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利用弹性波速度测量评估韩国核反应堆辅助建筑热损伤混凝土的静态和动态残余力学性能

Evaluation of Static and Dynamic Residual Mechanical Properties of Heat-Damaged Concrete for Nuclear Reactor Auxiliary Buildings in Korea Using Elastic Wave Velocity Measurements.

作者信息

Kee Seong-Hoon, Kang Jun Won, Choi Byong-Jeong, Kwon Juho, Candelaria Ma Doreen

机构信息

Department of Architectural Engineering, Dong-A University, Busan 49315, Korea.

Department of Civil Engineering, Hongik University, Seoul 04066, Korea.

出版信息

Materials (Basel). 2019 Aug 23;12(17):2695. doi: 10.3390/ma12172695.

DOI:10.3390/ma12172695
PMID:31443598
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6747792/
Abstract

The main objectives of this study are (1) to investigate the effects of heating and cooling on the static and dynamic residual properties of 35 MPa (5000 psi) concrete used in the design and construction of nuclear reactor auxiliary buildings in Korea; and (2) to establish the correlation between static and dynamic properties of heat-damaged concrete. For these purposes, concrete specimens (100 mm × 200 mm cylinder) were fabricated in a batch plant at a nuclear power plant (NPP) construction site in Korea. To induce thermal damages, the concrete specimens were heated to target temperatures from 100 °C to 1000 °C with intervals of 100 °C, at a heating rate of 5 °C/min and allowed to reach room temperature by natural cooling. The dynamic properties (dynamic elastic modulus and dynamic Poisson's ratio) of concrete were evaluated using elastic wave measurements (P-wave velocity measurements according to ASTM C597/C597M-16 and fundamental longitudinal and transverse resonance tests according to ASTM C215-14) before and after the thermal damages. The static properties (compressive strength, static elastic modulus and static Poisson's ratio) of heat-damaged concrete were measured by the uniaxial compressive testing in accordance with ASTM C39-14 and ASTM C469-14. It was demonstrated that the elastic wave velocities of heat-damaged concrete were proportional to the square root of the reduced dynamic elastic moduli. Furthermore, the relationship between static and dynamic elastic moduli of heat-damaged concrete was established in this study. The results of this study could improve the understanding of the static and dynamic residual mechanical properties of Korea NPP concrete under heating and cooling.

摘要

本研究的主要目的是

(1)研究加热和冷却对韩国核反应堆辅助建筑设计与施工中使用的35MPa(5000psi)混凝土的静态和动态残余性能的影响;(2)建立热损伤混凝土静态和动态性能之间的相关性。为此,在韩国一座核电站(NPP)施工现场的搅拌站制作了混凝土试件(100mm×200mm圆柱体)。为了诱导热损伤,将混凝土试件以5℃/min的加热速率加热至100℃至1000℃的目标温度,间隔为100℃,然后自然冷却至室温。在热损伤前后,使用弹性波测量(根据ASTM C597/C597M - 16进行纵波速度测量以及根据ASTM C215 - 14进行基本纵向和横向共振试验)评估混凝土的动态性能(动态弹性模量和动态泊松比)。热损伤混凝土的静态性能(抗压强度、静态弹性模量和静态泊松比)根据ASTM C39 - 14和ASTM C469 - 14通过单轴压缩试验进行测量。结果表明,热损伤混凝土的弹性波速度与降低后的动态弹性模量的平方根成正比。此外,本研究建立了热损伤混凝土静态和动态弹性模量之间的关系。本研究结果有助于加深对韩国核电站混凝土在加热和冷却条件下静态和动态残余力学性能的理解。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/6565/6747792/845d5901442a/materials-12-02695-g014.jpg
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