Flexural Behavior and Design of Prestressed Ultra-High Performance Concrete (UHPC) Beams: Failure Mode and Ductility

TL;DR

This paper develops a finite-element model and design methods to enhance the ductility and failure mode of prestressed UHPC beams, aiming to promote gradual strain hardening and prevent early failure after crack localization.

Contribution

It introduces a validated 3D FEA model for prestressed UHPC beams and proposes a design approach to achieve ductile failure modes through parameter analysis.

Findings

Validated FEA model matches experimental results.

Design method predicts failure modes effectively.

Parameter analysis identifies key factors influencing ductility.

Abstract

Ultra-high performance concrete (UHPC) is well-known for its ultra-high compressive strength and sustained post-cracking tensile ductility, making it an attractive choice for the construction of modern structures. Prestressed UHPC members, however, often fail quickly after crack localization accompanied by reinforcement rupture, which shows limited failure warnings (i.e., relatively small ductility, nearly invisible cracking, and negligible compressive damage). On the other hand, UHPC members can also be designed to allow the gradual strain hardening of reinforcement to compensate for the load loss due to crack localization, and the final failure is attributed to gradual crushing of UHPC prior to reinforcement rupture. Failure after gradual strain hardening is desirable since it brings warning signs through high ductility, visible cracks, and controlled spalling. To achieve a resilient structural design of UHPC members, this study aims to develop design methods to avoid early failure after crack localization and promote failure after gradual strain hardening. This study first establishes a three-dimensional finite-element analysis (FEA) model to simulate the flexural behavior of prestressed UHPC beams, which is validated against seven existing experimental beams. Then, parametric analyses are conducted to assess the influence of five key aspects, including the steel rebar-to-prestressing strand ratio, the post-yield hardening of mild steel rebars, the pretensioned stress of prestressing strands, the tensile behavior of UHPC, and the web width to bottom flange ratio. Additionally, the authors propose a design method to predict the failure mode of prestressed UHPC beams, which can be used to guide the design of reinforcement configuration and to promote ductile structural behavior.