NO20120468A1 - Integrated production manifold and multiphase pump station - Google Patents

Abstract

A subsea production station (SPS) including at least one production manifold and a multiphase pump unit (MPP) for subsea operation is shown. Each of them has respective control / operation modules, operatively connected to at least one floating production physician and discharge unit (FPSO), underwater umbilicals, risers, production pipelines, subsea wells, installations such as valve trees and other units in the system. The manifold (4) is adapted for its use to produce hydrocarbons from a number of wells. The pump unit (7) is arranged to add kinetic energy along the production pipelines. The manifold (4) and pump unit (7) are integrally positioned side by side on a common foundation (2) and are arranged to have a common support structure and common suction anchor (1).

Description

Integrated Production manifold and multiphase pumping station

The present invention generally relates to an underwater production system which has a simplified construction which is technically reliable and is cost-effective. The subsea production system includes floating production storage and offloading units (hereafter referred to as FPSO at locations), subsea umbilicals, risers, production pipelines (hereafter collectively referred to as SURF at locations), subsea wells, installations such as a valve tree and other devices that are all operatively connected to an integrated production manifold and multiphase pumping units (hereafter referred to as MPP at locations). More specifically, the present invention relates to an integrated production manifold and multiphase pumping unit that has a technically reliable simplified design and is cost-effective, as far as significant savings in terms of the use of connectivity/pull between the production manifold, MPP and other components of the subsea production system (hereinafter referred to such as SPS at locations) is achieved. In particular, the present invention provides an underwater production system in accordance with claim 1 and an integrated production manifold and multiphase pump unit for its application in an SPS, in accordance with claim 13.

In the field of offshore oil recovery, a subsea production system (SPS) is known to include production manifolds, multiphase pumping units, FPSO, subsea umbilicals, risers, flow lines (SURF), subsea wells, installations such as a valve tree and other features known to those skilled in the art. A floating production storage and offloading unit (FPSO) is commonly known to be a floating vessel used by the offshore industry for the processing and storage of oil and gas. An FPSO vessel is designed to receive oil or gas produced from nearby platforms or underwater fireframe, process it and store it until the oil or gas can be loaded onto a tanker or transported through a pipeline. Subsea production manifolds are known to be used to produce hydrocarbons from a plurality of wells. It may include an accessory piping system to a main piping system (or other conduit) that serves to divide a flow into multiple parts, to combine multiple flows into one, or to redirect a flow to any of several possible destinations. Alternatively, it can be a pipe fitting with several side outlets to connect it with other pipes. It is also known that an underwater multiphase pump increases the pressure in the well field. In other words, it adds kinetic energy directly to the flow. The effect is as if the flow pressure is increased. The flow from the wells increases until a new balance between fluid pressure and system resistance is achieved. The effect is a net increase in oil production. The importance of subsea umbilicals, risers, flow lines and other features in subsea production systems is known to those skilled in the art.

Now, for the extraction of oil and gas in a subsea level, production manifolds and multiphase pumping units are known to be separately installed together with different installations and this involves the use of several complicated connectivities/decks to ensure operational connection between production manifolds, multiphase pumping units, umbilicals, risers, flowlines, subsea wells and other units including installations, such as a valve tree, in a subsea production system. Obviously, these involve very high maintenance and installation costs and issues often related to technical reliability arise due to the complexity.

Over the years, attempts have been made to simplify and/or reduce the components necessary for operational connection between the various units in an underwater production system. In the prior art, however, no attempt has been made to integrate the production manifolds and the multiphase pump units with a view to simplifying and/or reducing the components, in order to ensure operational connection between the various units in an underwater production system. WO 2008/070648 A2 shows an improved manifold system comprising two or more underwater trees each connected to an underwater well, a manifold connected to each underwater tree and a first common riser connected to the manifold. Production, maintenance and/or overhaul of each underwater well takes place through the common riser. This document indicates in an indirect way the simplification and reduction of the components necessary for operational connection between the various units including installations, such as a valve tree, in an underwater production system. However, it does not direct the direct integration of a production manifold and a multiphase pumping unit with a view to achieving such a motive. Rather, it focuses on testing a low-cost manifold that can be used with an early production system (EPS) to produce, maintain and/or overhaul multiple subsea wetwood wells through a common riser system.

Framo Engineering has developed a multiport selector manifold (MSM) that includes production and test facilities, a gas lift system, a multiphase flow meter and a multiphase booster pump and controls. (Offshore Magazine, published August 1, 2006). Very similar to that shown in WO 2008/070648 A2, Framo Engineering concentrates on reducing the size and weight of the compact manifold. It also specifies a simple control system that can control not only a large number of valves and sensors for each control box, but also the pump, the multiphase meter and the three controls. However, Framo Engineering does not direct the direct integration of a production manifold and a multiphase pump unit with a view to simplifying and/or reducing the components necessary to ensure operational connection between the various units in a subsea production system.

