中小型煤粉锅炉低NO_x燃烧技术改造研究
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摘要
近年来,我国能源需求超常规增长、电力短缺、石油进口依赖度不断增加,能源问题已经成为制约我国经济发展的重要因素之一。作为我国主要能源的煤炭的消费量将逐年扩大,NO_x作为燃煤电站锅炉的排放烟气的主要污染物之一,对环境造成严重的污染。截止到2008年底,我国200MW以下的机组占全国火电总装机容量的26%,这些中小机组对城市以及大气环境污染的贡献率却非常的高,控制其污染物的排放对我国的可持续发展有着重要的意义。
本文以某电厂一台160t/h四角切圆燃煤锅炉为例,通过理论研究和数值模拟的方法,结合现场改造试验,研究锅炉的低NO_x燃烧改造技术。
首先确定主燃烧区域的最低过量空气系数,以确定出的最低过量空气系数为基础进行理论计算,再结合现场的实践经验制定出具体的改造方案并绘制改造方案的图纸;其次,运用目前使用比较广泛的FLUENT数值计算软件对改造前后炉膛内的冷态空气动力、燃烧状况以及NO_x的浓度分布进行模拟,为实际改造提供一定的理论支持;最后,实施现场改造,改造完成后进行性能考核测试,验收改造效果。
改造完成后NO_x的排放量降低了50%,与模拟结果基本吻合。此外,从模拟结果看出,由于重新分配了风和煤粉的混合,炉膛内煤粉的燃烧更加合理,使改造后锅炉的效率提高了0.88%,在改造的同时还兼顾了锅炉的经济性,达到了二者的双赢。
Increasing energy demand, electricity deficiency and increasing dependence onoil importation are among the main energy problems that China is facing today.Energy problem is becoming more and more important. The consumption of coal isincreasing year by year, the combustion of fuels generate more and more NO_xemission, which can lead to serious atmosphere pollution. Until2008, the units under200MW took26%of the total installed capacity of the national thermal power in ourcountry; the pollution from them was serious for the cities. So control the pollution ofpower plant is important for the sustainable development of our country.
A Corner-tangential-boiler of160t/h in a thermal power plant was studied in thethesis by means of theory and simulation and field tests, then the low NO_xcombustion modification technologies was researched.
Firstly,make sure minimum excess air coefficient of the lord burning zone andcalculate on base of it. And then make out the specific reform plan combining withthe practical experience, and render the drawings of the reconstruction plan. Secondly,use the more extensive numerical calculation software FLUENT to simulate the coldair kinetic, combustion status and NO_xconcentration distribution, providingtheoretical support for real reform. Finally, implement the reform, and test theperformance evaluation after the completion, and check the reform effect.
After the reform the NO_xemissions reduced by50%, which had a goodagreement with the simulation results. In addition, it is showed from the simulationresults that the pulverized coal was burned more reasonable because of theredistribution of wind and pulverized coal, which makes the boiler efficiencyincreased by0.88%after reform. Meanwhile the boiler’s economical efficiency wasconsidered, achieving both of the win-win.
本文以某电厂一台160t/h四角切圆燃煤锅炉为例,通过理论研究和数值模拟的方法,结合现场改造试验,研究锅炉的低NO_x燃烧改造技术。
首先确定主燃烧区域的最低过量空气系数,以确定出的最低过量空气系数为基础进行理论计算,再结合现场的实践经验制定出具体的改造方案并绘制改造方案的图纸;其次,运用目前使用比较广泛的FLUENT数值计算软件对改造前后炉膛内的冷态空气动力、燃烧状况以及NO_x的浓度分布进行模拟,为实际改造提供一定的理论支持;最后,实施现场改造,改造完成后进行性能考核测试,验收改造效果。
改造完成后NO_x的排放量降低了50%,与模拟结果基本吻合。此外,从模拟结果看出,由于重新分配了风和煤粉的混合,炉膛内煤粉的燃烧更加合理,使改造后锅炉的效率提高了0.88%,在改造的同时还兼顾了锅炉的经济性,达到了二者的双赢。
Increasing energy demand, electricity deficiency and increasing dependence onoil importation are among the main energy problems that China is facing today.Energy problem is becoming more and more important. The consumption of coal isincreasing year by year, the combustion of fuels generate more and more NO_xemission, which can lead to serious atmosphere pollution. Until2008, the units under200MW took26%of the total installed capacity of the national thermal power in ourcountry; the pollution from them was serious for the cities. So control the pollution ofpower plant is important for the sustainable development of our country.
