Geomechanics and Reservoir Containment for Heavy Oil - HOGM

Course

In San Francisco (USA)

Price on request

Description

  • Type

    Course

  • Location

    San francisco (USA)

  • Start date

    Different dates available

Seismic fundamentals as they relate to defining the appearance of hydrocarbons in the data; An inventory of direct hydrocarbon indicators, including AVO; Risk rating prospects that display AVO anomalies; Understanding rock properties and the effect of pore filling material; AVO and how it relates to the typical production zones around the world with various ages and depths of burial; Various methods of displaying AVO effects in the seismic data; Acquisition and processing considerations to display hydrocarbons as a pore filling material; Various approaches to seismic modeling and fluid replacement; Rock properties and pore filling material from seismic inversion; Spectral decomposition and seismic attributes as other ways of extracting reservoir information from the seismic image

Facilities

Location

Start date

San Francisco (USA)
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333 Bush Street, Suite 2400, 94104

Start date

Different dates availableEnrolment now open

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Subjects

  • Gas
  • Design
  • Performance
  • Production
  • Installation
  • Systems
  • Testing
  • Technology
  • IT risk
  • Image
  • Risk
  • Heat Transfer
  • Economics
  • Thermodynamics
  • Simulation
  • Mechanics
  • Basic IT
  • Basic
  • Refrigeration
  • Calibration
  • IT Management
  • Natural Gas
  • Basic IT training
  • Management
  • Surveillance

Course programme

Training Course Content

Seismic fundamentals as they relate to defining the appearance of hydrocarbons in the data; An inventory of direct hydrocarbon indicators, including AVO; Risk rating prospects that display AVO anomalies; Understanding rock properties and the effect of pore filling material; AVO and how it relates to the typical production zones around the world with various ages and depths of burial; Various methods of displaying AVO effects in the seismic data; Acquisition and processing considerations to display hydrocarbons as a pore filling material; Various approaches to seismic modeling and fluid replacement; Rock properties and pore filling material from seismic inversion; Spectral decomposition and seismic attributes as other ways of extracting reservoir information from the seismic image

Basic gas technology principles; Water-hydrocarbon system behavior; Hydrates; Thermodynamics of LNG processes; Separation equipment; Gas treatment, CO2 and H2S removal; Dehydration of natural gas; Heat transfer and exchangers; Pumps and compressors; Refrigeration systems; LNG liquefaction technologies; Fractionation and adsorption; Course summary and overview

Overview of artificial lift technology; Criteria for selection of artificial lift system; Reservoir performance: inflow and outflow relationships; Artificial lift screening; Introduction to rod-pumping, gas lift, and ESP systems; Rod-pump design: pumping unit, rods, pump, prime movers, gas anchor, pump-off controls; Gas lift design: mandrels, valves, injection gas requirements, temperature, chokes, spacing, equilibrium curve, continuous flow design; ESP design: pump performance curves, pump intake curves, typical problems, installation, troubleshooting; Best practices for installation and maintenance; Economic analysis

Gas reservoir fluid properties: gas condensate sampling and Understanding laboratory reports; Gas reservoir fluid flow and well testing: deliverability testing and non-darcy flow, testing for hydraulically Fractured wells, horizontal wells, and gas condensate reservoirs; Determination of original gas-in-place: material balance techniques for various drive mechanisms and reservoir types, alternate plotting techniques, production decline type curves; Gas flow in wellbores and pipelines: the gas production system, pressure drop in wellbores and flowlines, restrictions to gas production; Prediction of future performance and ultimate recovery: decline curves, coupled material balance and deliverability techniques, reservoir simulation, gas well spacing and infill drilling; Special topics; Reservoir management of water-drive gas reservoirs, predicting gas condensate reservoir performance, coalbed methane reservoirs

Overview of artificial lift technology; Criteria for selection of artificial lift system; Reservoir performance: inflow and outflow relationships; Artificial lift screening; Introduction to rod-pumping, gas lift, and ESP systems; Rod-pump design: pumping unit, rods, pump, prime movers, gas anchor, pump-off controls; Gas lift design: mandrels, valves, injection gas requirements, temperature, chokes, spacing, equilibrium curve, continuous flow design; ESP design: pump performance curves, pump intake curves, typical problems, installation, troubleshooting; Best practices for installation and maintenance; Economic analysis

Gas lift concepts and data; Inflow/Outflow; Nodal analysis; Equilibrium curves; Gas lift equipment and valve mechanics; Valve selection and calibration; Unloading; Mandrel spacing and step-by step, complete gas lift design for a well; Temperature effects on valves; Determine the Ptro; Orifice sizing techniques; Lift gas rates for best economics; Causes and solutions of instability; Gas lift surveillance and measurement; Analysis of flowing pressure gradient surveys; Analysis of GL surface charts and measurements; Gas allocation and field optimization; Use of computer programs for gas lift design, trouble-shooting and optimization

