The disclosed subject matter relates generally to subsea hydrocarbon production and, more particularly, to an optical leak detector for detecting material leakage from subsea equipment.
To control a subsea well, a connection is established between the well and a monitoring and control station. The monitoring and control station may be located on a platform or floating vessel near the subsea installation, or alternatively in a more remote land station. The connection between the control station and the subsea installation is usually established by installing an umbilical between the two points. The umbilical may include hydraulic lines for supplying hydraulic fluid to various hydraulic actuators located on or near the well. The umbilical may also include electrical and or fiber optic lines for supplying electric power and also for communicating control signals and/or well data between the control station and the various monitoring and control devices located on or near the well.
Hydrocarbon production from the subsea well is controlled by a number of valves that are assembled into a unitary structure generally referred to as a Christmas tree. Christmas tree and wellhead systems have the principle functions of providing an interface to the in-well environment, allowing flow regulation and measurement, and permitting intervention on the well or downhole systems during the operational life of the well. The actuation of the valves in the Christmas tree is normally provided using hydraulic fluid to power hydraulic actuators that operate the valves. Hydraulic fluid is normally supplied through an umbilical running from a remote station located on a vessel or platform at the surface. Alternative systems using electrically based actuators are also possible.
The subsea equipment includes many possible leakage paths, such as valves, pipe junction actuators, flanges, pipe connectors, jumpers, seals, etc. The detection of leaks of hydrocarbons, hydraulic fluids, tracers and other chemicals from underwater structures is an important requirement in enhancing the environmental and operational efficiency of underwater systems such as Christmas trees and subsea processing systems. A range of underwater leak detection systems have been developed including those based on acoustic, fluorescence, temperature and gas measurements. Often these are designed to be used as part of survey operations, but in a few instances as permanent monitors. Such devices are typically portable and are mounted to mobile devices, such as remotely operated vehicles (ROVs).
Acoustic devices are capable of detecting leaks from a wide area via the noise that may be produced by material leaking from underwater structures. Such acoustic systems detect only the secondary effect of the leak (i.e., the noise), hence, the application of acoustic detectors is significantly restricted in noisy environments. Further, acoustic detectors are not generally able to accurately locate a leak.
This section of this document is intended to introduce various aspects of art that may be related to various aspects of the disclosed subject matter described and/or claimed below. This section provides background information to facilitate a better understanding of the various aspects of the disclosed subject matter. It should be understood that the statements in this section of this document are to be read in this light, and not as admissions of prior art. The disclosed subject matter is directed to overcoming, or at least reducing the effects of, one or more of the problems set forth above.