Consequently, there has been a long-felt need for a design in an underwater production environment for the simplification and/or reduction of components necessary to ensure operational connection between the various units in an underwater production system, so that effective cost savings are achieved and at the same time the technical reliability of the whole system significantly improved. The present invention meets this long-felt need and other needs associated with it.

The present invention aims to meet the above-mentioned need which has not been shown in the prior art by providing an underwater production system which, by virtue of its specially designed construction, plays a significant role in simplifying and/or reducing the components necessary for operational connection between the various units in an underwater production system.

Another object of the present invention is to provide an integrated production manifold and multiphase pump unit for its application in an underwater production system in order to simplify and/or to reduce the components necessary for operational connection between the various units, in an underwater production system.

It is another object of the present invention to provide an integrated production manifold and multiphase pump for its application in a subsea production system so that significant cost efficiency is achieved without compromising technical efficiency.

Another purpose of the present invention is to achieve SURF area savings in an underwater production station.

It is a further object of the present invention to achieve SPS and MPP area savings in an underwater production station.

It is another purpose of the present invention to achieve advantageous designs in the control system and umbilicals for an underwater production station.

It is a further purpose of the present invention to substantially increase the technical reliability and to achieve significant cost savings in the operation of an underwater production station/system, by reducing the number of underwater connections and equipment in an underwater production system.

It is another important object of the present invention to provide an underwater production station that incorporates underwater production systems, where each such system by virtue of its specially designed construction, plays a significant role in simplifying and/or in reducing the components necessary for operational connection between the various units including production manifolds, multiphase pumping units, umbilicals, risers, production pipelines, subsea wells, installations such as a valve tree, in a subsea production station.

In addition, the present invention shows some advantageous features which have not yet been shown in the prior art.

Throughout the description, including the requirements, the words oil, gas, hydrocarbons, SPS, production manifold, multiphase pump unit, ROV are to be understood in the broadest sense of the respective terms and include all similar objects in the field known by other terms, which will be clear to the person skilled in the art . Furthermore, the term production, wherever used, shall be understood as relating to oil, gas and other hydrocarbons involved in underwater drilling operations.

In accordance with a first aspect of the present invention, there is provided an underwater production system (SPS) including at least one production manifold and a multiphase pump unit (MPP) for underwater operation. The production manifold and the pump unit have respective modules for control/operation. The manifold and pumping unit are operatively connected to at least one floating production storage and offloading unit (FPSO), subsea umbilicals, risers, production pipelines, subsea wells, installations such as valve trees and other units in the system. This manifold is adapted for its application to produce hydrocarbons from a number of wells. The pumping unit is adapted to add kinetic energy along the production pipelines. In accordance with the invention, the manifold and the pump unit are integrally placed next to each other, on a common foundation and are adapted to have a common support structure and common suction anchor system, along a single installation.

In accordance with a preferred embodiment of the first side of the present invention, MPP modules and equipment associated with this are incorporated inside the manifold module.

Advantageously, the pump's high-voltage power supply cables are incorporated into the production umbilicals.

In accordance with another preferred embodiment of the first aspect of the present invention, the manifold and the pump unit are adapted to have common parts and are adapted to be operated with the same ROV tools.

In accordance with a second aspect of the present invention, there is provided an installation operatively connected to the underwater production system in accordance with a first aspect of the present invention.

Preferably, the installation is a valve tree.

In accordance with a third aspect of the present invention, there is provided an underwater production station comprising at least one underwater production system (SPS) in accordance with the first aspect of the present invention.

In accordance with a fourth aspect of the present invention, there is provided an integrated production manifold and multiphase pump unit (MPP) for application in an underwater production system, each having respective modules for control/operation. The manifold and pumping unit are operatively connected to at least one floating production storage and offloading unit (FPSO), subsea umbilicals, risers, production pipelines, subsea wells, installations, such as a valve tree, and other units in the production system. In accordance with the fourth aspect of the present invention, the manifold and the pump unit are integrally placed next to each other on a common foundation and are adapted to have a common support structure and common suction anchor system in a single installation. The MPP modules and equipment associated with them are incorporated into the manifold modules and high-voltage power supply cables to the pumps are incorporated into the production umbilicals.

The present invention also includes a number of such integrated manifold and multiphase pump units, operatively connected to each other and to other units in an underwater production station.