Seismic fundamentals as they relate to defining the appearance of hydrocarbons in the data; An inventory of direct hydrocarbon indicators, including AVO; Risk rating prospects that display AVO anomalies; Understanding rock properties and the effect of pore filling material; AVO and how it relates to the typical production zones around the world with various ages and depths of burial; Various methods of displaying AVO effects in the seismic data; Acquisition and processing considerations to display hydrocarbons as a pore filling material; Various approaches to seismic modeling and fluid replacement; Rock properties and pore filling material from seismic inversion; Spectral decomposition and seismic attributes as other ways of extracting reservoir information from the seismic image

Basic gas technology principles; Water-hydrocarbon system behavior; Hydrates; Thermodynamics of LNG processes; Separation equipment; Gas treatment, CO2 and H2S removal; Dehydration of natural gas; Heat transfer and exchangers; Pumps and compressors; Refrigeration systems; LNG liquefaction technologies; Fractionation and adsorption; Course summary and overview

Overview of artificial lift technology; Criteria for selection of artificial lift system; Reservoir performance: inflow and outflow relationships; Artificial lift screening; Introduction to rod-pumping, gas lift, and ESP systems; Rod-pump design: pumping unit, rods, pump, prime movers, gas anchor, pump-off controls; Gas lift design: mandrels, valves, injection gas requirements, temperature, chokes, spacing, equilibrium curve, continuous flow design; ESP design: pump performance curves, pump intake curves, typical problems, installation, troubleshooting; Best practices for installation and maintenance; Economic analysis

Gas reservoir fluid properties: gas condensate sampling and Understanding laboratory reports; Gas reservoir fluid flow and well testing: deliverability testing and non-darcy flow, testing for hydraulically Fractured wells, horizontal wells, and gas condensate reservoirs; Determination of original gas-in-place: material balance techniques for various drive mechanisms and reservoir types, alternate plotting techniques, production decline type curves; Gas flow in wellbores and pipelines: the gas production system, pressure drop in wellbores and flowlines, restrictions to gas production; Prediction of future performance and ultimate recovery: decline curves, coupled material balance and deliverability techniques, reservoir simulation, gas well spacing and infill drilling; Special topics; Reservoir management of water-drive gas reservoirs, predicting gas condensate reservoir performance, coalbed methane reservoirs

Overview of artificial lift technology; Criteria for selection of artificial lift system; Reservoir performance: inflow and outflow relationships; Artificial lift screening; Introduction to rod-pumping, gas lift, and ESP systems; Rod-pump design: pumping unit, rods, pump, prime movers, gas anchor, pump-off controls; Gas lift design: mandrels, valves, injection gas requirements, temperature, chokes, spacing, equilibrium curve, continuous flow design; ESP design: pump performance curves, pump intake curves, typical problems, installation, troubleshooting; Best practices for installation and maintenance; Economic analysis

Gas lift concepts and data; Inflow/Outflow; Nodal analysis; Equilibrium curves; Gas lift equipment and valve mechanics; Valve selection and calibration; Unloading; Mandrel spacing and step-by step, complete gas lift design for a well; Temperature effects on valves; Determine the Ptro; Orifice sizing techniques; Lift gas rates for best economics; Causes and solutions of instability; Gas lift surveillance and measurement; Analysis of flowing pressure gradient surveys; Analysis of GL surface charts and measurements; Gas allocation and field optimization; Use of computer programs for gas lift design, trouble-shooting and optimization

Seismic fundamentals as they relate to defining the appearance of hydrocarbons in the data; An inventory of direct hydrocarbon indicators, including AVO; Risk rating prospects that display AVO anomalies; Understanding rock properties and the effect of pore filling material; AVO and how it relates to the typical production zones around the world with various ages and depths of burial; Various methods of displaying AVO effects in the seismic data; Acquisition and processing considerations to display hydrocarbons as a pore filling material; Various approaches to seismic modeling and fluid replacement; Rock properties and pore filling material from seismic inversion; Spectral decomposition and seismic attributes as other ways of extracting reservoir information from the seismic image

Basic gas technology principles; Water-hydrocarbon system behavior; Hydrates; Thermodynamics of LNG processes; Separation equipment; Gas treatment, CO2 and H2S removal; Dehydration of natural gas; Heat transfer and exchangers; Pumps and compressors; Refrigeration systems; LNG liquefaction technologies; Fractionation and adsorption; Course summary and overview

