Training Certificate

Prolific Consultants FZE Certificate of Course Completion will be issued to all attendees.

Course Introduction

Water Injection Treatment is a technique used in oil and gas reservoirs to enhance production by injecting water into the reservoir, typically to maintain pressure and improve oil recovery. This process involves using treated water, such as seawater, freshwater, or produced water, to push oil toward production wells, thereby increasing recovery rates, extending field life, and boosting production. While beneficial, it comes with challenges like scaling, corrosion, and microbial growth, which require effective monitoring and treatment. By using advanced technologies like filtration and chemical treatments, water injection can be made more efficient and environmentally sustainable, often utilizing seawater or treated wastewater to reduce the use of freshwater.

Course Objective

The aim of this course is to provide the participants with a complete and up-to-date overview of the area of Water Injection Treatment. Upon the successful completion of this course, the participant should have a solid grounding in the understanding of the purpose, operation and inspection of water injection systems for enhanced oil recovery. The course will illustrate potential problems and their resolution.

Suitable For

All engineers and technical staff (Superintendents, Supervisors & Foremen) whose responsibilities include the safe and cost effective operation of water injection systems.  Management will also benefit by increasing their awareness of the cost-effective use of treatment chemicals and by developing their skills in analysis of water quality data.

Training Methodology

A highly interactive combination of lectures and discussion sessions will be managed to maximize the amount and quality of information and knowledge transfer. The sessions will start by raising the most relevant questions, and motivate everybody find the right answers. You will also be encouraged to raise your own questions and to share in the development of the right answers using your own analysis and experiences.  Tests of multiple-choice type will be made available on daily basis to examine the effectiveness of delivering the course.

Very useful Course Materials will be given.

• 30% Lectures
• 30% Workshops and work presentation
• 20% Group Work& Practical Exercises
• 20% Videos & General Discussions

Course Content

Enhanced Oil Recovery - Preamble:-

Function of EOR. Reservoir structure.  Types of reservoir drive: solution gas, gas cap, water.  Permeability and porosity. EOR options available: water, polymer, microbial, gas re-injection. Secondaryrecovery options.

Enhanced Oil Recovery  -Injectivity:-

Injectivity requirements.  Breakthrough.  Fracturing.  Loss of Injectivity (Z-curves).  Recovering injectivity by acid treatments.  Scale formation.  Prevention of scale formation.

Water Injection Systems  -  Water Source:-

Water source: aquifers, seawater, produced water.  Nature and composition of waters.  Variability of seawater.  Matching reservoir requirements.  Water compatibilities and scale.

Water Injection Systems  -  Basic Water Treatment:-

Basic water treatment: filtration and deaeration.  Water depth selection. Prevention of macrofouling. Winning pumps.  Chlorination.

Water Injection Systems  - Filters & Deaeration:-

Types of filters: cartridge, gravity, upflow, mixed media, rotating drum.  Filter aids: iron salts, bentonite, polyelectrolyte.  Chlorination and upfilter biocide treatments.  Deaeration: gas stripping and mechanical vacuum deaeration.  Chemical scavengers and catalysts.  Effect of temperature.  Interaction of chlorine and scavenger. Bacterial growth.  Through plant chlorination.  Biocide treatment.  Types of biocide. Variations in biocide use.  Interaction of scavenger and biocide.

Seawater Corrosion:-

Corrosiveness of seawater.  Typical corrosion rates.  Oxygen corrosion.  Effect of flow.  Effect of temperature when seawater used as primary coolant.  Winning pumps.  Annular restrictions around winning pumps.  Flow tubing: mortar lined c-steel, duplex, titanium, cunifer.  Filter containers and coatings.  Deaeration towers and coatings.  Downstream flowline systems.  Injection tubing.

Buried and Subsea Pipelines:-

Soil corrosiveness.  Enhanced corrosion around water pipelines.  Seawater corrosiveness.  Seabed sediment corrosiveness.  External coatings.  Cathodic protection.Coating and CP interactions.  External damage to pipelines.  Internal coating of pipelines.  Refurbishment of pipelines.  Repair of pipelines. Replacement of pipelines.

Microbiological Growth and Corrosion:-

Structure and growth of diatoms, bacteria and algae.  Growth requirements. Interactions between organisms.  Microbiological corrosion.  Sessile bacteria.  Planktonic bacteria. Biofouling in filers, deaerators, flowlines.  Injectivity loss.  Reservoir souring.

Water Quality:-

Intake water.  Measuring particle counts.  Millipore filtration.  Post filtration water quality.  Residual chlorine after filtration.  Residual oxygen after deaeration. Residual scavenger.  Water quality at receiving wells.  Effect of injection water quality on injectivity. Total iron and corrosion.  Millipore filtration at the injection wells.  Calculating volumes and quantities.

Tests used to Evaluate Water Quality:-

Lab tests and field tests.  Test frequency.  Particle counts.  Filtration efficiency.  Millipore filtration tests.  Chlorine. Oxygen.  Oxygen scavenger. Total iron.  Residual biocide. Hydrogen sulphide. SRB. GAB. pH. Test points.  Collecting samples.  Transport of samples

Water Treatment Chemicals used in Water Injection Systems:-

Chlorine.  Bentonite.  Polyelectrolyte.  Filter aids. Scavenger.  Biocides.  Selection of biocides: time to kill, field tests.

End of Day Three

Inspection of Facilities:-

Using iron counts to evaluate corrosion.  Effects of flow.  Areas of corrosion.  Typical corrosion patterns.  Weld decay.  Ultrasonic testing.  X-radiography.  Internally coated vessels and lines.  Endoscopes.  Visual inspection.  Inspection frequency.

Pigging and Cleaning of Pipelines

Identifying the need to pig.  Types of pigs.  Risks involved.  Pig alerts.  Frequency of pigging.  Effectiveness.  Cleaning of pipelines.  Measuring effectiveness.  Intelligent pigging.  Evaluation of data.

Case Studies, Discussions, Last Day Review & Assessments will be carried out.

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