CIESC Journal ›› 2021, Vol. 72 ›› Issue (3): 1230-1241.DOI: 10.11949/0438-1157.20200855
• Reviews and monographs • Previous Articles Next Articles
TANG Heli1(),ZHANG Bing1(),HUANG Dongmei1,SHEN Yu1,2(),GAO Xu1,2,SHI Wenxin3
Received:
2020-06-30
Revised:
2020-09-21
Online:
2021-03-05
Published:
2021-03-05
Contact:
ZHANG Bing,SHEN Yu
唐和礼1(),张冰1(),黄冬梅1,申渝1,2(),高旭1,2,时文歆3
通讯作者:
张冰,申渝
作者简介:
唐和礼(1998—),男,硕士研究生,基金资助:
CLC Number:
TANG Heli, ZHANG Bing, HUANG Dongmei, SHEN Yu, GAO Xu, SHI Wenxin. Advances in membrane fouling analysis based on XDLVO theory[J]. CIESC Journal, 2021, 72(3): 1230-1241.
唐和礼, 张冰, 黄冬梅, 申渝, 高旭, 时文歆. XDLVO理论在膜污染解析中的应用研究[J]. 化工学报, 2021, 72(3): 1230-1241.
污染物-膜材料 | 前期阶段 | 后期阶段 | ||||||||
---|---|---|---|---|---|---|---|---|---|---|
ΔGLW/ (mJ·m-2) | ΔGAB/ (mJ·m-2) | ΔGEL/ (mJ·m-2) | ΔGTOT/ (mJ·m-2) | MFI×10-3 | ΔGLW/ (mJ·m-2) | ΔGAB/(mJ·m-2) | ΔGEL/(mJ·m-2) | ΔGTOT/(mJ·m-2) | MFI×10-3 | |
TiO2-PES | -5.79 | 24.52 | 0.21 | 18.94 | 3.58 | -11.45 | 25.16 | 0.24 | 13.95 | 1.78 |
(2 mg/L HA-TiO2)-PES | -5.81 | 23.75 | 0.21 | 18.15 | 8.23 | -11.52 | 24.31 | 0.25 | 13.04 | 3.48 |
(3 mg/L HA-TiO2)-PES | -5.70 | 22.35 | 0.17 | 16.82 | 11.7 | -11.10 | 21.76 | 0.30 | 10.96 | 3.67 |
(5 mg/L HA-TiO2)-PES | -5.62 | 22.06 | 0.03 | 16.47 | 20.7 | -10.80 | 21.20 | 0.39 | 10.79 | 4.91 |
(10 mg/L HA-TiO2)-PES | -5.61 | 20.13 | -0.02 | 14.50 | 27.6 | -10.75 | 17.32 | 0.41 | 6.98 | 5.86 |
MFI(×10-3)-ΔGTOT线性拟合 | y = -5.49x + 107.6, R2 = 0.93 | y = -0.53x + 9.8, R2 = 0.84 | ||||||||
TiO2-PVDF | -7.02 | -13.14 | 0.05 | 20.11 | 3.53 | -11.45 | 25.16 | 0.24 | 13.95 | 2.37 |
(2 mg/L HA-TiO2) -PVDF | -7.04 | -16.89 | 0.05 | -23.90 | 8.78 | -11.52 | 24.31 | 0.25 | 13.04 | 6.29 |
(3 mg/L HA-TiO2)-PVDF | -6.92 | -19.36 | 0.03 | -26.37 | 12.0 | -11.10 | 21.76 | 0.30 | 10.96 | 6.79 |
(5 mg/L HA-TiO2)-PVDF | -6.82 | -20.29 | -0.09 | -27.47 | 21.2 | -10.80 | 21.20 | 0.39 | 10.79 | 9.51 |
(10 mg/L HA-TiO2)-PVDF | -6.80 | -23.30 | -0.36 | -30.54 | 19.0 | -10.75 | 17.32 | 0.41 | 6.98 | 10.8 |
MFI×10-3 -ΔGTOT线性拟合 | y = 1.68x - 30.3, R2 = 0.82 | y = -1.07x + 19.1, R2 = 0.78 |
Table 1 Adhesion interfacial free energies in different phases of membrane filtration with HA-TiO2 and the correlativity of ΔGTOT and membrane fouling index[32]
污染物-膜材料 | 前期阶段 | 后期阶段 | ||||||||
---|---|---|---|---|---|---|---|---|---|---|
ΔGLW/ (mJ·m-2) | ΔGAB/ (mJ·m-2) | ΔGEL/ (mJ·m-2) | ΔGTOT/ (mJ·m-2) | MFI×10-3 | ΔGLW/ (mJ·m-2) | ΔGAB/(mJ·m-2) | ΔGEL/(mJ·m-2) | ΔGTOT/(mJ·m-2) | MFI×10-3 | |
TiO2-PES | -5.79 | 24.52 | 0.21 | 18.94 | 3.58 | -11.45 | 25.16 | 0.24 | 13.95 | 1.78 |
(2 mg/L HA-TiO2)-PES | -5.81 | 23.75 | 0.21 | 18.15 | 8.23 | -11.52 | 24.31 | 0.25 | 13.04 | 3.48 |
(3 mg/L HA-TiO2)-PES | -5.70 | 22.35 | 0.17 | 16.82 | 11.7 | -11.10 | 21.76 | 0.30 | 10.96 | 3.67 |
(5 mg/L HA-TiO2)-PES | -5.62 | 22.06 | 0.03 | 16.47 | 20.7 | -10.80 | 21.20 | 0.39 | 10.79 | 4.91 |
(10 mg/L HA-TiO2)-PES | -5.61 | 20.13 | -0.02 | 14.50 | 27.6 | -10.75 | 17.32 | 0.41 | 6.98 | 5.86 |
MFI(×10-3)-ΔGTOT线性拟合 | y = -5.49x + 107.6, R2 = 0.93 | y = -0.53x + 9.8, R2 = 0.84 | ||||||||
TiO2-PVDF | -7.02 | -13.14 | 0.05 | 20.11 | 3.53 | -11.45 | 25.16 | 0.24 | 13.95 | 2.37 |
(2 mg/L HA-TiO2) -PVDF | -7.04 | -16.89 | 0.05 | -23.90 | 8.78 | -11.52 | 24.31 | 0.25 | 13.04 | 6.29 |
