间歇式沥青搅拌站烘干加热系统的研究
|
摘要
作为沥青路面机械化施工的关键设备,沥青混凝土搅拌设备已经被广泛用于公路建设,并随着公路建设的快速发展,设备的需求量不断增加,但同时也对产品的性能提出了更高的要求,因为其运行状况的好坏不仅影响着道路的摊铺质量与施工的进度,而且对能源高效利用、减少对环境的污染有着重要的意义。本文主要进行以下几个方面的研究:
1.概述国内外沥青混凝土搅拌设备的发展状况以及现有的生产技术,并且结合我国国情,给出适合我国施工建设的沥青混凝土搅拌设备及相关技术。
2.介绍了沥青烘干加热系统各部分的结构和工作原理以及烘干加热系统的匹配问题。
3.分析烘干滚筒骨料平衡问题,并对燃烧过程进行计算,确定三个工艺区烘干加热所需要的热量及温度、通过筒壁的热量损失、燃料燃烧时的有效利用热量和消耗率及废气排出所带走的热量,并在此基础上计算出烘干滚筒的热效率。
4.根据烘干滚筒的热效率并结合骨料在滚筒内的充满率对滚筒的结构参数进行优化,主要包括滚筒的直径、长度和转速,并且分析了滚筒内腔叶片形状和分布的设计方法,燃烧器的选择需要从燃料燃烧的充分性和稳定性以及燃烧温度和油气喷射速度的关系去分析,最后从净化气体量和抽风机的功率的角度为常用除尘器的选择给出较为实用的计算方法,完成整个烘干加热系统的研究分析。
结合烘干滚筒的结构参数,利用流体动力学软件Fluent完成了对模型流场的数值模拟,并对模拟仿真结果进行了分析,在理论和软件分析的基础上对参数的设计优化、提高热效率、降低燃油消耗及环境污染有着十分重要的意义。
Asphalt mixing plant has been widely used in highway construction as animportant equipment for the mechanized construction of asphalt pavement. Thequantities of asphalt mixing plant are increasing with the rapid development ofhighway construction, but at the same time the quality of product have become moreimportant. Because it’s operational status not only direct impact the quality andprogress of road construction, but also has an important practical significance.Focusing on the following aspects:
1. Summary the development and existing production technology of asphalt mixingplant domestic and foreign and combining the situation of our country.Putting forwardthat which kind of equipment is more suitable for construction in our country and therelated technology.
2. Describe the structure and working principle of the asphalt heating system andput forward the problem that the matching of the dry heating system.
3. Analysis the aggregate balance and then calculate the combustion process todetermine the heat of the three technology areas and the temperature, the heat lossthrough the tube, the effective use and the consumption rate when fuel burns and theheat loss from the exhaust gas, at last calculate thermal efficiency of the drying drum.
4. According to the thermal efficiency of the drying drum and combined with thefull rate of the aggregate inside the drum to optimize the structure parameters of thedrying drum, including the roller diameter、volume、length and speed. Analyzing thedesign method of the shape and distribution about the material blades, the choice of theburner should analyze the adequacy and stability of fuel when it’s burning and therelationship about the combustion temperature and the gas jet velocity, at last give thepractical calculation method of the dust collector from the point of view of purificationthe amount of gas and the exhaust fan power.
Utilizing the Computational Fluid Dynamics (CFD) simulates the fluid flow basedon the structural parameters of drying drum. There’s a very important significance foroptimized design and improve thermal efficiency through the theory and softwareanalysis.
