INGLESE
English
Fundamentals of hydraulics; fundamentals of hydraulic construction; elements of sanitary-environmental engineering
Fundamentals of hydraulics; fundamentals of hydraulic construction; elements of sanitary-environmental engineering
Theory for 30 hours
Exercizes and practice for 18 hours
Guided visits to full scale wastewater and/or waste treatment plants might be provided
Theory for 30 hours
Exercizes and practice for 18 hours
Guided visits to full scale wastewater and/or waste treatment plants might be provided
The student will develop detailed knowledge of management technologies and processes optimization for the treatment and valorisation of municipal and industrial wastewaters and drinking water. This knowledge will allow scientific approach to solve complex and applied engineering problems with reference to the management and implementation issues typical of the chemical and environmental engineering.
The course enables students to acquire advanced technical knowledge for the interpretation of projects, the identification of systems and the measurement and optimization techniques for management the plants for urban and industrial wastewaters and drinking water. The use of advanced methods to solve applied problems will allow approach comparable to that commonly used in the advanced labour market.
The approach to performance-based operation and optimization of real environmental and chemical plants will increase the capacity to
critically analyze engineering and chemical-physical data and make decisions about technical, environmental and economic
optimization of existing environmental water infrastructures.
The student will develop detailed knowledge of management technologies and processes optimization for the treatment and valorisation of municipal and industrial wastewaters and drinking water. This knowledge will allow scientific approach to solve complex and applied engineering problems with reference to the management and implementation issues typical of the chemical and environmental engineering.
The course enables students to acquire advanced technical knowledge for the interpretation of projects, the identification of systems and the measurement and optimization techniques for management the plants for urban and industrial wastewaters and drinking water. The use of advanced methods to solve applied problems will allow approach comparable to that commonly used in the advanced labour market.
The approach to performance-based operation and optimization of real environmental and chemical plants will increase the capacity to
critically analyze engineering and chemical-physical data and make decisions about technical, environmental and economic
optimization of existing environmental water infrastructures.
SECTION 1: HOW TO MEASURE AND HOW TO AUDIT PERFORMANCES AND TREATMENT PLANTS; SECTION 2: USE OF SIMULATION TOOLS AND PLATFORMS FOR PROCESS ANALYSIS AND OPTIMIZATION; SECTION 3: IN-SITU EXPERIMENTAL PROCESS AUDIT; SECTION 4: PROCESSES AND PLANTS TO DELIVER URBAN CIRCULAR BIOECONOMY; SECTION 5: IPPC/IED AND EIA; SECTION 6: FOOTPRINTING AND ASSESSMENT; SECTION 7: EXERCISES ON CASE STUDIES; SECTION 8: FUNDAMENTALS OF MUNICIPAL WASTE TREATMENT PLANTS
SECTION 1: HOW TO MEASURE AND HOW TO AUDIT PERFORMANCES AND TREATMENT PLANTS; SECTION 2: USE OF SIMULATION TOOLS AND PLATFORMS FOR PROCESS ANALYSIS AND OPTIMIZATION; SECTION 3: IN-SITU EXPERIMENTAL PROCESS AUDIT; SECTION 4: PROCESSES AND PLANTS TO DELIVER URBAN CIRCULAR BIOECONOMY; SECTION 5: IPPC/IED AND EIA; SECTION 6: FOOTPRINTING AND ASSESSMENT; SECTION 7: EXERCISES ON CASE STUDIES; SECTION 8: FUNDAMENTALS OF MUNICIPAL WASTE TREATMENT PLANTS
Oral exam:
- Start with discussion about report on process audit and optimization of a real case study
- Questions about the main topics of the course
To successfully pass the evaluation of learning, the student must demonstrate the understanding of the concepts presented in class and the acqusition of the principles of management and optimization of wastewater and wastes treatment plants
During the examinations will be evaluated the understanding of the theoretical and experimental principles of the treated topics and the ability to management and optimization of wastewater and wastes treatment plants
The final mark is attributed with minimum grade of 18/30 associated with complete knowledge of the treated topics. Additional points up to 30/30 will be awarded based on the general and specific skills. The evaluation "cum laude" will be given to students with elevated outstanding and critical exposition of the arguments.
Oral exam:
- Start with discussion about report on process audit and optimization of a real case study
- Questions about the main topics of the course
To successfully pass the evaluation of learning, the student must demonstrate the understanding of the concepts presented in class and the acqusition of the principles of management and optimization of wastewater and wastes treatment plants
During the examinations will be evaluated the understanding of the theoretical and experimental principles of the treated topics and the ability to management and optimization of wastewater and wastes treatment plants
The final mark is attributed with minimum grade of 18/30 associated with complete knowledge of the treated topics. Additional points up to 30/30 will be awarded based on the general and specific skills. The evaluation "cum laude" will be given to students with elevated outstanding and critical exposition of the arguments.
Course notes; Metcalf and Eddy, "Wastewater engineering: treatment and resource recovery" Fifth Edition; Manuals, technical regulations and guidelines provided by the professor
Moodle link:
https://learn.univpm.it
Course notes; Metcalf and Eddy, "Wastewater engineering: treatment and resource recovery" Fifth Edition; Manuals, technical regulations and guidelines provided by the professor
Moodle link:
https://learn.univpm.it
Università Politecnica delle Marche
P.zza Roma 22, 60121 Ancona
Tel (+39) 071.220.1, Fax (+39) 071.220.2324
P.I. 00382520427