TRAINING.

Overview

By the end of this course, you will be able to:

• Analyze railway bridge systems using AREMA loading requirements and established assessment frameworks
• Evaluate redundancy, fatigue, and fracture control considerations in steel railway bridges
• Apply engineering judgement to assess bridge condition, rating, and performance under service loads
• Compare rehabilitation, strengthening, and replacement strategies for existing railway bridges
• Review bridge designs for constructability, value engineering, and long‑term maintainability

Description

Railway bridges are critical infrastructure assets that must safely support increasing rail traffic, heavier loads, and extended service lives—often while operating under constrained inspection, maintenance, and replacement windows. Engineers responsible for these structures face complex decisions related to design loads, redundancy, fatigue, constructability, and lifecycle performance, where errors or oversights can have significant safety and cost implications.

This course provides a practical, engineering‑focused overview of steel and reinforced concrete railway bridge systems, emphasizing real‑world design, assessment, and rehabilitation challenges. Participants will explore historical and modern bridge configurations, AREMA design loads, condition assessment and rating, fracture control, and fatigue behavior, supported by multiple case studies and design examples.

Through applied discussions and worked design examples—including reinforced concrete bridges, plate girder bridges, and steel box girder systems—participants will strengthen their ability to make informed, defensible engineering decisions. The course also addresses accelerated bridge construction, maintenance and repair strategies, and value engineering considerations, enabling engineers to apply course concepts directly to professional railway bridge projects.

Who This Course Is For

This course is designed for:

• Civil and structural engineers involved in railway or transportation infrastructure
• Engineers and technologists responsible for bridge design, assessment, or rehabilitation
• Technical professionals working with steel and reinforced concrete bridge systems
• Practicing engineers seeking practical exposure to railway bridge design standards and case studies
• Professionals involved in bridge asset management, maintenance planning, or constructability reviews

Please note: You can check other time zones here.

Syllabus

Day I

• Introduction - Bridge Engineering Overview
• History & Development of Steel Railway Bridges
• Description & Main Components of Railway Bridges
• Railway Bridge Design Loads - AREMA Standard
• Bridge assessment & Rating - Examples

Day II

• Steel Bridge Redundancy
• Fracture Control and Fatigue
• Coal Handling Railway Elevated Structure. - Case Study
• Accelerated Bridge Construction Techniques (ABC) - Case Studies
• Maintenance, strengthening and repair for steel and concrete bridges

Day III

• Design Example: Reinforced Concrete Bridge and Foundation Stability
• Design Example: Ballasted Through Plate Girder Railway Bridge
• Design Example: Steel Box with concrete Deck Railway Bridge
• Bridge Rehabilitation vs Replacement
• Value Engineering and Constructability Review
• Questions and Answers and Feedback to Participants on Achievement of Learning Outcomes
• Final Adjournment

Instructor

Adel R. Zaki is the Chief Engineer of bridges and structures with SNC-Lavalin. In his 40 years in civil engineering practice, Mr. Zaki has been engaged by Canada’s foremost engineering consulting firms, becoming an expert in the design and management for major bridge projects in North America and internationally.

In 1995, the World Bank recognized Mr. Zaki as an international specialist for his professional services in planning, project management and the design of railway and highway infrastructures.

Mr. Zaki has published more than twenty technical papers on bridges and received merit awards from the CSCE, the ACI, and the PCI. He is a member of numerous associations and committees including Professional Engineers Ontario, Order of Engineers of Quebec, Professional Engineers and Geoscientists of BC, Canadian Society for Civil Engineering, American Railway Engineering and Maintenance-of-Way Association, Transportation Research Board, Technical Committee of the CSA Bridge Code S6, and the International Association of Bridges and Structures.