Topic: Deepwater Riser Engineering Course Program

Deepwater Riser Engineering Course Program
(Technical and Industrial Method)

This training will provide participants rich multidisciplinary understanding of the design and materials selection in process design.

For more info Call :


Michael - 07034898577
Stan - 08133476558

Address: Suite 28, No 4 Irewole street,
Awosika B/S, Opebi Ikeja, Lagos State, Nigeria
Tel: 08133476558, 07085740887
Email: [email protected], [email protected]
website: www.Vogwconcept.Com

Delivered entirely by capable facilitators with thorough, accurate and up-to-date knowledge of Riser engineering.
At the end of the training the participants will be able to handle life projects.


• Each participant will receive a copy of :

1. ASME/ANSI B31.3, B31.4 and B31.8; APIRP 14E, API RP 14C, API RP 14J, NACE MR-01-75, API 520 Part 1 & 2, API 521, API 526, API 2000 and API 1104

2. A comprehensive manual for reference
3. Case study exercises using dummy and real life projects as applicable in the industries.
Duration: Weekdays/weekends schedule (Call for time frame duration)
Venue: VOGW Concept, out station training is also available for client anywhere in the world
Cost: Confirm from the Management
Mode of Training: 99% practical
Prerequisite: Fundamental of engineering terms with ability to reason logically
THE COURSE CONTENTS:
MODULE 1
Overview

• Riser Types
• Riser Concept Selection for Field Development
• Factors in Riser Selection
• Cost Comparison
• Technical Challenges and Potential Solutions
• Riser Risk Analysis and Integrity
• Inspection, Maintenance and Repair
• Deepwater Riser JIPs and R&D Activities
• Design Code General
• Design Format Expressions
• Limit State Categorization
• LRFD vs. WSD
• Comparison of API RP 2RD and DNV OS F201
• New API RP 2RD Developments

MODULE 2

Fundamentals of Riser Engineering

• Finite Element Method ABC
• Solution Methods (Eigenvalues, Frequency Domain, Time Domain)
• Wave Theory and Hydrodynamics ABC
• Catenary Theory
• SN Curves vs. Fracture Mechanics
• Rain Flow Counting Method

MODULE 3

Top Tensioned Risers

• Dry Tree vs. Wet Tree Concepts
• Global Configuration
  
  • Subsea Layout
  • Well Bay Layout
  
  
  
• Pros and Cons of Each Configuration
• Component Level Description
• TTR Examples

MODULE 4

Hybrid Riser Systems

• Global Configuration
  
  • Tower Risers
  • Hybrid Risers
  • Truss Risers
  • Offset Risers
  • Tension Leg Risers
  
  
  
• Pros and Cons of Each Configuration
• Component Level Description
• Hybrid Riser Examples

MODULE 5

Steel Catenary Risers

• Global Configuration
  
  • Simple Catenary Configuration
  • Lazy Wave Configuration
  
  
  
• Pros and Cons of Each Configuration
• Component Level Description
• Riser Top Hang-Off System
• Riser Closing Spool
• Riser Joints
• VIV Suppression Devices
• Buoyancy Modules
• Cathodic Protection System
• Riser Coating (Anti-Corrosion and Thermal Insulation)
• Thicker Pipe Section
• Riser End Termination
• Catenary Riser Examples

MODULE 6

Flexible Risers

• Global Configuration
  
  • Simple Free Hanging Catenary Configuration
  • Lazy Wave Configuration
  • Pliant Wave Configuration
  • Chinese Lantern Configuration
  • Steep S Configuration
  
  
  
• Pros and Cons of Each Configuration
• Component Level Description
• Cross Section
• End Fittings
• Bend Stiffener
• Top Vessel Interface Termination
• Subsea End Termination
• Clamp and Anchorage Pile
• Riser Support Structures and Arch Support
• Flexible Riser Examples

MODULE 7

Riser Design Methods Overview

• Design Philosophy, Principles and Objectives
• Design Spirals
• System Key Design Issues
• Design Methods General
• Design Acceptance Criteria
• Safety Factor and Design Format
• System Interface Design
• Analysis Considerations
• Component Design Considerations
• Design Beyond Codes