(3 mg/L HA-TiO2)-PVDF | -6.92 | -19.36 | 0.03 | -26.37 | 12.0 | -11.10 | 21.76 | 0.30 | 10.96 | 6.79 |
(5 mg/L HA-TiO2)-PVDF | -6.82 | -20.29 | -0.09 | -27.47 | 21.2 | -10.80 | 21.20 | 0.39 | 10.79 | 9.51 |
(10 mg/L HA-TiO2)-PVDF | -6.80 | -23.30 | -0.36 | -30.54 | 19.0 | -10.75 | 17.32 | 0.41 | 6.98 | 10.8 |
MFI×10-3 -ΔGTOT线性拟合 | y = 1.68x - 30.3, R2 = 0.82 | y = -1.07x + 19.1, R2 = 0.78 |
污染物-膜材料 | 前期阶段 | 后期阶段 | 文献 | ||||||
---|---|---|---|---|---|---|---|---|---|
ΔGLW/(mJ·m-2) | ΔGAB/ (mJ·m-2) | ΔGEL/(mJ·m-2) | ΔGTOT/ (mJ·m-2) | ΔGLW/(mJ·m-2) | ΔGAB/ (mJ·m-2) | ΔGEL/(mJ·m-2) | ΔGTOT/ (mJ·m-2) | ||
polystyrene-Al2O3 | -3.45 | -32.54 | 1.16×10-6 | -35.99 | -6.56 | -80.82 | 2.55×10-6 | -87.38 | [ |
glass-Al2O3 | -2.16 | 5.55 | 6.27×10-7 | 23.39 | -2.58 | 44.37 | 8.72×10-6 | 41.78 | [ |
SiO2-PAN | -4.66 | -0.589 | 5.67×10-10 | -5.25 | -2.81 | 9.39 | 5.87×10-10 | 6.58 | [ |
TiO2-PES | -5.79 | 24.52 | 0.21 | 18.94 | -11.45 | 25.16 | 0.24 | 13.95 | [ |
TiO2-PVDF | -7.02 | -13.14 | 0.05 | 20.11 | -11.45 | 25.16 | 0.24 | 13.95 | [ |
SA-PVDF | 1.83 | -19.65 | -0.10 | -17.82 | -3.34 | 12.09 | 0.27 | 8.74 | [ |
SA-PES | -3.38 | 17.12 | -0.04 | 13.75 | -3.34 | 12.09 | 0.27 | 8.74 | [ |
BSA-PVDF | 2.03 | -9.31 | 0.08 | -7.21 | -4.13 | 17.60 | 0.09 | 13.56 | [ |
BSA-PES | -4.20 | 21.14 | -0.52 | 16.43 | -4.13 | 17.60 | 0.09 | 13.56 | [ |
HA-PVDF① | 33.17 | 620.21 | 49.47 | 702.85 | -27.35 | 1717.42 | 3.30 | 1693.37 | [ |
HA-PES① | -56.14 | 2512.99 | 101.38 | 2558.23 | -27.35 | 1717.42 | 3.30 | 1693.37 | [ |
(HA+BSA)-PES① | -31.62 | 221.98 | 51.71 | 241.78 | -20.37 | -162.22 | 5.70 | -176.85 | [ |
(SiO2-NOM)-PES① | -97.98 | -362.55 | 87.70 | -372.83 | -42.15 | -141.38 | 5.81 | -177.72 | [ |
污泥絮体-PVDF | -3.80 | -20.44 | 0.16 | -24.08 | -7.47 | -28.56 | 0.12 | -35.92 | [ |
HPO-混合纤维素 | -4.69 | -51.35 | -0.65 | -56.69 | -3.45 | -72.35 | 0.02 | -75.78 | [ |
TPI-混合纤维素 | -5.53 | -38.45 | -0.53 | 44.51 | -4.79 | -39.98 | 0.02 | -44.75 | [ |
C-HPI-混合纤维素 | -3.70 | 32.63 | -0.33 | 28.60 | -2.15 | 35.56 | 0.04 | 33.45 | [ |
N-HPI-混合纤维素 | -4.34 | -47.95 | -0.80 | -53.10 | -2.96 | -60.04 | 0.01 | -62.99 | [ |
酱油-PVDF(0.45②) | -7.64 | 15.72 | -4.83×10-6 | 8.07 | -5.70 | 25.27 | 4.72×10-10 | 19.87 | [ |
酱油-PES(0.45②) | -0.44 | -1.27 | -8.72×10-7 | -1.71 | -5.70 | 25.27 | 4.72×10-10 | 19.87 | [ |
Table 2 Adhesion interfacial free energies in different phases of membrane filtration with different foulants
污染物-膜材料 | 前期阶段 | 后期阶段 | 文献 | ||||||
---|---|---|---|---|---|---|---|---|---|
ΔGLW/(mJ·m-2) | ΔGAB/ (mJ·m-2) | ΔGEL/(mJ·m-2) | ΔGTOT/ (mJ·m-2) | ΔGLW/(mJ·m-2) | ΔGAB/ (mJ·m-2) | ΔGEL/(mJ·m-2) | ΔGTOT/ (mJ·m-2) | ||
polystyrene-Al2O3 | -3.45 | -32.54 | 1.16×10-6 | -35.99 | -6.56 | -80.82 | 2.55×10-6 | -87.38 | [ |
glass-Al2O3 | -2.16 | 5.55 | 6.27×10-7 | 23.39 | -2.58 | 44.37 | 8.72×10-6 | 41.78 | [ |
SiO2-PAN | -4.66 | -0.589 | 5.67×10-10 | -5.25 | -2.81 | 9.39 | 5.87×10-10 | 6.58 | [ |
TiO2-PES | -5.79 | 24.52 | 0.21 | 18.94 | -11.45 | 25.16 | 0.24 | 13.95 | [ |
TiO2-PVDF | -7.02 | -13.14 | 0.05 | 20.11 | -11.45 | 25.16 | 0.24 | 13.95 | [ |
SA-PVDF | 1.83 | -19.65 | -0.10 | -17.82 | -3.34 | 12.09 | 0.27 | 8.74 | [ |
SA-PES | -3.38 | 17.12 | -0.04 | 13.75 | -3.34 | 12.09 | 0.27 | 8.74 | [ |
BSA-PVDF | 2.03 | -9.31 | 0.08 | -7.21 | -4.13 | 17.60 | 0.09 | 13.56 | [ |
