PL232153B1 - Method for obtaining polymer membranes modified with titanate nanotubes - Google Patents

Description

The subject of the invention is a method of obtaining polymer membranes modified with titanate nanotubes. Membranes can be used in particular in ultrafiltration processes where the feed solution (feed) is in the form of a suspension, such as e.g. systems combining suspension photocatalysis with membrane separation.

Literature data show that commercially available polymer and ceramic membranes can be damaged as a result of abrasion of the separation layer by particles of the photocatalyst contained in the feed. This phenomenon depends mainly on the type of membrane, the size and shape of the photocatalyst particles and the composition of the feed (S. Mozia, D. Darowna, R. Wróbel, AW Morawski, J. Membrane Sci., 495 (2015) 176-186, D. Darowna, R. Wróbel, AW Morawski, S. Mozia, Chem. Eng. J., 2016 and S. Mozia, K. Szymański, B. Michalkiewicz, B. Tryba, M. Toyoda, AW Morawski, Sep. Purif. Technol., 142 (2015) 137-148).

The literature describes polymer membranes modified with nanoparticles in order to increase the blocking resistance. The modifications were used, among others, carbon nanotubes (E. Celik, H. Park, H. Choi, H. Choi, Water Res. 45 (2011) 274-282), silver nanoparticles (A. Ananth, G. Arthanareeswaran, AF Ismail, YS Mok, T. Maatsura, Colloid Surface A (2014) 451, 151-160), SiO2 (J. Huang,

K. Zhang, K. Wang, Z. Xie, B. Ladewig, H. Wang, J. Membrane Sci. (2012) 423-424, 363-370), Al2O3 (JC Mierzwa, V. Arieta, M. Verlage, J. Carvalho, CD Vecitis, Desalination (2013) 314, 147-158), halloysite nanotubes (H. Yu, Y. Zhang, X. Sun, J. Liu, H. Zhang, Chem. Eng. J. (2014) 237, 322-328), ZnO nanoparticles (H. Rajabi, N. Ghaemi, SS Madaeni, P. Daraei, B. Astinchap, S. Zinadini, SH Razavizadeh, Appl. Surf. Sci. (2015) 349, 66-77) et al.

Moreover, the literature on the subject describes the preparation of membranes modified with titanium nanotubes (i.e. with TiO2 structure) or with titanate nanotubes. Both types of nanotubes are usually marked with the acronym TNT. Such nanotubes have been used, among others, in for modification of polyethersulfone membranes dedicated to water desalination by vacuum membrane distillation (H. Abdallah, A.F. Moustafa, A.A. AlAnezi, H.E.M. El-Sayed, Desalination 346 (2014) 30-36). According to the method described, 5% by weight was first dissolved. % of tetramethylsiloxane in acetonitrile and 5 wt.% was added. titanium nanotubes. 10 wt.% Was dissolved separately. PES in N-methylpyrrolidone and then mixed with the solution containing TNT. The film-forming solution prepared in this way was poured onto a glass plate with the aid of an applicator and the whole was immersed in a water bath in distilled water. Also in the work of M. Shaban, H. AbdAllah,

L. Said, H. S. Hamdy, A. A. Khalek (Chem. Eng. Res. Des. 95 (2015) 307-316) describes the phase inversion method, but a mixture containing 10 wt.% Was used as the film-forming solution. PES, 0.5% sodium dodecyl sulfate and an appropriate amount of hydrothermal TNT in N-methylpyrrolidone. Whereas in the work of R. J. Gohari, W.J. Lau, E. Halakoo, A. F. Ismail, F. Korminouri, I Matsuura, M.S.J. Gohari, Md. N. K. Chowdhury, (New J. Chem. 39 (2015) 8263-8272) describes the preparation of PES membranes modified with titanate nanotubes for the removal of arsenic from water. First, the blowing agent polyvinylpyrrolidone was dissolved in N-methylpyrrolidone, and the hydrothermal TNT was added. This mixture was sonicated for 12 h and then PES in the form of granules was added thereto while maintaining the temperature at 60 ° C. The film-forming solution prepared in this way was again sonicated and then poured onto a glass plate with an applicator. It was left for 30 seconds in air to evaporate the solvent, then immersed in a bath of deionized water. TNT has also found application in the preparation of photocatalytic membranes (K. Fischer, R. Glaser, A. Schulze, Appl. Catal. B-Environ. (2014) 160-161, 456-464). This paper describes the production of nanotubes by anodizing the titanium layer previously applied to the membrane.

