751-5500-00L Simulations and Sensors in Agri-Food Supply Chains
|Semester||Spring Semester 2021|
|Periodicity||yearly recurring course|
|Language of instruction||English|
|Abstract||This course provides students with expert knowledge and skills on how to effectively apply physics-based simulations and sensing in the supply chain of horticultural crops. The main targets are to use these technologies to better preserve food quality, extend shelf life and reduce food waste and the associated carbon footprint.|
|Objective||The course targets the postharvest part of the supply chain, as products pass through pre-cooling facilities, refrigerated containers and trucks, and cold storage facilities, before arriving at the retailer and consumer. We target supply chains of both domestic and tropical horticultural crops, including apple, citrus, mangoes, and berries. In addition, other applications in agri-food chains are highlighted, such as preharvest sensing and monitoring for horticultural crops as well as physics-based simulations and sensing in supply chains of foods of animal origin (meat or milk).|
In the course, we target innovative solutions that are enabled by the augmented insight that simulations and sensing provide with respect to the biophysical processes driving food decay in the cold chain. A key focus of the course is on digital tools for the agri-food chain, such as digital twins, food simulants, wireless and optical sensors, big data, data analytics, and blockchain technology.
A key objective is to gain specialized knowledge in order to:
- Identify which postharvest practices are most suitable for a certain produce and supply chain (e.g. dynamic controlled atmosphere, modified atmosphere packaging, ethylene scrubbing)
- Identify which heat and mass transfer processes (e.g. conduction, convection, radiation, respiration, evaporation) play a key role for a certain produce and supply chain
- Identify which state-of-the-art sensing technology is most optimal for a certain produce and supply chain (e.g. wireless communication, blockchain technology, and biophysical twins)
- Assess if a physics-based model and simulation is built up according to best practices, and if the reported results are realistic
- Understand the link of the cooling process to the evolution of food quality attributes
Another key objective is to acquire skills in order to:
- Perform hands-on multiphysics simulations of food cooling processes
- Measure hands-on a food cooling process with several types of sensors
- Calculate food shelf-life by experiments and kinetic-rate-law modeling
- Quantify the environmental impact of postharvest technology and food waste on the horticultural value chain
|Content||The course is built up of lectures, exercise sessions, and an excursion. The student will then apply this knowledge to perform an expert assessment of a postharvest problem (in a group), report the findings and present the solution strategies. Throughout the course, we also review upcoming national and international startups and companies in these fields.|
The content is as follows:
1. Introduction to the postharvest value chain
2. Postharvest quality and losses
3. Bio-environmental heat and mass transfer
4. Sensors & food simulants
5. Basics & best practice of physics-based simulations
6. Current and emerging postharvest technologies
7. Group assignment on physics-based simulation and sensors
8. Food waste & environmental impact
With this knowledge and skills, the student will be able to provide an expert assessment on a specific problem in postharvest engineering in the context of a group assignment:
- Apply the learned analytical approach to comprehensively understand and quantitatively analyze a simple postharvest problem.
- Identify and quantify strategies and solutions to improve quality preservation, shelf life and reduce food waste, and explain the scientific drivers behind these improvements.
- Identify challenges and prioritize solutions.
- Report and present the results.
|Lecture notes||Handouts of the slides will be provided|
|Literature||Recommended literature (not-obligatory):|
Datta (2017), Heat and Mass Transfer: A Biological Context. CRC Press, Taylor & Francis Group.
Thompson (2008), Commercial cooling of fruits, vegetables and flowers, University of California. University of California, California.