BSA-PES | -4.20 | 21.14 | -0.52 | 16.43 | -4.13 | 17.60 | 0.09 | 13.56 | [ |
HA-PVDF① | 33.17 | 620.21 | 49.47 | 702.85 | -27.35 | 1717.42 | 3.30 | 1693.37 | [ |
HA-PES① | -56.14 | 2512.99 | 101.38 | 2558.23 | -27.35 | 1717.42 | 3.30 | 1693.37 | [ |
(HA+BSA)-PES① | -31.62 | 221.98 | 51.71 | 241.78 | -20.37 | -162.22 | 5.70 | -176.85 | [ |
(SiO2-NOM)-PES① | -97.98 | -362.55 | 87.70 | -372.83 | -42.15 | -141.38 | 5.81 | -177.72 | [ |
污泥絮体-PVDF | -3.80 | -20.44 | 0.16 | -24.08 | -7.47 | -28.56 | 0.12 | -35.92 | [ |
HPO-混合纤维素 | -4.69 | -51.35 | -0.65 | -56.69 | -3.45 | -72.35 | 0.02 | -75.78 | [ |
TPI-混合纤维素 | -5.53 | -38.45 | -0.53 | 44.51 | -4.79 | -39.98 | 0.02 | -44.75 | [ |
C-HPI-混合纤维素 | -3.70 | 32.63 | -0.33 | 28.60 | -2.15 | 35.56 | 0.04 | 33.45 | [ |
N-HPI-混合纤维素 | -4.34 | -47.95 | -0.80 | -53.10 | -2.96 | -60.04 | 0.01 | -62.99 | [ |
酱油-PVDF(0.45②) | -7.64 | 15.72 | -4.83×10-6 | 8.07 | -5.70 | 25.27 | 4.72×10-10 | 19.87 | [ |
酱油-PES(0.45②) | -0.44 | -1.27 | -8.72×10-7 | -1.71 | -5.70 | 25.27 | 4.72×10-10 | 19.87 | [ |
膜材料名称 | γ- /(mJ·m–2) | ζ /mV | ΔG121 /(mJ·m-2) | 文献 | |||
---|---|---|---|---|---|---|---|
改性膜 | 基膜 | 改性膜 | 基膜 | 改性膜 | 基膜 | ||
PVDF/PES/PVA | 27.58 | 13.91 | -25.0 | -29.35 | 0.51 | -28.32 | [ |
PVDF-HEA | 30.13 | 10.48 | -30.83 | -20.95 | 5.24 | -36.92 | [ |
PES-PVP | 4.23 | 0.47 | — | — | -47.13 | -77.49 | [ |
PES-PVP-GO | 13.39 | 0.47 | — | — | -21.08 | -77.49 | [ |
PAN-PAMAM-ETA/NAOH | 52.70 | 7.67 | — | — | 22.55 | -6.14 | [ |
PVDF@ZnO (100 cycles) | 12.4 | 0.6 | -20.7 | -13.7 | — | — | [ |
PVDF@ZnO (200 cycles) | 46.3 | 0.6 | -27.8 | -13.7 | — | — | [ |
PA/Fe@PVDF-OH | 42.34 | 14.65 | -24.24 | -18.40 | — | — | [ |
PVDF@(TiO2/PSS)7 | 19.6 | 0.53 | -39.4 | -20.3 | — | — | [ |
PES-Ni@TiO2 | 44.188 | 7.098 | -35.74 | -33.8 | — | — | [ |
PANI-DBSA | 48.7 | 19.6 | -55.0 | -40.3 | — | — | [ |
PVDF-GO-Ni | 63.04 | 22.59 | -5.95 | -13.38 | — | — | [ |
Table 3 The key properties of modified membranes
膜材料名称 | γ- /(mJ·m–2) | ζ /mV | ΔG121 /(mJ·m-2) | 文献 | |||
---|---|---|---|---|---|---|---|
改性膜 | 基膜 | 改性膜 | 基膜 | 改性膜 | 基膜 | ||
PVDF/PES/PVA | 27.58 | 13.91 | -25.0 | -29.35 | 0.51 | -28.32 | [ |
PVDF-HEA | 30.13 | 10.48 | -30.83 | -20.95 | 5.24 | -36.92 | [ |
PES-PVP | 4.23 | 0.47 | — | — | -47.13 | -77.49 | [ |
PES-PVP-GO | 13.39 | 0.47 | — | — | -21.08 | -77.49 | [ |
PAN-PAMAM-ETA/NAOH | 52.70 | 7.67 | — | — | 22.55 | -6.14 | [ |
PVDF@ZnO (100 cycles) | 12.4 | 0.6 | -20.7 | -13.7 | — | — | [ |
PVDF@ZnO (200 cycles) | 46.3 | 0.6 | -27.8 | -13.7 | — | — | [ |
PA/Fe@PVDF-OH | 42.34 | 14.65 | -24.24 | -18.40 | — | — | [ |
PVDF@(TiO2/PSS)7 | 19.6 | 0.53 | -39.4 | -20.3 | — | — | [ |
PES-Ni@TiO2 | 44.188 | 7.098 | -35.74 | -33.8 | — | — | [ |
PANI-DBSA | 48.7 | 19.6 | -55.0 | -40.3 | — | — | [ |
PVDF-GO-Ni | 63.04 | 22.59 | -5.95 | -13.38 | — | — | [ |
1 | Drews A. Membrane fouling in membrane bioreactors—characterisation, contradictions, cause and cures[J]. Journal of Membrane Science, 2010, 363(1/2): 1-28. |
2 | 张海丰, 樊雪. 基于XDLVO理论解析MBR膜污染研究进展[J]. 化学通报, 2016, 79(7): 604-609. |
Zhang H F, Fan X. Research progress in membrane fouling in membrane bioreactor based on XDLVO approach[J]. Chemistry, 2016, 79(7): 604-609. | |
3 | 寇朝卫, 张干伟, 沈舒苏, 等. 基于XDLVO理论解析膜法水处理过程中膜污染问题的研究[J]. 膜科学与技术, 2017, 37(1): 8-15. |