In addition to polyethersulfone, other polymers were also used: polyetherimide (A. Sumisha, G. Arthanareeswaran, AF Ismail, DP Kumarc, MV Shankarc, RSC Adv., 2015, 5, 39464-39473) polybenzimidazole and poly (2,6-dimethyl-1, 4-phenylene oxide) (V. Giel, B. Galajdova, D. Popelkova, J. Kredatusov, M. Trchova, E. Pavlova, H. Benes, R. Valek, J. Peter, Desalin. Water Treat. 56, 12 ( 2015) 3285-3293) polysulfone and chitosan (R. Kumar, AM Isloor, AF Ismail, SA Rashid, A. Al Ahmed, Desalination 316 (2013) 76-84) and others.

TNT modified membranes are also described in the patents: CN101717984 L. Zixia, X. Kefeng, X. Hua, Z. Haoli, Method for preparing titanium dioxide nanotube membrane describes the preparation of TNT modified membranes by electrolytic oxidation; CN104028121 W. Hong, X Quingping, J. Zhongyi, G. Yunying, L. Congdi, L. Tianyu, S. Yue, Sulfonated polyether ether ketone-amino-modified

PL 232 153 B1 titanium nanotube hybrid membrane and preparation and application thereof describes the production of membranes from amine-modified titanium nanotubes and sulfonated poly (ether ether ketone), while CN101684566 Z. Ge, Titanium dioxide nanometer membrane and preparation method thereof describes the preparation of membranes by anodic oxidation followed by electrochemical deposition of copper oxide.

However, there is no information in the literature on the use of polyethersulfone-based membranes in the ultrafiltration process, modified with titanate nanotubes and showing increased abrasion resistance.

The method of obtaining polymer membranes modified with titanate nanotubes, according to the invention, by the phase inversion method - wet variant, using polyethersulfone, characterized by the fact that 15% by mass of polyethersulfone is mixed with a solvent in the form of N, N-dimethylformamide and titanate nanotubes as a modifier in amounts from 0.5 to 2.0% by weight with respect to the polyethersulfone. Used nanotubes titanate obtained by hydrothermal an internal diameter in the range of 2.8 nm - 4.6 nm and 6.4 nm external - 9.1 nm, a specific surface area SBET = 370-390 m ² / g. When using the phase inversion method, distilled water is used as the non-solvent. Ultrasound is used to mix the titanate nanotubes with the solvent and polymer.

The advantage of the process according to the invention is that the risk of abrasion damage to the membrane by particles present in the feed (feed solution), e.g. TiO2 particles, is significantly reduced. The method according to the invention is explained in more detail in the working examples.

P r z k ł a d 1

A PES / TNT 0.5% membrane was obtained as follows. The membrane was prepared by the phase inversion method (wet variant) using polyethersulfone in the form of granules, N, N-dimethylformamide (DMF) as a polymer solvent, distilled water as a non-solvent and titanate nanotubes (TNT) as a modifier.

Titanate nanotubes were obtained by the hydrothermal method from Aeroxide® TiO2 P25 titanium dioxide based on the methodology provided in S. Mozia, E. Borowiak-Paleń, J. Przepiórski, B. Grzmil, T. Tsumura,

M. Toyoda, J. Grzechulska-Damszel, AW Morawski, J. Phys. Chem. Solids 71 (3) (2010) 263-272. According to this method, a teflon vessel was weighed 1.5 g of a solution of TiO 2 and 10 mol / ^dm3 NaOH, the mixture was sonicated, then placed in an autoclave for 24 hours at 130 ° C. After completion of the hydrothermal treatment, the obtained precipitate was washed with ultrapure water (18.2-cm at 25 ° C) and 0.1 mol / dm ³ HCl solution, and then it was dried at 80 ° C. The diameter of the inner and outer nanotubes was, respectively, 2.8 nm to 4.6 nm, and from 6.4 nm to 9.1 nm, and the SBET specific surface area = 370-390 m ² / g.

To prepare the film-forming solution, 42 mg of TNT and 50 cm ^{3 of the} solvent were introduced into a glass bottle. The solution was sonicated for 30 minutes to disperse the TNT in the solvent. Then 8.34 g of PES was added and a magnetic stir bar was introduced. The glass bottle was tightly closed. The polymer and the solvent were mixed for 24 h at room temperature on a magnetic stirrer. After this time, the mixture was sonicated again for 15 minutes and allowed to degass. The mixture prepared in this way was poured in the form of a 150 μm film with the use of an applicator on a glass plate. The solution was allowed to evaporate in air for about 10 seconds before being immersed in a water bath (distilled water) at 20 ± 2 ° C. Water acted as a non-solvent. The finished membrane was left for 24 hours in distilled water to rinse residual solvent.