MODULE 8

Functional Requirements and Design Drivers

• General Design Requirements
• Design Procedure and Acceptance Criteria
• Functional Requirements for TTRs
• Functional Requirements for SCRs
• Functional Requirements for Hybrid Risers
• Functional Requirements for Flexible Risers
• Environmental Loading
• Design Drivers (Material, Fabrication, Welding, Coatings, Testing, Inspection, etc.)
• Metocean Data and Criteria

MODULE 9

Riser System Analytical Tools

• Riser Software Selection Requirements
• General FEA Tools
• Riser Global Analysis Tools
• Riser VIV Tools
• Riser Installation Analysis Tools
• Coupled System Analysis Tools

MODULE 10

Design Basis Development

• General Riser Design Basis
• Typical Structure of Riser DBD
• Boundary Limits and Scope of Work
• Regulatory Requirements
• Codes, Standards and Project Specs
• Design Data
• Design and Analysis Methodology
• Design Requirements and Acceptance Criteria
• Other Design Issues
• Example of an SCR DBD

MODULE 11

11.0 TTR Analysis and Design Methods

• TTR Design Phases
• Definition of Basic Configuration
• DBD Development and Preparation
• Design Steps
• Pipe Sizing
• Tensioning System Sizing
• Riser Stroke Analysis Riser Component Sizing
• VIV Induced Fatigue Analysis
• TTR Interference Analysis
• Strength Analysis
• Computer Modeling
• General Fatigue Analysis
• Centralizer Spacing Analysis
• Riser Running Analysis
• Buoyancy Can Compliant Guide Reaction Analysis
• Compliant Guide Design (SPAR)
• Installation Analysis
• Difference between Spar TTR and TLP TTR
• TTR Design Example

11.1 TTR Component Design

• TTR Design Options
• Wellheads & Tie-Back Connectors
• Riser Joints Design
• Spar Keel Joints
• TLP TTR Tension Joints
• Tensioning System Option and Design
• Riser Joint Buoyancy Option
• Surface Tree Option
• Topside Production Jumpers
• Stress Joints
• Buoyancy Cans and Guides

MODULE 12

12.0 Hybrid Riser Analysis and Design

• Hybrid Riser Analysis
• Modeling Approach
• Riser Sizing
• Strength Analysis
• VIV Analysis
• General Fatigue Analysis
• Design Example

12.1 Hybrid Riser Component Design

• Riser Pipe Design
• Flexible Jumper
• Mid-Water Buoyancy Can
• Buoyancy Modules
• Thermal Insulation Design
• Truss Structures
• Spacers
• Thermal Expansion Accommodations
• Riser Base Design (Pile & GBS)

12.2 Flexible Riser Analysis and Design Method

• Material selection
  
  • Steels
  • Plastics
  
  
  
• Structural design
• Resistance to internal pressure
• Resistance to hydrostatic external pressure
• Resistance to tensile loads
• Resistance to Installation loads
• Nominal configuration
• Extreme conditions
• Fatigue conditions
• End fittings
• Bend stiffeners
• Bell mouths
• Components
• Pressure layers
• Tensile layers
• Analysis Example
• Static and Dynamic Analyses
• Design of End fittings and Equipments
• Fatigue
• Flexible Riser Component Design
• General Requirements
• End Fittings Design
• Buoyancy
• Bend Stiffeners
• Bellmouths
• Bend Restrictor Design
• Tethers and Hold Down Equipment

MODULE 13

13.0 Riser Materials

• Carbon Steel Line Pipe Materials Corrosion Resistant Alloys
• Forging Materials
• Titanium Materials
• Effect of HP/HT on Material Selection Effect of H2S and CO2 on Material Selection
• Anti-Corrosion Coating Materials Thermal Insulation Materials

13.1 Riser Pipe Fabrication, Welding and NDE

• Line Pipe Fabrication Process
• Cladding Pipe Fabrication Welding Procedure and Requirements
• NDE Lab and Full Scale Testing
• Scheduling and Planning

