Abstract
Because of its benefits – from lowered inventory costs to greater flexibility in adapting to shifting market forces – the push–pull strategy is being widely used in today's competitive supply-chain designs. The push–pull strategy also brings potential supply-chain risks related to order fulfilment capability and robustness against external variability. More specifically, the use of this strategy often results in an inability to minimise the impact of lead-time variability. We present a new, hybrid push–pull strategy that incorporates additional stock points after the push–pull boundary as the pulling points in a serial supply chain, which can mitigate the risks and improve the robustness of the push–pull strategy without sacrificing its benefits in inventory cost reduction. For the evaluation and comparison of different supply-chain strategies, a nonlinear, mixed-integer programming model with a cost-minimisation objective function is developed and implemented in the numerical experimentation, with simulated annealing as the search algorithm. Results from the experiments demonstrate the potential improvement by our proposed strategy in terms of the robustness and cost-effectiveness against external variability. The results also verify the risks and limitations of the conventional push–pull strategy and provide some managerial implications regarding the use of push–pull supply chains.
Acknowledgement
This work was supported by the new faculty research fund of Ajou University.