Overview of artificial lift technology; Criteria for selection of artificial lift system; Reservoir performance: inflow and outflow relationships; Artificial lift screening; Introduction to rod-pumping, gas lift, and ESP systems; Rod-pump design: pumping unit, rods, pump, prime movers, gas anchor, pump-off controls; Gas lift design: mandrels, valves, injection gas requirements, temperature, chokes, spacing, equilibrium curve, continuous flow design; ESP design: pump performance curves, pump intake curves, typical problems, installation, troubleshooting; Best practices for installation and maintenance; Economic analysis

Gas reservoir fluid properties: gas condensate sampling and Understanding laboratory reports; Gas reservoir fluid flow and well testing: deliverability testing and non-darcy flow, testing for hydraulically Fractured wells, horizontal wells, and gas condensate reservoirs; Determination of original gas-in-place: material balance techniques for various drive mechanisms and reservoir types, alternate plotting techniques, production decline type curves; Gas flow in wellbores and pipelines: the gas production system, pressure drop in wellbores and flowlines, restrictions to gas production; Prediction of future performance and ultimate recovery: decline curves, coupled material balance and deliverability techniques, reservoir simulation, gas well spacing and infill drilling; Special topics; Reservoir management of water-drive gas reservoirs, predicting gas condensate reservoir performance, coalbed methane reservoirs

Overview of artificial lift technology; Criteria for selection of artificial lift system; Reservoir performance: inflow and outflow relationships; Artificial lift screening; Introduction to rod-pumping, gas lift, and ESP systems; Rod-pump design: pumping unit, rods, pump, prime movers, gas anchor, pump-off controls; Gas lift design: mandrels, valves, injection gas requirements, temperature, chokes, spacing, equilibrium curve, continuous flow design; ESP design: pump performance curves, pump intake curves, typical problems, installation, troubleshooting; Best practices for installation and maintenance; Economic analysis

Gas lift concepts and data; Inflow/Outflow; Nodal analysis; Equilibrium curves; Gas lift equipment and valve mechanics; Valve selection and calibration; Unloading; Mandrel spacing and step-by step, complete gas lift design for a well; Temperature effects on valves; Determine the Ptro; Orifice sizing techniques; Lift gas rates for best economics; Causes and solutions of instability; Gas lift surveillance and measurement; Analysis of flowing pressure gradient surveys; Analysis of GL surface charts and measurements; Gas allocation and field optimization; Use of computer programs for gas lift design, trouble-shooting and optimization

Seismic fundamentals as they relate to defining the appearance of hydrocarbons in the data; An inventory of direct hydrocarbon indicators, including AVO; Risk rating prospects that display AVO anomalies; Understanding rock properties and the effect of pore filling material; AVO and how it relates to the typical production zones around the world with various ages and depths of burial; Various methods of displaying AVO effects in the seismic data; Acquisition and processing considerations to display hydrocarbons as a pore filling material; Various approaches to seismic modeling and fluid replacement; Rock properties and pore filling material from seismic inversion; Spectral decomposition and seismic attributes as other ways of extracting reservoir information from the seismic image

Basic gas technology principles; Water-hydrocarbon system behavior; Hydrates; Thermodynamics of LNG processes; Separation equipment; Gas treatment, CO2 and H2S removal; Dehydration of natural gas; Heat transfer and exchangers; Pumps and compressors; Refrigeration systems; LNG liquefaction technologies; Fractionation and adsorption; Course summary and overview

Overview of artificial lift technology; Criteria for selection of artificial lift system; Reservoir performance: inflow and outflow relationships; Artificial lift screening; Introduction to rod-pumping, gas lift, and ESP systems; Rod-pump design: pumping unit, rods, pump, prime movers, gas anchor, pump-off controls; Gas lift design: mandrels, valves, injection gas requirements, temperature, chokes, spacing, equilibrium curve, continuous flow design; ESP design: pump performance curves, pump intake curves, typical problems, installation, troubleshooting; Best practices for installation and maintenance; Economic analysis

Gas reservoir fluid properties: gas condensate sampling and Understanding laboratory reports; Gas reservoir fluid flow and well testing: deliverability testing and non-darcy flow, testing for hydraulically Fractured wells, horizontal wells, and gas condensate reservoirs; Determination of original gas-in-place: material balance techniques for various drive mechanisms and reservoir types, alternate plotting techniques, production decline type curves; Gas flow in wellbores and pipelines: the gas production system, pressure drop in wellbores and flowlines, restrictions to gas production; Prediction of future performance and ultimate recovery: decline curves, coupled material balance and deliverability techniques, reservoir simulation, gas well spacing and infill drilling; Special topics; Reservoir management of water-drive gas reservoirs, predicting gas condensate reservoir performance, coalbed methane reservoirs

