TY - CONF TI - A proactive digital twin framework for dynamic pull scheduling in modular construction factories C1 - Singapore, Singapore C3 - Proceedings of the 34th Annual Conference of the International Group for Lean Construction (IGLC 34) SP - 837 EP - 848 PY - 2026 DO - 10.24928/2026/0246 AU - Moghimi, Nima AU - Shamaee, Sahar H. AU - Mei, Qipei AU - Gonzalez, Vicente A. AU - Hamzeh, Farook AD - Corresponding Author, Ph.D. Student, Department of Civil and Environmental Engineering, University of Alberta, Canada, nmoghimi@ualberta.ca, orcid.org/0009-0008-4733-1276 AD - Graduate Research Assistant, Department of Civil and Environmental Engineering, University of Alberta, Canada, hamedsha@ualberta.ca AD - Assistant Professor, Department of Civil and Environmental Engineering, University of Alberta, Canada, qipei@ualberta.ca AD - Hal Kvisle Professor and Tier 1 Canada Research Chair in Digital Lean Construction, Infrastructure Human Tech (IHT) Lab, Strategic Projects Insight Centre in Engineering (SPICE), Department of Civil and Environmental Engineering, Faculty of Engineering, University of Alberta, Canada, vagonzal@ualberta.ca, orcid.org/0000-0003-3408-3863 AD - Professor, Department of Civil and Environmental Engineering, University of Alberta, Canada, hamzeh@ualberta.ca, orcid.org/0000-0002-3986-9534 ED - Hamzeh, Farook ED - Poshdar, Mani ED - Garcia-Lopez,, Nelly P. AB - Achieving continuous flow in modular construction is challenging due to high-mix variability, where traditional static methods often fail, leading to excess Work-in-Process (WIP) and flow stagnation. This study proposes a Digital Twin framework utilizing a novel "Offline Learning, Online Control" architecture. The methodology employs Simulation-Based Optimization to derive optimal control policies offline, which are synthesized into a lightweight surrogate model. This model drives an autonomous Scheduler Agent that acts as a virtual pacemaker, regulating real-time flow to shift production from a 'push' to a dynamic 'pull' strategy. Specifically, the agent monitors the cumulative count of finished units at critical downstream constraints, throttling upstream releases until the cumulative count of finished units from the current project surpasses a dynamically calculated threshold. To validate this approach, a case study was conducted on a wall panel assembly line in Edmonton, Canada. For this specific implementation, a Genetic Algorithm was used to train a linear regression surrogate policy against stochastic demand scenarios. Experimental results demonstrate a 38.5% reduction in average Cycle Time (Lead Time) compared to the facility’s baseline practice. These findings confirm that integrating simulation-based learning with real-time surrogate control successfully stabilizes flow efficiency, minimizes WIP accumulation, and prevents gridlock in constrained manufacturing environments. KW - Lean construction KW - pull scheduling KW - modular construction KW - digital twin KW - simulation-based optimization PB - T2 - Proceedings of the 34th Annual Conference of the International Group for Lean Construction (IGLC 34) DA - 2026/06/22 CY - Singapore, Singapore L1 - http://iglc.net/Papers/Details/2541/pdf L2 - http://iglc.net/Papers/Details/2541 N1 - Export Date: 19 June 2026 DB - IGLC.net DP - IGLC LA - English ER -