Kou C W, Zhang G W, Shen S S, et al. Analysis and prediction of membrane fouling in water treatment based on the approach of the XDLVO theory[J]. Membrane Science and Technology, 2017, 37(1): 8-15. | |
4 | Hwang B K, Kim J H, Ahn C H, et al. Effect of disintegrated sludge recycling on membrane permeability in a membrane bioreactor combined with a turbulent jet flow ozone contactor[J]. Water Research, 2010, 44(6): 1833-1840. |
5 | Meng F G, Zhang S Q, Oh Y, et al. Fouling in membrane bioreactors: an updated review[J]. Water Research, 2017, 114: 151-180. |
6 | 印霞棐. 自生电场膜生物反应器中污染物去除及膜污染行为研究[D]. 无锡: 江南大学, 2019. |
Yin X F. Study on pollutants removal and membrane fouling behaviour in the spontaneous electric field membrane bioreactor[D]. Wuxi: Jiangnan University, 2019. | |
7 | 李宁. 基于原子层沉积的 PVDF 微滤膜表面亲水改性及膜污染控制机制[D]. 哈尔滨: 哈尔滨工业大学, 2019. |
Li N. Surface hydrophilic modification of PVDF micro-filtration membranes based on atomic layer deposition and mechanism of fouling control[D]. Harbin: Harbin Institute of Technology, 2019. | |
8 | Lin H J, Zhang M J, Wang F Y, et al. A critical review of extracellular polymeric substances (EPSs) in membrane bioreactors: characteristics, roles in membrane fouling and control strategies[J]. Journal of Membrane Science, 2014, 460: 110-125. |
9 | Sun M, Yan L L, Zhang L H, et al. New insights into the rapid formation of initial membrane fouling after in situ cleaning in a membrane bioreactor[J]. Process Biochemistry, 2019, 78: 108-113. |
10 | Lim A L, Bai R B. Membrane fouling and cleaning in microfiltration of activated sludge wastewater[J]. Journal of Membrane Science, 2003, 216(1/2): 279-290. |
11 | Meng F G, Chae S R, Drews A, et al. Recent advances in membrane bioreactors (MBRs): membrane fouling and membrane material[J]. Water Research, 2009, 43(6): 1489-1512. |
12 | Zhang B, Zhang R J, Huang D M, et al. Membrane fouling in microfiltration of alkali/surfactant/polymer flooding oilfield wastewater: effect of interactions of key foulants[J]. Journal of Colloid and Interface Science, 2020, 570: 20-30. |
13 | Guo H, Li Z H, Huang J, et al. Microfiltration of soy sauce: efficiency, resistance and fouling mechanism at different operating stages[J]. Separation and Purification Technology, 2020, 240: 116656. |
14 | Zhao L H, Qu X L, Zhang M J, et al. Influences of acid-base property of membrane on interfacial interactions related with membrane fouling in a membrane bioreactor based on thermodynamic assessment[J]. Bioresource Technology, 2016, 214: 355-362. |
15 | Hong H C, Zhang M J, He Y M, et al. Fouling mechanisms of gel layer in a submerged membrane bioreactor[J]. Bioresource Technology, 2014, 166: 295-302. |
16 | 刘晓倩. xDLVO理论定量解析混合有机物微滤膜污染机理[D]. 济南: 山东大学, 2017. |
Liu X Q. Quantitative analysis of membrane fouling mechanism involved in mixed organics microfiltration utilizing xDLVO theory[D]. Jinan: Shandong University, 2017. | |
17 | van Oss C J. Acid-base interfacial interactions in aqueous media[J]. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 1993, 78: 1-49. |
18 | 张媚佳. 膜生物反应器中膜污染的形成机理及其影响因素研究[D]. 金华: 浙江师范大学, 2015. |
Zhang M J. Study on membrane fouling mechanism and its influence factors in a membrane bioreactor[D]. Jinhua: Zhejiang Normal University, 2015. | |
