In today’s market, it is imperative to be knowledgeable and have an edge over the competition. ACI members have it…they are engaged, informed, and stay up to date by taking advantage of benefits that ACI membership provides them.
Read more about membership
Learn More
Become an ACI Member
Founded in 1904 and headquartered in Farmington Hills, Michigan, USA, the American Concrete Institute is a leading authority and resource worldwide for the development, dissemination, and adoption of its consensus-based standards, technical resources, educational programs, and proven expertise for individuals and organizations involved in concrete design, construction, and materials, who share a commitment to pursuing the best use of concrete.
Staff Directory
ACI World Headquarters 38800 Country Club Dr. Farmington Hills, MI 48331-3439 USA Phone: 1.248.848.3800 Fax: 1.248.848.3701
ACI Middle East Regional Office Second Floor, Office #207 The Offices 2 Building, One Central Dubai World Trade Center Complex Dubai, UAE Phone: +971.4.516.3208 & 3209
ACI Resource Center Southern California Midwest Mid Atlantic
Feedback via Email Phone: 1.248.848.3800
ACI Global Home Middle East Region Portal Western Europe Region Portal
Home > Education > Free Web Sessions
Browse from hundreds of recorded presentations from ACI Conventions and other concrete industry events.
UHPC Fiber Orientation and Volume using Electrochemical Impedance Spectroscopy: A Simulation Study Presented by: Khaoula Ettini, University of South Florida
Presentation details
Fiber Orientation in Ultra High-Performance Concrete: Quantification, Characterization, and Implications for Design and Performance, Part 2 (ACI Spring 2024, New Orleans, LA) Fiber orientation in ultra-high performance concrete (UHPC) is a critical factor that relates to both material- and structural-level behavior. Many techniques have been studied to quantify fiber orientation including but not limited to computer vision-aided image analysis, computerized tomography (CT) scanning, and electromagnetic methods. This presentation will discuss a pilot study on the application of electrochemical impedance spectroscopy (EIS) to determine fiber orientation and fiber volume in UHPC-class materials. A series of prismatic beam samples were created with different fiber volume fractions. Different casting methods were employed to create random and aligned fiber orientations. Specimens were scanned using EIS and subsequently subjected to 4-point bending to assess tensile resistance. Additionally, a limited parametric study was completed using a commercially available multiphysics modeling platform. This aimed to determine how different parameters such as fiber orientation and fiber volume fraction influence the impedance response. The presentation will provide an overview of this work and its preliminary findings.
October 14 - 20
Review and Analysis of FRP Bond Lengths from Pull-out Testing Database with Reduced Embedment Lengths Presented by: John Myers, Missouri S&T
FRP Bond and Anchorage in Concrete Structures, Part 1 (ACI Spring 2024, New Orleans, LA) The American Concrete Institute (ACI) 440.1R-15 Guide for the Design and Construction of Structural Concrete Reinforced with Fiber-Reinforced Polymer (FRP) Bars linearly reduces the bar stress and thereby pull-out capacity of FRP bars to zero from an embedment length at 20 bar diameters (db) or less. Most experimental research and data examine the development length of various FRP bars at longer, more traditional, embedment lengths. A database was created from select available data in literature to compare to empirical standards. This investigation examines the bond performance of short embedded FRP bars into concrete considering a pull-out failure mode to expand the understanding of short embedded FRP bars into concrete. Based upon the database collected, for the glass fiber-reinforced polymer (GFRP) rebars, the current 440.1R appear quite conservative. For the basalt fiber-reinforced polymer (BFRP) rebar database collected, the current ACI 440.1R-15 provisions appear unconservative for a statistically significant number of the specimen test results within the database. In the case of the carbon fiber-reinforced polymer (CFRP) database, which is quite limited, the data appears to develop considerably less bond strength than the current 440.1R provisions might suggest which requires deeper investigation for the case of short embedment length bonded CFRP bars.
Use the below tools to find an education presentation on the topic of interest to you.
SEARCH FOR A PRESENTATION»