Reorganization of the surface geometry of hollow-fiber membranes using dip-coating and vapor-induced phase separation

• Published in: Journal of membrane science Vol. 460; pp. 229 - 240
• Main Authors: Hao, Yan, Sano, Rie, Shimomura, Ayane, Matsuyama, Hideto, Maruyama, Tatsuo
• Format: Journal Article
• Language: English
• Published: Amsterdam Elsevier B.V 01.06.2014; Elsevier
• Subjects: Applied sciences; Chemistry; Colloidal state and disperse state; Dip coatings; Dip-coating; Exact sciences and technology; Exchange resins and membranes; Filtration; Forms of application and semi-finished materials; Fouling; General and physical chemistry; Membrane structures; Membranes; Phase separation; Polymer industry, paints, wood; Polyvinylidene fluorides; Proteins; Surface geometry; Technology of polymers; Vapor-induced phase separation (VIPS); Fouling; Dip-coating; Vapor-induced phase separation (VIPS); Surface geometry; Polymeric membrane; Vapor phase; Phase separation; Vinylidene fluoride polymer; Hollow fiber; Dip coating
• ISSN: 0376-7388; 1873-3123
• DOI: 10.1016/j.memsci.2014.02.039

Phase separation is one of the major methods to prepare a hollow-fiber membrane in industry. Despite the strong demands for the control of the inner membrane structure and surface geometry, it is still difficult to obtain the desired membrane structure and surface geometry simply by phase separation. In this work, we employed thermally induced phase separation, dip-coating and vapor-induced phase separation to prepare a hollow-fiber membrane with the controlled surface geometry and homogeneous inner structure, which led to high water permeability and high mechanical strength. First a poly(vinylidene fluoride) (PVDF) hollow-fiber membrane was prepared via thermally induced phase separation (TIPS) and then the outer surface of a membrane was dip-coated with another PVDF solution, followed by vapor induced phase separation (VIPS) to reorganize the outer surface of the membrane. The dip-coating and the VIPS treatment produced a highly porous mesh-like layer on the membrane surface. Filtration experiments using nanospheres and protein solutions revealed that the newly-formed layer served as a “separation layer” to determine the separation properties. The membrane pore-size was controlled to some extent by the conditions for the dip-coating and the VIPS treatment. The surface-reorganized membrane kept its intrinsic high water permeability and mechanical strength. In addition, the membrane exhibited improved low-fouling properties in the filtration of humic acid and protein solutions. •We reorganized the surface of a hollow-fiber membrane using dip-coating and VIPS.•A highly porous mesh-like layer was prepared on a membrane.•The pore-size of the surface-reorganized membrane can be controlled.•The surface-reorganized membrane exhibited improved low-fouling properties.