NO852804L - PROCEDURE FOR AA RECOVERY FAVORABLE CONDITIONS IN A PIPELINE CONDUCTING A SINGLE OR MULTIPLE PHASE, AND A DEVICE FOR IMPLEMENTING THIS PROCEDURE. - Google Patents

Description

The present invention relates to another method

to restore favorable flow conditions in a pipeline carrying a single- or multi-phase flow, as well as a device for carrying out this method.

When operating pipelines that carry a multiphase flow, problems are often encountered that are directly related to the fact that the flow rate of the fluid through the line is lower than the flow rate for which the pipeline is designed. Such too low flow rates can under certain conditions become permanent and give rise to problems such as hard slugging, hydrate formation, accumulation of formation water and unstable discharge pressure. As a rule, multiphase pipelines are dimensioned with the aim of achieving a maximum flow rate, but at the same time so that erosion is avoided. If the fluid flow decreases, the flow rate may become too low, and the aforementioned problems will occur. In extreme cases, the problems can become so great that production has to be stopped.

The invention is particularly, but not exclusively, related to pipelines between two sea-based platforms; pipelines between a sea-based platform and a treatment facility on land; pipelines leading from subsea wells or foundations to a central processing platform, for example gas/condensate pipelines between a simple water removal platform and a central processing platform, gas/condensate/water pipelines between a wellhead platform and a central processing platform, subsea flow lines in general , gas/condensate/water pipelines from sea-based wellhead platform or underwater foundation to land-based treatment plant etc.

The purpose of the invention is thus to restore favorable flow conditions in a pipeline that carries a multiphase flow and comes into use when the flow rate of the fluids flowing in the pipeline has on a permanent basis decreased to a level where normal operation is not achieved or can be carried out.

The purpose is achieved by the features specified in the patent claims.

The invention is thus based on the insertion of tubular insert sections in the pipeline when the flow of hydrocarbons has decreased permanently to such an extent that normal operation can no longer be maintained. The pipeline's new cross-sectional area must be chosen so that gas and liquid velocities are created that lie within a favorable flow range.

In order to reduce the formation of liquids and hydrates, it is desirable to provide an insulating effect in the pipeline. The insert pipe sections should therefore be made of an insulating material that is compatible with the environment they will be in. An oil-resistant polymer material has proven to be appropriate. The insulation effect can be increased by supplying the insert pipe sections with an insulation layer (foam plastic, insulation materials with closed cells, microspheres etc.)

It is preferred to install the insert pipe sections in the pipeline during normal operation. If special measures are taken, the installation can also be carried out during downtime periods. The insert pipe sections can have a length of, for example, 10 metres, dimensioned to fit the available equipment for sending spikes. The insert pipe sections are inserted section by section like normal spikes. If necessary, a membrane can be placed at the front or rear end of the insert tube sections, which thus forms a reaction surface for the necessary propulsion force. Such a membrane is dimensioned so that it will break down and burst as a result of the flow in the pipeline or by direct impact from the end of the insert pipe section that is then installed.

The pipeline provided with the insert pipe sections can be operated in the same way as the original one, but will provide higher flow rates for the fluids. Pipe scraping can be carried out as for any other pipeline, but if the insert pipe sections consist of a somewhat sensitive material, for example oil-resistant polymer material, the use of hard scraping spikes should be avoided. The first spike used after the installation of the insert pipe sections should be a relatively soft scraper, which at this point serves to remove any remnants of burst membranes from the pipeline.

As previously mentioned, the invention is used in connection with pipelines between platforms in one-, two- or multi-phase operation. It can also be advantageously used for pipelines that connect sea-based platforms with facilities on land and from underwater wells or foundations to a central treatment platform. If automatic insertion of the insert pipe sections is used, it will be possible to install 500 - 1000 meters of insert pipe sections per day, depending on the diameter and length of the insert pipe sections.

The following examples show some areas of application where the invention brings advantages:

(a) In the case of gas/condensate piping between a single water removal platform and a central treatment platform. Installation of the tubular insert sections will in this case ensure stable flow and help prevent hydrates from forming; (b) In the case of gas/condensate/water pipelines between a wellhead platform and a central processing platform. Installation of the insert pipe sections will in this case, in addition to counteracting the formation of hydrates, counteract the collection of water in the pipeline; (c) In the case of gas/condensate/water pipelines from sea-based wellhead platforms or subsea foundations to land-based treatment facilities. The aforementioned problems in connection with a reduced flow rate are greater with such pipelines than with pipelines between platforms, as the former pipelines follow hilly terrain.

