The Woodruff School

SUMMARY

Lithium-Ion Batteries (LIBs) at End-of-Life (EoL) pose several safety risks, as LIBs have the potential to self-ignite during transportation, release toxic compounds during incineration, and can leach contaminants into landfills. To reduce these safety risks in the United States, LIBs are labeled Class 9 hazardous materials under the Code of Federal Regulations. This causes LIBs to be subject to numerous policies, including the requirement of certified personnel and companies to pack and ship the items and regulatory processing with government agencies involved in transport. Efforts to improve LIB recycling focus on reducing costs to make recycling economically lucrative. Hence, there is a significant emphasis on improving recycling processes; however, transport cost alone has been identified to be on average 41% of the total cost of LIB recycling.

This thesis aims to provide a methodology for choosing a Spatially Constrained Multivariate Clustering Analysis (SCMCA) heuristic applied to a case study which determines potential decentralized pre-processing facility locations for Electric Vehicle Batteries (EVBs) in California. The decentralized facilities aim to minimize the transportation distance and costs of shipping intact EVBs between end-use sectors, the facilities, and potential second-use locations.

The methodology consists of a clustering analysis comparison of unsupervised SCMCA Machine Learning heuristics followed by location analyses of potential pre-processing facilities. The freight capacity of the solutions under different transportation scenarios is utilized as the primary criteria to determine an appropriate SCMCA heuristic for the case study, with a sensitivity analysis to determine the volatility of the solutions presented by the various heuristics. Finally, a staged development scenario is proposed for the construction and expansion of facilities in California to manage the increasing rate of EoL EVBs from 2024 to 2030.

SUBJECT:	M.S. Thesis Presentation

BY:	Megan Haynes

TIME:	Wednesday, July 20, 2022, 3:30 p.m.

PLACE:	https://bit.ly/3nJu7gl, N/A

TITLE:	Machine learning approaches for considering decentralized EVB pre-processing facilities with respect to end-use sectors and a potential second-use location

COMMITTEE:	Dr. Marta Hatzell, Chair (ME) Dr. Yan Wang (ME) Dr. Paul Braun (MSE)

SUMMARY Lithium-Ion Batteries (LIBs) at End-of-Life (EoL) pose several safety risks, as LIBs have the potential to self-ignite during transportation, release toxic compounds during incineration, and can leach contaminants into landfills. To reduce these safety risks in the United States, LIBs are labeled Class 9 hazardous materials under the Code of Federal Regulations. This causes LIBs to be subject to numerous policies, including the requirement of certified personnel and companies to pack and ship the items and regulatory processing with government agencies involved in transport. Efforts to improve LIB recycling focus on reducing costs to make recycling economically lucrative. Hence, there is a significant emphasis on improving recycling processes; however, transport cost alone has been identified to be on average 41% of the total cost of LIB recycling. This thesis aims to provide a methodology for choosing a Spatially Constrained Multivariate Clustering Analysis (SCMCA) heuristic applied to a case study which determines potential decentralized pre-processing facility locations for Electric Vehicle Batteries (EVBs) in California. The decentralized facilities aim to minimize the transportation distance and costs of shipping intact EVBs between end-use sectors, the facilities, and potential second-use locations. The methodology consists of a clustering analysis comparison of unsupervised SCMCA Machine Learning heuristics followed by location analyses of potential pre-processing facilities. The freight capacity of the solutions under different transportation scenarios is utilized as the primary criteria to determine an appropriate SCMCA heuristic for the case study, with a sensitivity analysis to determine the volatility of the solutions presented by the various heuristics. Finally, a staged development scenario is proposed for the construction and expansion of facilities in California to manage the increasing rate of EoL EVBs from 2024 to 2030.