A Corner-tangential-boiler of160t/h in a thermal power plant was studied in thethesis by means of theory and simulation and field tests, then the low NO_xcombustion modification technologies was researched.
Firstly,make sure minimum excess air coefficient of the lord burning zone andcalculate on base of it. And then make out the specific reform plan combining withthe practical experience, and render the drawings of the reconstruction plan. Secondly,use the more extensive numerical calculation software FLUENT to simulate the coldair kinetic, combustion status and NO_xconcentration distribution, providingtheoretical support for real reform. Finally, implement the reform, and test theperformance evaluation after the completion, and check the reform effect.
After the reform the NO_xemissions reduced by50%, which had a goodagreement with the simulation results. In addition, it is showed from the simulationresults that the pulverized coal was burned more reasonable because of theredistribution of wind and pulverized coal, which makes the boiler efficiencyincreased by0.88%after reform. Meanwhile the boiler’s economical efficiency wasconsidered, achieving both of the win-win.
引文
[1]谌天兵,武建军,韩甲业.燃煤污染现状及其治理技术综述.煤,2006,15(2):1~7
[2]吴忠标.大气污染控制工程.北京:化学工业出版社,2002.15~20
[3]董文彬.中国火电行业氮氧化物中长期控制方案和技术经济研究:[硕士学位论文].南京:南京信息工程大学,2008.5~26
[4]何华庆,朱跃,潘志强,等.低NO_x燃烧技术综述.锅炉制造,2000,(4):34~38
[5]钟秦.选择性非催化还原法脱除NO_x的实验研究.南京理工大学学报,2000,24(1):68~71
[6]毕玉森.低氮氧化物燃烧技术的发展状况.热力发电,2000(2):2~9
[7]滕加伟,宋庆英,于岚,等.催化法脱除NO_x的研究进展.环境污染治理技术与设备,2000(1):38~45
[8]吴碧君,刘晓勤.燃煤锅炉低NO_x燃烧器的类型及其发展.电力环境保护,2004,20(3):24~27
[9] Dipl.-ing,Franz-Josef Marx,Dipl.-ing,Georg.Koch,etal,Low NO_xBituminousCoal Tangential System of the750MW Power Station Unit BexbachEVT-Bericht.2001:22~27
[10]Gaen H.Richards,Charles Q.Maney,Richard W.Borio.Final report preparedfor U.S.department of energy national energy technology laboratory.2002:12~30
[11]Ulrich Greul,Helmut Rudiger,Harmut Spliethoff. NO_xcontrolled combustionin a bench scale test facility.21stInt.Techn.Conf.on Coal Utilization&FuelSystems,1996:18~21
[12]J.O.L.Wendt. Mechanisms Governing the Formation and Destruction of NO_xand Other Nitrogenous Species in Low NO_xCoal CombustionSystems.Conbust.Sci and Tech,1995,108(2):323~344