1.概述国内外沥青混凝土搅拌设备的发展状况以及现有的生产技术,并且结合我国国情,给出适合我国施工建设的沥青混凝土搅拌设备及相关技术。
2.介绍了沥青烘干加热系统各部分的结构和工作原理以及烘干加热系统的匹配问题。
3.分析烘干滚筒骨料平衡问题,并对燃烧过程进行计算,确定三个工艺区烘干加热所需要的热量及温度、通过筒壁的热量损失、燃料燃烧时的有效利用热量和消耗率及废气排出所带走的热量,并在此基础上计算出烘干滚筒的热效率。
4.根据烘干滚筒的热效率并结合骨料在滚筒内的充满率对滚筒的结构参数进行优化,主要包括滚筒的直径、长度和转速,并且分析了滚筒内腔叶片形状和分布的设计方法,燃烧器的选择需要从燃料燃烧的充分性和稳定性以及燃烧温度和油气喷射速度的关系去分析,最后从净化气体量和抽风机的功率的角度为常用除尘器的选择给出较为实用的计算方法,完成整个烘干加热系统的研究分析。
结合烘干滚筒的结构参数,利用流体动力学软件Fluent完成了对模型流场的数值模拟,并对模拟仿真结果进行了分析,在理论和软件分析的基础上对参数的设计优化、提高热效率、降低燃油消耗及环境污染有着十分重要的意义。
Asphalt mixing plant has been widely used in highway construction as animportant equipment for the mechanized construction of asphalt pavement. Thequantities of asphalt mixing plant are increasing with the rapid development ofhighway construction, but at the same time the quality of product have become moreimportant. Because it’s operational status not only direct impact the quality andprogress of road construction, but also has an important practical significance.Focusing on the following aspects:
1. Summary the development and existing production technology of asphalt mixingplant domestic and foreign and combining the situation of our country.Putting forwardthat which kind of equipment is more suitable for construction in our country and therelated technology.
2. Describe the structure and working principle of the asphalt heating system andput forward the problem that the matching of the dry heating system.
3. Analysis the aggregate balance and then calculate the combustion process todetermine the heat of the three technology areas and the temperature, the heat lossthrough the tube, the effective use and the consumption rate when fuel burns and theheat loss from the exhaust gas, at last calculate thermal efficiency of the drying drum.
4. According to the thermal efficiency of the drying drum and combined with thefull rate of the aggregate inside the drum to optimize the structure parameters of thedrying drum, including the roller diameter、volume、length and speed. Analyzing thedesign method of the shape and distribution about the material blades, the choice of theburner should analyze the adequacy and stability of fuel when it’s burning and therelationship about the combustion temperature and the gas jet velocity, at last give thepractical calculation method of the dust collector from the point of view of purificationthe amount of gas and the exhaust fan power.
Utilizing the Computational Fluid Dynamics (CFD) simulates the fluid flow basedon the structural parameters of drying drum. There’s a very important significance foroptimized design and improve thermal efficiency through the theory and softwareanalysis.