19 | 申露文, 沈宗泽, 王一惠, 等. 膜污染层微生物与聚丙烯微滤膜间的界面作用及其吸附特征[J]. 环境科学学报, 2017, 37(7): 2561-2571. |
Shen L W, Shen Z Z, Wang Y H, et al. The adsorption characteristics of microorganisms isolated from biofouling layer of MBR and the interaction between the microorganisms and polypropylene microfiltration membrane[J]. Acta Scientiae Circumstantiae, 2017, 37(7): 2561-2571. | |
20 | 高欣玉, 纵瑞强, 王平, 等. xDLVO理论解析微滤膜海藻酸钠污染中pH影响机制[J]. 中国环境科学, 2014, 34(4): 958-965. |
Gao X Y, Zong R Q, Wang P, et al. The impact of pH on microfiltration membrane fouling by sodium alginate: mechanism analysis using xDLVO theory[J]. China Environmental Science, 2014, 34(4): 958-965. | |
21 | 屈晓璐. 任意粗糙膜表面的构建及其与膜污染界面作用力的关系研究[D]. 金华: 浙江师范大学, 2018. |
Qu X L. Construction of random rough membrane surface and its relationship with interfacial interactions in membrane fouling[D]. Jinhua: Zhejiang Normal University, 2018. | |
22 | 张楠. 超滤膜界面特性与蛋白质和腐殖酸膜污染行为的相关性研究[D]. 西安: 西安建筑科技大学, 2014. |
Zhang N. The correlation research of UF membranes interface properties and BSA, HA membrane fouling behavior[D]. Xi'an: Xi'an University of Architecture and Technology, 2014. | |
23 | Zhao L H, Wang F Y, Weng X X, et al. Novel indicators for thermodynamic prediction of interfacial interactions related with adhesive fouling in a membrane bioreactor[J]. Journal of Colloid and Interface Science, 2017, 487: 320-329. |
24 | Derjaguin V B. Theorie des Anhaftens kleiner Teilchen[J]. Progress in Surface Science, 1992, 40(1/2/3/4): 6-15. |
25 | Wu H H, Shen F, Wang J F, et al. Membrane fouling in vacuum membrane distillation for ionic liquid recycling: interaction energy analysis with the XDLVO approach[J]. Journal of Membrane Science, 2018, 550: 436-447. |
26 | Zamani F, Ullah A, Akhondi E, et al. Impact of the surface energy of particulate foulants on membrane fouling[J]. Journal of Membrane Science, 2016, 510: 101-111. |
27 | Yin Z Q, Ma Y Q, Tanis-Kanbur B, et al. Fouling behavior of colloidal particles in organic solvent ultrafiltration[J]. Journal of Membrane Science, 2020, 599: 117836. |
28 | 王平. xDLVO理论解析溶解性微生物产物微滤膜污染机制[D]. 济南: 山东大学, 2012. |
Wang P. Analysis of microfiltration membrane fouling by soluble microbial products using xDLVO theory[D]. Jinan: Shandong University, 2012. | |
29 | 高欣玉. 腐殖酸微滤膜污染中界面作用力的定量解析及系统阐释[D]. 济南: 山东大学, 2014. |
Gao X Y. Quantitative analysis and systematic elucidation of the interfacial interactions involved in microfiltration membrane fouling by humic acid[D]. Jinan: Shandong University, 2014. | |
30 | 赵应许. xDLVO理论解析不同溶液条件下多糖微滤膜污染行为[D]. 济南: 山东大学, 2014. |
Zhao Y X. Fouling behavior of polyssachride during microfiltration at various solution conditions: xDLVO approach[D]. Jinan: Shandong University, 2014. | |
31 | 周鸣天, 张干伟, 寇朝卫, 等. XDLVO理论分析混合有机污染物的膜污染[J]. 水处理技术, 2020, 46(4): 73-77, 96. |
Zhou M T, Zhang G W, Kou C W, et al. XDLVO theory analysis of membrane fouling by mixture organic pollutants[J]. Technology of Water Treatment, 2020, 46(4): 73-77, 96. | |
32 | 田琳. xDLVO理论解析天然有机物存在下纳米颗粒膜污染行为[D]. 济南: 山东大学, 2017. |
Tian L. Assessment of the membrane fouling by nanoparticles in the presence of NOM using xDLVO theory[D]. Jinan: Shandong University, 2017. | |
33 | 孙春意. xDLVO理论定量解析纳米SiO2和天然有机物超滤膜污染机理[D]. 济南: 山东大学, 2018. |
