Alternatively, the electrical insulation can be made by selection of insulation material(s) or coating(s) for the plates 2, 3, 10, 11 combined with insulation of the components restricting the longitudinal movement of the pipe support beams 5. Additionally and/or alternatively, the insulation can be corrosion resistant / proof.

Each one from the group of the brackets 17, 18, the pipe support beam 5 and the optional plates 2, 3, 10, 11 can be arranged with a hole 13, 19 therethrough; the group of holes 13, 19 being parallel to the structural beam 16. At least one restraining bolt 14 and coupling nut 15 can be fastened or installed through the hole(s) 13, 19 and connect the two brackets 17, 18 and the pipe support beam 5. The holes 19 of the brackets 17, 18 and the optional bracket plates 2, 3 can be circular holes. The hole(s) 13 of the pipe support beam 5 and the optional support plates 10, 11 can be a slit hole allowing for translation of the pipe support beam 5 in longitudinal direction and within desired limits determined by the slit hole. Alternatively, the hole 13 of the pipe support beam 5 can be a circular hole. The holes 19 of the brackets 17, 18 can be slit holes. In this case, washers can be used. Alternatively, the hole 13 in the pipe support beam 5 can be threaded and two shoulder screws can be used to interface the slit 19 in the brackets 17, 18. It can also be possible, as an alternative, to firmly fix or weld studs into the hole(s) 13 of the pipe support beam 5, which can interface the slit 19 in the brackets 17, 18. Alternatively, as shown on figures 4A-4B, at least one stud 23 can be firmly fixed or welded to each bracket 17, 18 and/or to the structural beam 16 in order to interact with the slit 13’ of the pipe support beam 5.

The restraining bolt(s) 14 or the like (other suitable fastening means) will prevent motion of the pipe support beam 5 in transverse direction. Other suitable fastening means, such as but not limited to: rivet(s); a through bolt fixed with a nut on opposite side; a threaded rod with two nuts; two rods with heads inserted from each side and welded together; stud welded into the holes 19 of the brackets 17, 18, etc., can also be used (through the hole(s)), wherein the fastening means is(are) configured for allowing for translation of the pipe support beam 5 within desired limits and in longitudinal direction (see the arrows on figures 2B, 3B, 4B) and for preventing motion of the pipe support beam 5 in transverse direction. Alternatively, two specially made bolts with a threaded middle part and cylindrical end like a reversed shoulder screw can be used. Threading the holes 19 in the brackets 17, 18 allows for installation of these bolts after the pipe support beam 5 is correctly placed between the two brackets 17, 18.

Figures 3A - 3B show a second solution for longitudinal translation of the pipe support 5 (figure 3A) and a detailed view of the sliding faces for longitudinal translation (figure 3B). Instead of a hole and a bolt and nut connection or a rivet or stud connection, a lip 24 can be firmly arranged on each side of each of the brackets 17, 18 in order to allow translation of the pipe support beam 5 in longitudinal direction and within desired limits and to prevent motion of the pipe support beam 5 in transverse direction. The lips 24 can be welded, bolted or firmly fastened, by suitable fastening means, to the brackets 17, 18. Alternatively, the lips 24 can constitute a part of the brackets 17, 18.

Figures 4A - 4B show a third solution for longitudinal translation of the pipe support 5 (figure 4A) and a detailed view of the sliding faces for longitudinal translation (figure 4B). Flere it is exemplified that the brackets 17, 18 can be firmly fixed to the structural beam 16 by means of bolt(s) 22 and optionally nut(s). One of several solutions for use of stud(s) is also shown here, where at least one stud 23 is used for interfacing with a slit 13’ for achieving limited longitudinal translation of the pipe support beam 5.

The fluid to be cooled and running through the pipes 9 can be a coolant fluid (i.e. a special fluid with one or more additives, such as but not limited to different glycols) or water (if necessary with one or more additives thereto) in cases when the submerged cooler is used for offshore electricity production from wind power. In the oil and gas production the fluid to be cooled and running through the pipes 9 is the production fluid itself.

Additional modifications, alterations and adaptations of the present invention will suggest themselves to those skilled in the art without departing from the scope of the invention as defined in the following patent claims.