Unbonded flexible pipes constitute key components in floating production systems for the offshore oil and gas industry and it is important to continuously improve the performance of these pipes to meet the demands of production regularity under increasingly severe operational conditions. The polymeric pressure sheath is a critical component in flexible pipes as the function of the layer is to make the pipe leak proof. Therefore, it is important to carry out material research to enhance the performance of this layer thus further securing the long term integrity of the pipe. A new method to cross-link HDPE pressure sheath in flexible pipes using Peroxide in combination with infrared radiation (IR) has been developed. This method is unique in the sense that it is an inline process where extrusion and cross-linking is done in one step. The IR-cured XLPE technology will be described in this paper with emphasis on presentation of detailed results from the comprehensive qualification programme which has been carried out according to API Spec 17J / ISO 13628-2 [1]. Also, actual field applications of these pipes will be presented including ID15" flowlines.The newly developed IR cross-linking method significantly expands the application envelope of the conventional XLPE flexible pipes, for example with respect to increase of allowable bore pressure and temperature, and the manufacture of large size pipes up to ID16" or more with uniform cross-linking of the entire thick-walled pressure sheath. Further novel applications which this technology enables include the manufacture of cross-linked intermediate and outer sheath layers. The paper will present comprehensive qualification test results from both material and mid-scale pipe testing which document that the new IR cross-linking technology is superior to the conventional cross-linking technology previously used for flexible pipes. In particular, it is shown that the new XLPE material can sustain considerably higher pressure and temperature loads compared to existing industry standards, for example as specified in API RP 17B / ISO 13628-11 [2].
Dynamic flexible risers are unique in the sense that they can accommodate substantial curvature variations combined with high tensile loads without compromising their fatigue capacity. However, as the fatigue endurance assessment becomes increasingly challenging with increasing water depth it is of utmost importance to know the fatigue driving mechanisms in flexible risers used for deepwater applications. Thus, key fatigue drivers are discussed in this paper including high inter-layer contact pressure due to severe tension and ambient hydrostatic pressure loads, corrosion fatigue in connection with high strength steel armour, riser structural properties (e.g. stiffness and damping), impact from riser VIV and second order springing effects of the floating unit. Furthermore, helpful fatigue analyses procedures are presented including a methodology based upon transfer functions that can determine the fatigue damage along the length of a riser thus facilitating an efficient irregular wave fatigue assessment. At present, dynamic flexible risers are used in connection with oil and gas floating production facilities in water depth down to approximately 2000m. However, research is ongoing to further expand the flexible riser capabilities thus meeting the requirements of the future offshore field developments at even more demanding water depth between 2000m and 3000m. Thus, it is demonstrated in the paper how a new flexible pipe concept, Flextreme®, having excellent fatigue performance can be used for deep- and ultra-deepwater applications, and how failure modes normally associated with the conventional flexible pipe structure have been eliminated. Finally, ways to manage the risk of fatigue failure during operation of a deepwater flexible riser are addressed, including presentation of a condition monitoring technique using optical fiber technology. Also, a concept based upon active flushing of the riser annulus is described which can be used to extend the service life of in particular sour service risers. Introduction Fatigue assessment of flexible riser systems in general is a challenging design task, involving dynamic system configurtion analyses combined with static pipe cross-sectional stress calculations. Despite the fact that flexible riser systems have been analyzed for a couple of decades substantial resources are still being spent to develop theoretical analysis models that can better describe their fatigue behaviour. As a result, many of the governing fatigue input parameters can now be established with a high degree of accuracy (e.g. design S-N curves, stress distribution of pipe cross-section), thus increasing the confidence in the results. Furthermore, the recent advances in condition monitoring (including optical fiber technology) make it possible to verify the riser integrity during service. However, the originally established safety factor of 10 is often still used as acceptance criterion when assessing the accumulated fatigue damage. This circumstance becomes increasingly challenging with increasing water depth as deepwater riser systems may have difficulties in meeting similar safety factor, in particular when analyzing risers subjected to corrosion fatigue. Thus, it is important to understand the key fatigue driving mechanisms for deepwater riser systems to establish a sound basis for assessing the fatigue endurance with confidence. Thereby, it becomes viable to establish an updated safety factor without compromising the intended reliability of the riser system. Recent work on establishing reliability-based fatigue safety factors can be found in [1] and [2].
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.