Current State of the Art in the Design of Subsea HIPPS Systems

Davalath, Janardhan; Skeels, H.B.; Corneliussen, Sverre

doi:10.4043/14183-ms

Cited by 8 publications

(1 citation statement)

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“…A surface HIPPS system is perceived to be more reliable because it is easier to inspect and repair 3 . In addition, it is more costeffective to test the system regularly without concern for the cool down effects associated with seawater cooling in deepwater, which must be considered when testing a Subsea HIPPS system.…”

Section: Introductionmentioning

confidence: 99%

Optimizing Production Rates and Reducing Life-Cycle Cost for High-Pressure Fields

Patni¹

2006

Offshore Technology Conference

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TX 75083-3836, U.S.A., fax 01-972-952-9435. AbstractHigh pressure challenges are particularly significant in deep wells on the Gulf of Mexico shelf and in deep and ultradeepwater. Operators evaluating potential deepwater prospects are beginning to encounter wellhead pressures that exceed current industry development capabilities and/or that results in high CAPEX. Operators are looking for technologies that increase value of these fields by reducing cost and increasing production.A key enabling technology for developing these highpressure fields is a high integrity pressure protection system (HIPPS). The HIPPS isolates the lower pressure rated flowlines and riser from an overpressure. Thus HIPPS would allow a high-pressure field to tie-in to existing lower pressure rated infrastructure, a capability that will facilitate the development of high-pressure fields. One of the drivers in developing these high CAPEX HP/HT fields is to optimize production from these subsea fields. Installing a HIPPS system subsea allows the flowline to be designed to just above well flowing pressure instead of well shut-in pressure. This results in de-bottlenecking the flowline/riser by increasing the crosssectional area for flow for the same nominal size flowline. Based on flow simulation over the life cycle of the field using a reservoir pressure decline curve for an example case, the paper demonstrates that installing subsea HIPPS results in:• Higher total recoverable reserves from the field • Abandonment at lower reservoir pressure • Maintaining economical oil flow rates even at the commencement of water cut • Secondary benefits including higher flowing wellhead and flowline temperatures. These benefits will be illustrated based on the analysis of a deepwater field development design case. This paper will give decision makers an insight into the benefits of subsea HIPPS in optimizing production and a method for developing project / portfolio valuation matrices for the HP/HT fields.

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Section: Introductionmentioning

confidence: 99%