29 Jun - 10 Jul 2025
Cairo (Egypt)
Hotel : Holiday Inn & Suites Cairo Maadi, an IHG Hotel
Cost : 6240 € Euro
The mechanical integrity and reliability of process equipment and piping systems can only be achieved if they are designed by competent engineers and operated and maintained effectively within the design envelope, namely, the integrity operating window (IOW).
This course provides the appropriate mix of fundamentals, methodologies, best industry practices, and practical tools to enhance the competencies and improve the performance of design, operation, and maintenance technical professionals individually and collectively with the objective of adding value to the organization and improving the plant safety and reliability.
Module 1 - Process Equipment & Piping Systems: Application, Design & Operation
Module 2 - Process Equipment & Piping Systems: Failures, Failure Prevention and Repairs
The key objectives of this comprehensive course are as follows:
To increase the participants' awareness and understanding that mechanical integrity of process equipment and piping systems depends jointly on the proper design, operation, condition assessment, and maintenance of the equipment, underscoring their vital individual and team roles in managing change.
Provide participants with practical and sound methods and tools to enable them to carry out basic design calculations for pressure equipment in accordance with applicable industrial codes, standards, and best practices.
To provide the participants with a clear understanding of the degradation mechanisms that process equipment could be subjected to over their operating life, how to identify them, predict and determine their impact, and what appropriate measures can be taken to prevent and control the resultant damage.
To provide the participants with the knowledge and failure analysis skills they need to conduct damage and failure analysis so as to prevent similar failures from happening.
To enhance the knowledge and skills of the participants in hazard identification and analysis, and in risk assessment and management.
This is a 'core' course for the professional development of engineers, technical professionals, operations and maintenance personnel involved in design, projects, operation, inspection and maintenance of oil & gas plants, oil refineries & petrochemical plants, and power plants.
New graduates will gain essential and integrated knowledge about pressure equipment and piping systems design and the significance of appropriate design, operation, and maintenance on their mechanical integrity.
Delegates will enhance their knowledge and expertise in pressure equipment and piping system design and will be equipped with structured procedures and effective guidelines to perform design calculations.
Participants will gain a sound working knowledge of the interdependence of design, operation, and maintenance on integrity, reliability, and cost-effectiveness of piping systems.
Participants will extend their knowledge of the requirements and application of relevant sections of the ASME Boiler and Pressure Vessel Code and B31 Piping Codes, as well as relevant API Codes, standards, and Recommended Practices such as API 510 and 570 in pressure equipment and piping system design, operation, inspection repairs, and alterations.
The delegates will gain sound and practical understanding of the major degradation mechanisms that affect process equipment and piping systems, how to predict them, how to assess their impact on process equipment over their operating life, and how to prevent and control these degradation and damage mechanisms using best industry practices including API 571 and API 580.
Participants will add to their ability and skills in process equipment and piping failure detection and analysis, estimating failure consequences, and conducting level 1 fitness-for-service assessments in accordance with API/ASME 579.
This course will help the company achieve measurable improvement in mechanical integrity, as demonstrated by a reduction in failure incidents, through improved competency in design as well as through effective interaction and collaboration between the engineering, operation and maintenance functions. As a result, the company will be able to enhance its loss prevention and safety performance.
The company will be able to enhance its ability to use risk-based inspection & maintenance, fitness-for-service assessments, and risk assessment methodologies to quantify and prioritize risks, and to allocate resources for optimum benefit. This will result in lower life cycle costs while complying with codes, standards, and other regulatory requirements.
