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Article : Articles dans des revues internationales ou nationales avec comité de lecture

Planning disassembly operations for a given demand in components is challenging in practice because the quality of
recovered components is very uncertain, and thus the duration of refurbishing operations is unpredictable. In this paper,
we address the capacitated disassembly lot-sizing problems under uncertain refurbishing durations. More precisely, we
consider a two-level disassembly system with a single type of end-of-life product, a dynamic demand, and stochastic
refurbishing lead times for all components. To deal with the static decision frameworks, this problem is modeled as a
two-stage stochastic Mixed-Integer Linear Program (MILP), where the objective is to minimize the expected total cost.
To alleviate the scalability issues, we propose a reformulation of the inventory constraint that significantly reduces
the number of scenarios. In addition, to solve large scale problems, we couple this reformulation with Monte-Carlo
sampling. We provide a rolling horizon approach to deal with the static decision framework, where disassembly
decisions are updated when new information unfolds. Experimental results show the effectiveness of the proposed
models and the convergence of the resulting Sample Average Approximation (SAA) estimator.