Having described the main features of the invention in the above, a more detailed and non-limiting description of some exemplary preferred embodiments will be given in the following with reference to the drawings, where: Fig. 1(a) is a perspective view of the integrated unit in accordance with the present invention. Fig. 1(b) is a perspective view of a preferred embodiment of the integrated unit in accordance with the present invention, which shows the connectability between the various components. Fig. 1(c) is an exploded front view of the integrated unit illustrated in Fig. Kb).

Fig. 1(d) is a top view of the integrated unit illustrated in Fig. let).

Fig. 2 is a block diagram of the various interfaces to the integrated unit, in accordance with the present invention. Fig. 3 is a flow diagram, which illustrates the connectivity between the various components of the MPP system in accordance with a preferred embodiment of the present invention.

The present invention aims to simplify and/or reduce the components that are necessary to ensure operational connection between the various units in an underwater production system. The present invention ensures a significant reduction in costs and at the same time ensures a significant increase in technical reliability in the operation of an underwater production system. This is achieved primarily by a brilliant engineering move that involves the integration of the production manifold and the multiphase unit in a subsea production station, so that the components necessary for coupling between the production manifold and the multiphase pump unit and between the other units such as FPSO, SURF, subsea wells, installations such as valve trees in a the underwater production station is simplified and/or reduced.

The attached figure 1(a) further illustrates the integrated production manifold 4 and the multiphase pump unit 7 in accordance with the present invention. As will be quickly understood from this figure, the manifold 4 includes the ROV panel 6, a housing which advantageously has eight production inlets into which individual wells are connected. Advantageously, it has a main production outlet and a test outlet. It also has a steering column 5. It may be of a larger dimension compared to other CLOV manifolds, which will be known to the person skilled in the art, but this has no consequences for the present invention. Similar comments apply with regard to the multiphase pump unit 7 as well, which has been field-tested over several years. The novelty and height of invention lies in the integration of these two units together into a compact, comprehensive unit, whereby marked technical advantages and economic progress have emerged which have not been achieved in the industry until now. As will be clearly seen from the attached figure 1, this integrated unit is installed together in a single installation, and therefore departs from the old requirement for separate installations for both such units. This integrated unit rests on a common foundation 2 and is anchored with a common suction anchor 1. The leveling frame 3 advantageously enables integrated adjacent placement of the production manifold 4 and the multiphase pump 7 in a single installation. Advantageously, the production power lines connected to the manifold 4 form a spiked loop (not shown) around the control post 5 in the manifold.

In the context above, it is hereby clarified that, for the sake of understanding, only one integrated unit is shown in the attached figure 1(a), but the present invention embraces a number of such integrated units which are used in an underwater extraction operation.

The attached figure 1(b) illustrates another preferred embodiment of the integrated unit in accordance with the present invention. In this embodiment, the connections between the various components are shown. The same reference numbers in fig. l(b) indicates the same features as in fig. let). In this preferred embodiment, the manifold 4 is shown positioned to the left of the multiphase pump unit 7. It also shows the manifold valves 4'. The attached figure 1(c) is an exploded view of the unit shown in fig. l(b), the like reference numerals indicate the same features. The attached figure 1(d) illustrates a top view of the unit shown in fig. Ka).

Combining the production manifold and multiphase pump into a combined subsea manifold/pump station in accordance with the present invention reduces cost and increases reliability by reducing the number of subsea connections and equipment in a subsea production system.

Advantageously, in accordance with the present invention, high voltage power delivery cables for the pump are incorporated within the production umbilicals, thereby obviating the need for a dedicated pump umbilical.

An outline of the significant savings for subsea umbilicals, risers, production pipelines (SURF) is as follows:

- 2 fewer pipe connections are saved between manifold and pump.

- Installation of a smaller manifold saved (installation of a combined manifold instead of separate pump and manifold installation).

- Installation of one smaller manifold foundation saved.

- Installation of 2 fewer production pipe pieces between manifold and pump saved. 1 smaller production umbilical saved functionally for production umbilical included in the pump umbilicals based on combined design (ie reduce double functions).

An outline of the extent of savings for the subsea production system (SPS) and multiphase pump unit (MPP) is as follows: - Intake boss saved (piping system on manifold directly connected to piping system on pump, and thus no need for jumpers), 1 smaller manifold module saved (only a combined manifold module is needed for combined pump/manifold), 1 smaller manifold support structure saved (only one combined manifold support structure is needed for combined pump/manifold), 1 smaller suction anchor saved (one combined MPP/production suction anchor instead of separate MPP and SPS manifold suction anchors) .