Delegates will enhance their competencies in the following areas:
Working knowledge in mechanical design of pressure equipment and piping systems in compliance with applicable codes, standards, and regulations - ASME B&PVC Section VIII, B31.3
The inter-dependence of design, operation, and maintenance for achieving mechanical integrity of pressure equipment and piping systems
Understanding, prediction and Identification and assessment of active degradation mechanisms and the failures they may cause
Failure investigation techniques and root cause analysis
Application of risk-based methodologies in inspection and maintenance - API 580
NDT methods and their effective application - ASMEB&PVC Section V
Performing Level 1 fitness-for-service assessments - API 579
Engineering materials properties and selection criteria for specific applications
Hazard identification and risk analysis and management
Module 1:
Process Equipment and Piping Systems: Application, Design & Operation
Day 1:
Key Design Considerations, Guidelines and Practices
Process Equipment - An Overview
Plant Integrity and Reliability
Interdependence of engineering, operation and maintenance
Management of change
Fitness for Purpose
Service conditions, equipment sizing, and functional performance
Business-Focused-Facilities – Appropriate quality at lowest life cycle cost
Safety by Design
Worst foreseeable credible scenarios, safeguarding, best industry practices
Codes, Standards, Industry Practices
Compliance with Regulations and Acts - HS&E requirements and considerations
Day 2:
Design and Operation of Pressure Equipment
Pressure Vessels and Reactors
Materials of construction and standards
Basic Design Methodology
ASME Boiler and Pressure Vessel Code Sections 2, 5, 8 and 9
Worked examples
Storage Tanks
Types and application; cone roof tanks, floating roof tanks
Basic design methodology
Overview of API 650
Piping Systems
Materials of construction and standards
Basic Design Methodology – hydraulic design, pressure integrity, mechanical integrity
ASME B31.1 and B31.3
Piping flexibility and support
Piping system components – valves and fittings; classes, ratings
Worked Examples
Overpressure Protection
Types and application of pressure-relieving devices
Code requirements
Sizing methodology: API 520 and 521
Specific operation and maintenance requirements: API 576
Day 3:
Design and Operation of Thermal Equipment
Process Heaters
Types and configuration; box type, vertical cylindrical type
Thermal and mechanical design
API 560, API 530
Boilers
Types and configuration; water tube, firetube, and waste heat recovery boilers
Fundamentals of design and operation
Operating efficiency and testing
ASME B&PVC Section 1 and Section 4, ASME PTC-4
Heat Exchangers
Types and application; Shell & Tube Heat Exchangers, Plate Heat Exchangers, Air Cooled Heat Exchangers
Thermal and mechanical design
Overview of TEMA standards, API 660, API 661
Operation, fouling, and effectiveness
Day 4:
Design and Operation of Fluid Handling Equipment
Pumps
Types and application; Centrifugal, Positive Displacement
Performance characteristics
Selection and design considerations and standards; ANSI, API 610
Worked examples
Compressors
Types and application; Centrifugal, Screw, Reciprocating
Design considerations and standards
Operation and troubleshooting
Electric motors
Types and application
Operation and troubleshooting
Condition Monitoring
Vibration monitoring
Lubricating oil analysis
Troubleshooting
Methodology and guidelines
Reliability improvement
Day 5:
Degradation and Condition Assessment of Process Equipment
Module 2:
Day 6:
Process Equipment & Piping Systems: Failures, Failure Prevention & Repairs
Failure Mechanics
Wear & Failure Mechanisms
Imperfections and Defects
Corrosion Mechanisms
Failure Modes
Fatigue
Fretting
Creep & Thermal fatigue
Stress Corrosion Cracking, Other modes
Material properties, and selection
Carbon & Alloy steels
Nickel, Titanium, and Specialty alloys
Aluminum, aluminum alloys
Copper, copper alloys
Plastic piping
Alternative options-linings, cladding
Limitations and safeguards
Material selection - economics-life cycle costing
Day 7:
Failure Prevention By Design
Failure Causes - Design, Operation; Maintenance, Other Causes
Material properties, and selection
Physical properties and limitations of components
Physical properties of steel and alloy piping and tubing
Physical properties of fittings
Basic Design
Pressure Vessels
Piping Systems
Liquid Storage Tanks
Operation and Maintenance of Process Equipment
Damage Mechanisms Affecting Process Equipment
Day 8:
Process Equipment Failures
Failures in Pressure Vessels, Piping and Boilers
Strength reduction through material loss
Case histories
Piping System Vibration
Mechanical & Flow-Induced Resonance
Transient Hydraulic pulsation
Pipe supports and restraints
Wind Loading
Industry Practices for Failure Prevention
Day 9:
Inspection, Assessment and Maintenance
Inspection Strategies Plans and Procedures - Risk-Based Inspection (API 580)
Developing an RBI Plan
Fitness-For-Service Assessment(API 579)
NDT Methods and Techniques
Probability of Detection
Damage Characterization
Selecting the correct technique(s)
Pigging of Pipelines
Smart pigging
Cleaning
Operational procedures
Day 10:
Operation and Maintenance
Maintenance Programs
Repair and Alteration of Pressure Equipment and Piping
Rerating Piping and Pressure Vessels
Estimation of the the Consequences of Pressure Vessels and Piping Failures
Failure Analysis Techniques