引文
[1]张超群.国内沥青搅拌设备技术现状和发展趋势[J].交通世界,2007,161(12):32-35
[2]李科锋,马俊.发展中的我国沥青搅拌设备行业[J].建筑机械,2007,9:8-9
[3]赵伶玲.旋流燃烧器的稳燃及其结构优化分析[J].动力工程,2006,26(1):74-80
[4]孙祖望,刘洪海.影响间歇式沥青混凝土搅拌设备生产能力的因素和额定生产能力的确定[J].筑路机械与施工机械化,1995,12(55):6-9
[5]孙祖望.连续式搅拌设备的发展及其与间歇式搅拌设备的比较[J].建设机械技术与管理,2011,24(4):84-89
[6]耿凡,徐大勇.筒干燥器中颗粒混合运动的三维数值模拟[J].应用力学学报,2008,25(3):529-534
[7]倪寿璋.色路面成套机械与设备[M].北京:人民交通出版社,1988
[8]何挺继.路机械手册[M].北京:人民交通出版社,1998
[9]惠光云.燥筒叶片布置结构与热交换[J].建筑机械,2010,23:120-122
[10]田奇.凝土搅拌楼及沥青混凝土搅拌站[M].北京:中国建材工业出版,2005
[11]崔振东.沥青搅拌站除尘设备工作原理及改进方法[J].建筑机械:2002,2:55-57
[12]胡艳和.沥青搅拌站骨料烘干加热热工学分析计算[J].施工技术,2006,7:82-85
[13]沈维道.工程热力学[M].北京:高等教育出版社,1982
[14]余建辉.沥青搅拌设备袋式除尘器[J].筑路机械与施工机械化,2004,9:17-18
[15]邵成东.滚筒式沥青混凝土搅拌设备除尘系统的配置设计[J].筑路机械与施工机械化,2001,4:3-4
[16]李殿健.沥青路面施工机械与机械化施工[M].北京:交通出版社,2000
[17]黄玉河,余建辉.沥青搅拌设备主燃烧器的选型[J].工程机械与维修,2007,3:101-102
[18]廖道升.烘干滚筒燃烧火焰区叶片的“T”形结构设计[J].筑路机械与施工机械化,1993,10(47):5-7
[19]李德超.浅议间歇式沥青搅拌站烘干滚筒的干燥能力[J].施工机械与施工技术,2009,12:42-44
[20] Henrikas Sivilevicius,Valentinas Podvezko,Sigute Vakriniene.The use ofconstrained and unconstrained optimization models in gradation design of hotmix asphalt mixture[J].Construction and Building Materials,2010,(39):115-122
[21] D.Peinado,Mde Vega,N.Garcia-Hernando,C.Marugan-Cruz.Energy and exergyanalysis in an asphalt plant's rotary dryer[J].Applied Thermal Engineering,2010,1039-1049
[22]王浩.传统沥青砼拌和设备的再生工艺改造及热效率研究[D].江苏:江苏大学,2007
[23]姜涛,邢军. LQB-3000型沥青混合料搅拌设备烘干筒的设计[J].筑路机械与施工机械化,2002,19(97):1-2
[24]凌杰.厂拌热再生沥青混凝土干燥滚筒设计方法[J].工程机械,2008,39(2):38-40
[25]黄志刚,朱慧.转筒内物料滞留时间的研究[J].包装工程,2007,28(1):106-107
[26] Sefa Tarhana,Isa Telci,M. Taner Tuncayc,Hakan Polatci.Product quality andenergy consumption when drying peppermint by rotary drum dryer[J].IndustrialCrops and Products,2010,(32):420–427
[27] P.M. Wadke,A.D. Salman,M.J. Hounslow.The ‘Smart’ temperature sphere:Application in rotary drum mixers[J].Powder Technology,2008,185:274-279
[28]李海鹏.沥青搅拌设备干燥滚筒热效率分析和结构优化设计[D].陕西:长安大学,2011
[29]谢立扬,李卫章.沥青搅拌设备燃烧器性能分析[J].筑路机械与施工与机械化,2007,(9):4-6
[30]杨文龙. BD-1600沥青拌和站燃烧系统的工作原理及故障诊断[J].建筑机械,2000,3:45-46
[31] Shaopeng Wu,Jian Qiu a,Liantong Mo,Jianying Yu a,Yongmei Zhang c,Bo Lia.Resources Conservation&Recycling[J].2007,(51):610-620
[32]王应时.燃烧过程数值计算[M].北京:科学出版社,1986
[33]谢立扬,党森纪.沥青混合料搅拌设备风压系统计算[J].路面机械与施工技术,2005,(4):15-18
[34]杨卫东.间歇式沥青搅拌设备骨料烘干加热系统匹配研究[D].陕西:长安大学,2008
[35]张晓,杨光,魏凤春.布袋除尘器在沥青搅拌设备中的应用[J].路桥建设,2010,(2):88-89
[36]李海鹏,孔德勇,王鹏.干燥滚筒内流场和传热过程的数值模拟[J].工程机械,2011,42(6):20-23
[37]王福军.计算流体动力学分析-CFD软件原理与应用[M].北京:清华大学出版社,2004
[38]韩占忠.流体工程仿真计算实例与分析[M].北京:北京理工大学出版社,2009
