不同含水率与静置时间下滩涂土壤流变特性试验

    Experiment on the rheological properties of tidal flat soil with moisture content and standing time

    • 摘要: 为了研究贝类养殖的滩涂土壤的流变属性和结构稳定性,采用旋转流变仪对不同含水率和不同静置时间的滩涂土壤进行了流变试验,通过单因素试验研究了各因素对滩涂土壤流变特性的影响,并分析了土壤剪切过程中的变化机理。同时,通过Response Surface Methodology中的Central Composite Design试验建立了屈服应力与含水率和静置时间之间的数值模型,并比较了含水率和静置时间对屈服应力产生的影响。结果表明:1)剪切过程中滩涂试样经过了弹塑性阶段、固液转化阶段和流体阶段,滩涂土壤表现出了静置时间越长,固液转化阶段就越长的性质,且剪切过程中表现出剪切稀化的性质。2)静置时间的增加会导致整体剪切应力和屈服应力同时增加,含水率的增加会导致整体剪切应力和屈服应力的降低,且滩涂土壤存在一个含水率分界点,此含水率分界点在64.5%~67.0%之间,当超过这个含水率分界点的试样的静置时间超过31 h时,试样的屈服应力基本不会再发生较大的波动,大小在2 240~4 380 Pa之间,此外,静置时间在0~53 h之间且含水率在62.0%~69.5%之间的试样的屈服应力在1 870~5 410 Pa之间。3)含水率对屈服应力的影响比静置时间的影响更加显著,模型的R2为0.953 4,并且在验证试验中,屈服应力的测量值与预测值之间的误差在15.0%以内,都说明了数值模型的可靠性。研究定性和定量地表征了滩涂土壤的流变特性,为滩涂贝类采收机械的研发和优化提供参考。

       

      Abstract: This study aims to determine the rheological properties and structural stability of the beach soil for shellfish cultivation. A series of rheological tests were carried out on the beach soil with different water content and standing time using a rotary rheometer. A single-factor test was also conducted to explore the influence of water content and standing time on the rheological properties of the beach soil. The soil shear was then analyzed to determine the influence of water content and standing time on yield stress. At the same time, the numerical model was established for the yield stress, water content and resting time after the central composite design (CCD) test in the response surface method (RSM). A comparison was then made on the influence of water content and resting time on yield stress. Finally, the reliability and accuracy of the regression model were further verified to compare the error between the measured and the actual values. The results show as follows: 1) The shear stress gradually decreased with the increase of water content under the same shearing rate in the shearing process, whereas there was a gradual increase with the increase of standing time; In addition, the beach soil was characterized by the consolidation. The longer the static time was, the longer the solid-liquid transformation was, and the later the solid-liquid node was. The static time shared the greatest impact on the solid-liquid node in the early stage. The longer the static time was, the smaller the impact on the solid-liquid node was. 2) When the average shear stress and yield stress were at the shear rate of 10 -60 s-1 under the same standing time, the overall shear stress of the tidal flat soil gradually decreased with the increase of water content, thus reducing the structural stability of the tidal flat soil. In addition, the overall shear stress of the tidal flat soil gradually increased under the same moisture content with the increase of static time, indicating the increase in the structural stability of tidal flat soil. The change rate of yield stress with the static time showed that there was a cut-off point of moisture content in the beach soil, which was between 64.5% and 67.0%. In the samples exceeding this moisture content cut-off point, the change rate of yield stress with the static time remained stable after the static time exceeded 31 h, where there was no fluctuation in the yield stress. The yield stress ranged from 2 240 to 4 380 Pa. In addition, the yield stress in the sample of 62.0%-69.5% was between the 0-53 h, and the yield stress between 62.0%-69.5% was between 1 870-5 410 Pa. 3) The P and R2 values of numerical models were above 0.05, and 0.953 4, respectively, indicating the high reliability and accuracy. There was a more significant influence of water content on the yield stress, compared with the resting time. However, the interaction between water content and resting time shared no significant influence on the yield stress. The test verified that the measured yield stress was basically consistent with the predicted one, with an error of less than 15.0%. The rheological properties of beach soil can be better characterized as well. The findings can provide a strong reference for the research and optimization of beach shellfish harvesting machinery.

       

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