Experimental investigation of influence of high-pressure condition on filtration performance of natural gas filter cartridge

doi:10.11949/0438-1157.20201260

Abstract

Abstract:

In order to explore the changing law and influencing factors of the filtering performance of natural gas filter elements under high pressure conditions, four types of filter elements were selected as the research objects, and field tests and laboratory performance tests were carried out. The evaluation was carried out in turn according to the technical standards, including the field test for about 410 d, the laboratory test before and after the field test, and the performance test on filter layers. It was found that after the field test, the pressure drop in filter cartridges increased by about 20%, and the rise rate of pressure drop increased even more under the same experiment condition of gas-solid filtration, while the relative difference of the filtration efficiency and quality factor decreased between the four types of filter cartridges. The filter layers were compressed by 7%—31% under the high-pressure condition. As particles were embedded or deposited at the filter media, the permeability of each filter layer generally decreased while the tensile strength of the material increased. Besides, some methods were shown to benefit the stable and reliable operation of the filter cartridge under high pressure conditions, including the selection of fiber material with uniform pore size distribution, composite material with cascade design of filtration accuracy, pleating of filtration layers and inlet side skeleton with pre-separation and diversion functions. The research provides a guidance for the development and optimization of separation cartridges suitable for high-pressure natural gas transportation.

Key words: natural gas, filtration, porous media, pressure drop, pore size

摘要：

为探究高压工况下天然气滤芯的过滤性能变化规律及影响因素，选取了四种规格的滤芯为研究对象，开展了现场实验和实验室性能测试。发现在现场运行410 d后，四种滤芯的压差平均增长约20%，在相同气固过滤实验条件下压差增长速率更大，而四种滤芯的过滤效率和品质因子的差异相对缩小。高压工况下过滤材料压缩了7%~31%，大量颗粒嵌入过滤材料或沉积在表面，各过滤层的透气度普遍下降，而抗拉强度均有所上升。结果表明，选用孔径分布均匀的纤维材料、过滤精度梯级设计的复合材料，对过滤层打褶以及采用导流式骨架，均有助于滤芯在高压运行工况下长周期稳定可靠运行。

关键词: 天然气, 过滤, 多孔介质, 压差, 孔径

CLC Number:

TQ 028.2

LIU Zhen, DU Huadong, HU Xu, JI Zhongli. Experimental investigation of influence of high-pressure condition on filtration performance of natural gas filter cartridge[J]. CIESC Journal, 2021, 72(5): 2669-2679.

刘震, 杜华东, 胡旭, 姬忠礼. 高压工况对天然气滤芯性能影响的实验研究[J]. 化工学报, 2021, 72(5): 2669-2679.

Figures/Tables 14

Table 1 Basic information of the experimental natural gas filter cartridges

滤芯代号	生产单位及型号	纤维过滤介质			滤材装配方式	外骨架形式	内骨架形式
滤芯代号	生产单位及型号	保护层	预过滤层	主过滤层	滤材装配方式	外骨架形式	内骨架形式
A	Jonell JMPG	棉	聚酯	聚丙烯	缠绕	百叶窗式	百叶窗式
B	PECO PCHG	无	聚酯	聚酯	缠绕	无	百叶窗式
C	BCB 52CC	棉	纤维素	玻璃	打褶	冲孔管式	冲孔管式
D	Shengda QLX	聚酯	聚酯	聚酯	缠绕	冲孔管式	冲孔管式

Fig.1 Field test schematic of natural gas filter cartridges

Fig.2 Filtration performance testing system of natural gas filter cartridge

Fig.3 Operating conditions and pressure drop of filters during the field test

Fig.4 Dust collection amount of four filters during the field test

Fig.5 Filtration performance of four filter cartridges before and after field test

