高海拔地区水泥生产线的节能技术改造

doi:10.19698/j.cnki.1001-6171.20205019

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摘要海拔高度＞2 200m的某公司水泥生产线已投产多年，水泥生产能耗和废气排放难以满足日益严格的国家标准要求。经现场节能诊断，对烧成窑尾预热器及废气系统、烧成窑中及三次风管、烧成窑头及篦冷机等实施了节能技术改造，2018年7月完成了改造验收。改造后，烧成热耗降低438.9kJ/kg熟料，熟料电耗降低6.1kW·h/t熟料。投产一年多来，系统运行稳定，达到了预期技改目标。

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	马娇媚
	何俊秀
	俞为民
	尚再国

关键词: 高海拔低能耗自脱硝技术改造

Abstract:

A certain plant located at an altitude of more than 2 200m had been put into operation for many years, the energy consumption and emissions could not meet the increasingly stringent national standard. After diagnosis on site, the energy-saving transformations were implemented including the preheater, calciner, exhaust gas treating system, kiln and tertiary air duct, cooler, etc. The upgrade project was completed and accepted in July, 2018. After the transformation, the clinker heat consumption was reduced by 438.9kJ/kg.cl, and the power consumption of the clinker was reduced by 6.1kW·h/t.cl. Since it was put into production for more than one year, the system has been operating stably and has reached the expected technical transformation target.

Key words: high altitude low energy consumption self-denitrification technical transformation

收稿日期: 2020-03-18 出版日期: 2020-09-25 发布日期: 2020-10-12 整期出版日期: 2020-09-25

ZTFLH:

TQ172.622.29

引用本文:

马娇媚, 何俊秀, 俞为民, 尚再国.

高海拔地区水泥生产线的节能技术改造

[J]. 水泥技术, 2020, 1(5): 19-23.
MA Jiaomei, HE Junxiu, YU Weimin, SHANG Zaiguo. Energy Saving and Transformation Technology of Cement Plant in High Altitude. Cement Technology, 2020, 1(5): 19-23.

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http://www.cemteck.com/CN/10.19698/j.cnki.1001-6171.20205019 或 http://www.cemteck.com/CN/Y2020/V1/I5/19

[1]	马娇媚, 彭学平, 代中元, 谌佳荣, 刘瑞芝. 水泥生产燃用石油焦自脱硝技术的实践 [J]. 水泥技术, 2019, 1(6): 19-25.
[2]	马娇媚, 彭学平, 狄东仁, 赵亮, 陈昌华, 李波, 王伟. 水泥低能耗先进烧成技术研究与应用[J]. 水泥技术, 2019, 1(3): 21-28.
[3]	余慧英. 窑尾技术改造结构加固设计简介[J]. 水泥技术, 2017, 1(5): 77-80.
[4]	武晓萍, 徐俊杰. 高海拔地区水泥生产线技术诊断及优化[J]. 水泥技术, 2017, 1(1): 85-89.
[5]	胡龙. 第三代篦冷机锤式破碎机的改造[J]. 水泥技术, 2015, 1(6): 88-89.
[6]	才世杰, . 2000t/d干法窑生产G级高抗硫油井水泥 [J]. 水泥技术, 2013, 1(1): 89-92.

[1]	. Review and Prospect of Engineering Practice of Waste Disposal in Cement Kiln in China[J]. Cement Technology, 2018, 1(1): 17 -21 .
[2]	DI Dongren, TAO Congxi, CHAI Xingteng. Revision of Cement Energy Consumption Standards and Energy Saving Technology(Ⅰ)[J]. Cement Technology, 2018, 1(1): 22 -26 .
[3]	LIU Yonggang, GAO Hongwei, XIAO Guiqing. Design Method of Road Structure Using Lean Concrete Base[J]. Cement Technology, 2018, 1(1): 27 -31 .
[4]	LIU Xu, LI Liang. Investigation of New Medium Temperature Wear-resistant Alloy Steel[J]. Cement Technology, 2018, 1(1): 32 -34 .
[5]	MA Debao. Finite Element Analysis of Inverted Cone in Raw Meal Silo[J]. Cement Technology, 2018, 1(1): 35 -38 .
[6]	HAN Zhongqi. [J]. Cement Technology, 2018, 1(1): 38 -48 .
[7]	XIE Jianzhong, LIAN Xuewen. Analysis and Solution of Segregation of the Kiln Ash in Continuous Raw Meal Homogenization Silo#br#[J]. Cement Technology, 2018, 1(1): 49 -53 .
[8]	GUAN Laiqing, HE Yongxian. [J]. Cement Technology, 2018, 1(1): 54 -59 .
[9]	WEI Can, ZHANG Yuanyuan, AI Jun. Application of Cement Intelligent Control System in Overseas Projects[J]. Cement Technology, 2018, 1(1): 60 -64 .
[10]	JIN Shuang. [J]. Cement Technology, 2018, 1(1): 72 -73 .