Innovation and Successful Application for Calcium Sulfate Scale Removal in Gemsa Oil Field: A Field Study

Riad, Emad Hamdy; Fahmy, M.; Faramawy, Ahmed

doi:10.2118/149883-ms

SPE International Symposium and Exhibition on Formation Damage Control 2012

DOI: 10.2118/149883-ms

|View full text |Cite

Innovation and Successful Application for Calcium Sulfate Scale Removal in Gemsa Oil Field: A Field Study

Emad Hamdy Riad¹,

M. Fahmy²,

Ahmed Faramawy³

Abstract: Water flooding is the hinge pin for Gemsa Oil Field. Water injection is supplied from shallow water supply wells. Compatibility tests had indicated probable deposition of calcium sulphate scale on surface and subsurface production equipment. Calcium sulphate scale has been recognized to be a major operational problem. The bad consequences of scale formation comprised the contribution to flow restriction thus resulting in oil and gas production decrease. The nature of calcium sulphate scale is very hard and can… Show more

Help me understand this report

Search citation statements

Order By: Relevance

Paper Sections

Select...

Citation Types

Supporting

Mentioning

Contrasting

Year Published

2013

2020

Publication Types

Select...

Other3

Relationship

Self Cite0

Independent3

Authors

Journals

Cited by 3 publications

References 2 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

New Workflow for Scale Precipitation in Production Equipment Resulting from Formation and Injected Water Incompatibility: Field Case

Al-Arji

Al-Amri

2013

All Days

View full text Add to dashboard Cite

Scale precipitation is a common phenomenon that can be seen in a large number of oil fields worldwide. The presence of scaling is due to many reasons, including: temperature change, pressure drop, release of CO2 or the mixture of incompatible waters. Usually, scaling comes in a mixture of different scales, such as calcium carbonate (CaCO3), barium sulfate (BaSO4), and calcium sulfate (CaSO4). Scaling has a great impact on the production regimes where it sometimes ultimately decreases the well productivity to less than half of its potential. The presence of scaling can cause blockages in perforations, restrict/block flowlines or sometimes the failure of safety and choke valves. Precipitation of calcium carbonate on surface or subsurface equipment creates operational problems and acts as a blockage agent. In this case study, water incompatibility caused the first scale formation in the flowlines where a pressure maintenance mechanismvia peripheral injection in this field is being utilized. It was predicted from the well performance data as it showed more than 50% of the production loss. The lab results revealed that the major element was calcium with minor amounts of strontium and barium. This paper presents the results of both experimental and field work performed to identify scale formation. In addition, well performance data was used to predict future scale formation in parallel with the water geochemical analysis. The method used to remove scale precipitation is to use inhibited HCl acid mixture and it is required to be used either though squeeze treatments or by continuous treatments at the wellhead. Based on the lab and field studies, this paper will show new workflow for potential scale prediction and remedy actions prior to laboratory and well performance analyses.

show abstract

New Workflow for Scale Precipitation in Production Equipment Resulting from Formation and Injected Water Incompatibility: Field Case

