TRAINING.

Overview

After participating in this course, you will be able to:

• Apply advanced engineering principles to optimize the design of buried pipelines.
• Analyze and calculate loads for various types of buried pipes with precision.
• Develop solutions to address common and complex challenges in pipeline engineering.
• Design effective, durable pipeline systems using rigid, semi-flexible, and flexible materials.
• Interpret and utilize AWWA and ASTM guidelines for buried pipeline design.

Description
Modern subsurface infrastructure is essential for the functioning of contemporary society, encompassing a wide range of piping systems used in sewers, drainage, subway tunnels, water mains, and utility conduits. Although often overlooked, these buried pipelines are critical to our everyday lives. These systems can deteriorate without proper maintenance and design, leading to service disruptions, costly repairs, and extensive legal disputes. This course comprehensively explores the design and analysis of buried pipes, focusing on understanding the complex dynamics that affect these underground lifelines.

Participants will delve into the latest engineering techniques for calculating external loads on buried pipelines, including the effects of soil subsidence, temperature changes, seismic activity, and other environmental factors. The course also covers designing various types of pipes, such as rigid, ductile, and flexible materials, using AWWA and ASTM guidelines. Through practical examples and case studies, attendees will learn how to apply these principles to real-world situations, ensuring the integrity and longevity of buried pipeline systems.

By the end of this course, attendees will have a thorough understanding of the critical aspects of buried pipeline engineering. They will be equipped with the knowledge to design robust pipeline systems that meet modern standards and address the specific needs of different environments and applications.

Who Should Attend
This course is ideal for professionals involved in planning, designing, constructing, and maintaining buried pipeline systems. Construction managers, utility engineers, geotechnical and civil engineers, city managers, pipeline engineers, and consulting engineers will significantly benefit from the content covered. It is also valuable for contractors, pipeline system fabricators, and manufacturers who seek to enhance their understanding of buried pipeline design and application.

This course may also interest project managers, environmental engineers, urban planners, and infrastructure consultants involved in projects requiring a deep understanding of subsurface piping systems and their design considerations.

Special Features & Requirements
Attendees are expected to have a foundational knowledge of loads on buried pipelines as the course builds on advanced concepts introduced in EPIC's "Buried Pipeline Design" course.

Please note: You can check other time zones here.

Syllabus

Day I

Introduction

• Application of buried pipes
• Common pipe materials and characteristics

Loads on Buried Pipelines

• Loads on buried, tunnelled, and flexible pipes
• Effect of pipe axial bending
• Live wheel loads
• Minimum soil cover
• Pipe flotation
• Longitudinal fractures
• Effect of soil subsidence, temperature rise, seismic loads
• Frost loads
• Soil bearing

Design of Rigid Pipelines

• Vitrified Clay Pipes
• Concrete Pipes
• Pre-stressed Concrete Cylinder Pipe:
• Reinforced Concrete Cylinder Pipe:
• Pre-tensioned Concrete Cylinder Pipe:
• AWWA Design of Reinforced Concrete Pressure Pipes
• Design Procedure for Rigid Pipes (AWWA C300 & C302):
• Design Procedure for AWWA C303-type Pipes
• Indirect Design Method
• Three-Edge Bearing Design Criteria
• Direct Design Method
• Soil-Pipe Interaction Design and Analysis

Day II

Steel and Ductile Iron Flexible Pipes

• Corrugated steel pipes
• Steel pipes
• Ductile iron pipes
• Pressurized ductile iron pipes

Plastic Flexible Pipes

• Types of Thermoplastic Pipes
• PVC pipes
• Polyethylene (PE) Pipes
• HDPE Profile-wall Pipes
• Experimental observations
• HDPE Pipes with Steel Rib
• Steel Mesh Reinforced HDPE pipe
• Acrylonitrile-Butadiene-Styrene Pipes
• Thermoset Plastic Pipes

Questions and Answers and Feedback to Participants on Achievement of Learning Outcomes

Instructor

Abouzar Sadrekarimi, Ph.D., P.Eng.

Dr. Sadrekarimi is an Associate Professor of Civil Engineering at Western University (London, Ontario). Dr. Sadrekarimi’s academic and professional expertise involves soil mechanics, foundation engineering, deep foundations, dam, advanced soil testing and characterization of soil behavior, in-situ testing, soil dynamics and geotechnical earthquake engineering, static and dynamic analysis of retaining walls, buried structures, and slope stability analysis. He joined Western after several years of engineering practical experience at Golder Associates Ltd. Dr. Sadrekarimi has over 50 published papers in peer-reviewed conference proceedings and journals.

Dr. Sadrekarimi is a member of the International Society of Soil Mechanics and Foundation Engineering (ISSMFE), the American Society of Civil Engineers (ASCE), the Canadian Geotechnical Society, research director of Western’s Geotechnical Research Centre (GRC).