MODULE 14

14.0 SCR Analysis and Design Methods

• General SCR Design Flowchart Material Selection and Wall Thickness Sizing
• Initial Global Configuration Design Computer Modeling
• Selection of Hydrodynamic Coefficients
• Analysis Methods (Strength, VIV, Motion Fatigue, Interference, VIM Fatigue, Heave VIV, & Installation) SCR Fatigue Design
• Interaction with Pipelines Specification Developments
• Typical Drawings
• SCR Design Example

14.1 SCR Component Design

• Composition of SCR System
• Hang Off System Design
• SCR Pipe Joints
• SCR Coating System Design
• SCR Field Joint Design
• VIV Suppression System
• SCR Cathodic Protection System Design
• Subsea Termination System
• SCR Accessories (J-Lay Collar; PIP Bulkhead; Water Stopper; Centralizer; Closing Spool)
• SCR Monitoring System Design

MODULE 15

Installation Engineering

• Installation Methods Overview
• Installation Fleet
• Typical Installation Procedure (SCR & Flexible)
• SCR Installation Analysis
• Offshore Commissioning
• Installation Examples (SCR & Tower Riser)

Presentation of Result and Project reporting
Project work

WHO SHOULD ATTEND?
• New engineers, design and construction engineers, team leaders/coordinators, operations engineers, construction coordinators, maintenance team leaders/engineers, operations team leaders, senior operations and maintenance personnel and other personnel who are or will be responsible for designing, selecting, sizing, specifying, installing, testing, operating and maintaining plant piping and oil and gas pipelines
• Experienced professionals who want to review or broaden their understanding in process design

• Other professionals who want a better understanding of the subject
For more information:

For more info Call :


Michael - 07034898577
Stan - 08133476558

Address: Suite 28, No 4 Irewole street,
Awosika B/S, Opebi Ikeja, Lagos State, Nigeria
Tel: 08133476558, 07085740887
Email: [email protected], [email protected]
website: www.Vogwconcept.Com

Deepwater Riser Engineering Course Program
(Technical and Industrial Method)

This training will provide participants rich multidisciplinary understanding of the design and materials selection in process design.

For more info Call :


Michael - 07034898577
Stan - 08133476558

Address: Suite 28, No 4 Irewole street,
Awosika B/S, Opebi Ikeja, Lagos State, Nigeria
Tel: 08133476558, 07085740887
Email: [email protected], [email protected]
website: www.Vogwconcept.Com

Delivered entirely by capable facilitators with thorough, accurate and up-to-date knowledge of Riser engineering.
At the end of the training the participants will be able to handle life projects.


• Each participant will receive a copy of :

1. ASME/ANSI B31.3, B31.4 and B31.8; APIRP 14E, API RP 14C, API RP 14J, NACE MR-01-75, API 520 Part 1 & 2, API 521, API 526, API 2000 and API 1104

2. A comprehensive manual for reference
3. Case study exercises using dummy and real life projects as applicable in the industries.
Duration: Weekdays/weekends schedule (Call for time frame duration)
Venue: VOGW Concept, out station training is also available for client anywhere in the world
Cost: Confirm from the Management
Mode of Training: 99% practical
Prerequisite: Fundamental of engineering terms with ability to reason logically
THE COURSE CONTENTS:
MODULE 1
Overview

• Riser Types
• Riser Concept Selection for Field Development
• Factors in Riser Selection
• Cost Comparison
• Technical Challenges and Potential Solutions
• Riser Risk Analysis and Integrity
• Inspection, Maintenance and Repair
• Deepwater Riser JIPs and R&D Activities
• Design Code General
• Design Format Expressions
• Limit State Categorization
• LRFD vs. WSD
• Comparison of API RP 2RD and DNV OS F201
• New API RP 2RD Developments

MODULE 2

Fundamentals of Riser Engineering

• Finite Element Method ABC
• Solution Methods (Eigenvalues, Frequency Domain, Time Domain)
• Wave Theory and Hydrodynamics ABC
• Catenary Theory
• SN Curves vs. Fracture Mechanics
• Rain Flow Counting Method

MODULE 3

Top Tensioned Risers

• Dry Tree vs. Wet Tree Concepts
• Global Configuration
  
  • Subsea Layout
  • Well Bay Layout
  
  
  
  
• Pros and Cons of Each Configuration
• Component Level Description
• TTR Examples

