提升管出口T型弯头压降特性的实验分析

doi:10.3969/j.issn.0438-1157.2014.02.027

化工学报 ›› 2014, Vol. 65 ›› Issue (2): 555-560.DOI: 10.3969/j.issn.0438-1157.2014.02.027

提升管出口T型弯头压降特性的实验分析

汪贵磊, 陈勇, 严超宇, 魏耀东

中国石油大学(北京)重质油国家重点实验室, 北京 102249

收稿日期:2013-05-16 修回日期:2013-10-04 出版日期:2014-02-05 发布日期:2014-02-05
通讯作者: 魏耀东
基金资助:
国家自然科学基金项目（21176250）。

Experimental analysis of T-abrupt exit’s pressure drop characteristics in riser

WANG Guilei, CHEN Yong, YAN Chaoyu, WEI Yaodong

State Key Laboratory of Heavy Oil Processing, China University of Petroleum, Beijing 102249, China

Received:2013-05-16 Revised:2013-10-04 Online:2014-02-05 Published:2014-02-05
Supported by:
supported by the National Natural Science Foundation of China (21176250).

摘要/Abstract

摘要： 在大型循环流化床装置上，以FCC催化剂颗粒为实验物料，针对提升管出口T型弯头用动态压力传感器测量了操作参数和结构尺寸变化对其压降的影响，系统地分析了T型弯头的压降特性。实验结果表明T型弯头的压降与颗粒浓度呈线性关系，与入口速度（提升表观气速）呈二次方关系；T型弯头出口管截面积的减小使得压降显著增大；T型弯头盲管高度的增加可使T型弯头的压降降低，但是当盲管高度增加到一定值时，压降减小不明显。盲管高度对压降的影响是由于盲管高度的增加改变了提升管上部压力的分布，使T型弯头入口压力减小，导致T型弯头的压降降低；同时盲管高度的增加也使提升管出口区域的负压约束区长度增加。盲管所形成的负压约束区构成了对提升管出口的约束作用，T型弯头的盲管高度越大负压约束区越长，约束作用越强。

关键词: 循环流化床, 提升管, T型弯头, 出口结构, 两相流

Abstract: The pressure drop characteristics of T-abrupt exit of the riser were analyzed based on dynamic pressure data of gas-solids two-phase flow in a circulating fluidized bed equipment by using FCC catalyst particles, and varying the operation parameters and equipment dimensions. The pressure drop of T-abrupt exit changed linearly with inlet particle density, and quadratically with inlet gas velocity. It increased significantly with the decrease of outlet tube area of T-abrupt exit. Further, the pressure drop of T-abrupt exit decreased as blind tube length increased, but changed little above a specific length, because increased blind tube length changed the pressure distribution along the upper riser. As blind tube length increased, inlet pressure of T-abrupt exit decreased, hence pressure drop decreased. There was a negative pressure zone along the upper riser and blind tube, which constrained gas-solids two-phase flow in the riser. The longer the blind tube, the longer the negative pressure zone and the greater the constraint.

Key words: circulating fluidized bed, riser, T-abrupt exit, exit configuration, two-phase flow

中图分类号:

TQ021

汪贵磊, 陈勇, 严超宇, 魏耀东. 提升管出口T型弯头压降特性的实验分析[J]. 化工学报, 2014, 65(2): 555-560.

WANG Guilei, CHEN Yong, YAN Chaoyu, WEI Yaodong. Experimental analysis of T-abrupt exit’s pressure drop characteristics in riser[J]. CIESC Journal, 2014, 65(2): 555-560.

参考文献 15

[1]	Grace J R. Influence of riser geometry on particle and fluid dynamics in circulating fluidized bed risers //Proceedings of 5th International Conference on Circulating Fluidized Beds[C]. Beijing, 1999：16-28
[2]	Brereton C M H, Grace J R. End effects in circulating fluidized bed hydrodynamics//Proceedings of 4th International Conference on Circulating Fluidized Beds[C]. AIChE, 1994：137-144
[3]	Jin Yong (金涌), Zhu Jingxu (祝京旭), Wang Zhanwen (汪展文). Fluidization Engineering Principles (流态化工程原理)[M]. Beijing：Tsinghua University Press,2001
[4]	Gupta A V S S K S, Reddy B V. Bed-to-wall heat transfer modelling in the top region of a CFB riser column with abrupt riser exit geometries [J]. International Journal of Heat and Mass Transfer ,2005,48：4307-4315
[5]	van Engelandt G, Heynderickx G J, de Wilde Juray, Marin G B. Experimental and computational study of T- and L-outlet effects in dilute riser flow [J]. Chemical Engineering Science ,2011,66：5024-5044
[6]	Yan Aijie, Pärssinen J H, Zhu Jingxu. Flow properties in the entrance and exit regions of a high-flux circulating fluidized bed riser [J]. Powder Technology,2003,131:256- 263
[7]	Ulrike Lackermeier, Joachim Werther. Flow phenomena in the exit zone of a circulating fluidized bed [J]. Chemical Engineering and Processing,2002,41：771-783
[8]	Chian Wen Chan, Anke Brems, Shiva Mahmoudi, et al. Joseph Gargiuli. PEPT study of particle motion for different riser exit geometries [J]. Particuology,2010,6:623-630
[9]	Cheng Yi, Wei Fei, Yang Guoqiang, Jin Yong. Inlet and outlet effects on flow patterns in gas-solid risers [J]. Powder Technology, 1998,98：151-156
[10]	Juray De Wilde, Guy B Marin, Geraldine J Heynderickx. The effects of abrupt T-outlets in a riser: 3D simulation using the kinetic theory of granular flow [J]. Chemical Engineering Science,2003,58：877- 885
[11]	Cui Xin(崔鑫), Wang Yin(汪印), Dong Li (董利), et al. Effect of fluidized bed configuration on solids circulation rate in high solids flux circulating fluidized bed [J]. CIESC Joural (化工学报),2010,61(1)：49-54
[12]	Chen Yong (陈勇), Wang Guilei (汪贵磊), Han Tianzhu (韩天竹), et al. An experimental analysis of pressure drop of the T-abrupt exit of FCCU riser [J]. Petroleum Refinery Engineering (炼油技术与工程),2012,42(1)：38-40
[13]	Wu Xuezhi, Jiang Fan, Xu Xiang, Xiao Yunhan. CFD simulation of smooth and T-abrupt exits in circulating fluidized bed risers [J]. Particuology ,2010,8：343-350
[14]	Wu Xuezhi(吴学智),Wang Xueyao(王雪瑶),Jiang Fan(姜凡), et al. The numerical investigation of gas-solid flow in a riser with a T-abrupt exit [J]. Journal of Engineering Thermophysics(工程热物理学报),2009,30(8)：1327-1330
[15]	Bao Fubing(包福兵), Chen Lihua(陈丽华), Lin Jianzhong(林建忠), et al. Optimization of T-shape blind elbow length in pneumatic conveying system [J]. Hoisting and Conveying Machinery(起重运输机械),2004,5：46-50

提升管出口T型弯头压降特性的实验分析

Experimental analysis of T-abrupt exit’s pressure drop characteristics in riser

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