Sun C Y. Quantitative analysis of membrane fouling mechanisms involved in ultrafiltration of nano-SiO2 and natural organic using xDLVO theory[D]. Jinan: Shandong University, 2018. | |
34 | 彭伟. 基于XDLVO理论对膜生物反应器中膜污染微观界面作用机制的研究[D]. 金华: 浙江师范大学, 2014. |
Peng W. Study on interfacial interaction mechanisms of membrane fouling in a membrane bioreactor based on XDLVO theory[D]. Jinhua: Zhejiang Normal University, 2014. | |
35 | Cai H H, Fan H, Zhao L H, et al. Effects of surface charge on interfacial interactions related to membrane fouling in a submerged membrane bioreactor based on thermodynamic analysis[J]. Journal of Colloid and Interface Science, 2016, 465: 33-41. |
36 | Lei Q, Li F Q, Shen L G, et al. Tuning anti-adhesion ability of membrane for a membrane bioreactor by thermodynamic analysis[J]. Bioresource Technology, 2016, 216: 691-698. |
37 | 范浩. 表面性质对膜生物反应器中膜污染影响及膜污染控制研究[D]. 金华: 浙江师范大学, 2016. |
Fan H. Study on effects of surface properties on membrane fouling and the control of membrane fouling[D]. Jinhua: Zhejiang Normal University, 2016. | |
38 | Shen L G, Lei Q, Chen J R, et al. Membrane fouling in a submerged membrane bioreactor: impacts of floc size[J]. Chemical Engineering Journal, 2015, 269: 328-334. |
39 | Zhao L H, Shen L G, He Y M, et al. Influence of membrane surface roughness on interfacial interactions with sludge flocs in a submerged membrane bioreactor[J]. Journal of Colloid and Interface Science, 2015, 446: 84-90. |
40 | Hong H C, Peng W, Zhang M J, et al. Thermodynamic analysis of membrane fouling in a submerged membrane bioreactor and its implications[J]. Bioresource Technology, 2013, 146: 7-14. |
41 | Huang W W, Chu H Q, Dong B Z. Understanding the fouling of algogenic organic matter in microfiltration using membrane-foulant interaction energy analysis: effects of organic hydrophobicity[J]. Colloids and Surfaces B: Biointerfaces, 2014, 122: 447-456. |
42 | Huang W W, Chu H Q, Dong B Z, et al. Evaluation of different algogenic organic matters on the fouling of microfiltration membranes[J]. Desalination, 2014, 344: 329-338. |
43 | Xu K W, Li Y P, Zou X T, et al. Investigating microalgae cell-microsphere interactions during microalgae harvesting by ballasted dissolved air flotation through XDLVO theory[J]. Biochemical Engineering Journal, 2018, 137: 294-304. |
44 | Lu D W, Jia B H, Xu S, et al. Role of pre-coagulation in ultralow pressure membrane system for microcystis aeruginosa-laden water treatment: membrane fouling potential and mechanism[J]. Science of the Total Environment, 2020, 710: 136340. |
45 | Feng L, Li X, Song P, et al. Surface interactions and fouling properties of micrococcus luteus with microfiltration membranes[J]. Applied Biochemistry and Biotechnology, 2011, 165(5/6): 1235-1244. |
46 | Zhang X R, Wang Z W, Chen M, et al. Polyvinylidene fluoride membrane blended with quaternary ammonium compound for enhancing anti-biofouling properties: effects of dosage[J]. Journal of Membrane Science, 2016, 520: 66-75. |
47 | Gentile G J, Cruz M C, Rajal V B, et al. Electrostatic interactions in virus removal by ultrafiltration membranes[J]. Journal of Environmental Chemical Engineering, 2018, 6(1): 1314-1321. |
48 | 赵飞, 许柯, 任洪强, 等. XDLVO理论解析有机物和钙离子对纳滤膜生物污染的影响[J]. 中国环境科学, 2015, 35(12): 3602-3611. |
