SWAG Injection on the Siri Field - An Optimized Injection System for Less Cost

Quale, Eileen A.; Crapez, Benedicte; Stensen, Jan Åge; Berge, Lars Inge

doi:10.2118/65165-ms

Cited by 26 publications

(8 citation statements)

References 6 publications

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“…The improved gas handling and oil recovery have been reported for SWAG injection at Siri field (Berg et al 2002 andQuale et al 2000), the Joffre Viking (Stephenson et al 1993) CO 2 miscible flood and SWAG emulation at the Rangely CO 2 miscible flood (Attanucci et al 1993). Pilot tests performed on Kuparuk River Field in Alaska Stoisits et al 1995) have also demonstrated the feasibility of SWAG injection.…”

mentioning

confidence: 87%

Visualisation of Residual Oil Recovery by Near-miscible Gas and SWAG Injection Using High-pressure Micromodels

2008

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We present results of high-pressure micromodel visualizations of pore-scale fluid distribution and displacement mechanisms during the recovery of residual oil by nearmiscible hydrocarbon gas and SWAG (simultaneous water and gas) injection under conditions of very low gas-oil IFT (interfacial tension), negligible gravity forces and water-wet porous medium. We demonstrate that a significant amount of residual oil left behind after waterflooding can be recovered by both near-miscible gas and SWAG injection. In particular, we show that in both processes, the recovery of the contacted residual oil continues behind the main gas front and ultimately all of the oil that can be contacted by the gas will be recovered. This oil is recovered by a microscopic mechanism, which is strongly linked to the low IFT between the oil and gas and to the perfect spreading of the oil over water, both of which occur as the critical point of the gas-oil system is approached. Ultimate oil recovery by near-miscible SWAG injection was as high as near-miscible gas injection with SWAG injection using much less gas compared to gas injection. Comparison of the results of SWAG experiments with two different gas fractional flow values (SWAG ratio) of 0.5 and 0.2 shows that fractional flow of the near-miscible gas injected simultaneously with water is not a crucial factor for ultimate oil recovery. This makes SWAG injection an attractive IOR (improved oil recovery) process especially for reservoirs, where continuous and high-rate gas injection is not possible (e.g. due to supply constraint).

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confidence: 87%

Visualisation of Residual Oil Recovery by Near-miscible Gas and SWAG Injection Using High-pressure Micromodels

2008

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“…The IOR has been reported for Simultaneous Water And Gas (SWAG) injection at Siri Field (Berge et al 2002;Quale et al 2000), the Joffre Viking CO 2 miscible flood (Stephenson et al 1993) and SWAG emulation at the Rangely CO 2 miscible flood (Attanucci et al 1993). Pilot tests performed in the Kuparul River Field in Alaska (Stoisits et al 1995;Ma et al 1995) have also demonstrated the feasibility of SWAG injection.…”

Section: Introductionmentioning

confidence: 92%

Analytical Modeling for Gravity Segregation in Gas Improved Oil Recovery of Tilted Reservoirs

Jamshidnezhad

Ghazvian

2010

Transp Porous Med

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Stone's model for gravity segregation in gas improved oil recovery (IOR) indicates the distance that injected gas and water travel together before the segregation being completed (length of complete segregation). This model is very useful for co-injection of water and gas into horizontal depleted reservoirs. A proof by Rossen and van Duijn showed that Stone's model applies to steady-state gas-liquid flow, and also foam flow, in horizontal reservoirs as long as the standard assumptions of fractional flow theory (incompressible flow, Newtonian mobilities, local equilibrium) are applied. However, until now, there has been no analytical study on the length of segregation when co-injection of water and gas occurs in tilted reservoirs. In this article, in order to extent the validity of Stone's model to tilted reservoirs, governing equations of fluids displacement based on fractional flow theory are solved by the method of characteristics, MOC. The results are then compared to Stone's model and to the results of a three-dimensional finite-difference compositional reservoir simulator. This study shows that Stone's model should be corrected for tilted reservoirs and that the presented math proof can model gravity segregation in gas IOR of tilted reservoirs, appropriately. The effect of co-injecting of water and gas into tilted reservoirs on recovery efficiency is also examined.

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“…1 This design was derived from the lack of gas export and the ability to lower the gas compression pressure requirements by mixing it with water; however due to the mixture in the injected fluid (ca. 0.5% CO 2 in the water, high pressure and therefore high partial pressure of CO 2 ) together with oxygen content created several corrosion issues.…”

Section: Review Of the Problemmentioning

confidence: 99%

An Isolation and Remediation Solution for Wellhead Maintenance in the North Sea

Petrone

Rice

Proulx

et al. 2008

SPE/ICoTA Coiled Tubing and Well Intervention Conference and Exhibition

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Internal corrosion is prevalent in offshore wellheads in the Siri field in the Danish North Sea. Certain wellhead components must be replaced with corrosion-resistant parts. During the wellhead maintenance work, local regulations require a dual barrier and each of these barriers must be tested independently. The casing below the wellhead is completed with fiberglass lining. Standard bridge plugs and standard cleaning methods of tubing are incompatible with the lining and are not considered feasible.This paper presents an alternative solution that uses two inflatable bridge plugs as an isolation method and provides the ability to remove the scale present in the well in the setting area. It details yard tests performed to ensure the chosen technique does not damage the lining of the tubing and can efficiently isolate the wellhead. It also reviews results of several operations performed between 2006 and 2007, in which inflatable bridge plugs were successfully set and retrieved in the fiberglass-lined tubing. Review of the problemThe original recovery / gas disposal design for Siri field was SWAG (simultaneous water and gas injection). 1 This design was derived from the lack of gas export and the ability to lower the gas compression pressure requirements by mixing it with water; however due to the mixture in the injected fluid (ca. 0.5% CO 2 in the water, high pressure and therefore high partial pressure of CO 2 ) together with oxygen content created several corrosion issues. The corrosion can severely affect both the tubulars and the wellhead components. The wells require some sort of corrosion protection in order to avoid having to change completion often; however the corrosion protection systems have not always been successful. On some wells of the Siri field parts of the wellhead needed to be changed with inconel inserts due to corrosion while the tubulars are GRE lined. It is required to pressure test the wellheads while having a double barrier in place. To protect the tubulars from corrosion the following options are available:• Install alloy completion • Perform corrosion protection treatments • Install lined tubulars Each one of these options has advantages as well as disadvantages.Chrome or alloy completion. Chrome or alloy completions are the best possible solution as these are resistant to most of the wellbore fluids and have good mechanical properties as well. The main disadvantage is high product cost and ordering lead time, which is much longer than traditional steel. The use of this technique is increasing all over the world particularly in the North Sea as it guarantees long term performance. Corrosion protection treatmentsCorrosion protection systems like cathodic protection are available and less expensive than chrome or alloy tubulars. However, the main disadvantage is the limited effect on particular types of corrosion where the electrochemical mechanism is clearly understood and in less severe environments. 2, 3

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SWAG Injection on the Siri Field - An Optimized Injection System for Less Cost

Cited by 26 publications

References 6 publications

Visualisation of Residual Oil Recovery by Near-miscible Gas and SWAG Injection Using High-pressure Micromodels

Visualisation of Residual Oil Recovery by Near-miscible Gas and SWAG Injection Using High-pressure Micromodels

Analytical Modeling for Gravity Segregation in Gas Improved Oil Recovery of Tilted Reservoirs

An Isolation and Remediation Solution for Wellhead Maintenance in the North Sea

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