Advanced Biological Wastewater Treatment

Overview:

Introduction:

This training program provides comprehensive instruction on the theoretical foundations, practical applications, and innovative technologies in the field of biological wastewater treatment. Through a combination of theoretical learning, and case studies, participants will develop the knowledge and skills necessary to address complex challenges in wastewater treatment and contribute to sustainable environmental stewardship.

Program Objectives:

At the end of this program, participants will be able to:

• Demonstrate a thorough understanding of the fundamental principles and advanced technologies used in biological wastewater treatment.

• Apply mathematical modelling techniques to simulate and optimize biological treatment processes.

• Design efficient and sustainable advanced biological treatment systems based on site-specific requirements and regulatory standards.

• Implement effective operational strategies to optimize the performance and reliability of biological treatment plants.

• Utilize preventive maintenance practices and troubleshooting techniques to address operational challenges and ensure the long-term efficiency of treatment facilities.

Targeted Audience:

• Sanitary engineers.

• Environmental biotechnologists.

• Biochemists, Chemists.

• Civil engineers.

• Environmental engineers and scientists.

• Different professionals working or interested in the wastewater treatment field.

Program Outlines:

Unit 1:

Fundamentals of Biological Wastewater Treatment:

• Introduction to biological wastewater treatment processes.

• Microbial communities and their roles in wastewater treatment.

• Biochemical reactions involved in aerobic and anaerobic treatment.

• Factors influencing microbial activity and growth in wastewater treatment systems.

• Importance of dissolved oxygen, pH, temperature, and nutrient balance in biological treatment.

Unit 2:

Advanced Biological Treatment Technologies:

• Overview of advanced biological treatment technologies (e.g., activated sludge, trickling filters, sequencing batch reactors).

• Design principles and operating parameters for various advanced treatment processes.

• Comparison of different biological treatment technologies in terms of efficiency, cost, and applicability.

• Case studies of successful applications of advanced biological treatment technologies.

• Emerging trends and innovations in biological wastewater treatment.

Unit 3:

Modelling of Biological Wastewater Treatment Processes:

• Introduction to mathematical modelling techniques for biological treatment processes.

• Development of process models to simulate biological reactions in wastewater treatment.

• Calibration and validation of biological treatment models using experimental data.

• Modelling tools to optimize and design biological treatment systems.

• Case studies demonstrating the use of modelling in the design and operation of wastewater treatment plants.

Unit 4:

Design Considerations for Advanced Biological Treatment Plants:

• Design parameters and criteria for sizing and configuring advanced biological treatment units.

• Factors influencing the selection of treatment technologies and process configurations.

• Integration of biological treatment units with other unit processes in wastewater treatment plants.

• Design of ancillary systems for nutrient removal, sludge handling, and odor control.

• Compliance with regulatory requirements and environmental standards in the design of biological treatment plants.

Unit 5:

Operation and Maintenance of Advanced Biological Treatment Systems:

• Operational strategies for optimizing the performance of biological treatment systems.

• Monitoring and control techniques for maintaining stable operation and effluent quality.

• Troubleshooting common operational issues in advanced biological treatment plants.

• Preventive maintenance practices to ensure the long-term reliability and efficiency of treatment facilities.

Unit 6:

Wastewater Treatment Development:

• Understanding the historical development of wastewater treatment processes.

• Exploring microbial metabolism involved in biological treatment.

• Analyzing the characteristics and composition of wastewater for effective treatment.

Unit 7:

Advanced Nutrient Removal:

• Removal of organic matter through advanced treatment techniques.

• Strategies for nitrogen removal, including innovative approaches.

• Techniques and processes for efficient phosphorus removal from wastewater.

Unit 8:

Enhancing Treatment Efficiency:

• Methods for pathogen removal to ensure water safety.

• Utilizing aeration and mixing for enhanced treatment performance.

• Addressing toxicity concerns in wastewater treatment processes.

Unit 9:

Advanced Treatment Technologies:

• Dealing with challenges such as bulking sludge and optimizing final settling.

• Implementation and operation of membrane bioreactors for superior treatment.

• Modeling activated sludge processes for better understanding and optimization.

Unit 10:

Optimization and Control:

• Implementing process control measures for efficient operation.

• Exploring anaerobic treatment methods for specific wastewater streams.

• Modeling biofilms and utilizing biofilm reactors for enhanced treatment outcomes.