MODULE 4

Hybrid Riser Systems

• Global Configuration
  
  • Tower Risers
  • Hybrid Risers
  • Truss Risers
  • Offset Risers
  • Tension Leg Risers
  
  
  
  
• Pros and Cons of Each Configuration
• Component Level Description
• Hybrid Riser Examples

MODULE 5

Steel Catenary Risers

• Global Configuration
  
  • Simple Catenary Configuration
  • Lazy Wave Configuration
  
  
  
  
• Pros and Cons of Each Configuration
• Component Level Description
• Riser Top Hang-Off System
• Riser Closing Spool
• Riser Joints
• VIV Suppression Devices
• Buoyancy Modules
• Cathodic Protection System
• Riser Coating (Anti-Corrosion and Thermal Insulation)
• Thicker Pipe Section
• Riser End Termination
• Catenary Riser Examples

MODULE 6

Flexible Risers

• Global Configuration
  
  • Simple Free Hanging Catenary Configuration
  • Lazy Wave Configuration
  • Pliant Wave Configuration
  • Chinese Lantern Configuration
  • Steep S Configuration
  
  
  
  
• Pros and Cons of Each Configuration
• Component Level Description
• Cross Section
• End Fittings
• Bend Stiffener
• Top Vessel Interface Termination
• Subsea End Termination
• Clamp and Anchorage Pile
• Riser Support Structures and Arch Support
• Flexible Riser Examples

MODULE 7

Riser Design Methods Overview

• Design Philosophy, Principles and Objectives
• Design Spirals
• System Key Design Issues
• Design Methods General
• Design Acceptance Criteria
• Safety Factor and Design Format
• System Interface Design
• Analysis Considerations
• Component Design Considerations
• Design Beyond Codes

MODULE 8

Functional Requirements and Design Drivers

• General Design Requirements
• Design Procedure and Acceptance Criteria
• Functional Requirements for TTRs
• Functional Requirements for SCRs
• Functional Requirements for Hybrid Risers
• Functional Requirements for Flexible Risers
• Environmental Loading
• Design Drivers (Material, Fabrication, Welding, Coatings, Testing, Inspection, etc.)
• Metocean Data and Criteria

MODULE 9

Riser System Analytical Tools

• Riser Software Selection Requirements
• General FEA Tools
• Riser Global Analysis Tools
• Riser VIV Tools
• Riser Installation Analysis Tools
• Coupled System Analysis Tools

MODULE 10

Design Basis Development

• General Riser Design Basis
• Typical Structure of Riser DBD
• Boundary Limits and Scope of Work
• Regulatory Requirements
• Codes, Standards and Project Specs
• Design Data
• Design and Analysis Methodology
• Design Requirements and Acceptance Criteria
• Other Design Issues
• Example of an SCR DBD

MODULE 11

11.0 TTR Analysis and Design Methods

• TTR Design Phases
• Definition of Basic Configuration
• DBD Development and Preparation
• Design Steps
• Pipe Sizing
• Tensioning System Sizing
• Riser Stroke Analysis Riser Component Sizing
• VIV Induced Fatigue Analysis
• TTR Interference Analysis
• Strength Analysis
• Computer Modeling
• General Fatigue Analysis
• Centralizer Spacing Analysis
• Riser Running Analysis
• Buoyancy Can Compliant Guide Reaction Analysis
• Compliant Guide Design (SPAR)
• Installation Analysis
• Difference between Spar TTR and TLP TTR
• TTR Design Example

11.1 TTR Component Design

• TTR Design Options
• Wellheads & Tie-Back Connectors
• Riser Joints Design
• Spar Keel Joints
• TLP TTR Tension Joints
• Tensioning System Option and Design
• Riser Joint Buoyancy Option
• Surface Tree Option
• Topside Production Jumpers
• Stress Joints
• Buoyancy Cans and Guides

MODULE 12

12.0 Hybrid Riser Analysis and Design

• Hybrid Riser Analysis
• Modeling Approach
• Riser Sizing
• Strength Analysis
• VIV Analysis
• General Fatigue Analysis
• Design Example

