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主办单位:煤炭科学研究总院有限公司、中国煤炭学会学术期刊工作委员会
基于光纤系统的物理相似模型温度分布与演化特征
  • Title

    Temperature distribution and its evolution characteristics of physical similarity model by optical fiber sensing system

  • 作者

    柴敬刘奇张丁丁宋军李毅袁强

  • Author

    CHAI Jing1,2 ,LIU Qi1 ,ZHANG Ding-ding1,2 ,SONG Jun1 ,LI Yi1,2 ,YUAN Qiang1

  • 单位

    西安科技大学能源学院教育部西部矿井开采与灾害防治重点实验室

  • Organization
    1. College of Energy Science and Engineering,Xi’an University of Science and Technology,Xi’ an  710054,China; 2. Key Laboratory of Western Mine Ex-ploitation and Hazard Prevention,Ministry of Education,Xi’an  710054,China
  • 摘要
    为减小水分因素引起的模型试验相似误差,提出了用温度特征确定模型干燥过程的干燥时间(判断模型试验开挖)的方法。建立了光纤传感测温系统,提出克里金空间插值法的估值公式计算模型温度,给出物理模型的温度变异函数表达式。开展了3.0 m×1.2 m×0.2 m二维模型和3.6 m×2.0 m×2.0 m三维模型温度监测试验,监测时间分别超过65,310 d,绘制出模型温度分布云图,探讨了模型干燥(试验开挖)的判断方法。研究表明,模型干燥存在水化放热和液-气相态转变的不同过程,模型温度场演化具有明显的阶段特征,最大温差分别为3.0,4.8℃。干燥后期呈现出竖直方向上高下低的温度梯度,水平方向大致相同的特征,其中低温核区下移并消失是判断模型干燥完成的标志,可作为试验开挖的判断指标。二维模型干燥时间为47 d左右,三维模型干燥时间为213 d左右。
  • Abstract
    In order to reduce errors that are caused by moisture content changing during physical model simulation tests,a method is proposed for determining the model’s drying process time using temperature-distribution characteris- tics. A fiber optic temperature-sensing system is used to measure temperature distributions within the physical model. A Kriging space interpolation formula is presented to calculate temperature values between the measured temperature locations and a function expressing the variation of temperatures in the physical model is given. Temperature monito- ring experiments of model drying process were carried out in a two-dimensional model with the size of 3. 0 m×1. 2 m× 0. 2 m and a three-dimensional model with the size of 3. 6 m×2. 0 m×2. 0 m,and the monitoring time were each be- yond 65 days and 310 days Subsequently,the temperature distribution map of model drying was drawn and the distin- guishing method of model drying completing was analyzed. The results of these tests show that the drying process in the physical model consists of hydration heat release and liquid-gas phase state change,and found a maximum temperature difference of 3. 0 ℃ and 4. 8 ℃ for the two-dimensional and three-dimensional models,respectively. In the later stage of the drying process,the vertical temperature gradient presents a high and low form model’s up to down,and the horizontal direction is approximately the same form model’s right to left. The nucleus of the low temperature zone moved downward and then disappeared signaling the completion of the drying process,and thus can be used as the judgment of a model excavation experiment. The drying time of two-dimensional model is about 47 days in the winter season,and the drying time of the three-dimensional model is about 213 days in the spring and summer seasons.
  • 关键词

    相似物理模型干燥过程光纤测温系统克里金温度场

  • KeyWords

    similar physical model;drying process;optical fiber temperature measuring system;Kriging;temperature field

  • 基金项目(Foundation)
    国家自然科学基金资助项目(41027002);高等学校博士学科点专项科研基金资助项目(20126121110003);
  • DOI
  • Citation
    Chai Jing,Liu Qi,Zhang Dingding,et al. Temperature distribution and its evolution characteristics of physical similarity model by optical fi- ber sensing system[J]. Journal of China Coal Society,2017,42(5):1146-1155.
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主办单位:煤炭科学研究总院有限公司 中国煤炭学会学术期刊工作委员会

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