Plant integrity and reliability is the cornerstone of process plant optimization. For optimization benefits to be sustainable, production interruptions must be kept to a minimum which requires effective management of degradation processes that affect equipment and systems and effective inspection and maintenance strategies, plans and methods. Plant optimization can be an effective way to achieve improved profitability without the large investment associated with building a new plant.
Common industrial processes and systems, such as steam, cooling water, process heating, and electric motors consume most of the energy and offer significant opportunities for savings. Process changes such as advanced controls, new catalysts, and new technologies also present opportunities for plant optimization. This course will provide a comprehensive review of the various aspects of process plant integrity as an essential foundation for sustainable plant profitability and optimization.
Principal emphasis is placed on:
understanding the elements of plant optimization
systematic and coordinated efforts by engineering, operations, and maintenance functions
maximization of plant availability, reliability, and productivity
minimizing operational costs
safeguarding of plant integrity over its intended life based on total life cycle cost principles
To assist participants in clearly understanding what plant optimization and energy conservation is all about – the drivers, the potential benefits, and how to realize them
To enhance the business focus of participants and equip them to make more contributions to sustainable plant profitability
Learn how to identify the most attractive opportunities for energy savings
Provide the delegate with managerial tools to effectively optimize plant operations
To provide participants with practical and effective methods and tools to perform technical and economic evaluations of the alternatives
Delegates will:
Gain a sound understanding of the main elements of plant integrity and reliability and why this is the cornerstone of sustainable plant optimization and energy efficiency.
Improve their understanding of the business aspects of the process plant which will help them focus on improving the economic performance.
Learn how to perform key project analyses including technical, economic, and environmental evaluations.
Enhance their competence and productivity thereby enhancing their competence and performance level and making additional value-added contributions to their organization.
Develop the technical and analytical skills necessary for conducting technical evaluations.
Have the skills necessary to participate in plant energy audits.
Be able to apply risk-based methodologies in inspection and maintenance.
Through effective management of energy use, the plant can minimize the overall cost of energy.
By diligent use of process optimization techniques, the company can improve production rates while maintaining the best safety practices.
Management can lessen the risk associated with production operations while realizing direct measurable bottom-line savings.
The company will be able to enhance its plant reliability and integrity by using improved maintenance strategies and methods based on risk-based inspection and maintenance.
Lower life cycle costs can be achieved while complying with codes and standards, and other regulatory requirements.
The company will have personnel who will have the economic and analytical skills necessary for performing credible economic evaluations.
Planning and predictive maintenance of plant is vital to the budgetary success of the operations organisation. On completion of this seminar, the delegate will be able to critically analyze the methodologies employed within the organization and instigate improvements where required.
Technical knowledge is key to effective control and peer respect within any maintenance organisation; when this is achieved personal satisfaction follows. This seminar will give the delegate the required level of technical knowledge and skill to achieve personal satisfaction.
Day 1:
Process Plant Operation, Integrity and Reliability
Process Plant Optimization and Energy Conservation – Overview
Asset Integrity Management (AIM) and Optimization - Integrating operation, inspection, maintenance effort
Plant Integrity and Reliability – Cornerstone of Plant Optimization and Energy Management
Operation and Maintenance Impacts on Plant Integrity and Reliability
Equipment condition monitoring and assessment
Establishment of Operating Windows (OW) - Maximize throughput within the limits defined by mechanical-structural integrity over the expected life of the asset components
Effective management of change (MOC) program – On-going link between engineering, operations, and maintenance
Process Plant Economics
Day 2:
Process Plant Optimization
Process Control Basics
Elements of Process Plant Optimization
Components Required To Optimize An Industrial Process
Process or a mathematical model of the process, and process variables which can be manipulated and controlled
Application Of Simulation Technology To Plant Optimization And Control - Plant Optimization Models
The Basics Of Heat Integration
Pinch technology
Heat exchanger train optimization
Optimization procedure
Application Of Simulation Technology To Plant Optimization And Control - Plant Optimization Models
Day 3:
Industrial Energy Management – Energy Efficiency: Good for Business – Good for the Environment
Energy Use and Optimization in Process industries
Industrial Energy Management Techniques
Industrial Energy Management and System Standards
Industry Program for Energy Conservation
Best Practices in Process Plant Energy Management
Developing Customized Energy Management Program
An obstacle that Face Energy Management Programs
Workshop - Examples of energy management programs and standards – CIPEC, UNIDO. Incentives for an energy assessment and energy retrofit projects
Day 4:
Energy Conservation Opportunities
Implementing an Energy Management Program
Benchmarking Energy Intensity and Usage
Technology Options - New energy-efficient technologies. Examples include Corrosion analyzer for advanced materials and fabricated components Fiber optic sensor for combustion measurement and control
Energy Conservation Checklist
Plant processes
Mechanical Systems
Electric Power
Technical and Economic Evaluation of Potential Opportunities
Day 5:
The Implications of Plant Optimization Activities
Relating Energy Efficiency To Business Outcomes
Impact of optimization activities and technological modifications to the plant
Plant integrity and safety
Technology licenses
Financing agreements
Impact on Human Resources – The human factor