Overview of artificial lift technology; Criteria for selection of artificial lift system; Reservoir performance: inflow and outflow relationships; Artificial lift screening; Introduction to rod-pumping, gas lift, and ESP systems; Rod-pump design: pumping unit, rods, pump, prime movers, gas anchor, pump-off controls; Gas lift design: mandrels, valves, injection gas requirements, temperature, chokes, spacing, equilibrium curve, continuous flow design; ESP design: pump performance curves, pump intake curves, typical problems, installation, troubleshooting; Best practices for installation and maintenance; Economic analysis

Gas lift concepts and data; Inflow/Outflow; Nodal analysis; Equilibrium curves; Gas lift equipment and valve mechanics; Valve selection and calibration; Unloading; Mandrel spacing and step-by step, complete gas lift design for a well; Temperature effects on valves; Determine the Ptro; Orifice sizing techniques; Lift gas rates for best economics; Causes and solutions of instability; Gas lift surveillance and measurement; Analysis of flowing pressure gradient surveys; Analysis of GL surface charts and measurements; Gas allocation and field optimization; Use of computer programs for gas lift design, trouble-shooting and optimization

Seismic fundamentals as they relate to defining the appearance of hydrocarbons in the data; An inventory of direct hydrocarbon indicators, including AVO; Risk rating prospects that display AVO anomalies; Understanding rock properties and the effect of pore filling material; AVO and how it relates to the typical production zones around the world with various ages and depths of burial; Various methods of displaying AVO effects in the seismic data; Acquisition and processing considerations to display hydrocarbons as a pore filling material; Various approaches to seismic modeling and fluid replacement; Rock properties and pore filling material from seismic inversion; Spectral decomposition and seismic attributes as other ways of extracting reservoir information from the seismic image

Basic gas technology principles; Water-hydrocarbon system behavior; Hydrates; Thermodynamics of LNG processes; Separation equipment; Gas treatment, CO2 and H2S removal; Dehydration of natural gas; Heat transfer and exchangers; Pumps and compressors; Refrigeration systems; LNG liquefaction technologies; Fractionation and adsorption; Course summary and overview

Overview of artificial lift technology; Criteria for selection of artificial lift system; Reservoir performance: inflow and outflow relationships; Artificial lift screening; Introduction to rod-pumping, gas lift, and ESP systems; Rod-pump design: pumping unit, rods, pump, prime movers, gas anchor, pump-off controls; Gas lift design: mandrels, valves, injection gas requirements, temperature, chokes, spacing, equilibrium curve, continuous flow design; ESP design: pump performance curves, pump intake curves, typical problems, installation, troubleshooting; Best practices for installation and maintenance; Economic analysis

Gas reservoir fluid properties: gas condensate sampling and Understanding laboratory reports; Gas reservoir fluid flow and well testing: deliverability testing and non-darcy flow, testing for hydraulically Fractured wells, horizontal wells, and gas condensate reservoirs; Determination of original gas-in-place: material balance techniques for various drive mechanisms and reservoir types, alternate plotting techniques, production decline type curves; Gas flow in wellbores and pipelines: the gas production system, pressure drop in wellbores and flowlines, restrictions to gas production; Prediction of future performance and ultimate recovery: decline curves, coupled material balance and deliverability techniques, reservoir simulation, gas well spacing and infill drilling; Special topics; Reservoir management of water-drive gas reservoirs, predicting gas condensate reservoir performance, coalbed methane reservoirs

Overview of artificial lift technology; Criteria for selection of artificial lift system; Reservoir performance: inflow and outflow relationships; Artificial lift screening; Introduction to rod-pumping, gas lift, and ESP systems; Rod-pump design: pumping unit, rods, pump, prime movers, gas anchor, pump-off controls; Gas lift design: mandrels, valves, injection gas requirements, temperature, chokes, spacing, equilibrium curve, continuous flow design; ESP design: pump performance curves, pump intake curves, typical problems, installation, troubleshooting; Best practices for installation and maintenance; Economic analysis

Gas lift concepts and data; Inflow/Outflow; Nodal analysis; Equilibrium curves; Gas lift equipment and valve mechanics; Valve selection and calibration; Unloading; Mandrel spacing and step-by step, complete gas lift design for a well; Temperature effects on valves; Determine the Ptro; Orifice sizing techniques; Lift gas rates for best economics; Causes and...

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Geomechanics and Reservoir Containment for Heavy Oil - HOGM

Price on request