Abstract

The global trend of increasing resource utilization in industry has drawn great attention from researchers and practitioners. Industrial managers are increasingly optimizing their production strategies based on time-of-use (TOU) electricity tariffs to reduce energy consumption costs. This study investigates a new energy-efficient single-machine scheduling problem with release dates under TOU electricity tariffs. It consists in sequencing a set of jobs with release dates to a machine under TOU pricing to minimize the total energy cost given a bounded maximum completion time. We first formulate the problem using the widely used time-indexed mixed-integer linear programming (T-MILP). Due to its time-consuming disadvantage, a new period-based MILP (P-MILP) model is developed based on the characteristics of the problem. Given the NP-hardness of the problem, a two-stage heuristic (TSH) algorithm is proposed to solve practical-sized problems. Specifically, in the first stage, a constructive heuristic is designed to obtain an initial solution, and in the second one, a tailored tabu search is devised to yield a better satisfactory solution. Numerical experiments are conducted on a real-life case and 1150 randomly generated instances with up to 1000 jobs. Computational results show that (i) the proposed models can save the total electricity cost by about 30% compared with an existing empirical scheduling method when solving small-sized instances; (ii) the efficiency of P-MILP is about 140.94% higher than that of T-MILP; and (iii) the proposed TSH algorithm can efficiently obtain high-quality solutions for practical-sized instances with gaps of less than 7% compared to the lower bounds, which can effectively support production managers to save the energy costs in practical production.

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