Document Type
Extended Abstract
Abstract
Concrete strength is a key factor influencing construction quality, cost, schedule, and durability. However, current testing methods—such as cylinder and beam breaks—are time-consuming, costly, and carbon-intensive, often delaying construction and generating unnecessary waste. Existing maturity methods (e.g., ASTM C1074) also require pre-established, mix-specific curves that take weeks and thousands of dollars to develop.To address these challenges, we developed the REBEL Sensor—an IoT-enabled technology that enables direct, real-time, and wireless monitoring of in-place concrete strength without the need for pre-determined calibration curves. By accurately predicting final strength at 28 or 56 days from the initial mix, our sensor empowers engineers to optimize curing schedules and validate new low-carbon mixes more efficiently. Importantly, our field data show that concrete strength often exceeds specified targets by 20–25%, revealing significant potential for cement reduction. By avoiding “over cementing,” the sensor directly supports carbon footprint reduction without compromising strength or durability. Furthermore, minimizing or eliminating destructive testing reduces material waste and associated emissions.
Keywords
Electromechanical impedance (EMI); Direct mechanical monitoring; Wireless data transmission; IoT; carbon reduction.
DOI
10.5703/1288284318019
REBEL Sensor for Real-Time Concrete Strength: Eliminating Calibration and Reducing Carbon Footprint
Concrete strength is a key factor influencing construction quality, cost, schedule, and durability. However, current testing methods—such as cylinder and beam breaks—are time-consuming, costly, and carbon-intensive, often delaying construction and generating unnecessary waste. Existing maturity methods (e.g., ASTM C1074) also require pre-established, mix-specific curves that take weeks and thousands of dollars to develop.To address these challenges, we developed the REBEL Sensor—an IoT-enabled technology that enables direct, real-time, and wireless monitoring of in-place concrete strength without the need for pre-determined calibration curves. By accurately predicting final strength at 28 or 56 days from the initial mix, our sensor empowers engineers to optimize curing schedules and validate new low-carbon mixes more efficiently. Importantly, our field data show that concrete strength often exceeds specified targets by 20–25%, revealing significant potential for cement reduction. By avoiding “over cementing,” the sensor directly supports carbon footprint reduction without compromising strength or durability. Furthermore, minimizing or eliminating destructive testing reduces material waste and associated emissions.