[13]Sen Li,Tongmo Xu,Shien Hui. NO_xemission and thermal efficiency of a300MWe utility boiler retrofitted by air staging. Appl Energy(2009),2008:12~32
[14]张树国,韩应,王智微.空气分级燃烧技术中两级燃尽风技术实验研究.锅炉制造,2008(2):12~15
[15]由长福,祁海鹰,徐旭常.采用不同湍流模型及差分格式对四角切向燃烧煤粉锅炉内冷态流场的数值模拟.动力工程,2001,21(2):1128~1131
[16]范贤振,郭烈锦,高晖.200MW四角切向燃烧煤粉炉炉内过程的数值模拟.西安交通大学学报,2002,36(3):241~245
[17]周昊,孙平,岑可法.偏转二次风系统600MW燃煤锅炉NO_x排放特性及数值模拟.环境科学学报,2001,21(2):198~202
[18]徐旭常,钟北京.低NO_x煤粉燃烧器的设计原理.动力工程,1995,15(5):53~64
[19]Hill SC,Smoot LD. Modeling of nitrogen oxides formation and destruction incombustion systems. Progress in Energy and Combustion Science,2002,23:269~271
[20]S.C.Hill,L.Douglas Smoot. Modeling of nitrogen oxides formation anddestruction in combustion systems. Progress in energy and combustion science,2007,26:417~458
[21]曾庆广,王阳,董建勋,等.常规煤粉作为再燃燃料的燃料分级燃烧试验研究.中国电力.2005,38(4):5~7
[22]钟北京,傅维标.再燃过程中HCN对NO_x还原的重要性.燃烧科学与技术,2000(6):77~84
[23]C.K.Man,J.R.Gibbins,J.G.Witkamp. Coal characterisation for NO_xprediction in air-staged combustion of pulverised coal. Fuel,2005,84:2190~2195
[24]郝雪梅.空气分级燃烧技术中两级燃尽风技术试验研究.洁净煤燃烧技术,2007(2):436~441
[25]张慧娟.四角切圆空气分级燃烧技术及应用.热能动力工程,2003,18(3):67~72
[26]刘振琪.三级燃烧降低NO_x生成量试验.热力发电,1999,(2):27~30
[27]张晓辉,孙锐,孙绍增,等.200MW锅炉低NO_x燃烧系统改造与试验研究.中国电机工程学报,2008,28(17):8~14
[28]Sloss,Leslie F. Nitrogen Oxides Control Technology Fact Book. New Jersey:Noyes Data Corporation,1992,396~400
[29]蒋欣军.大型燃煤电站锅炉低NO_x燃烧优化运行的研究:[工程硕士学位论文].上海:上海交通大学,2007,22~36
[30]王涌,周屈兰,刘国庆.分离式燃尽风降低NO_x排放的试验研究.工程热物理学报,2011,32(2):243~246
[31]景雪晖,曹志猛,王涌.两段式分级燃烧技术及其实炉应用.新疆电力技术,2011(2):38~43
[32]戚红梅,惠世恩,崔大伟.分离燃尽风反切角度对炉内空气动力场影响的试验研究.热力发电,2010,39(5):13~17
[33]刘霞,葛新锋.Fluent软件及其在我国的应用.能源研究与利用,2003(2):55~62
[34]王瑞金,张凯,王刚.Fluent技术基础与应用实例.北京:清华大学出版社,2007.75~81
[35]刘向军,徐旭常.采用不同网格比较伪扩散对四角切圆型炉膛流场计算的影响.燃烧科学与技术,1997(2):98~105
[36]潘维,池作和,斯东波.四角切圆燃烧锅炉炉膛网格生成方法的研究.动力工程,2005,25(3):55~61
[37]Black T. The Cooper Tool.Proceedings of the5th International MeshingRoundtable,Pittsburgh,1996,13~29
[38]张波,文军,徐党旗.某电站亚临界直流炉改造前、后炉内燃烧的数值模拟及分析.热能动力工程,2005,20(2):197~200
[39]周力行.NO_x生成湍流反应率数值模拟的进展.力学进展,2000,30(1):77~82
[40]张文革.电站锅炉空气分级燃烧的数值模拟.电站系统工程,2008,24(5):9~12