[2]李科锋,马俊.发展中的我国沥青搅拌设备行业[J].建筑机械,2007,9:8-9
[3]赵伶玲.旋流燃烧器的稳燃及其结构优化分析[J].动力工程,2006,26(1):74-80
[4]孙祖望,刘洪海.影响间歇式沥青混凝土搅拌设备生产能力的因素和额定生产能力的确定[J].筑路机械与施工机械化,1995,12(55):6-9
[5]孙祖望.连续式搅拌设备的发展及其与间歇式搅拌设备的比较[J].建设机械技术与管理,2011,24(4):84-89
[6]耿凡,徐大勇.筒干燥器中颗粒混合运动的三维数值模拟[J].应用力学学报,2008,25(3):529-534
[7]倪寿璋.色路面成套机械与设备[M].北京:人民交通出版社,1988
[8]何挺继.路机械手册[M].北京:人民交通出版社,1998
[9]惠光云.燥筒叶片布置结构与热交换[J].建筑机械,2010,23:120-122
[10]田奇.凝土搅拌楼及沥青混凝土搅拌站[M].北京:中国建材工业出版,2005
[11]崔振东.沥青搅拌站除尘设备工作原理及改进方法[J].建筑机械:2002,2:55-57
[12]胡艳和.沥青搅拌站骨料烘干加热热工学分析计算[J].施工技术,2006,7:82-85
[13]沈维道.工程热力学[M].北京:高等教育出版社,1982
[14]余建辉.沥青搅拌设备袋式除尘器[J].筑路机械与施工机械化,2004,9:17-18
[15]邵成东.滚筒式沥青混凝土搅拌设备除尘系统的配置设计[J].筑路机械与施工机械化,2001,4:3-4
[16]李殿健.沥青路面施工机械与机械化施工[M].北京:交通出版社,2000
[17]黄玉河,余建辉.沥青搅拌设备主燃烧器的选型[J].工程机械与维修,2007,3:101-102
[18]廖道升.烘干滚筒燃烧火焰区叶片的“T”形结构设计[J].筑路机械与施工机械化,1993,10(47):5-7
[19]李德超.浅议间歇式沥青搅拌站烘干滚筒的干燥能力[J].施工机械与施工技术,2009,12:42-44
[20] Henrikas Sivilevicius,Valentinas Podvezko,Sigute Vakriniene.The use ofconstrained and unconstrained optimization models in gradation design of hotmix asphalt mixture[J].Construction and Building Materials,2010,(39):115-122
[21] D.Peinado,Mde Vega,N.Garcia-Hernando,C.Marugan-Cruz.Energy and exergyanalysis in an asphalt plant's rotary dryer[J].Applied Thermal Engineering,2010,1039-1049
[22]王浩.传统沥青砼拌和设备的再生工艺改造及热效率研究[D].江苏:江苏大学,2007
[23]姜涛,邢军. LQB-3000型沥青混合料搅拌设备烘干筒的设计[J].筑路机械与施工机械化,2002,19(97):1-2
[24]凌杰.厂拌热再生沥青混凝土干燥滚筒设计方法[J].工程机械,2008,39(2):38-40
[25]黄志刚,朱慧.转筒内物料滞留时间的研究[J].包装工程,2007,28(1):106-107
[26] Sefa Tarhana,Isa Telci,M. Taner Tuncayc,Hakan Polatci.Product quality andenergy consumption when drying peppermint by rotary drum dryer[J].IndustrialCrops and Products,2010,(32):420–427
[27] P.M. Wadke,A.D. Salman,M.J. Hounslow.The ‘Smart’ temperature sphere:Application in rotary drum mixers[J].Powder Technology,2008,185:274-279
[28]李海鹏.沥青搅拌设备干燥滚筒热效率分析和结构优化设计[D].陕西:长安大学,2011
[29]谢立扬,李卫章.沥青搅拌设备燃烧器性能分析[J].筑路机械与施工与机械化,2007,(9):4-6
[30]杨文龙. BD-1600沥青拌和站燃烧系统的工作原理及故障诊断[J].建筑机械,2000,3:45-46
[31] Shaopeng Wu,Jian Qiu a,Liantong Mo,Jianying Yu a,Yongmei Zhang c,Bo Lia.Resources Conservation&Recycling[J].2007,(51):610-620
[32]王应时.燃烧过程数值计算[M].北京:科学出版社,1986
[33]谢立扬,党森纪.沥青混合料搅拌设备风压系统计算[J].路面机械与施工技术,2005,(4):15-18
[34]杨卫东.间歇式沥青搅拌设备骨料烘干加热系统匹配研究[D].陕西:长安大学,2008
[35]张晓,杨光,魏凤春.布袋除尘器在沥青搅拌设备中的应用[J].路桥建设,2010,(2):88-89
[36]李海鹏,孔德勇,王鹏.干燥滚筒内流场和传热过程的数值模拟[J].工程机械,2011,42(6):20-23
[37]王福军.计算流体动力学分析-CFD软件原理与应用[M].北京:清华大学出版社,2004
[38]韩占忠.流体工程仿真计算实例与分析[M].北京:北京理工大学出版社,2009
© 2004-2018 中国地质图书馆版权所有 京ICP备05064691号 京公网安备11010802017129号 地址:北京市海淀区学院路29号 邮编:100083 电话:办公室:(+86 10)66554848;文献借阅、咨询服务、科技查新:66554700 |