土壤热脱附系统的控制策略及仿真
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摘要
当下,土壤污染问题日益显著,土壤的安全问题引起社会广泛关注,社会各界都在寻求一种安全可靠的土壤修复方法。土壤热脱附是一种广泛用于处理土壤挥发性有机化合物(VOCs)的土壤修复方法。土壤热脱附修复涉及气体传输与流量控制问题。该文提出了一种将传统PID控制算法与Smith预估补偿器结合,同时联合气体流量相关计算的控制方法,有效地解决了土壤热脱附系统中温度滞后环节对系统稳定的问题,显着提高了系统的稳定性。根据仿真结果表明,提出的控制方法能显着增强系统的稳定性并能有效降低土壤中挥发性有机化合物。
At present,the problem of soil pollution is becoming more and more obvious,and the safety of soil has caused widespread concern in society. All sectors of society are seeking a safe and reliable method of soil remediation. Soil thermal desorption is a kind of the method of soil remediation to be widely used to process the volatile organic compounds( VOCs) in the soil,and it concerns the transmission and flowrate control of the gas and wasted gas. In this paper,a control algorithm based on traditional PID control algorithm combined with Smith predictor compensator and calculation on flow rate control of gas could effectively deal with the impact of large hysteresis in combustion system and significantly improve the stability of the system. The simulation results show that the proposed control method significantly enhanced system stability and effectively decrease the volatile organic compounds to be present in the soil.
At present,the problem of soil pollution is becoming more and more obvious,and the safety of soil has caused widespread concern in society. All sectors of society are seeking a safe and reliable method of soil remediation. Soil thermal desorption is a kind of the method of soil remediation to be widely used to process the volatile organic compounds( VOCs) in the soil,and it concerns the transmission and flowrate control of the gas and wasted gas. In this paper,a control algorithm based on traditional PID control algorithm combined with Smith predictor compensator and calculation on flow rate control of gas could effectively deal with the impact of large hysteresis in combustion system and significantly improve the stability of the system. The simulation results show that the proposed control method significantly enhanced system stability and effectively decrease the volatile organic compounds to be present in the soil.
引文
[1]环境保护部.挥发性有机物(VOCs)污染防治技术政策[J].今日农药,2013,(7):6-7.
[2] Lee Kee Joong,Park Dalkeun,Kim Byeong Uk,et al.Remediation of Petroleum-contaminated Soils by Fluidized Thermal Desorption[J]. Waste Management,1998,18(6/8):503-507.
[3]祁志福.多氯联苯污染土壤热脱附过程关键影响因素的实验研究及应用[D].杭州:浙江大学,2014.
[4]傅海辉,黄启飞,朱晓华,等.温度和停留时间对十溴联苯醚在污染土壤中热脱附的影响[J].环境科学研究,2012,(9).
[5]王春行.液压伺服控制系统[M].北京:机械工业出版社,1989.
[6]回胜.旋流燃天然气燃烧器燃烧特性实验研究[D].哈尔滨:哈尔滨工业大学,2015.
[7]沈维道,童钧耕.工程热力学[M].北京:高等教育出版社,2007.
[8] GB/T 11062-1998,天然气发热量、密度、相对密度和沃泊指数的计算方法[S].
[9]张攀,高彦征,孔火良.污染土壤中硝基苯热脱附研究[J].土壤,2012,44(5):801-806.
[10]高国龙,蒋建国,李梦露.有机物污染土壤热脱附技术研究与应用[J].环境工程,2012,30(1):128-131.
[11]蒋小红,喻文熙,江家华,等.污染土壤的物理/化学修复[J].环境污染与防治,2006,28(03):61-65.
[12]辛星.工业加热炉温度Smith模糊自适应PID控制算法研究[J].中国科技信息,2009,(12):52-53.
[13] Smith O J M. Closer Control of Loops With Dead Time[J].Chemical Engineering Progress,1957,53(5).
[14] Lv Guojian. Experimental Research on Temperature Control System of Resistance Furnace Based on KMM[J]. Automation Technology and Application,2002,21(4):36-37.
[2] Lee Kee Joong,Park Dalkeun,Kim Byeong Uk,et al.Remediation of Petroleum-contaminated Soils by Fluidized Thermal Desorption[J]. Waste Management,1998,18(6/8):503-507.
[3]祁志福.多氯联苯污染土壤热脱附过程关键影响因素的实验研究及应用[D].杭州:浙江大学,2014.
[4]傅海辉,黄启飞,朱晓华,等.温度和停留时间对十溴联苯醚在污染土壤中热脱附的影响[J].环境科学研究,2012,(9).
[5]王春行.液压伺服控制系统[M].北京:机械工业出版社,1989.
[6]回胜.旋流燃天然气燃烧器燃烧特性实验研究[D].哈尔滨:哈尔滨工业大学,2015.
[7]沈维道,童钧耕.工程热力学[M].北京:高等教育出版社,2007.
[8] GB/T 11062-1998,天然气发热量、密度、相对密度和沃泊指数的计算方法[S].
[9]张攀,高彦征,孔火良.污染土壤中硝基苯热脱附研究[J].土壤,2012,44(5):801-806.
[10]高国龙,蒋建国,李梦露.有机物污染土壤热脱附技术研究与应用[J].环境工程,2012,30(1):128-131.
[11]蒋小红,喻文熙,江家华,等.污染土壤的物理/化学修复[J].环境污染与防治,2006,28(03):61-65.
[12]辛星.工业加热炉温度Smith模糊自适应PID控制算法研究[J].中国科技信息,2009,(12):52-53.
[13] Smith O J M. Closer Control of Loops With Dead Time[J].Chemical Engineering Progress,1957,53(5).
[14] Lv Guojian. Experimental Research on Temperature Control System of Resistance Furnace Based on KMM[J]. Automation Technology and Application,2002,21(4):36-37.
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