[41]Fiveland,WA,Latham,C E.Use of Mathematical Modeling in the Design ofLow-NO_xBurner for Utility Boiler.Comb. Sci. and Tech,1993,93:53~72
[42]向军,熊友辉.PDF-ARRHENIUS方法模拟煤粉燃烧氮氧化物生成.中国电机工程学报,2002,22(6):156~160
[43]曾小林.水平浓淡煤粉燃烧器近场气固两相流场的数值模拟:[硕士学位论文].哈尔滨:哈尔滨工业大学,2004,31~44
[44]郭印诚,林文漪.煤粉燃烧过程中NO_x生成的数值模拟.燃烧科学与技术,1998,4(1):18~23
[45]钱力庚,樊建人,孙平.600MW锅炉炉内流动与燃烧过程的数值模拟.动力工程,2001,21(1):1032~1037
[46]M.H.Xu,J.L.T.Azevedo. Modelling of the Combustion Process and NO_xEmission in a Utility Boiler.Fuel,2000,79(13):1611~1619
[47]陈志兵,宋亚强.四角切圆锅炉炉内过程热态数值模拟.江苏电机工程,2005,24(2):77~78
[48]李力,李荣先.三维湍流回流气相和煤粉燃烧辐射传热离散坐标模型和热流模型比较.燃烧科学与技术,2000,(1):19~23
[2]吴忠标.大气污染控制工程.北京:化学工业出版社,2002.15~20
[3]董文彬.中国火电行业氮氧化物中长期控制方案和技术经济研究:[硕士学位论文].南京:南京信息工程大学,2008.5~26
[4]何华庆,朱跃,潘志强,等.低NO_x燃烧技术综述.锅炉制造,2000,(4):34~38
[5]钟秦.选择性非催化还原法脱除NO_x的实验研究.南京理工大学学报,2000,24(1):68~71
[6]毕玉森.低氮氧化物燃烧技术的发展状况.热力发电,2000(2):2~9
[7]滕加伟,宋庆英,于岚,等.催化法脱除NO_x的研究进展.环境污染治理技术与设备,2000(1):38~45
[8]吴碧君,刘晓勤.燃煤锅炉低NO_x燃烧器的类型及其发展.电力环境保护,2004,20(3):24~27
[9] Dipl.-ing,Franz-Josef Marx,Dipl.-ing,Georg.Koch,etal,Low NO_xBituminousCoal Tangential System of the750MW Power Station Unit BexbachEVT-Bericht.2001:22~27
[10]Gaen H.Richards,Charles Q.Maney,Richard W.Borio.Final report preparedfor U.S.department of energy national energy technology laboratory.2002:12~30
[11]Ulrich Greul,Helmut Rudiger,Harmut Spliethoff. NO_xcontrolled combustionin a bench scale test facility.21stInt.Techn.Conf.on Coal Utilization&FuelSystems,1996:18~21
[12]J.O.L.Wendt. Mechanisms Governing the Formation and Destruction of NO_xand Other Nitrogenous Species in Low NO_xCoal CombustionSystems.Conbust.Sci and Tech,1995,108(2):323~344
[13]Sen Li,Tongmo Xu,Shien Hui. NO_xemission and thermal efficiency of a300MWe utility boiler retrofitted by air staging. Appl Energy(2009),2008:12~32
[14]张树国,韩应,王智微.空气分级燃烧技术中两级燃尽风技术实验研究.锅炉制造,2008(2):12~15
[15]由长福,祁海鹰,徐旭常.采用不同湍流模型及差分格式对四角切向燃烧煤粉锅炉内冷态流场的数值模拟.动力工程,2001,21(2):1128~1131
[16]范贤振,郭烈锦,高晖.200MW四角切向燃烧煤粉炉炉内过程的数值模拟.西安交通大学学报,2002,36(3):241~245
[17]周昊,孙平,岑可法.偏转二次风系统600MW燃煤锅炉NO_x排放特性及数值模拟.环境科学学报,2001,21(2):198~202
[18]徐旭常,钟北京.低NO_x煤粉燃烧器的设计原理.动力工程,1995,15(5):53~64
[19]Hill SC,Smoot LD. Modeling of nitrogen oxides formation and destruction incombustion systems. Progress in Energy and Combustion Science,2002,23:269~271
