The Effect of Pressure Decline Rate and Pressure Gradient on the Behaviour of Solution Gas Drive in Heavy oil

Sheikha, Hussain; Pooladi‐Darvish, Mehran

doi:10.2118/109643-ms

Cited by 2 publications

(1 citation statement)

References 31 publications

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“…Sheikha and Pooladi-Darvish 46 further studied the effect of pressure decline rate and pressure gradient on the behaviour of solution gas drive in heavy oil. They suggested that a high pressure decline rate results in larger super-saturation and faster nucleation and therefore leads to more dispersed gas bubbles.…”

Section: Effect Of Depletion Rate and Pressure Gradientmentioning

confidence: 99%

Gas Recharging Process Study in Heavy Oil Reservoirs

Zhang

2014

Day 3 Thu, June 12, 2014

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Gas recharging process, as a supplemental technique for heavy oil reservoirs with thin layers, has attracted researchers' attention. This thesis focused on three post-cold production process studies-CH 4 recharging and depletion, CO 2 and C 3 H 8 huff-puff, and C 3 H 8 flooding. Two 18m in length glass beads and sand packed cores and one 1.5m in length sand packed core were used for testing. The mechanisms of each process were investigated. Foamy oil flow under the solution gas drive mechanism was clearly observed during two long core methane depletion processes.The effects of core length and permeability on oil recovery were discussed. CT scanning technique was applied to capture core saturation variations after each process at the 1.5m core, which helped better understanding of the mechanisms of the three gas recharging processes and also was successfully applied to explain what happened in two long cores.iii Acknowledgements

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Section: Effect Of Depletion Rate and Pressure Gradientmentioning

confidence: 99%

Gas Recharging Process Study in Heavy Oil Reservoirs

Zhang

2014

Day 3 Thu, June 12, 2014

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Fullfield Heavy Oil Conversion from Cold to Hot Production; Challenges and Solutions

Jansen

Curtis

Mejia-cana

et al. 2011

SPE Annual Technical Conference and Exhibition

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With an increasing interest for extra heavy oil (EHO) extraction, a number of heavy oil fields will initially be produced using a cold production scheme, while at a later stage thermal production in the form of steam injection can be introduced to enhance the recovery. Such a fullfield conversion from cold to hot production has so far only been performed to a limited extent, hence the experience and understanding of the various challenges with such a task is limited. While much work has been carried out on both cold and hot production of extra heavy oil as stand alone processes, little has been published around the procedure of converting from cold to hot production. This conversion contains a number of pitfalls detrimental to a successful field development. In an EHO cold to hot conversion scheme, several choices will have to be made with respect to well positioning, completion options, timing and scale of the conversion. Investment decisions in surface equipment, handling and cost of water and gas for steam generation are also important considerations. All of these designs and decisions affect the success and profitability of the conversion scheme. One of the basic challenges with modeling cold to hot conversion is the difference in scale required. The thermal simulation of a hot production scheme requires a very fine grid to capture the fine scale processes, while for full field simulation one needs a much coarser grid to be able to obtain a manageable model both in size and simulation time. The high number of producers and injectors required on a fullfield scale adds to the complexity of the problem, making recovery, production profile and optimal number of wells highly uncertain. A simplified translation to fullfield conditions of these parameters from sector models or spreadsheets, can introduce erroneous results and conclusions. To assure the best field performance over its lifetime, these issues need to be considered already in the initial field design. Based on the work performed, several interesting observations have been made regarding how to optimize field performance.

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The Effect of Pressure Decline Rate and Pressure Gradient on the Behaviour of Solution Gas Drive in Heavy oil

Cited by 2 publications

References 31 publications

Gas Recharging Process Study in Heavy Oil Reservoirs

Gas Recharging Process Study in Heavy Oil Reservoirs

Fullfield Heavy Oil Conversion from Cold to Hot Production; Challenges and Solutions

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