The aforementioned areas of application obviously only form part of the areas of application where the invention can be used with advantage.

In extreme cases, it may become necessary to have to carry out the insert pipe sections with such a large wall thickness that pipeline inspection cannot be carried out with the help of so-called "intelligent" spikes or pipe scrapers. Such a lack of inspection options is also quite common in connection with flexible pipelines. The problem can be reduced through a thorough inspection of the pipeline in question before installation of the insert pipe sections, as annual pressure tests are then carried out. In principle, there is nothing to prevent removing the inserted pipe sections for inspection purposes, but this will probably represent time-consuming work and is assumed to be redundant in the vast majority of cases. Corrosion in the space between the pipeline and insert pipe-six ion can present problems. It is therefore recommended to inject corrosion inhibitor in large doses during the installation of the insert pipe sections and in smaller doses while production is underway. It is also possible to supply the outer surface of the insert tube sections with sacrificial anodes.

The insert pipe sections must be properly connected to each other, otherwise spikes or pipe scrapers will have difficulty sliding through the pipeline. It is advantageous to chamfer the ends of the sections to thereby provide an even, smooth path for the pipe scrapers.

Special consideration must be given to pipeline bends. Insert pipe sections for such pipe bends should be made of a plastic material that makes the sections pliable and flexible.

To ensure correct connection of the insert pipe sections, they can advantageously be designed with per se known pipe joints or connectors. This can be advantageous with regard to parts of the pipeline or possibly the entire pipeline. Especially in risers where the insert pipe sections can fall back during installation or due to thermal shrinkage, such connections may prove necessary. On the downstream side of the pipeline, it may be necessary to rigidly secure the insert pipe sections. This can be implemented using pipe end fittings connected to a flange.

The temperature in the pipeline can change in different operating situations. The insert pipe section material will probably have a coefficient of thermal expansion that deviates from that of the steel pipeline. The connections must therefore be dimensioned and designed in such a way that they allow such deviations.

The invention is explained in the following description with reference to the drawings, in which the invention is illustrated

connection to execution examples, and where:

Fig. 1 schematically shows a typical application case for the invention, where a pipeline connects two platforms; Fig. 2 shows an axial section through a pipeline in which insert pipe sections according to the invention are placed; Fig. 3 shows in axial section an insert pipe section with a rear propulsion membrane in two phases during the introduction into a pipeline; Figs 4 and 5 show schematic principle sketches of insertion methods for insert pipe sections in a pipeline; Figs 6 and 7 illustrate a part of an insert pipe section equipped with sacrificial anodes which are connected to the inner surface of the pipeline; and Figs. 8 and 9 show suitable pipe end connectors for connecting insert pipe sections. Fig. 1 schematically illustrates a typical application case for the invention. A pipeline 1 here connects two platforms 2 and 3 with each other. One can, for example, be a wellhead platform and the other a central processing platform. Fig. 2 shows an axial section through a pipeline 1 in which are placed two insert pipe sections 4 and 4' according to the invention, where the sections are provided with known per se pipe end coupling pieces, for example in the form of cooperating pointed end and socket couplings. Fig. 3 shows in an axial section an insert pipe section 4 in two phases during the introduction into the pipeline 1. In the one with full

in the position shown by solid lines, the insert pipe section 4 is almost brought into place in the pipeline, while in the position shown by dashed lines it takes the correct position in the pipeline.

The insert tube section 4 is provided at the rear end with a membrane 5 which forms a reaction surface across the feed direction. Such a propulsion-promoting membrane 5 will be dimensioned in such a way that it collapses and explodes as soon as it is stopped and exposed to the forces from the fluids flowing in the pipeline. The membrane 5 will also be able to be placed so that the connecting piece, for example a pointed end on the subsequent section, will ensure the bursting of the membrane. Remains of such membranes can be removed with a suitable pipe scraper after the installation of the insert pipe sections 4, 41.