12.1 Hybrid Riser Component Design

• Riser Pipe Design
• Flexible Jumper
• Mid-Water Buoyancy Can
• Buoyancy Modules
• Thermal Insulation Design
• Truss Structures
• Spacers
• Thermal Expansion Accommodations
• Riser Base Design (Pile & GBS)

12.2 Flexible Riser Analysis and Design Method

• Material selection
  
  • Steels
  • Plastics
  
  
  
  
• Structural design
• Resistance to internal pressure
• Resistance to hydrostatic external pressure
• Resistance to tensile loads
• Resistance to Installation loads
• Nominal configuration
• Extreme conditions
• Fatigue conditions
• End fittings
• Bend stiffeners
• Bell mouths
• Components
• Pressure layers
• Tensile layers
• Analysis Example
• Static and Dynamic Analyses
• Design of End fittings and Equipments
• Fatigue
• Flexible Riser Component Design
• General Requirements
• End Fittings Design
• Buoyancy
• Bend Stiffeners
• Bellmouths
• Bend Restrictor Design
• Tethers and Hold Down Equipment

MODULE 13

13.0 Riser Materials

• Carbon Steel Line Pipe Materials Corrosion Resistant Alloys
• Forging Materials
• Titanium Materials
• Effect of HP/HT on Material Selection Effect of H2S and CO2 on Material Selection
• Anti-Corrosion Coating Materials Thermal Insulation Materials

13.1 Riser Pipe Fabrication, Welding and NDE

• Line Pipe Fabrication Process
• Cladding Pipe Fabrication Welding Procedure and Requirements
• NDE Lab and Full Scale Testing
• Scheduling and Planning

MODULE 14

14.0 SCR Analysis and Design Methods

• General SCR Design Flowchart Material Selection and Wall Thickness Sizing
• Initial Global Configuration Design Computer Modeling
• Selection of Hydrodynamic Coefficients
• Analysis Methods (Strength, VIV, Motion Fatigue, Interference, VIM Fatigue, Heave VIV, & Installation) SCR Fatigue Design
• Interaction with Pipelines Specification Developments
• Typical Drawings
• SCR Design Example

14.1 SCR Component Design

• Composition of SCR System
• Hang Off System Design
• SCR Pipe Joints
• SCR Coating System Design
• SCR Field Joint Design
• VIV Suppression System
• SCR Cathodic Protection System Design
• Subsea Termination System
• SCR Accessories (J-Lay Collar; PIP Bulkhead; Water Stopper; Centralizer; Closing Spool)
• SCR Monitoring System Design

MODULE 15

Installation Engineering

• Installation Methods Overview
• Installation Fleet
• Typical Installation Procedure (SCR & Flexible)
• SCR Installation Analysis
• Offshore Commissioning
• Installation Examples (SCR & Tower Riser)

Presentation of Result and Project reporting
Project work

WHO SHOULD ATTEND?
• New engineers, design and construction engineers, team leaders/coordinators, operations engineers, construction coordinators, maintenance team leaders/engineers, operations team leaders, senior operations and maintenance personnel and other personnel who are or will be responsible for designing, selecting, sizing, specifying, installing, testing, operating and maintaining plant piping and oil and gas pipelines
• Experienced professionals who want to review or broaden their understanding in process design

• Other professionals who want a better understanding of the subject
For more information:

For more info Call :


Michael - 07034898577
Stan - 08133476558

Address: Suite 28, No 4 Irewole street,
Awosika B/S, Opebi Ikeja, Lagos State, Nigeria
Tel: 08133476558, 07085740887
Email: [email protected], [email protected]
website: www.Vogwconcept.Com

Reply Reply With Quote Blog this Post

Nov 5th, 13, 09:46 am #1
stanhiz

Senior Member Join DateJan 2012LocationLAGOSPosts973

Deepwater Riser Engineering Course Program

Deepwater Riser Engineering Course Program (Technical and Industrial Method)

