Monitoring hydrocarbon fluid flow

A method of monitoring a plurality of properties relating to a hydrocarbon fluid flow through a pipeline at a tree for a subsea hydrocarbon extraction facility, the method comprising locating a plurality of sensors at or near a position which is optimum for monitoring the at least one of the plurality of properties in regard to the configuration of the pipeline, the sensors being configured to monitor at least one of the plurality of properties.

BACKGROUND OF THE INVENTION

1. Field of the Invention

Embodiments of the present invention relate to monitoring hydrocarbon fluid flow and, more particularly, monitoring hydrocarbon fluid flow at a tree of a subsea hydrocarbon extraction facility.

2. Description of the Prior Art

Hydrocarbon fluid flowing from an offshore reservoir or well is multiphase in nature in that it contains oil, gas and water and can also contain particulates such as sand. Multiphase meters are used to measure the content of gas, oil and water in the fluid, and other sensors are incorporated to measure the particulates. The sensor equipment is normally mounted on a Christmas tree installed on the seabed, and is usually placed on the Christmas tree after the design has been established. Therefore, the sensor location is often dictated by practical issues rather than the optimum positions for measurements. Current practice is to install a multiphase meter on the Christmas tree with a sensor package positioned at a convenient position. The sensor package usually contains a bundle of sensors. Because the sensors are bundled, the individual sensors may not all be ideally positioned to accurately measure their particular parameter. Some fluid flow measurement techniques require the flow to be conditioned (for example, laminar or turbulent) to be at their optimal accuracy. There is a need for a more accurate method of measurement.

One of the most critical aspects of fluid flow is the effect it has on equipment and fluid pipes due to hydrate formation, wax deposition, slugging and corrosion.

These have a serious effect on the efficiency of the fluid flow, equipment lifetime and through-life maintenance requirements, but can be minimized by taking appropriate remedial action, such as the use of chemical injection to clean the surfaces of the fluid pipes. There is a need for accurately identifying, locating and measuring these effects. However, the availability of sufficiently reliable and accurate sensors has limited the ability to provide the required information. Since the positioning of the sensor package on the Christmas tree is decided after the Christmas tree design has been established, the positioning is not optimized.

BRIEF SUMMARY OF INVENTION

According to an embodiment of the present invention, there is provided a method of monitoring a plurality of properties relating to a hydrocarbon fluid flow through a pipeline at a tree for a subsea hydrocarbon extraction facility. The method comprises locating a plurality of sensors at or near a position which is optimum for monitoring the at least one of the plurality of properties in regard to the configuration of the pipeline, the sensors being configured to monitor at least one of the plurality of properties.

According to another embodiment of the present invention, there is provided a tree for a subsea hydrocarbon extraction facility. The tree comprises a plurality of sensors configured to monitor a plurality of properties relating to a hydrocarbon fluid flow through a pipeline at the tree, wherein each of the plurality of sensors is configured to monitor at least one of the plurality of properties, and wherein each of the plurality of sensors is located at or near a position which is optimum for monitoring the at least one of the plurality of properties in regard to the configuration of the pipeline.

DETAILED DESCRIPTION OF THE INVENTION

A subsea Christmas tree of a subsea hydrocarbon extraction facility, in its basic form, houses a number of valves for controlling the flow of fluid from a well (such as the main flow control and directional flow valves) together with a subsea control module which enables the valves to be controlled by means of electric or hydraulic actuators. There is also a sensor pack which provides essential data on the state of health of the subsea system and for the provision of data for optimizing the fluid flow from the well.

The physical configuration of the Christmas tree mechanical structure and of the equipment installed results in the flow pipeline, which carries the hydrocarbon fluid, having several sharp bends. These bends can provide optimized positions for some sensor measurements.

FIG. 1is a simplified schematic illustration showing the main hydrocarbon flow pipeline components and appropriate positions for installing some typical sensors in a tree according to an embodiment of the present invention.

InFIG. 1, a subsea Christmas tree1at a wellhead2has a tree cap3and a flow pipeline4fed from production tubing5. The flow pipeline4exits the tree1to a flow line in the direction of arrow A and has first, second and third severe or sharp bends6,7and8. Between the tubing5and the first bend6, the pipeline4has a flow control valve9. Between the third bend8and the exit of the flow pipeline4, the flow pipeline4has a directional control valve10. Between the third bend8and directional control valve10, there is a branch section11having a directional control valve12.

The embodiment of the present invention utilizes the knowledge of the flow regimes in the hydrocarbon flow pipeline4and valve configurations on the tree1to place suitable discrete sensors in the most appropriate positions to acquire a more accurate overall monitoring of properties relating to hydrocarbon fluid flow. The arrangement of sensors utilizes the physical configuration of the tree1and the configuration of the flow pipeline4to enable measurements of such properties to be made by using discrete sensors each placed at or near an optimum position in the fluid flow for its measurement in the most meaningful manner.

Typical measurements for which optimum positions (shown inFIG. 1) can be identified on the Christmas tree are described below.

For vibration and/or strain measurement, a sensor13can be located at or near flow control valve9, which could cause vibration, or can be located at a known weak point.

For bulk density measurement, a sensor14can be located at or near a point of high turbulence such as after flow control valve9or at or near other disruptions.

For particulate detection, such as sand detection, an acoustic sensor15can be located at or near the second bend7in the flow pipeline4to detect particle impact. The acoustic sensor being non-intrusive can be fitted to the outside of the flow pipeline4.

For ultrasound, electrical impedance spectroscopy, microwave measurements or similar measurements, a sensor16can be located between the second bend7and the third bend8where there is a conditioned steady state flow.

For erosion measurement, a sensor17can be located at or near the third bend8, where there is most serious erosion, to make a direct measurement.

For pressure drop, a sensor18which measures pressure drop through a restriction or known change in geometry, such as the pressure drop, can be located across directional control valve10.

For temperature measurement, a sensor19can be placed before directional control valve12at or near a most isolated point from any interfering temperature.

Embodiments of the present invention offer a significantly more detailed and accurate method of measuring produced fluid properties compared to conventional methods. Embodiments of the present invention also offer increased functionality for a Christmas tree compared to the conventional approach of integrating instruments attached to a tree as stand-alone instrument packages.

Although embodiments of this invention have been described above with reference to the drawing, those skilled in the art could make numerous alterations to the disclosed embodiments without departing from the spirit or scope of this invention. For example, features shown or described in one embodiment can be applied to another embodiment to form a new embodiment. The particular embodiments described above shall be interpreted as illustrative only and not limiting. All alternative changes that are made on the basis of the description and drawing of the present application are within the scope of the claims.