Author(s): Lucas Moretti, Sophie Laurent, Markus Huber and Daniela Costa

Abstract: Precast staircase systems are increasingly adopted in residential buildings due to their advantages in construction speed, dimensional accuracy, and quality control. Despite their widespread use, the structural behavior of precast staircases, particularly the mechanisms governing load transfer between stair components and supporting structural elements, remains insufficiently addressed in routine residential design practice. Load transfer in these systems depends on the interaction between precast flights, landings, supports, and connection details, which together influence global stability, serviceability, and long-term performance. This research examines the fundamental load transfer mechanisms in precast staircase systems commonly employed in low- and mid-rise residential buildings. Emphasis is placed on vertical and horizontal load paths, bearing behavior at supports, and the role of connection interfaces in distributing forces to beams, slabs, and walls. The influence of geometric configuration, support conditions, and construction tolerances on load redistribution is also discussed. Particular attention is given to differences between simply supported, partially restrained, and fully restrained staircase systems, as these conditions significantly affect internal force development and crack control. The paper synthesizes findings from existing experimental investigations, analytical models, and codal provisions to provide a coherent understanding of staircase load behavior under gravity and incidental lateral actions. By clarifying how loads are transferred through precast stair assemblies, the research aims to bridge the gap between theoretical design assumptions and actual structural response in residential applications. The outcomes of this review are intended to assist designers and engineers in making informed decisions regarding connection detailing, support design, and safety considerations. Ultimately, improved understanding of load transfer mechanisms can enhance structural reliability, optimize material usage, and support the broader adoption of precast staircase systems in cost-effective residential construction.

DOI: 10.22271/27078280.2026.v7.i1a.58

Pages: 12-16 | Views: 13 | Downloads: 5

Download Full Article: Click Here