This training will provide participants rich multidisciplinary understanding of the design and materials selection in process design. For more info Call : Michael - 07034898577 Stan - 08133476558 Address: Suite 28, No 4 Irewole street, Awosika B/S, Opebi Ikeja, Lagos State, Nigeria Tel: 08133476558, 07085740887 Email: [email protected], [email protected] website: www.Vogwconcept.Com Delivered entirely by capable facilitators with thorough, accurate and up-to-date knowledge of Riser engineering. At the end of the training the participants will be able to handle life projects. • Each participant will receive a copy of : 1. ASME/ANSI B31.3, B31.4 and B31.8; APIRP 14E, API RP 14C, API RP 14J, NACE MR-01-75, API 520 Part 1 & 2, API 521, API 526, API 2000 and API 1104 2. A comprehensive manual for reference 3. Case study exercises using dummy and real life projects as applicable in the industries. Duration: Weekdays/weekends schedule (Call for time frame duration) Venue: VOGW Concept, out station training is also available for client anywhere in the world Cost: Confirm from the Management Mode of Training: 99% practical Prerequisite: Fundamental of engineering terms with ability to reason logically THE COURSE CONTENTS: MODULE 1 Overview Riser Types Riser Concept Selection for Field Development Factors in Riser Selection Cost Comparison Technical Challenges and Potential Solutions Riser Risk Analysis and Integrity Inspection, Maintenance and Repair Deepwater Riser JIPs and R&D Activities Design Code General Design Format Expressions Limit State Categorization LRFD vs. WSD Comparison of API RP 2RD and DNV OS F201 New API RP 2RD Developments MODULE 2 Fundamentals of Riser Engineering Finite Element Method ABC Solution Methods (Eigenvalues, Frequency Domain, Time Domain) Wave Theory and Hydrodynamics ABC Catenary Theory SN Curves vs. Fracture Mechanics Rain Flow Counting Method MODULE 3 Top Tensioned Risers Dry Tree vs. Wet Tree Concepts Global Configuration Subsea Layout Well Bay Layout Pros and Cons of Each Configuration Component Level Description TTR Examples MODULE 4 Hybrid Riser Systems Global Configuration Tower Risers Hybrid Risers Truss Risers Offset Risers Tension Leg Risers Pros and Cons of Each Configuration Component Level Description Hybrid Riser Examples MODULE 5 Steel Catenary Risers Global Configuration Simple Catenary Configuration Lazy Wave Configuration Pros and Cons of Each Configuration Component Level Description Riser Top Hang-Off System Riser Closing Spool Riser Joints VIV Suppression Devices Buoyancy Modules Cathodic Protection System Riser Coating (Anti-Corrosion and Thermal Insulation) Thicker Pipe Section Riser End Termination Catenary Riser Examples MODULE 6 Flexible Risers Global Configuration Simple Free Hanging Catenary Configuration Lazy Wave Configuration Pliant Wave Configuration Chinese Lantern Configuration Steep S Configuration Pros and Cons of Each Configuration Component Level Description Cross Section End Fittings Bend Stiffener Top Vessel Interface Termination Subsea End Termination Clamp and Anchorage Pile Riser Support Structures and Arch Support Flexible Riser Examples MODULE 7 Riser Design Methods Overview Design Philosophy, Principles and Objectives Design Spirals System Key Design Issues Design Methods General Design Acceptance Criteria Safety Factor and Design Format System Interface Design Analysis Considerations Component Design Considerations Design Beyond Codes MODULE 8 Functional Requirements and Design Drivers General Design Requirements Design Procedure and Acceptance Criteria Functional Requirements for TTRs Functional Requirements for SCRs Functional Requirements for Hybrid Risers Functional Requirements for Flexible Risers Environmental Loading Design Drivers (Material, Fabrication, Welding, Coatings, Testing, Inspection, etc.) Metocean Data and Criteria MODULE 9 Riser System Analytical Tools Riser Software Selection Requirements General FEA Tools Riser Global Analysis Tools Riser VIV Tools Riser Installation Analysis Tools Coupled System Analysis Tools MODULE 10 Design Basis Development General Riser Design Basis Typical Structure of Riser DBD Boundary Limits and Scope of Work Regulatory Requirements Codes, Standards and Project Specs Design Data Design and Analysis Methodology Design Requirements