喷嘴总面积与喷吹管截面积比对滤袋清灰性能的影响

毕远霞; 张留祥; 钱云楼

doi:10.12030/j.cjee.201605211

环境工程学报

喷嘴总面积与喷吹管截面积比对滤袋清灰性能的影响

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毕远霞, 张留祥, 钱云楼. 喷嘴总面积与喷吹管截面积比对滤袋清灰性能的影响[J]. 环境工程学报, 2017, 11(7): 4210-4216. doi: 10.12030/j.cjee.201605211

引用本文:

毕远霞, 张留祥, 钱云楼. 喷嘴总面积与喷吹管截面积比对滤袋清灰性能的影响[J]. 环境工程学报, 2017, 11(7): 4210-4216. doi: 10.12030/j.cjee.201605211

BI Yuanxia, ZHANG Liuxiang, QIAN Yunlou. Influence of ratio of total area of nozzles on blow tube to cross-sectional area of blow tube on bag cleaning performance[J]. Chinese Journal of Environmental Engineering, 2017, 11(7): 4210-4216. doi: 10.12030/j.cjee.201605211

Citation:

BI Yuanxia, ZHANG Liuxiang, QIAN Yunlou. Influence of ratio of total area of nozzles on blow tube to cross-sectional area of blow tube on bag cleaning performance[J]. Chinese Journal of Environmental Engineering, 2017, 11(7): 4210-4216. doi: 10.12030/j.cjee.201605211

喷嘴总面积与喷吹管截面积比对滤袋清灰性能的影响

1.
四川省宜宾学院资源与环境工程学院, 宜宾 644000
2.
浙江吉天环保科技有限公司, 杭州 310018
3.
西南科技大学, 固体废物处理与资源化教育部重点实验室, 绵阳 621010
基金项目:
西南科技大学研究生创新基金重点项目（15ycx031）
中图分类号: X964

Influence of ratio of total area of nozzles on blow tube to cross-sectional area of blow tube on bag cleaning performance

1.
College of Resources and Environmental Engineering, Yibin University, Yibin 644000, China
2.
Zhejiang Ji Tian Environmental and Technology Co. Ltd., Hangzhou 310018, China
3.
Key Laboratory of Solid Waste Treatment and Resource Recycle, Ministry of Education, Southwest University of Science and Technology, Mianyang 621010, China
Fund Project:

摘要: 在自建的脉冲喷吹实验装置上，利用MYD-1540A型压电式压力传感器，对尺寸规格φ120×2 000 mm聚酯无纺布覆PTFE膜滤袋在不同孔管截面积比条件下的滤袋侧壁压力进行测试，实验同时测试了使用不同阀时对应同一孔管截面积比滤袋的侧壁压力，并利用MYD-1380C型压电式压力传感器测试不同阀不同开孔面积时喷吹管内压力随时间的变化。对比分析了同一阀在不同孔管截面积比、不同阀同样孔管截面积比时滤袋的清灰强度，并结合喷吹管内压力随时间变化的曲线分析了孔管截面积比对滤袋清灰性能影响的原理。结果显示：随着孔管截面积比的增大，滤袋清灰强度先增大后减小，喷吹管的最佳孔管截面积比为73.8%，当孔管截面积比达到152.5%及以上或小于26.5%时，清灰强度明显降低；阀的性能会直接影响孔管截面积比对清灰效果的影响；孔管截面积比对滤袋清灰性能影响的本质原因是引起喷吹孔出口气流速度的变化，从而影响压缩空气二次诱导气流量，进而影响滤袋清灰性能。
- 脉冲喷吹 /
- 袋式除尘器 /
- 喷吹管 /
- 孔管截面积比
Abstract: Piezoelectric transducers (Model MYD-1540A) were utilized to measure the pulse pressure inside bags of different ratios of size (120×2 000 mm). The filter bag was made of non-woven polyester with a PTFE membrane, and was used on experimental pulse-jet equipment. The pulse pressure when different valves were employed corresponding to the same ratio, was also measured. The piezoelectric transducers (Model MYD-1380C) were also utilized to measure the variation of blow-tube air pressures over time, with different valves and different ratios. The cleaning intensities under the following conditions (same valve with different ratios, same ratio with different valves, and different ratios with different number of nozzles) were compared. The principle of the effect of ratio on bag cleaning performance was analyzed in combination with variation of the pressure curve over time in the blow tube. The results showed that the bag cleaning intensity first increases;then decreases as the ratio increases. There is an optimum ratio for the blow tube nozzle settings. The optimum ratio in this study was 73.8%. When the ratio was ≥ 152.5% or ≤ 26.5%, the cleaning intensity clearly dropped. The performance of a valve will directly affect the influence of ratio on the cleaning effect. The essential reason for the effect of the ratio on the cleaning performance is that it causes a change of the airflow velocity at the nozzle exit, thus affecting the secondary air flow induced by the compressed air, which affects the bag cleaning performance.
- pulse-jet cleaning /
- bag filter /
- blow tube /
- the ratio of total area of nozzles on the blow tube to the cross-sectional area of blow tube