To test the abrasion resistance of the membrane, an ultrafiltration installation equipped with a stainless steel membrane module, a piston pump and a feed tank was used. The pressure was regulated with a needle valve. The feed solution (feed) was directed to the membrane module, where it was divided into two streams: permeate and retentate. A transmembrane pressure AP = 3 bar and a feed temperature of 20 ± 1 ° C were used. Membrane sheet with an area of 25 cm ² was placed in a membrane module. The feed used was a suspension with a concentration of 0.5 g / dm ³ TiO2 Aeroxide® P25 (Evonik, Germany) in distilled water.

In order to estimate the abrasion resistance of TiO2 particles, the separation properties of the membrane were determined before and after the TiO2 process using model dextran solutions. Dextran concentration with molecular weights of 110,000 g / mol, 200,000 g / mol and 500,000 g / mol (Polfa Kutno, Poland)

The feed and permeate production was determined by high performance liquid chromatography. The degree of dextran retention was calculated using the relationship: R [%] = 1- (Cp / Cn) x100%, where cp and cn are the dextran concentration in the permeate and in the feed.

After 35 hours of running the process with TiO2, the retention rate of dextran 110,000 g / mol through the PES / TNT0.5% membrane decreased by 0.5%, dextran 200,000 g / mol by 1.5%, and dextran 500,000 g / mol. the mole has not changed. The abrasion resistance of the PES / TNT0.5% membrane was significantly higher than that of the membrane prepared according to the same method, but not containing titanate nanotubes (PES / TNT0%). Dextran 110,000 g / mol retention by the unmodified PES / TNT0% membrane decreased by 57%, dextran 200,000 g / mol by 40%, and dextran 500,000 g / mol by 26%.

P r z k ł a d 2

The UF plant was used as in Example 1. The PES / TNT1% membrane obtained as in Example 1 was placed in the membrane module, except that 84 mg of TNT was weighed into a glass bottle and 50 cm ^{3 of} solvent was added, and after 30 minutes of sonication, 8 was added, 29 g of PES.

After 35 hours of running the process with TiO2, the retention rate of dextran 110,000 g / mol through the PES / TNT1% membrane decreased by 4%, dextran 200,000 g / mol by 3%, and dextran 500,000 g / mol did not change. The abrasion resistance of the PES / TNT0.5% membrane was significantly higher than that of the membrane prepared according to the same method, but not containing titanate nanotubes (PES / TNT0%). Dextran 110,000 g / mol retention by the unmodified PES / TNT0% membrane decreased by 57%, dextran 200,000 g / mol by 40%, and dextran 500,000 g / mol by 26%.

P r z k ł a d 3

UF system used for as in Example 1. The membrane module provided membrane PES / TNT2% obtained as in the first example, except that the glass bottle was weighed 168 mg of TNT and 50 cm ³ of solvent, and after 30 minutes of sonication was added 8 22 g of PES.

After 35 hours of running the process with TiO2, the retention rate of dextran 110,000 g / mol through the PES / TNT1% membrane decreased by 8%, dextran 200,000 g / mol by 9%, and dextran 500,000 g / mol did not change. The abrasion resistance of the PES / TNT0.5% membrane was significantly higher than that of the membrane prepared according to the same method, but not containing titanate nanotubes (PES / TNT0%). Dextran 110,000 g / mol retention by the unmodified PES / TNT0% membrane decreased by 57%, dextran 200,000 g / mol by 40%, and dextran 500,000 g / mol by 26%.

Patent claims

Claims (4)

1. The method of obtaining polymer membranes modified with titanate nanotubes, by the phase inversion method - wet variant, using polyethersulfone, characterized in that 15% by mass of polyethersulfone is mixed with a solvent in the form of N, N-dimethylformamide and titanate nanotubes as a modifier in an amount from 0.5 to 2.0% by weight with respect to the polyethersulfone. 2. The method according to p. 1, characterized in that titanate nanotubes obtained by the hydrothermal method are used, with an internal diameter in the range of 2.8 nm - 4.6 nm, and an external diameter in the range of 6.4 nm - 9.1 nm, with a specific surface area of Sbet = 370-390 m ² / g. 3. The method according to p. A process as claimed in claim 1, characterized in that distilled water is used as the non-solvent in the phase inversion method. 4. The method according to p. The method of claim 1, wherein ultrasound is used to mix the titanate nanotubes with the solvent and polymer.