Course Outline

Introduction and context

• What are earthing systems
• Functions of an earthing system
• Why earthing system interest is increasing
• The importance of getting it earthing systems right

Overview of railway earthing systems

• Utility power supply
• Substations and distribution
• Traction power earthing requirements
• Bonding versus earthing
• Key hazards with the earthed infrastructure of the railway network
• Key design conflicts and challenges

Safety, human factors and zero risk

• Risk assessment and risk management
• Applicable and background safety criteria sources
• Conditions for risk
• The physiological effects and risks, AC and DC
• Human electrical models and voltage criteria
• Review of changes to earthing standards and how they’ll affect rail

Soil as part of the circuit

• Key soil electrical characteristics
• Soil electrical resistivity
• Information sources on soil
• Resistivity test methods
• Analysis techniques and model determination

Railway earthing system interactions

• Signalling
• Communications
• Low-voltage supplies
• The importance of correct coordination

Earth grids

• Key grid components and what they do
• Conductor ratings
• Earth grid resistance
• Determining earth grid performance
• Step, touch and transfer voltages
• Empirical versus analytical analysis techniques
• Strategies in earth grid design
• Common pitfalls

Earthing systems and alternate paths

• Transfer of energy
• Conductive current distribution
• Induction mechanisms in current distribution
• Inductive hazard creation including tracks, fences and other metallic paths

DC railway electrification

• Key considerations in DC bonding and earthing in a DC traction environment traction environment
• Isolated systems and earth clamps for safety and performance

AC railway electrification

• Key considerations in AC bonding and earthing in an AC traction environment
• Key considerations of booster transformers and auto-transformer systems

Earthing strategies and issues

• Separation and isolation in earthing systems
• Interconnected and common bonded systems
• Rail return systems
• Drainage and transient bonding
• Unearthed and floating systems
• Effects of various systems on touch potentials

Corrosion mechanisms and minimisation

• How stray current causes steel corrosion
• Procedures to control stray current

Lightning protection

• Introduction to lightning mechanisms and risks
• Approaches to lightning risk management

Earthing system commissioning and testing

• Benefits and risks associated
• Recommended strategies
• Test methods and equipment
• Common traps and sources of errors

Demonstration, practical examples and class participation throughout