[20]S.C.Hill,L.Douglas Smoot. Modeling of nitrogen oxides formation anddestruction in combustion systems. Progress in energy and combustion science,2007,26:417~458
[21]曾庆广,王阳,董建勋,等.常规煤粉作为再燃燃料的燃料分级燃烧试验研究.中国电力.2005,38(4):5~7
[22]钟北京,傅维标.再燃过程中HCN对NO_x还原的重要性.燃烧科学与技术,2000(6):77~84
[23]C.K.Man,J.R.Gibbins,J.G.Witkamp. Coal characterisation for NO_xprediction in air-staged combustion of pulverised coal. Fuel,2005,84:2190~2195
[24]郝雪梅.空气分级燃烧技术中两级燃尽风技术试验研究.洁净煤燃烧技术,2007(2):436~441
[25]张慧娟.四角切圆空气分级燃烧技术及应用.热能动力工程,2003,18(3):67~72
[26]刘振琪.三级燃烧降低NO_x生成量试验.热力发电,1999,(2):27~30
[27]张晓辉,孙锐,孙绍增,等.200MW锅炉低NO_x燃烧系统改造与试验研究.中国电机工程学报,2008,28(17):8~14
[28]Sloss,Leslie F. Nitrogen Oxides Control Technology Fact Book. New Jersey:Noyes Data Corporation,1992,396~400
[29]蒋欣军.大型燃煤电站锅炉低NO_x燃烧优化运行的研究:[工程硕士学位论文].上海:上海交通大学,2007,22~36
[30]王涌,周屈兰,刘国庆.分离式燃尽风降低NO_x排放的试验研究.工程热物理学报,2011,32(2):243~246
[31]景雪晖,曹志猛,王涌.两段式分级燃烧技术及其实炉应用.新疆电力技术,2011(2):38~43
[32]戚红梅,惠世恩,崔大伟.分离燃尽风反切角度对炉内空气动力场影响的试验研究.热力发电,2010,39(5):13~17
[33]刘霞,葛新锋.Fluent软件及其在我国的应用.能源研究与利用,2003(2):55~62
[34]王瑞金,张凯,王刚.Fluent技术基础与应用实例.北京:清华大学出版社,2007.75~81
[35]刘向军,徐旭常.采用不同网格比较伪扩散对四角切圆型炉膛流场计算的影响.燃烧科学与技术,1997(2):98~105
[36]潘维,池作和,斯东波.四角切圆燃烧锅炉炉膛网格生成方法的研究.动力工程,2005,25(3):55~61
[37]Black T. The Cooper Tool.Proceedings of the5th International MeshingRoundtable,Pittsburgh,1996,13~29
[38]张波,文军,徐党旗.某电站亚临界直流炉改造前、后炉内燃烧的数值模拟及分析.热能动力工程,2005,20(2):197~200
[39]周力行.NO_x生成湍流反应率数值模拟的进展.力学进展,2000,30(1):77~82
[40]张文革.电站锅炉空气分级燃烧的数值模拟.电站系统工程,2008,24(5):9~12
[41]Fiveland,WA,Latham,C E.Use of Mathematical Modeling in the Design ofLow-NO_xBurner for Utility Boiler.Comb. Sci. and Tech,1993,93:53~72
[42]向军,熊友辉.PDF-ARRHENIUS方法模拟煤粉燃烧氮氧化物生成.中国电机工程学报,2002,22(6):156~160
[43]曾小林.水平浓淡煤粉燃烧器近场气固两相流场的数值模拟:[硕士学位论文].哈尔滨:哈尔滨工业大学,2004,31~44
[44]郭印诚,林文漪.煤粉燃烧过程中NO_x生成的数值模拟.燃烧科学与技术,1998,4(1):18~23
[45]钱力庚,樊建人,孙平.600MW锅炉炉内流动与燃烧过程的数值模拟.动力工程,2001,21(1):1032~1037
[46]M.H.Xu,J.L.T.Azevedo. Modelling of the Combustion Process and NO_xEmission in a Utility Boiler.Fuel,2000,79(13):1611~1619
[47]陈志兵,宋亚强.四角切圆锅炉炉内过程热态数值模拟.江苏电机工程,2005,24(2):77~78
[48]李力,李荣先.三维湍流回流气相和煤粉燃烧辐射传热离散坐标模型和热流模型比较.燃烧科学与技术,2000,(1):19~23