Recycle and Life Cycle Assessment (LCA) of Products and Processes
A.Y. 2024/2025
Learning objectives
Main objective is to give a wide scenario on the most important processes of the worldwide industrial chemistry, covering both inorganic and organic industrial chemistry. There is also a small part of the economy to introduce students to the key concepts related to the cost of a product and the costs of managing a chemical plant.
Expected learning outcomes
Students will become familiar with the basic processes of organic and inorganic industrial chemistry. They will gain also a bacis knowledge of economics and management of a plant.
Lesson period: First semester
Assessment methods: Esame
Assessment result: voto verbalizzato in trentesimi
Single course
This course cannot be attended as a single course. Please check our list of single courses to find the ones available for enrolment.
Course syllabus and organization
Single session
Responsible
Lesson period
First semester
Course syllabus
The course has two main objectives: 1) to foster a deep understanding of the computational structure of the Life Cycle Assessment (LCA) methodology; 2) to apply this methodology in evaluating the sustainability of materials and processes. In pursuing these objectives, particular attention will be paid to defining and constructing systems of environmental impact indicators for use in the evaluation process. A significant portion of the course will be devoted to applying the LCA methodology to representative real-life cases. Training sessions will be primarily quantitative; no specific numerical skills are required.
1. Life Cycle Analysis and Life Cycle Thinking: Historical context, regulation, procedures, applications. Calculation methodology, databases, and technical software. Sustainability assessment: introductory concepts.
2. Eco-indicators: Spread of pollutants in the environment, measurement methods, environmental impact and damage category, impact quantification, energy approach.
3. Industrial Processes for Material Production: Case studies (e.g., Cement, polymeric materials, metallic materials, and ceramic materials).
4. End of Life of Materials: Open and closed-loop recycling, reuse, waste-to-energy processes, waste management processes.
This curriculum is designed to provide students with both theoretical knowledge and practical skills in the field of sustainability and LCA. By integrating lectures, practical tutorials, and case studies, the course aims to equip students with the necessary tools to critically assess and improve the environmental impact of materials and processes.
1. Life Cycle Analysis and Life Cycle Thinking: Historical context, regulation, procedures, applications. Calculation methodology, databases, and technical software. Sustainability assessment: introductory concepts.
2. Eco-indicators: Spread of pollutants in the environment, measurement methods, environmental impact and damage category, impact quantification, energy approach.
3. Industrial Processes for Material Production: Case studies (e.g., Cement, polymeric materials, metallic materials, and ceramic materials).
4. End of Life of Materials: Open and closed-loop recycling, reuse, waste-to-energy processes, waste management processes.
This curriculum is designed to provide students with both theoretical knowledge and practical skills in the field of sustainability and LCA. By integrating lectures, practical tutorials, and case studies, the course aims to equip students with the necessary tools to critically assess and improve the environmental impact of materials and processes.
Prerequisites for admission
No specific prerequisites are required to follow this course. However, a good understanding of mass and energy balances and good computer skills can be helpful in tackling the material and carrying out the activities more effectively.
Teaching methods
The educational approach involves a combination of traditional classroom lectures and virtual sessions held on Teams. During the lectures, the teacher uses a projector to display PowerPoint slides (PPT) on the screen or the classroom's whiteboard. This allows students to visually follow along and interact with the material.
Furthermore, students engage in practical tutorials specifically focused on using SimaPro software. These tutorials aim to enhance their proficiency in using SimaPro, a powerful software tool used for life cycle assessment and environmental impact analysis. Through these practical tutorials, students gain hands-on experience and develop their skills in navigating and effectively using SimaPro.
Overall, this teaching methodology combines theoretical concepts conveyed through lectures with practical application and interaction with SimaPro software. By incorporating both classroom and virtual elements, students have the opportunity to learn and apply their knowledge in a dynamic and interactive way.
Furthermore, students engage in practical tutorials specifically focused on using SimaPro software. These tutorials aim to enhance their proficiency in using SimaPro, a powerful software tool used for life cycle assessment and environmental impact analysis. Through these practical tutorials, students gain hands-on experience and develop their skills in navigating and effectively using SimaPro.
Overall, this teaching methodology combines theoretical concepts conveyed through lectures with practical application and interaction with SimaPro software. By incorporating both classroom and virtual elements, students have the opportunity to learn and apply their knowledge in a dynamic and interactive way.
Teaching Resources
· W. Klöpffer and B. Grahl, Life Cycle Assessment (LCA) - A Guide to Best Practice, Wiley-VCH, 2014
· M.F. Ashby, Materials and the Environment - Eco-informed materials choice, Elsevier, 2013
- Life Cycle Assessment Handbook: A Guide for Environmentally Sustainable Products, Editor(s):Mary Ann Curran, 2012, Print ISBN:9781118099728, DOI:10.1002/9781118528372
· M.F. Ashby, Materials and the Environment - Eco-informed materials choice, Elsevier, 2013
- Life Cycle Assessment Handbook: A Guide for Environmentally Sustainable Products, Editor(s):Mary Ann Curran, 2012, Print ISBN:9781118099728, DOI:10.1002/9781118528372
Assessment methods and Criteria
Preparation of a freely chosen project through the use of the SimaPro software provided to the student for the duration of the course.
CHIM/04 - INDUSTRIAL CHEMISTRY - University credits: 6
Lessons: 48 hours
Professor:
Bianchi Claudia Letizia Maddalena
Professor(s)