Fig.6 Thickness comparison of filter layers

Fig.7 The cross-section SEM images of filter cartridge D

Fig.8 Permeability comparison of different filter material

Fig.9 SEM images of filter layers in filter cartridge A1 and C1

Fig.10 Comparison of average pore size of each filter layer

Fig.11 Pore size distribution of pre-filter layers of filter cartridges A and D

Fig.12 Comparison of fracture load curve of each filter layer

Fig.13 Comparison of tensile strength of each filter layer

References 30

1	Heidenreich S. Hot gas filtration—a review[J]. Fuel, 2013, 104: 83-94.
2	Sparks T, Chase G. Air and gas filtration[M]//Filters and Filtration Handbook. Amsterdam: Elsevier, 2016: 117-198.
3	Mokhatab S, Poe W A, Mak J Y. Handbook of Natural Gas Transmission and Processing: Principles and Practices[M]. Houston, United States: Gulf Professional Publishing, 2018: 197-246.
4	Cachia M, Carrier H, Bouyssiere B, et al. Solid particles in natural gas from a transportation network: a chemical composition study[J]. Energies, 2019, 12(20): 3866.
5	Azadi M, Mohebbi A, Soltaninejad S, et al. A case study on suspended particles in a natural gas urban transmission and distribution network[J]. Fuel Processing Technology, 2012, 93(1): 65-72.
6	Khan T S, Al-Shehhi M S. Review of black powder in gas pipelines—an industrial perspective[J]. Journal of Natural Gas Science and Engineering, 2015, 25: 66-76.
7	吴延鹏, 赵薇, 陈凤君. 不同相对湿度下亲疏水纳米纤维膜空气过滤性能实验研究[J]. 化工学报, 2020, 71: 471-478.
	Wu Y P, Zhao W, Chen F J. Experimental study on air filtration performance of nanofiber membrane with hydrophilic and hydrophobic function at different relative humidity[J]. CIESC Journal, 2020, 71: 471-478.
8	陈锋, 姬忠礼, 齐强强. 孔径梯度分布对亲油型滤材气液过滤性能的影响[J]. 化工学报, 2017, 68(4): 1442-1451.
	Chen F, Ji Z L, Qi Q Q. Influence of pore size distribution on gas-liquid filtration performance of oleophilic filters[J]. CIESC Journal, 2017, 68(4): 1442-1451.
9	黄益平, 张春尧, 耿洪鑫, 等. 聚丙烯中空纤维膜气体除尘性能[J]. 化工学报, 2016, 67(10): 4231-4239.
	Huang Y P, Zhang C Y, Geng H X, et al. Performance of polypropylene hollow fiber membrane module for dust removal[J]. CIESC Journal, 2016, 67(10): 4231-4239.
10	Li W, Shen S N, Li H. Study and optimization of the filtration performance of multi-fiber filter[J]. Advanced Powder Technology, 2016, 27(2): 638-645.
11	Liu G L, Xiao M X, Zhang X X, et al. A review of air filtration technologies for sustainable and healthy building ventilation[J]. Sustainable Cities and Society, 2017, 32: 375-396.
12	Xu B, Yu X, Wu Y, et al. Experimental investigation of air pressure affecting filtration performance of fibrous filter sheet[J]. Environmental Technology, 2017, 38(5): 558-565.
13	Tanabe E H, de Mello Innocentini M D, de Barros P M, et al. Analysis of the behavior of a metallic filter in particle removal under high pressure conditions[J]. Materials Science Forum, 2012, 727/728: 1648-1653.
14	Innocentini M D M, Tanabe E H, Aguiar M L, et al. Filtration of gases at high pressures: permeation behavior of fiber-based media used for natural gas cleaning[J]. Chemical Engineering Science, 2012, 74: 38-48.
15	Chang C, Ji Z L, Liu C B, et al. Permeability of filter cartridges used for natural gas filtration at high pressure[J]. Journal of Natural Gas Science and Engineering, 2016, 34: 419-427.
16	Azadi M, Mohebbi A, Scala F, et al. Experimental study of filtration system performance of natural gas in urban transmission and distribution network: a case study on the City of Kerman, Iran[J]. Fuel, 2011, 90(3): 1166-1171.
17	国家能源局. 输气管道工程过滤分离设备规范: [S]. 北京: 石油工业出版社, 2012.
	China National Energy Administration. Specification for filtration & separation equipment of gas transmission pipeline engineering: [S]. Beijing: Petroleum Industry Press, 2012.
18	Tian S R, Yang G H, Li Z, et al. Cascade filtration properties of a dual-layer granular bed filter[J]. Powder Technology, 2016, 301: 545-556.
19	Khoo W, Chung S, Lim S C, et al. Fracture behavior of multilayer fibrous scaffolds featuring microstructural gradients[J]. Materials & Design, 2019, 184: 108184.
20	Chauhan V K, Singh J P, Debnath S. Investigation on filtration properties of polyester needle-punched dust filter[J]. The Journal of the Textile Institute, 2020, 111(6): 897-905.
21	Mead-Hunter R, King A J C, Mullins B J. Aerosol-mist coalescing filters—a review[J]. Separation and Purification Technology, 2014, 133: 484-506.
22	Tang M, Chen S C, Chang D Q, et al. Filtration efficiency and loading characteristics of PM_2.5 through composite filter media consisting of commercial HVAC electret media and nanofiber layer[J]. Separation and Purification Technology, 2018, 198: 137-145.
23	Barone D, Loth E, Snyder P. Influence of particle size on inertial particle separator efficiency[J]. Powder Technology, 2017, 318: 177-185.
24	Hasolli N, Park Y O, Rhee Y W. Filtration performance evaluation of depth filter media cartridges as function of layer structure and pleat count[J]. Powder Technology, 2013, 237: 24-31.
25	Chen D R, Pui D Y H. Optimization of pleated filter designs[J]. Journal of Aerosol Science, 1996, 27(4): 654-655.
26	Gong J, Stewart M L, Zelenyuk A, et al. Importance of filter's microstructure in dynamic filtration modeling of gasoline particulate filters (GPFs): inhomogeneous porosity and pore size distribution[J]. Chemical Engineering Journal, 2018, 338: 15-26.
27	Yunok T, Matsumoto K, Nakamura K. Pore size distribution measurements of nonwoven fibrous filter by differential flow method[J]. Membrane, 2004, 29(4): 227-235.
28	Nakamura K, Suda T, Matsumoto K. Characterization of pore size distribution of non-woven fibrous filter by inscribed sphere within 3D filter model[J]. Separation and Purification Technology, 2018, 197: 289-294.
29	Hosseini S A, Tafreshi H V. Modeling particle-loaded single fiber efficiency and fiber drag using ANSYS-Fluent CFD code[J]. Computers & Fluids, 2012, 66: 157-166.
30	Dai H L, Huang Z W, Mei C, et al. Prediction of the tensile strength of hybrid polymer composites filled with spherical particles and short fibers[J]. Composite Structures, 2018, 187: 509-517.