and Acceptance Criteria Other Design Issues Example of an SCR DBD MODULE 11 11.0 TTR Analysis and Design Methods TTR Design Phases Definition of Basic Configuration DBD Development and Preparation Design Steps Pipe Sizing Tensioning System Sizing Riser Stroke Analysis Riser Component Sizing VIV Induced Fatigue Analysis TTR Interference Analysis Strength Analysis Computer Modeling General Fatigue Analysis Centralizer Spacing Analysis Riser Running Analysis Buoyancy Can Compliant Guide Reaction Analysis Compliant Guide Design (SPAR) Installation Analysis Difference between Spar TTR and TLP TTR TTR Design Example 11.1 TTR Component Design TTR Design Options Wellheads & Tie-Back Connectors Riser Joints Design Spar Keel Joints TLP TTR Tension Joints Tensioning System Option and Design Riser Joint Buoyancy Option Surface Tree Option Topside Production Jumpers Stress Joints Buoyancy Cans and Guides MODULE 12 12.0 Hybrid Riser Analysis and Design Hybrid Riser Analysis Modeling Approach Riser Sizing Strength Analysis VIV Analysis General Fatigue Analysis Design Example 12.1 Hybrid Riser Component Design Riser Pipe Design Flexible Jumper Mid-Water Buoyancy Can Buoyancy Modules Thermal Insulation Design Truss Structures Spacers Thermal Expansion Accommodations Riser Base Design (Pile & GBS) 12.2 Flexible Riser Analysis and Design Method Material selection Steels Plastics Structural design Resistance to internal pressure Resistance to hydrostatic external pressure Resistance to tensile loads Resistance to Installation loads Nominal configuration Extreme conditions Fatigue conditions End fittings Bend stiffeners Bell mouths Components Pressure layers Tensile layers Analysis Example Static and Dynamic Analyses Design of End fittings and Equipments Fatigue Flexible Riser Component Design General Requirements End Fittings Design Buoyancy Bend Stiffeners Bellmouths Bend Restrictor Design Tethers and Hold Down Equipment MODULE 13 13.0 Riser Materials Carbon Steel Line Pipe Materials Corrosion Resistant Alloys Forging Materials Titanium Materials Effect of HP/HT on Material Selection Effect of H2S and CO2 on Material Selection Anti-Corrosion Coating Materials Thermal Insulation Materials 13.1 Riser Pipe Fabrication, Welding and NDE Line Pipe Fabrication Process Cladding Pipe Fabrication Welding Procedure and Requirements NDE Lab and Full Scale Testing Scheduling and Planning MODULE 14 14.0 SCR Analysis and Design Methods General SCR Design Flowchart Material Selection and Wall Thickness Sizing Initial Global Configuration Design Computer Modeling Selection of Hydrodynamic Coefficients Analysis Methods (Strength, VIV, Motion Fatigue, Interference, VIM Fatigue, Heave VIV, & Installation) SCR Fatigue Design Interaction with Pipelines Specification Developments Typical Drawings SCR Design Example 14.1 SCR Component Design Composition of SCR System Hang Off System Design SCR Pipe Joints SCR Coating System Design SCR Field Joint Design VIV Suppression System SCR Cathodic Protection System Design Subsea Termination System SCR Accessories (J-Lay Collar; PIP Bulkhead; Water Stopper; Centralizer; Closing Spool) SCR Monitoring System Design MODULE 15 Installation Engineering Installation Methods Overview Installation Fleet Typical Installation Procedure (SCR & Flexible) SCR Installation Analysis Offshore Commissioning Installation Examples (SCR & Tower Riser) Presentation of Result and Project reporting Project work WHO SHOULD ATTEND? • New engineers, design and construction engineers, team leaders/coordinators, operations engineers, construction coordinators, maintenance team leaders/engineers, operations team leaders, senior operations and maintenance personnel and other personnel who are or will be responsible for designing, selecting, sizing, specifying, installing, testing, operating and maintaining plant piping and oil and gas pipelines • Experienced professionals who want to review or broaden their understanding in process design • Other professionals who want a better understanding of the subject For more information: For more info Call : Michael - 07034898577 Stan - 08133476558 Address: Suite 28, No 4 Irewole street, Awosika B/S, Opebi Ikeja, Lagos State, Nigeria Tel: 08133476558, 07085740887 Email: [email protected], [email protected] website: www.Vogwconcept.Com