Zhao F, Xu K, Ren H Q, et al. Impact of organic matter and calcium on nanofiltration membrane biofouling: XDLVO approach[J]. China Environmental Science, 2015, 35(12): 3602-3611. | |
49 | Kühnl W, Piry A, Kaufmann V, et al. Impact of colloidal interactions on the flux in cross-flow microfiltration of milk at different pH values: a surface energy approach[J]. Journal of Membrane Science, 2010, 352(1/2): 107-115. |
50 | Zhang M J, Chen J R, Ma Y J, et al. Fractal reconstruction of rough membrane surface related with membrane fouling in a membrane bioreactor[J]. Bioresource Technology, 2016, 216: 817-823. |
51 | Feng S S, Yu G Y, Cai X, et al. Effects of fractal roughness of membrane surfaces on interfacial interactions associated with membrane fouling in a membrane bioreactor[J]. Bioresource Technology, 2017, 244: 560-568. |
52 | Cai X, Shen L G, Zhang M J, et al. Membrane fouling in a submerged membrane bioreactor: an unified approach to construct topography and to evaluate interaction energy between two randomly rough surfaces[J]. Bioresource Technology, 2017, 243: 1121-1132. |
53 | Cai X, Yang L N, Wang Z W, et al. Influences of fractal dimension of membrane surface on interfacial interactions related to membrane fouling in a membrane bioreactor[J]. Journal of Colloid and Interface Science, 2017, 500: 79-87. |
54 | Mei R W, Li R J, Lin H J, et al. A new approach to construct three-dimensional surface morphology of sludge flocs in a membrane bioreactor[J]. Bioresource Technology, 2016, 219: 521-526. |
55 | 方乘, 杨盛, 吴云, 等. 絮体表面形态对膜污染预测的影响[J]. 化工学报, 2020, 71(2): 715-723. |
Fang C, Yang S, Wu Y, et al. Effect of floc surface morphology on membrane pollution prediction[J]. CIESC Journal, 2020, 71(2): 715-723. | |
56 | Shen L G, Cui X, Yu G Y, et al. Thermodynamic assessment of adsorptive fouling with the membranes modified via layer-by-layer self-assembly technique[J]. Journal of Colloid and Interface Science, 2017, 494: 194-203. |
57 | Li N, Zhang J, Tian Y, et al. Anti-fouling potential evaluation of PVDF membranes modified with ZnO against polysaccharide[J]. Chemical Engineering Journal, 2016, 304: 165-174. |
58 | 杜锦滢. ZnS/GO改性PVDF膜的制备及其对水中腐殖酸处理性能研究[D]. 哈尔滨: 哈尔滨工业大学, 2018. |
Du J Y. Research on the treatment performance of humic acid in water by the prepared ZnS/GO modified PVDF membrane[D]. Harbin: Harbin Institute of Technology, 2018. | |
59 | 赵传起. 氧化石墨烯改性PVDF微孔膜的制备及其在MBR中的性能研究[D]. 大连: 大连理工大学, 2015. |
Zhao C Q. Study on preparation and antifouling properties of graphene oxide nanosheets modified PVDF membranes in MBRs[D]. Dalian: Dalian University of Technology, 2015. | |
60 | 周贤娇, 董秉直. 不同组分的有机物对膜过滤通量下降的影响[J]. 环境科学, 2009, 30(2): 432-438. |
Zhou X J, Dong B Z. Effect of different organic fraction on membrane flux declines[J]. Environmental Science, 2009, 30(2): 432-438. | |
61 | Zhang J, Wang Q Y, Wang Z W, et al. Modification of poly(vinylidene fluoride)/polyethersulfone blend membrane with polyvinyl alcohol for improving antifouling ability[J]. Journal of Membrane Science, 2014, 466: 293-301. |
62 | Song D, Zhang W J, Cheng W, et al. Micro fine particles deposition on gravity-driven ultrafiltration membrane to modify the surface properties and biofilm compositions: water quality improvement and biofouling mitigation[J]. Chemical Engineering Journal, 2020, 393: 123270. |
