Electrically Heat-Traced Flowline Technology – Key Enabler for Optimised Field Architecture Developments and Operated Fields with High Thermal Performance Requirements

Cherkaoui, Saad; Verdeil, Julien; Giraudbit, Sonia; Girard, Christian

doi:10.4043/27100-ms

Cited by 8 publications

(3 citation statements)

References 10 publications

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“…The EHTF is a pipe-in-pipe system (grey and yellow colours in figure below) with a set of electrical wires (red colour) positioned around the inner pipe and below an aerogel thermal insulation layer (blue colour). See [8] for detailed presentation of the EHTF.…”

Section: Figure 13-schematic Showing Hydro-forming Of Cra Liner and Bmentioning

confidence: 99%

Field Development Cost Optimization: a SURF Contractor's Experience and Perspective

Seguin

Roux

Louvet

2016

Day 3 Thu, March 24, 2016

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In the current offshore industry context, ways for significant cost optimizations must be explored and developed to make offshore projects viable. The cost share of the SURF (Subsea Umbilicals Risers and Flowlines) system is increasing, with developments in deeper waters and with more spread reservoirs. The SURF system also presents a wide range of possible options to be considered, thus with many opportunities for overall cost reductions.This paper presents examples of solutions to reduce costs: early engagement of SURF contractor for the field concept selection, global understanding and optimization of the field architecture, closely linked to installation vessels and methods selection, introduction of new technology, and consideration of interfaces between SURF, SPS (Subsea Production System) and Floater packages to reach a global optimum. The efficient development of these emerging solutions is supported by strong experience in full Engineering, Procurement, Construction and Installation (EPCI) execution of SURF contracts.• Possibility to integrate new technologies developed by SURF contractor into the field development plan, unlocking technical challenges or generating significant cost savings. • Robust cost estimates, execution schedule and risk evaluation, based on extensive EPCI project execution track-record.

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Section: Figure 13-schematic Showing Hydro-forming Of Cra Liner and Bmentioning

confidence: 99%

Field Development Cost Optimization: a SURF Contractor's Experience and Perspective

Seguin

Roux

Louvet

2016

Day 3 Thu, March 24, 2016

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“…1), has been well described and documented in previous papers (Cherkaoui 2016, McDermott 2014, Louvet 2016 and in very basic terms comprises a Pipe-in-Pipe (PiP), high performance thermal insulation, specifically designed electrical heating wires and various dual barrier connecting methods (to gain electrical access to the enclosed heating wires within the PiP annulus) typically forming a low power EHTF system as developed by Subsea 7 and ITP InTerPipe. The EHTF system presented ( Fig.…”

Section: Introductionmentioning

confidence: 99%

“…There may be multiple power feeds on longer lines (Cherkaoui 2016). This voltage can be supplied from either local or remote topsides facilities bringing with them the option of multiple power circuits direct from topsides to subsea or alternatively using one three phase supply feed plus a subsea distribution/splitting system.…”

Section: Introductionmentioning

confidence: 99%

Electrical Power Infrastructure and Control Solutions for Subsea Electrically Heat-Traced Flowline Pipe-in-Pipe EHTF PiP System

Silcock

Charbonnier

Girard³

2016

Offshore Technology Conference

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This paper describes the electrical power infrastructure including high voltage and low voltage power transformers, switchboards, distribution units and their associated connection and protection systems required to power a subsea EHTF installation. It discusses the options considered for both topsides and subsea electrical power infrastructure, their integrity monitoring and methods of fault protection.The low power EHTF PiP system, developed by Subsea 7 and ITP InTerPipe, typically requires a subsea supply operating voltage of 1kVrms phase to neutral at the flowline start and the requirement to supply multiple heating wires arranged in subsets of three phase circuits, typically 12. This voltage sits at the challenging intersection of normal industry low voltage (Ͻ1kV) and high voltage standards (Ͼ1.8kV) and thus relevant clauses have to be selected to fit the qualification purpose of the full EHTF PiP system. This voltage can be supplied from either local or remote topsides facilities bringing with them the option of multiple power circuits direct from topsides to subsea or alternatively using a subsea distribution/splitting system. The electrical power system needs to be able to either adjust the applied voltage, the time applied or the number of heating elements in order to control the power required by the pipeline heating system for different production scenarios and redundancy purposes. It also needs full integrity monitoring and appropriate fault clearance facilities that can operate for the local and remote topsides solutions and operate successfully on long umbilicals and EHTF lengths up to ca. 30 km from a single power feed. There may be multiple power feeds on longer lines (Cherkaoui 2016).Instead of complex phase control systems, a simple heating control, using contactors on individual circuits in the local topsides option provides sufficient EHTF heat control. Whereas the addition of subsea fuse modules and/or solid state relay modules (SSR) in the remote topsides option can provide individual subsea circuit isolation and protection.The benefits and drawbacks of different power transformer arrangements are reviewed with available topsides electrical network (power balance / voltages / redundancy). Integrity monitoring and fault protection for local and remote topsides options are reviewed; specifically, the application of line insulation monitoring systems and residual current protection devices.

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Buckle Propagation in Pipe-in-Pipe Systems

Kyriakides¹,

Lee²

2021

Mechanics of Offshore Pipelines, Volume 2

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Electrically Heat-Traced Flowline Technology – Key Enabler for Optimised Field Architecture Developments and Operated Fields with High Thermal Performance Requirements

Cited by 8 publications

References 10 publications

Field Development Cost Optimization: a SURF Contractor's Experience and Perspective

Field Development Cost Optimization: a SURF Contractor's Experience and Perspective

Electrical Power Infrastructure and Control Solutions for Subsea Electrically Heat-Traced Flowline Pipe-in-Pipe EHTF PiP System

Buckle Propagation in Pipe-in-Pipe Systems

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