An outline of the scope of FPSO savings is as follows:

- Saves guide pipes on the FPSO

The attached figure 2 illustrates a block diagram of the various interfaces of the integrated unit in accordance with the present invention. It shows production umbilicals 14' which connect to the power control module (PCM) 8 and to the MPP system control unit (SCU) 9 and to the subsea production system (SPS) 10. These production umbilicals therefore have power supply cables for both the pumping unit as well as the production manifolds. The power cable cores generate a fairly high temperature when the umbilicals are exposed to hot air in the I-tube. The temperature in the combined cross-section (two smaller umbilicals) is 15°C less than that which stands alone (one large umbilical). The only community of parts is ensured. Furthermore, each of the production umbilicals 14' is adapted to function in an inviolable manner, in the event of a breakdown in the other.

The other interfaces shown in the attached figure 2 are the high voltage jumper 13, the barrier fluid jumper 12, the umbilical terminal heads 14, the 250mm pipe sockets 20 and the welding interface 23. The pumping station comprises 250mm ball valves 21 which are hydraulically/ROV operated (2 smaller for each pump module), 200mm butterfly valves or ball valves 22 . 4.

As will be understood from the description of the invention with reference to the drawings as given below, the main advantages of the combined MPP/SPS underwater station in accordance with the invention are: a) the MPP modules and associated equipment are incorporated inside the production manifold, which thus removes the need for a dedicated MPP

manifold.

b) The MPP support structure is incorporated into the SPS support structure, which thereby removes the need for a dedicated MPP support structure. c) The MPP suction anchor is incorporated into the SPS suction anchor, which thereby removes the need for a dedicated MPP suction anchor.

The main advantages of the control system used in the present invention are:

a) Application of existing underwater production system (SPS) power and communication distribution equipment to support the MPP system. b) MPP underwater control module (SCM)/underwater control module mounting base (SCMMB) design and associated control equipment are subject to the same

specification requirements and shares the same common enclosure and ROV interface features as the SPS main equipment which ensures the commonality of tools and test equipment.

c) The MPP system control modules (SCM) are controlled and monitored via the subsea main production system (SPS) subsea control unit (SCU)/subsea

production control unit (SPCU).

d) Community in parts.

The main advantages of the umbilicals used in the present invention are:

a) The power cable cores generate a rather high temperature when the umbilicals are exposed to hot air in the I-tube. The temperature in the combined cross-section (two

smaller umbilicals) as illustrated in the attached figure 2 and explained above, is 15 °C less than that alone (a large umbilical).

b) Community in parts

c) Increased reliability/availability of the pumping system. With one power umbilical damaged/down, there is still one more to supply power to one pump system and

communication to both pump system control modules.

The main advantages of the retracting system used in the present invention are:

a) Removal of the pull-in connections between the MPP and the SPS manifold

b) Community in parts

The main advantages of the intervention system and the ROV tool system used in it

the present invention is:

a) Application of the same ROV tool as for both the pump system and the manifold system.

b) Community in parts

In a nutshell, the present invention achieves significant improvement in technical

reliability and significant cost savings in the operation of a subsea production station/system, by reducing the number of subsea connections and equipment in a subsea production system.

The attached Figure 3 is a flow chart which illustrates, by way of understanding and not as a limitation, the connectivity between the various components of the MPP system in accordance with a preferred embodiment of the present invention. It shows the pump 7, the chemical injection valve 24, the throttle 25, outlet branch valves 26, flow parts 27, recirculation line 28, flow mixer 29, inlet branch valves 30, bypass manifold 31, and bypass valve 32. Furthermore, the 150,200,250mm dimensions given here are exemplary and not limiting. The way the various components work will be clear to the professionals.

The present invention has been described with reference to some exemplary embodiments and some drawings for the sake of understanding and it should be clear to the person skilled in the art that the present invention includes all legitimate modifications that lie within what is described above and required in the attached claims.

Claims (21)

