期刊
JOURNAL OF BUILDING ENGINEERING
卷 39, 期 -, 页码 -出版社
ELSEVIER
DOI: 10.1016/j.jobe.2021.102290
关键词
Heavyweight concrete; X-ray and gamma-ray radiations; Radiation shielding; Radiation attenuation; By-product aggregate
资金
- Ministry of Science, Technology and Innovation (MOSTI) of Malaysia through the International Collaboration Fund (ICF) [IF0420I1224]
Heavy weight concrete (HWC) is widely used in special infrastructures such as nuclear power, medical, nuclear science, and industrial facilities for its ability to effectively attenuate harmful radiation. However, current research faces limitations and challenges in cost efficiency, material combinations, and improving performance that need further study and optimization.
Heavy weight concrete (HWC) is one of the most used artificial materials for the embodiment of special infrastructures such as nuclear power, medical, nuclear science and industrial facilities. The review highlights the main aspects of HWC covering the general concept of radiation physics, fundamental of geometrical design for radiation attenuation and recent advances of HWC technology. An overview of recent research and development of HWC for various applications in engineering and radiation attenuation is elaborated. Besides, the primary industrial applications, future challenges and current limitations of research and development of HWC are also deliberated. Recent works had established that the degree of attenuation of biologically harmful forms of radiation, such as gamma-rays and X-rays, is proportional to the atomic mass (Z) of the shielding material. The high penetration power enables the radiations to penetrates the living bodies and causes harmful ionization of the biological cells. Therefore, the concrete material capable of effective attenuation of these rays plays a critical role in ensuring the safety and health of personnel in nuclear facilities. A comprehensive analysis of the literature shows the limitations in the present body of knowledge associated with the use of more than one type of nanomaterials to achieve a virtually impervious HWCs. Besides, a significant gap was identified on the method of improving the cost efficiency of HWC by the use of byproduct heavyweight aggregates or by adding more than one type of aggregate and inclusion of heavyweight fiber. The review had established several critical areas for future works covering cost optimization in the formulation of high-quality HWC, reactive powder and geopolymer HWC, combinations of nano-materials, crack control and elevating Z-value of HWC to improve harmful radiation attenuation performance.
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