Contents:

1 Executive Summary 1.1 Introduction 1.2 The global produced water management challenge 2 Drivers for Innovation 2.1 Regulations 2.2 Cost of water management 2.3 Waterflooding for Improved Oil Recovery (IOR) 2.4 Process de-bottlenecking 3 Produced Water Treatment 3.1 Introduction 3.2 Technology overview 3.3 Latest treatment technologies 4 Produced Water Minimisation 4.1 Mechanical blocking devices 4.2 Chemical water shut-off 4.3 Intelligent Well Technology (IWT) & Inflow Control Valves (ICV) 4.4 Passive Inflow Control Devices (ICD) 4.5 ICD screen technology 4.6 Fracturing horizontal wells to offset water production 4.7 Concept of membrane wells 4.8 Squeeze cementing technology 4.9 Use of “Bright Water Polymer®” (BP) 4.10 Use of expandable tubular technology for zonal isolation 5 Downhole Oil Water Separation (DOWS) 6 Subsea Separation 6.1 Introduction 6.2 Unique features of subsea separation 6.3 Technology overview 6.4 Separation technologies 6.5 Technology trends 7 Produced Water Re-Injection 7.1 Produced water injection for Enhanced Oil Recovery 7.2 Modern technologies for optimal waterflood performance 7.3 Produced water injection as the preferred management approach 8 Operators’ Opinions on Produced Water Management 8.1 Drivers for new technology 8.2 Produced water re-injection 8.3 Downhole oil/water separation 8.4 Deciding on an optimal produced water management solution 9 Produced Water Treatment Market 9.1 Introduction 9.2 Overview 9.3 The forecasting process 9.4 Offshore produced water market by market type 9.5 Offshore produced water market by region 9.6 Conclusions 10 Appendices 10.1 General Assumptions 10.2 Key assumptions for treatment systems in existing installations 10.3 Key assumptions for treatment systems in new installations 10.4 Key assumptions for re-injection systems in existing installations 10.5 Key assumptions for re-injection systems in new installations Figures: Figure 1: Produced water management cost distribution Figure 2: Average abatement cost Figure 3: PWRI cost variation of filtering up to 2 micron particulate size Figure 4: Relative cost of re-injection as a reference (Ekofisk Case) Figure 5: Relative cost efficiency of the CTour process as a reference (Ekofisk Case) Figure 6: Produced Water Constituents Figure 7: Oilspin AV Liquid/ Liquid Hydrocyclone Figure 8: Schematic – Hydrocyclone Figure 9: Produced Water Treatment skid Figure 10: Hydrocyclone Figure 11: IGF unit (Hydraulic Tridair™) suitable for offshore application Figure 12: IGF unit (Hydraulic Tridair™) sectional drawing Figure 13: EPCON CFU sectional view Figure 14: Opus compact flotation technology Figure 15: CrudeSorb® process description Figure 16: CETCO’s RFV2000 CrudeSorb® Adsorption Skid Figure 17: TORR™ Separation System Figure 18: MPPE extraction process system layout Figure 19: Membrane Bio-Reactor Process diagram Figure 20: Depiction of a membrane module of DHV MBR system Figure 21: Typical CTour process layout Figure 22: Historical and forecast water production rate (BPWD) Figure 23: AltelaRainSM System sectional view Figure 24: AquaPurge® System Figure 25: Process description of produced water treatment using hydrates Figure 26: Enviro Voraxial® Separator Figure 27: Process description of treatment using modulated high voltage DC field Figure 28: Process description of treatment using bimodal field modulation Figure 29: WaterCatox Process sectional view Figure 30: WaterCatox Process sectional view Figure 31: WaterCatox equipment Figure 32: GLCC sectional view Figure 33: Large diameter monolith membrane element with permeate conduits Figure 34: Effect of fluid gel solutions on the oil zone Figure 35: Flow distribution variables Figure 36: EQUALIZER™ Inflow Control Device Figure 37: Fracturing technique to help offset water production Figure 38: Expandable tubular open hole cladding solution-schematic Figure 39: Schematic – Typical DOWS System Figure 40 : Typical layout of a subsea O/W separation system Figure 41: Tordis subsea unit Figure 42: Typical produced water re-injection system layout Figure 43: Minox De-oxygenation process Figure 44: Factors that influence Produced Water Re-injection Performance Figure 45: Typical well production profile and value added by waterflood operations Figure 46: Drivers for new technology Figure 47: Breakdown of environmental and regulatory drivers Figure 48: Cost/performance drivers for innovation in produced water treatment Figure 49: Drivers for PWRI Figure 50: Environmental drivers for PWRI Figure 51: Cost/production drivers for PWRI Figure 52: Impact of PWRI on produced water treatment Figure 53: Main problems associated with PWRI Figure 54: Breakdown of issues related to formation damage Figure 55: Breakdown of operational problems with PWRI Figure 56: Breakdown of Cost related PWRI problems Figure 57: Breakdown of PWRI corrosion issues Figure 58: PWRI - other prominent issues Figure 59: DOWS key concerns Figure 60: Breakdown of operational issues with downhole oil-water separation Figure 61: Factors that contribute to produced water management decision Figure 62: Breakdown of reservoir considerations Figure 63: Breakdown of macro factors Figure 64: Stages of produced water separation Figure 65: Flowchart for produced water market model for new installations Figure 66: Flowchart for produced water market model for existing installations Figure 67: Produced water management option decision tree for existing installations Figure 68: Produced water market forecast summary Figure 69: Forecast of average number of final stage treatment units sold per year Figure 70: Global produced water market split by market type Figure 71: Global produced water treatment market for new installations Figure 72: Regional share of treatment market for new installations in 2009 Figure 73: Global re-injection market for new installations Figure 74: Regional share of re-injection equipment for new installations in 2009 Figure 75: Global market for produced water treatment for existing installations Figure 76: Regional share of treatment equipment for existing installations in 2009 Figure 77: Global market for Produced water re-injection for existing installations Figure 79: Gulf of Mexico produced water market Figure 80: Middle East produced water market Figure 81: North Sea produced water market Figure 82: South East Asia produced water market Figure 83: South America produced water market Figure 84: Africa produced water market Figure 85: Australasia produced water market Figure 86: Regional share of the offshore produced water market Figure 87: PW treatment probability distribution for existing installations Figure 88: PW re-injection probability distribution for existing installations Tables: Table 1: Improved separation efficiency with oils of different densities Table 2: Comparison of flotation processes for treating oily waste/ produced water Table 3: Water treatment technologies and their providers Table 4: Leading vendors of ICD equipment and their products Table 5: BP funded research on low salinity water injection on waterflood programme Table 6: Operator Technology Wish List Table 7: Emerging Technologies Table 8: Representative age of platforms going for treatment system upgrade Table 9: Produced water market summary ($million) Table 10: Top three operators of offshore processing facilities between 10-25 years Table 11: Offshore installations with processing facilities between 10-25 years Table 12: Probability of opting for conventional treatment systems Table 13: Probability for produced water treatment (new installation) Table 14: Probability for reinjection (new installation)