[1]	He JIANG, Junfei YUAN, Lin WANG, Guyu XING. Experimental study on the effect of flow sharing cavity structure on phase change flow characteristics in microchannels [J]. CIESC Journal, 2023, 74(S1): 235-244.
[2]	Ruihang ZHANG, Pan CAO, Feng YANG, Kun LI, Peng XIAO, Chun DENG, Bei LIU, Changyu SUN, Guangjin CHEN. Analysis of key parameters affecting product purity of natural gas ethane recovery process via ZIF-8 nanofluid [J]. CIESC Journal, 2023, 74(8): 3386-3393.
[3]	Jinming GAO, Yujiao GUO, Chenglin E, Chunxi LU. Study on the separation characteristics of a downstream gas-liquid vortex separator in a closed hood [J]. CIESC Journal, 2023, 74(7): 2957-2966.
[4]	Xiaoyu JIA, Jian YANG, Bo WANG, Mei LIN, Qiuwang WANG. Pore scale numerical simulations for wicking performance of metallic woven mesh [J]. CIESC Journal, 2023, 74(5): 1928-1938.
[5]	Yongyao SUN, Qiuying GAO, Wenguang ZENG, Jiaming WANG, Yifei CHEN, Yongzhe ZHOU, Gaohong HE, Xuehua RUAN. Design and optimization of membrane-based integration process for advanced utilization of associated gases in N₂-EOR oilfields [J]. CIESC Journal, 2023, 74(5): 2034-2045.
[6]	Huizhu YANG, Jingling LAN, Yue YANG, Jialin LIANG, Chuanwen LYU, Yonggang ZHU. Experimental study on thermal performance of high power flat heat pipe [J]. CIESC Journal, 2023, 74(4): 1561-1569.
[7]	Yangguang LYU, Peipei ZUO, Zhengjin YANG, Tongwen XU. Triazine framework polymer membranes for methanol/n-hexane separation via organic solvent nanofiltration [J]. CIESC Journal, 2023, 74(4): 1598-1606.
[8]	Ruiheng WANG, Pinjing HE, Fan LYU, Hua ZHANG. Parameter comparison and optimization of three solid-liquid separation methods for washed air pollution control residues from municipal solid waste incinerators [J]. CIESC Journal, 2023, 74(4): 1712-1723.
[9]	Xiangning HU, Yuanbo YIN, Chen YUAN, Yun SHI, Cuiwei LIU, Qihui HU, Wen YANG, Yuxing LI. Experimental study on visualization of refined oil migration in soil [J]. CIESC Journal, 2023, 74(4): 1827-1835.
[10]	Xiaoxuan WANG, Xiaohong HU, Yunan LU, Shiyong WANG, Fengxian FAN. Numerical simulation of flow characteristics in a rotating membrane filter [J]. CIESC Journal, 2023, 74(4): 1489-1498.
[11]	Mingchuan LI, Shuanshi FAN, Fuhai XU, Huidong LU, Xiaojun LI. Existence and Laplace transform of the solution to Stefan phase change model in thermal dissociation hydrate [J]. CIESC Journal, 2023, 74(4): 1746-1754.
[12]	Zhiguang QIAN, Yue FAN, Shixue WANG, Like YUE, Jinshan WANG, Yu ZHU. Effect of purging conditions on the impedance relaxation phenomenon and low temperature start-up of PEMFC [J]. CIESC Journal, 2023, 74(3): 1286-1293.
[13]	Junxian CHEN, Zhongli JI, Yu ZHAO, Qian ZHANG, Yan ZHOU, Meng LIU, Zhen LIU. Study on online detection method of particulate matter in natural gas pipeline based on microwave technology [J]. CIESC Journal, 2023, 74(3): 1042-1053.
[14]	Jianzhao BAI, Zixuan GUO, Dewu WANG, Yan LIU, Ruojin WANG, Meng TANG, Shaofeng ZHANG. Effect of roll on pressure drop in concurrent gas-liquid columns with tridimensional rotational flow sieve tray [J]. CIESC Journal, 2023, 74(2): 707-720.
[15]	Jinlin MENG, Yu WANG, Qunfeng ZHANG, Guanghua YE, Xinggui ZHOU. Pore network model of low-temperature nitrogen adsorption-desorption in mesoporous materials [J]. CIESC Journal, 2023, 74(2): 893-903.