1. Subsea production system (SPS) including at least one production manifold and one multiphase pumping unit (MPP) for subsea operation each having respective modules for control/operation, operatively connected to at least one floating production storage and offloading unit (FPSO), subsea umbilicals, risers, production pipelines, subsea wells, installations such as valve trees and other units in said system, where the manifold (4) is adapted for its use to produce hydrocarbons from a number of wells and the pump unit (7) is arranged to add kinetic energy along the production pipelines, characterized in that the manifold (4) and the pump unit (7) is integrally placed next to each other, on a common foundation (2) and is designed to have a common support structure and common suction anchor (1) in a single installation. 2. Underwater production system as specified in claim 1, characterized in that MPP modules and equipment associated with these are incorporated into the manifold module. 3. Underwater production system as specified in one of the preceding requirements, characterized by high-voltage power supply cables for pumps being incorporated into the production umbilicals. 4. Underwater production system as stated in one of the preceding requirements, characterized in that the manifold and the pump unit are adapted to have common parts and are adapted to be operated with the same ROV tools. 5. Underwater production system as specified in one of the preceding claims, characterized in that the intake connections between the pump unit and the manifold have been replaced with a pipe system on the manifold, directly connected to the pipe system on the pump unit. 6. Underwater production system as stated in one of the preceding claims, characterized in that two pieces of production line pipe between the manifold and the pump unit have been removed. 7. Underwater production system as stated in one of the preceding claims, characterized in that a control system for the underwater production system is adapted to use the existing power and communication distribution system in the underwater production system. 8. Subsea production system as set forth in one of the preceding claims, characterized in that in the control system the multiphase pump unit (MPP), the subsea control module (SCM), the subsea control module mounting base (SCMMB) design and equipment associated therewith have the same specification requirements and share the same common enclosure and ROV interface feature as SPS main equipment. 9. Underwater production system as specified in one of the preceding requirements, characterized in that the control system, the multiphase pump unit (MPP) and the underwater control modules (SCM) are adapted to be controlled and monitored via the SPS underwater main control unit (SCU)/underwater production control unit (SPCU). 10. An installation operatively connected to the subsea production system in accordance with one or more of the preceding requirements to enable subsea oil extraction. 11. Installation according to claim 10, characterized in that the installation is a valve tree. 12. Subsea production station comprising at least one subsea production system (SPS), each such system including at least one production manifold and a multiphase pump unit (MPP) for subsea operation each having respective modules for control/operation, operatively connected to at least one floating production storage and offloading unit (FPSO), subsea umbilicals, risers, production pipelines, subsea wells, installations such as valve trees and other devices in said system, wherein the manifold (4) is adapted for its use to produce hydrocarbons from a plurality of wells and the pumping unit (7) is adapted to add kinetic energy along the production pipelines, characterized in that the manifold (4) and the pump unit (7) are integrally placed next to each other, on a common foundation (2) and are arranged to have a common support structure and common suction anchor system (1) in a single installation. 13. Integrated production manifold and a multiphase pumping unit (MPP) for use in a subsea production system, each having respective modules for control/operation, wherein the manifold (4) and the pumping unit (7) are operatively connected to at least one floating production storage and offloading unit (FPSO), subsea umbilicals, risers, production pipelines, underwater wells, installations such as valve trees and other units in said system, characterized in that the manifold (4) and the pump unit (7) are integrally placed next to each other, on a common foundation (2) and are designed to have a common support structure and joint suction anchor system (1) in a single installation, where MPP modules and equipment associated with these are incorporated into the manifold modules and the pump's high-voltage power supply cables are incorporated into the production umbilicals. 14. Integrated production manifold and a multiphase pump unit as set forth in claim 13, characterized in that the manifold and the pump unit are adapted to have common parts and are adapted to be operated with the same ROV. 15. Integrated production manifold and a multi-phase pump unit as specified in claim 13 or 14, characterized in that the intake connections between the pump unit MPP and the manifold are replaced with a pipe system on the manifold, directly connected to the pipe system on the pump unit. 16. Integrated production manifold and a multiphase pump unit as stated in claim 15, characterized in that at least two production umbilicals (14') are arranged which have high voltage power supply cables for both pump units as well as for the production manifold. 17. Integrated production manifold and a multiphase pumping unit as set forth in claim 16, characterized in that each of said production umbilicals (14') is arranged to function normally in an inviolable manner in the event of a breakdown in the other. 18. Integrated production manifold and a multiphase pump unit as set forth in one of claims 13 to 17, characterized in that two pieces of production line pipe between the manifold and the pump unit have been removed. 19. Integrated production manifold and a multiphase pump unit as specified in one of claims 13 to 18, characterized in that the control system of the underwater production system is designed to use power and communication distribution equipment in the existing underwater production system and in said control system the multiphase pump unit (MPP), the underwater control module (SCM) ), the underwater steering module mounting base (SCMMB) design and equipment associated with this have the same specification requirements and share the same common enclosure and ROV interface features as the main SPS equipment. 20. Integrated production manifold and a multiphase pump unit as specified in claim 19, characterized in that the control system, the multiphase pump unit (MPP) and the subsea control modules (SCM) are adapted to be controlled and monitored via the SPS subsea main control unit (SCU)/subsea production control unit (SPCU). 21. Integrated production manifold and a multiphase pump unit as stated in claim 20, characterized in that the production pipelines connected to the manifolds form a spiked loop around the control post in the manifold.