Fig. 4 and 5 schematically show an installation device for the insert pipe sections. The reference number 6 denotes a hydraulic storage and feed container with downwardly sloping support plates 7 for the sections 4. The bottom inclined plate ends in a central guide channel 8, from which the insert pipe section lying at any time is fed into the pipeline. A hydraulic feed means is indicated at 9. The line for the production flow is denoted by 10 and the line for fuel gas flushing by 11.

In the axial section according to fig. 6 and 7 it is shown that the insert tube six ions 4 can be equipped with sacrificial anodes 12 at its outer surface with connection means 13 to the inner surface of the pipeline 1.

Fig. 8 and 9 show suitable designs for pipe-end coupling pieces, where 14 denotes the design of the coupling at the front end of the section 4 and 15 the design of the coupling at its rear end. In addition to being designed as pointed end and socket couplings, respectively, the pointed end coupling has a circumferential projection 14' which, when connected to the section inserted in front, is designed to engage in a correspondingly shaped circumferential groove 15' in the socket coupling 15.

Fig. 9 shows a pipe end fitting 16 designed in a similar way to the sleeve connection 15 in fig. 8. The pipe end fitting 16 is intended to be mounted on the platform and can be attached to a flange connection 17 on the pipeline 1.

Claims (12)

1. Method of restoring favorable flow conditions in a pipeline (1) carrying a single- or multi-phase flow, in particular for pipelines between two sea-based platforms (2, 3), between a sea-based platform and a treatment facility on land, or pipelines leading from subsea wells or foundations to a central treatment platform, for example gas/condensate pipelines between a simple water removal platform and a central treatment platform, gas/condensate/water pipelines between a wellhead platform and a central treatment platform , undersea flow lines in general, or gas/condensate/water pipelines from a sea-based wellhead platform or undersea foundation to a land-based treatment facility, etc., characterized in that in the pipeline (1), when the flow rate has decreased on a permanent basis to a level where normal operation is not achieved or can be carried out, insert tubular insert sections (4, 4') with substantially min dre effective flow cross-sectional area than that of the pipeline. 2. Method according to claim 1, characterized in that tubular insert sections (4, 4') are inserted into the pipeline (1) in that insert sections (4, 4'), provided with a membrane (5), are fed up to connection with already installed insert sections of the fluid flow through the pipeline, as membranes (5) and insert sections are of such a nature and are arranged so that the membranes are caused to burst during connection of adjacent sections. 3. Method according to claim 2, characterized in that tubular insert sections (4, 4'), provided with a membrane (5), are introduced into the pipeline (1) via spike emitters known per se. 4. Method according to claim 3, characterized in that known automatic spike senders are used. 5. Method according to claim 1, characterized in that, in order to prevent corrosion in the space between the pipeline (1) and the insert pipe section (4, 4'), a corrosion inhibitor is injected. 6. Device for carrying out the method specified in patent claim 1, characterized by insert pipe sections (4, 4') for insertion into said pipelines, which insert pipe sections have a substantially smaller flow cross-sectional area than the pipeline and preferably consist of insulating material, for example oil-resistant polymer material. 7. Device according to claim 6, characterized in that the insert pipe sections are provided with an insulation layer. 8. Device according to claim 6 or 7, characterized in that the outer surface of the insert pipe sections is provided with one or more sacrificial anodes (12) with connection means (13) for contact with the inner casing surface of the pipeline (1). 9. Device according to one or more of claims 6-8, characterized in that the ends of the insert pipe sections are designed with simple, per se known pipe connections (14, 15) which cooperate with a correspondingly designed connection on the adjacent end of a nearby insert pipe section. 10. Device according to one or more of claims 6-9, intended for pipeline bends, characterized in that the insert pipe sections consist of pliable and flexible material, preferably insulating material. 11. Device according to claim 9, where the ends of the insert pipe section are designed with cooperating coupling pieces of the pointed end/socket coupling type, characterized in that the pointed end coupling at one end of the insert pipe section has a radially projecting circumferential portion (14') designed to engage in a corresponding formed circumferential groove (15') in the socket coupling on the adjacent end of a nearby insert pipe section. 12. Device according to any one of claims 6-11, characterized in that each insert pipe section is provided with a membrane (5), which forms a reaction surface for the forces that serve to feed the section forward during installation in the pipeline (1) , and that insert sections and membranes are dimensioned and arranged so that the membranes will burst when connected to an adjacent section, respectively by the forces the membrane is exposed to from the fluids flowing in the pipeline when it is in operation.