63 | Li R J, Wang X N, Cai X, et al. A facile strategy to prepare superhydrophilic polyvinylidene fluoride (PVDF) based membranes and the thermodynamic mechanisms underlying the improved performance[J]. Separation and Purification Technology, 2018, 197: 271-280. |
64 | Shen L G, Wang H Z, Zhang Y C, et al. New strategy of grafting hydroxyethyl acrylate (HEA) via γ ray radiation to modify polyvinylidene fluoride (PVDF) membrane: thermodynamic mechanisms of the improved antifouling performance[J]. Separation and Purification Technology, 2018, 207: 83-91. |
65 | Chen L, Tian Y, Cao C Q, et al. Interaction energy evaluation of soluble microbial products (SMP) on different membrane surfaces: role of the reconstructed membrane topology[J]. Water Research, 2012, 46(8): 2693-2704. |
66 | Choo K H, Lee C H. Effect of anaerobic digestion broth composition on membrane permeability[J]. Water Science and Technology, 1996, 34(9): 173-179. |
67 | Zhang M J, Liao B Q, Zhou X L, et al. Effects of hydrophilicity/hydrophobicity of membrane on membrane fouling in a submerged membrane bioreactor[J]. Bioresource Technology, 2015, 175: 59-67. |
68 | Zhao Y Q, Yu W M, Li R J, et al. Electric field endowing the conductive polyvinylidene fluoride (PVDF)-graphene oxide (GO)-nickel (Ni) membrane with high-efficient performance for dye wastewater treatment[J]. Applied Surface Science, 2019, 483: 1006-1016. |
69 | Karkooti A, Rastgar M, Nazemifard N, et al. Study on antifouling behaviors of GO modified nanocomposite membranes through QCM-D and surface energetics analysis[J]. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2020, 588: 124332. |
70 | Jiang L Y, Yun J H, Wang Y X, et al. High-flux, anti-fouling dendrimer grafted PAN membrane: fabrication, performance and mechanisms[J]. Journal of Membrane Science, 2020, 596: 117743. |
71 | Luo J, Chen W W, Song H W, et al. Fabrication of hierarchical layer-by-layer membrane as the photocatalytic degradation of foulants and effective mitigation of membrane fouling for wastewater treatment[J]. Science of the Total Environment, 2020, 699: 134398. |
72 | Sun T, Liu Y, Shen L G, et al. Magnetic field assisted arrangement of photocatalytic TiO2 particles on membrane surface to enhance membrane antifouling performance for water treatment[J]. Journal of Colloid and Interface Science, 2020, 570: 273-285. |
73 | Wang K P, Xu L L, Li K L, et al. Development of polyaniline conductive membrane for electrically enhanced membrane fouling mitigation[J]. Journal of Membrane Science, 2019, 570/571: 371-379. |
74 | Li N, Tian Y, Zhao J H, et al. Anti-irreversible fouling of precisely-designed PVDF-ZnO membrane: effects of ion strength and co-existing cations[J]. Applied Surface Science, 2018, 459: 397-405. |
75 | Zhao F C, Chu H Q, Su Y M, et al. Microalgae harvesting by an axial vibration membrane: the mechanism of mitigating membrane fouling[J]. Journal of Membrane Science, 2016, 508: 127-135. |
76 | Zhao F C, Li Z X, Zhou X L, et al. The comparison between vibration and aeration on the membrane performance in algae harvesting[J]. Journal of Membrane Science, 2019, 592: 117390. |
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