| Citation: | Su Yuewei, Zhao Jinggang, Zhang Jiakang, Sun Shaokang, Wang Junxiang, Lv Xianjun. Experimental Study on Low Alkalinity Ecotype Artificial Reef Materials[J]. Multipurpose Utilization of Mineral Resources, 2023, 44(1): 197-203. doi: 10.3969/j.issn.1000-6532.2023.01.029 |
A new type of artificial reef with high strength was prepared by using slag-CaO-FGD gypsum as cementitious material and sea sand as aggregate. The effects of FGD gypsum on the compressive strength and hydration products of the new artificial reef materials were investigated by means of mechanical properties test, X-ray diffraction, thermogravimetric analysis and SEM. The results show that the addition of appropriate amount of desulfurized gypsum can significantly improve the cementitious strength of CaO activated slag cementitious materials, and promote the preferential formation of ettringite (AFt) in the hydration process. Under the optimal gypsum content, the 3 d strength can be increased by 51.4%, the 7 d strength by 35.7%, and the 28 d strength by 25.2%. The dissolution test results of heavy metal ions show that the seawater quality of the immersed samples conforms to the national first class sea water quality standard; pH detection of surface leaching solution showed that a small amount of OH- dissolved in the surface of the artificial reef material test block at the initial stage of seawater immersion, so that the pH value of immersion solution increased from 8.0 of fresh seawater to 8.5, but returned to the normal value after 60 days; in addition, the real sea area hanging board experiment showed that the reef had good marine compatibility and a large number of aquatic organisms attached. Low-alkalinity ecological artificial fish reefs can meet the basic performance requirements of fish reefs, have broad application prospects, and provide a new way for the comprehensive utilization of slag and sea sand.
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XRD pattern of Rizhao slag
XRD pattern of desulfurization gypsum
Effect of the compressive strength of fish reef samples under different gypsum content
XRD patterns of different hydration ages
TG-DTG analysis spectrum at 28 d hydration age
SEM analysis of 28 d hydration age
Change rule of seawater pH value of immersion test block
Biological attachment effect of the test block 90 days after being put in