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[6]	杨雪莲, 党小庆, 边靖, 等. 袋式除尘器脉冲喷吹清灰过程的数值计算[J]. 重型机械, 2010(3): 56-59
[7]	李志华, 夏鹏, 刘建凤, 等. 袋式除尘器喷吹过程的数值模拟[J]. 起重运输机械, 2011(10): 26-29
[8]	DENNIS R, KLEMM H A. Modeling concepts for pulse jet filtration[J]. Journal of the Air Pollution Control Association, 1980, 30(1): 38-43
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[13]	LEITH D, ELLENBECKER M J. Theory for pressure drop in a pulse-jet cleaned fabric filter[J]. Atmospheric Environment, 1980, 14(7): 845-852
[14]	沈恒根, 唐华, 邓晓飞,等. 袋式除尘器脉冲阀耗气量与清灰效果的关系的探讨[C]//全国袋式除尘技术研讨会, 2009
[15]	LU H C, TSAI C J. A pilot-scale study of the design and operation parameters of a pulse-jet baghouse[J]. Aerosol Science and Technology, 1998, 29(6): 510-524
[16]	田玮. 脉冲喷吹袋式除尘器清灰的研究[D]. 西安:西安建筑科技大学, 2005
[17]	杨迪. 脉冲喷吹滤筒除尘器清灰性能研究[D]. 绵阳:西南科技大学, 2008
[18]	SIMON X, CHAZELET S, THOMAS D, et al. Experimental study of pulse-jet cleaning of bag filters supported by rigid rings[J]. Powder Technology, 2007, 172(2): 67-81
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喷嘴总面积与喷吹管截面积比对滤袋清灰性能的影响

1. 四川省宜宾学院资源与环境工程学院, 宜宾 644000
2. 浙江吉天环保科技有限公司, 杭州 310018
3. 西南科技大学, 固体废物处理与资源化教育部重点实验室, 绵阳 621010

收稿日期: 2016-08-04

基金项目:

西南科技大学研究生创新基金重点项目（15ycx031）

关键词:

摘要: 在自建的脉冲喷吹实验装置上，利用MYD-1540A型压电式压力传感器，对尺寸规格φ120×2 000 mm聚酯无纺布覆PTFE膜滤袋在不同孔管截面积比条件下的滤袋侧壁压力进行测试，实验同时测试了使用不同阀时对应同一孔管截面积比滤袋的侧壁压力，并利用MYD-1380C型压电式压力传感器测试不同阀不同开孔面积时喷吹管内压力随时间的变化。对比分析了同一阀在不同孔管截面积比、不同阀同样孔管截面积比时滤袋的清灰强度，并结合喷吹管内压力随时间变化的曲线分析了孔管截面积比对滤袋清灰性能影响的原理。结果显示：随着孔管截面积比的增大，滤袋清灰强度先增大后减小，喷吹管的最佳孔管截面积比为73.8%，当孔管截面积比达到152.5%及以上或小于26.5%时，清灰强度明显降低；阀的性能会直接影响孔管截面积比对清灰效果的影响；孔管截面积比对滤袋清灰性能影响的本质原因是引起喷吹孔出口气流速度的变化，从而影响压缩空气二次诱导气流量，进而影响滤袋清灰性能。

English Abstract

Influence of ratio of total area of nozzles on blow tube to cross-sectional area of blow tube on bag cleaning performance

1. College of Resources and Environmental Engineering, Yibin University, Yibin 644000, China
2. Zhejiang Ji Tian Environmental and Technology Co. Ltd., Hangzhou 310018, China
3. Key Laboratory of Solid Waste Treatment and Resource Recycle, Ministry of Education, Southwest University of Science and Technology, Mianyang 621010, China

Received Date: 2016-08-04

Fund Project:

Keywords:

pulse-jet cleaning /
bag filter /
blow tube /
the ratio of total area of nozzles on the blow tube to the cross-sectional area of blow tube

Abstract: Piezoelectric transducers (Model MYD-1540A) were utilized to measure the pulse pressure inside bags of different ratios of size (120×2 000 mm). The filter bag was made of non-woven polyester with a PTFE membrane, and was used on experimental pulse-jet equipment. The pulse pressure when different valves were employed corresponding to the same ratio, was also measured. The piezoelectric transducers (Model MYD-1380C) were also utilized to measure the variation of blow-tube air pressures over time, with different valves and different ratios. The cleaning intensities under the following conditions (same valve with different ratios, same ratio with different valves, and different ratios with different number of nozzles) were compared. The principle of the effect of ratio on bag cleaning performance was analyzed in combination with variation of the pressure curve over time in the blow tube. The results showed that the bag cleaning intensity first increases;then decreases as the ratio increases. There is an optimum ratio for the blow tube nozzle settings. The optimum ratio in this study was 73.8%. When the ratio was ≥ 152.5% or ≤ 26.5%, the cleaning intensity clearly dropped. The performance of a valve will directly affect the influence of ratio on the cleaning effect. The essential reason for the effect of the ratio on the cleaning performance is that it causes a change of the airflow velocity at the nozzle exit, thus affecting the secondary air flow induced by the compressed air, which affects the bag cleaning performance.

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喷嘴总面积与喷吹管截面积比对滤袋清灰性能的影响

Influence of ratio of total area of nozzles on blow tube to cross-sectional area of blow tube on bag cleaning performance

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喷嘴总面积与喷吹管截面积比对滤袋清灰性能的影响

English Abstract

Influence of ratio of total area of nozzles on blow tube to cross-sectional area of blow tube on bag cleaning performance

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