旋风分离器有无灰斗对气相流场动态特性的影响

doi:10.11949/j.issn.0438-1157.20181443

化工学报 ›› 2019, Vol. 70 ›› Issue (6): 2202-2210.DOI: 10.11949/j.issn.0438-1157.20181443

旋风分离器有无灰斗对气相流场动态特性的影响

孙立强²(),王迪^1,²,宋健斐^1,²,王江云^1,³,魏耀东^1,³()

1. 中国石油大学（北京）重质油国家重点实验室，北京 102249
2. 过程流体过滤与分离技术北京重点实验室，北京 102249
3. 中国石油大学（北京）克拉玛依校区工学院，新疆克拉玛依 834000

收稿日期:2018-12-05 修回日期:2019-03-25 出版日期:2019-06-05 发布日期:2019-06-05
通讯作者: 魏耀东
作者简介:<named-content content-type="corresp-name">孙立强</named-content>(1986—)，男，博士研究生，讲师，<email>sunlq_cup@126.com</email>
基金资助:
国家自然科学基金项目(21776305，21566038);中国石油大学（北京）克拉玛依校区科研启动基金项目(RCYJ2016B-02-002)

Effect of ashless separator on dynamic characteristics of gas phase flow field in cyclone separator

Liqiang SUN²(),Di WANG^1,²,Jianfei SONG^1,²,Jiangyun WANG^1,³,Yaodong WEI^1,³()

1. State Key Laboratory of Heavy Oil Processing, China University of Petroleum, Beijing 102249, China
2. Beijing Key Laboratory of Process Fluid Filtration & Separation, Beijing 102249, China
3. Faulty of Engineering, China University of Petroleum-Beijing at Karamay, Karamay 834000, Xinjiang, China

Received:2018-12-05 Revised:2019-03-25 Online:2019-06-05 Published:2019-06-05
Contact: Yaodong WEI

摘要/Abstract

摘要：

旋风分离器底端的排尘口依据气固分离工艺的要求分别采用有灰斗或无灰斗结构。但灰斗是否存在对旋风分离器内部流场影响的研究尚显不足。为此，采用热线风速仪对排尘口有灰斗和无灰斗的旋风分离器气相流场的切向速度进行了测量。结果表明旋风分离器内旋转流具有较强的不稳定性，表现为瞬时切向的速度低频高幅值波动变化。灰斗的存在进一步导致了排尘口附近瞬时切向速度的强烈波动。通过对瞬时切向速度的频谱分析表明，有灰斗结构的旋风分离器瞬时切向速度有2个主频，分别是存在于整个空间的全空间主频和出现在锥体下端排尘口附近区域的局部主频。无灰斗结构的旋风分离器仅有1个全空间主频。全空间主频是气体旋流中心围绕旋风分离器几何中心摆动造成的，而局部主频是灰斗气体回流造成的。灰斗气体回流主频与全空间旋转流摆动的主频叠加形成了锥体下端排尘口附近区域瞬时切向速度的2个主频。

关键词: 旋风分离器, 流场, 热线风速仪, 灰斗, 速度波动, 主频

Abstract:

The dust exhaust port at the bottom end of the cyclone separator adopts an ash or ashless bucket structure according to the requirements of the gas-solid separation process. The existence of the hopper has an important influence on the flow field inside the cyclone separator, and then the separating performance. But the research of this aspect is few. Therefore, the tangential velocity of gas flow field in the cyclone separator with and without hopper was measured by using hot wire anemometry (HWA). The results show that the swirling flow in the cyclone is highly instability, and the real tangential velocity fluctuates with low frequency and high amplitude. Further, the existence of hopper leads to strong instability of swirling flow field near the dust outlet, which is characterized by intense fluctuation of real tangential velocity. Fast Fourier transform analysis of measured data shows that the real tangential velocity of cyclone separator with hopper has two dominant frequencies, one exists in the whole space and another one presents in the local area near the dust outlet. However there is only one dominant frequency in the whole space of the cyclone without hopper. The dominant frequency of the whole space is caused by the swing of the swirling flow center around the geometric center, while the local dominant frequency is caused by the backflow from the hopper. So, the swing of the swirling flow from the hopper is superimposed on the swing of the swirling flow in the separation space, which forms two dominant frequencies near the dust outlet region.

Key words: cyclone separator, flow field, hot wire anemometry, hopper, velocity fluctuation, dominant frequency

中图分类号:

TQ 051.8

孙立强, 王迪, 宋健斐, 王江云, 魏耀东. 旋风分离器有无灰斗对气相流场动态特性的影响[J]. 化工学报, 2019, 70(6): 2202-2210.

Liqiang SUN, Di WANG, Jianfei SONG, Jiangyun WANG, Yaodong WEI. Effect of ashless separator on dynamic characteristics of gas phase flow field in cyclone separator[J]. CIESC Journal, 2019, 70(6): 2202-2210.

图/表 13

图1 旋风分离器流场测量装置

Fig.1 Schematic of experimental device of cyclone separator

图2 旋风分离器尺寸及测点

Fig.2 Cyclone dimensions and measurement point

表1 旋风分离器尺寸

Table 1 Dimensions of experimental cyclone/mm

D	D _r	D _e	D _h	D _p	H	H _c	H _h	a	b
300	110	130	220	80	430	660	230	178	84

表2 旋风分离器轴向测量截面

Table 2 Axial measuring sections of cyclone/mm

Item	Z ₁	Z ₂	Z ₃	Z ₄	Z ₅	Z ₆	Z ₇
with hopper	370	580	760	990	1190	1215	1240
without hopper	370	580	760	990	—	—	—

图3 有无灰斗存在的时均切向速度分布

Fig.3 Time mean tangential velocity distribution with or without hopper

图4 瞬时切向速度随时间的变化

Fig.4 Variation of real tangential velocity with time

图5 瞬时切向速度的功率谱密度分布(Z=370 mm)

Fig.5 Power spectral densities of real tangential velocity frequency along radial direction (Z=370 mm)

图6 瞬时切向速度的功率谱密度分布(Z=990 mm)

Fig.6 Power spectral densities of real tangential velocity frequency along radial direction (Z= 990mm)

图7 有无灰斗旋风分离器的主频分布

Fig.7 Dominant frequency distribution in cyclone with or without hopper

图8 有无灰斗旋风分离器的主频f 1的能量分布 (r/R=0.12)

Fig.8 f 1 power distribution in cyclone with or without hopper (r/R=0.12)

图9 有灰斗旋风分离器的主频f 2的能量分布

Fig.9 f 2 power distribution in cyclone with hopper

图10 旋风分离器内旋转流的偏心旋转

Fig.10 Swirling flow in cyclone

图11 旋转中心偏移对速度波动的影响

Fig.11 Effect of rotation center offset on tangential velocity fluctuation

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旋风分离器有无灰斗对气相流场动态特性的影响

Effect of ashless separator on dynamic characteristics of gas phase flow field in cyclone separator

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