TY - GEN
T1 - Research on Intelligent Perception Visualization of Concrete Vibrating Based on Ultrasonic Technology
AU - Zheng, Haoran
AU - Jia, Xuejun
AU - Su, Weijun
AU - Wang, Xiaoxiao
AU - Lv, Xiang
AU - Zhang, Guangming
N1 - Publisher Copyright:
© 2025 IEEE.
PY - 2025
Y1 - 2025
N2 - The propagation of ultrasonic waves in concrete provides valuable insights into the material's internal properties, enabling the intelligent monitoring and evaluation of the vibration process. This study focuses on the development and application of ultrasonic technology to achieve intelligent perception and visualization during concrete vibration. Based on the elastic wave theory, the effects of material properties such as density, elastic modulus, and composition on wave propagation were analyzed. A systematic experimental investigation was conducted using concrete mixtures with varying aggregate contents to explore the relationship between ultrasonic wave characteristics and material heterogeneity. Results showed that as aggregate content increased, the wave velocity decreased, while attenuation and scattering effects became more pronounced, reflecting the growing complexity of the internal structure. This research establishes a strong theoretical and experimental foundation for optimizing the concrete vibration process and highlights the potential of ultrasonic technology for real-time quality monitoring and intelligent control in concrete construction. The findings offer practical significance for improving compactness and uniformity, thereby enhancing the overall quality of construction.
AB - The propagation of ultrasonic waves in concrete provides valuable insights into the material's internal properties, enabling the intelligent monitoring and evaluation of the vibration process. This study focuses on the development and application of ultrasonic technology to achieve intelligent perception and visualization during concrete vibration. Based on the elastic wave theory, the effects of material properties such as density, elastic modulus, and composition on wave propagation were analyzed. A systematic experimental investigation was conducted using concrete mixtures with varying aggregate contents to explore the relationship between ultrasonic wave characteristics and material heterogeneity. Results showed that as aggregate content increased, the wave velocity decreased, while attenuation and scattering effects became more pronounced, reflecting the growing complexity of the internal structure. This research establishes a strong theoretical and experimental foundation for optimizing the concrete vibration process and highlights the potential of ultrasonic technology for real-time quality monitoring and intelligent control in concrete construction. The findings offer practical significance for improving compactness and uniformity, thereby enhancing the overall quality of construction.
KW - Concrete Vibration
KW - Intelligent Monitoring
KW - Ultrasonic Technology
UR - http://www.scopus.com/inward/record.url?scp=105003906677&partnerID=8YFLogxK
U2 - 10.1109/ICEAAI64185.2025.10957141
DO - 10.1109/ICEAAI64185.2025.10957141
M3 - 会议稿件
AN - SCOPUS:105003906677
T3 - 2025 International Conference on Electrical Automation and Artificial Intelligence, ICEAAI 2025
SP - 1356
EP - 1360
BT - 2025 International Conference on Electrical Automation and Artificial Intelligence, ICEAAI 2025
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 2025 International Conference on Electrical Automation and Artificial Intelligence, ICEAAI 2025
Y2 - 10 January 2025 through 12 January 2025
ER -