煤炭地下气化双层注气管传热特性研究

Heat transfer characteristics of double layer gas injection pipe for underground coal gasification

  • 摘要: 强制氧化点火技术是在地面将空气或富氧气体加热到一定温度后,通过双层注气管的内管输送到地下煤层,对煤层进行强制氧化直至煤层着火。为获得煤炭地下气化强制氧化点火技术的工艺参数,对双层注气管装置的传热特性进行试验研究,获得了2种不同介质在不同注气条件下的流体温度参数,分析了双层注气管内空气和氧气介质的传热过程,计算了不同条件下对应的双层注气管内管传热局部热损失及换热系数,基于傅里叶传热理论建立了二维圆柱体系下圆管内充分发展的稳定流动时流体温度的计算模型,得出了1 000 m的双层注气管的流体温度参数。结果表明,氧气的温度上升速率明显比空气快,并且达到稳定状态时的温度也更高;随着流体流速的增加,注气管出口流体温度随之升高;局部换热系数逐渐降低并在过渡流区域逐渐稳定趋于定值,其中空气约为42.229 W/(m2·℃),氧气约为41.384 W/(m2·℃);局部热损失随着距离的延伸逐渐减小,其中热空气的稳定热损值为3.28 J/s,热氧气的稳定热损值为2.68 J/s;试验温度分布值与理论温度计算模型结果的相对误差小于2%,基于建立的温度计算模型得出当双层注气管距离达到1 000 m时空气出口温度约为104.52℃,氧气出口温度约为114.36℃。上述结果可以为强制氧化点火技术的工程应用提供借鉴。

     

    Abstract: The forced oxidation ignition technology is to heat the air or oxygen enriched gas to a certain temperature on the ground and then transport it to the underground coal seam through the inner pipe of the double-layer gas injection pipe, so as to carry out forced oxidation of the coal seam until the coal seam is on fire.In order to obtain the process parameters of forced oxidation ignition technology for underground coal gasification, the heat transfer characteristics of double-layer gas injection pipe device are experimentally studied, the fluid temperature parameters of two different media under different gas injection conditions are obtained, and the heat transfer process of air and oxygen media in double-layer gas injection pipe is analyzed, The local heat loss and heat transfer coefficient of the corresponding double-layer injection pipe under different conditions are calculated.Based on the Fourier heat transfer theory, the calculation model of the fluid temperature in the fully developed stable flow in the circular pipe under the two-dimensional cylindrical system is established, and the fluid temperature parameters of the 1 000 m double-layer injection pipe are obtained.The results show that the temperature rise rate of oxygen is obviously faster than that of air, and the temperature when reaching the steady state is also higher; With the increase of fluid velocity, the fluid temperature at the outlet of gas injection pipe increases; The local heat transfer coefficient gradually decreases and tends to a constant value in the transition flow region, in which the air is about 42.229 W/(m2·℃),and the oxygen is about 41.384 W/(m2·℃); The local heat loss decreases gradually with the extension of distance, in which the stable heat loss value of hot air is 3.28 J/s and that of hot oxygen is 2.68 J/s; The relative error between the experimental temperature distribution value and the theoretical temperature calculation model is less than 2%.Based on the established temperature calculation model, when the distance between the double-layer gas injection pipe reaches 1 000 m, the air outlet temperature is about 104.52 ℃ and the oxygen outlet temperature is about 114.36 ℃.The above results can provide theoretical guidance for the engineering application of forced oxidation ignition technology.

     

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