【作者】 刘正；

【导师】 周孑民； 邓胜祥；

【作者基本信息】 中南大学 ， 工程热物理， 2007， 硕士

【摘要】 铝电解槽是炼铝的主要设备，其能耗巨大，吨铝直流电耗在13000kWh以上，因此如何降低其能耗是一个很有意义的研究课题。本论文建立了槽壳温度在线检测系统，采集到了槽壳温度值，研究了槽壳温度与槽膛内形之间的关系，设计了槽况诊断专家系统，实现了对电解槽能量及物料平衡的监视，达到了节能降耗的目的。(1)建立了槽壳温度在线检测系统。槽壳温度在线检测系统由工控机、温度转换模块和温度转换器及热电偶组成。热电偶将温度信息传送至温度转换模块，温度转换模块将模拟量转换为数字量后传送至温度转换器，再由温度转换器传送至工控机，进行信息处理、数据库管理和报警提示等。系统所测温度值一方面以图表形式存储和显示；另一方面作为槽况诊断专家系统进行槽况诊断的依据。(2)设计了槽膛内形仿真系统。应用有限容积方法，根据槽壳温度以及相关工艺参数，基于软测量原理，建立了电解槽槽膛内形准三维仿真模型；运用Fortran和Visual Basic语言，开发了电解槽温度场的仿真程序，显示槽膛内形。(3)开发了槽况诊断专家系统。根据槽壳温度值、槽膛内形仿真值及电解槽工艺参数，用对象—属性—值三元组模式建立了数据库；根据各种病槽的发生原因、现象及处理方法，用产生式方法建立了规则库；在它们的基础上构建了专家系统，实现了电解槽槽能量及物料平衡的诊断。本论文的创新点：将温度在线检测和数值仿真技术及人工智能技术三者结合，把槽壳温度检测值和槽膛内形仿真结果作为槽况诊断专家系统对槽况的诊断依据，实现了铝电解槽能量及物料平衡的监视。半年多的试用表明系统运行稳定可靠，智能化程度高。槽壳温度在线检测系统能实时可靠的检测槽壳温度；槽膛内形仿真系统对槽膛的仿真结果与其测量值误差不超过1cm；诊断专家系统能有效地抑制电解槽病槽的发生，保证电解槽的稳定生产。该课题研究成果的应用使电解槽的经济技术指标明显改善，电流效率由92.8％升高到了93.5％，直流电耗由13715kWh／t-Al降到了13578 kWh／t-Al。更多还原

【Abstract】 Aluminum cell is the main aluminum producing equipment with so much energy consumption as 13000kWh per ton, so it makes sense to study the method to reduce energy consumption. In this paper, the aluminum cell temperature on-line inspecting system was constructed, shell temperature was collected, relationship between shell temperature and freeze profile was studied, aluminum cell status diagnosing expert system was designed, realizing the inspection of aluminum cell energy and material balance, achieving the object of reducing energy consumption.(1) The on-line detecting system for shell temperature was constructed.Shell temperature detecting system consists of industrial computer, temperature transform module, temperature transform apparatus and thermocouple. Temperature signal is transferred to the transform module through thermocouple. After the temperature is transformed into digital signals, the signals are transferred to the temperature transform apparatus and again to the industrial computer through temperature transform apparatus, followed by signal processed, database managed and alarm notice. On one hand, the measured temperature values are stored and displayed as the form of table, and on the other hand, its values are provided as basis for the aluminum cell status diagnosing expert system.(2) The temperature and freeze profile simulation system was designed.Based on shell temperature and related technical parameter, finite volume method was used to construct freeze profile quasi three dimension simulation model based on soft measure principle. Fortran and Visual Basic software was used to develop aluminum cell temperature field simulation program displaying the current freeze profile。(3) The aluminum cell status diagnosing expert system was developed.According to inspected temperature of shell, the result of freeze profile simulation and aluminum cell technical parameter, the expert system database was built in the mode of object-property-value and stored in tree structure. Based on the cause of its failure, phenomenon and disposal of the diseased aluminum cell, rules for expert system was produced by the fuzzy producing method, and the energy balance diagnosing for aluminum cell was realized.Some original points in this paper: Based on shell temperature inspected values and freeze profile simulation results, the on-line shell temperature detection, numeric simulation and AI technology were integrated to fulfill the diagnosis for aluminum cell status.More than half year’s application verified its stability and high intelligence. The error between freeze profile simulation result and the measured value was less than 2cm. The diagnosis expert system can effectively prevent malfunction of aluminum cell, ensure its stable production. The technical indexes of aluminum cell were improved with application of our research, with electric efficiency enhanced from 92.8% to 93.5%, and energy consumption decreased from 13715 kWh/t-Al to 13578 kWh/t-Al.更多还原