Al-Arji

Al-Amri

2013

All Days

View full text Add to dashboard Cite

show abstract

Removing Scale Damage with Fast-Acting Anhydrite CaSO4 Removal System

Reyes-García

Holan

2020

SPE International Conference and Exhibition on Formation Damage Control

View full text Add to dashboard Cite

The development of a highly efficient calcium sulfate (CaSO4) scale removal fluid containing a first-of-its class dissolver system is presented. Common CaSO4 scale dissolvers require chelant(s) along with scale converters. A drawback of this type of dissolver is that removal of anhydrite represents a problem if extended shut-in periods are necessary. To help minimize the nonproductive time (NPT) necessary to dissolve CaSO4, a solution has been identified that can restore production within two hours or less and is field-proven. Mineral anhydrite and gypsum samples were exposed to dissolver formulations at 200°F under static conditions, from one hour up to 24 hours. Dissolution kinetics investigation indicates that the limiting step is a substitution surface process that catalyzes the reaction. The formulation was generated based on the discrete chemical activities of individual components with respect to anhydrite, and then refined against a performance-based design of experiments (DoE). Various chemical agents were tested for activity as a function of the chemical functionality (i.e., carboxylate, halide, etc.). Combining the results from multiple design spaces allowed determination of the most desirable formulation. A customized performance methodology was implemented to rapidly identify formulations having a dissolution efficiency exceeding 70% within one hour, followed by a targeted design space aiming for 90% dissolution of actual wellbore anhydrite scale. All tests were conducted with low surface area samples cut from mined substrates for the purpose of experimental designs while wellbore scale was used to validate the formulation efficacy. Elemental analysis of gypsum and anhydrite dissolution products over time was conducted to elucidate kinetic parameters at 150 and 200°F from 1 to 24 hours. The dissolution of anhydrite as a function of time, at 150 and 200°F, showed limiting effect dependency as a function of scale converter concentration. Mass of scale to volume of dissolver fluid effects indicate a dependence on the converter concentration while temperature had the most significant effect. Formulations showed 60-80% dissolution in one hour using anhydrite. This signifies that wellbore and equipment clean out can be accomplished with a simple, non-corrosive treatment fluid when the mineral is of the CaSO4 type. Field trials have been conducted, demonstrating the efficacy of the fluid. The anhydrite dissolver formulation provides mineral dissolution within one hour under conditions representative of a wellbore, such as static fluid column and temperatures of 200°F. The treatment is delivered as a one-fluid system, or single treatment design, whereas a majority of existing treatments require multiple fluids providing protection to downhole equipment such as electro submersible pumps (ESP). The new system functions without the need for prolonged well shut-ins or the use of complicated treatment fluid designs.

show abstract

Operational Efficiency Gains in the Removal of Calcium Sulfate Scale from Electric Submersible Pumps in Offshore Wells

Reyes-García

Henkel-Holan

Campos

et al. 2020

SPE Annual Technical Conference and Exhibition

View full text Add to dashboard Cite

Removal of wellbore scale from downhole equipment continues to impact well economics due to productivity losses and asset maintenance. The use of first-of-its-class calcium sulfate (CaSO4) scale dissolver in high producing offshore wells equipped with electric submersible pumps (ESP) is presented. The efficiency of the new fluid surpasses the performance of established dissolvers since it does not require long shut-in periods. Anhydrite (CaSO4) scale dissolution and removal can be accomplished with a simple treatment fluid employing a formulation that has been field-proven to restore production and protect downhole equipment in a time-efficient manner. Mineral anhydrite and wellbore scale samples were tested with the dissolver formulation at 200°F (93.3°C), under static conditions for one hour. Dissolution efficiencies greater than 94% were a requirement. Fluid compatibility with metallic and non-metallic components in the wellbore were assessed at bottom hole static temperature (BHST) conditions for a period of 24 hours. The fluid was deployed from a stimulation vessel at a pumping rate from 1 to 5 bpm. A small volume pill of 5 m3 on average was pumped in at least 20 wells, through the production tubing to the ESP and was allowed to soak for 1 hour. Wells were immediately opened to production after a 1-h soak period. Minimizing the non-productive time incurred when long soak periods are required has been attained with the use of the new dissolver fluid, leading to greater efficiencies associated with CaSO4-type scale removal. ESP temperature was monitored and reduced by 13°F (7.2°C) after treatment, similar to temperatures before scale build up. After the treatment, the results show a 1.125-fold increase in oil production. The fast-acting formulation exceeds 90% dissolution efficiency within one hour and improves operations by using a fluid that is non-corrosive to downhole materials in a one-stage removal package. The dissolver formulation provides dissolution of anhydrite at 200°F in ESPs. The fast acting dissolver is delivered as a single fluid package and eliminates the need for separate fluid stages as well as the use of incompatible fluids. Anhydrite scale dissolution and removal can be accomplished with a simple treatment fluid and extend the life of the ESP.

show abstract

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.

Contact Info

customersupport@researchsolutions.com

10624 S. Eastern Ave., Ste. A-614

Henderson, NV 89052, USA

This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.

Blog Terms and Conditions API Terms Privacy Policy Contact Cookie Preferences Do Not Sell or Share My Personal Information

Made with 💙 for researchers

Part of the Research Solutions Family.

Innovation and Successful Application for Calcium Sulfate Scale Removal in Gemsa Oil Field: A Field Study

Cited by 3 publications

References 2 publications

New Workflow for Scale Precipitation in Production Equipment Resulting from Formation and Injected Water Incompatibility: Field Case

New Workflow for Scale Precipitation in Production Equipment Resulting from Formation and Injected Water Incompatibility: Field Case

Removing Scale Damage with Fast-Acting Anhydrite CaSO4 Removal System

Operational Efficiency Gains in the Removal of Calcium Sulfate Scale from Electric Submersible Pumps in Offshore Wells

Contact Info

Product

Resources

About