Preparation of porous <scp>PTFE</scp>/C composite foam and its application in gravity‐driven oil–water separation

Guo, Xiaoming; Yao, Yongyi; Zhu, Ping; Zhou, Mi; Zhou, Tao

doi:10.1002/pi.6356

Cited by 6 publications

(8 citation statements)

References 53 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Subsequently, LTISC sintering was performed to obtain a porous PTFE/C composite MEF. 48 The bubble pore created by mechanical stirring and the icetemplated pore generated by freeze-casting play the roles of the cavity of size R and the pore neck of size r, respectively. Here, the bubble pores serve as the cavities of the PTFE/C composite MEF, while the ice-templated pores function as equivalent membrane pores that interconnect all the cavities.…”

Section: Resultsmentioning

confidence: 99%

“…47 To address this limitation, a porous PTFE/carbon (PTFE/C) composite foam with a one-level microporous structure was prepared in our previous work. 48 Porous PTFE/C composite foam was derived from the PTFE/glutaraldehyde crosslinked polyvinyl formal (PVFG) composite foam green body via a method of low-temperature in situ carbonization (LTISC) and exhibited significant oil flux and purity, along with exceptional resistance and stability. Unfortunately, its larger pore size hindered its effectiveness in separating emulsified oil-water mixtures.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Design and preparation of polytetrafluoroethylene/carbon (PTFE/C) composite membrane‐equivalent foam for gravity‐driven emulsion separation

Guo,

Lan,

Wang

2023

Polymer International

Self Cite

View full text Add to dashboard Cite

Herein, a concept of the membrane‐equivalent‐foam (MEF) with equivalent characteristics of a separated‐multi‐layer membrane was proposed and elaborated to mitigate the conflict between efficiency and selectivity in emulsion separation. Porous PTFE/C composite MEF with a two‐level microporous structure (bubble pores and ice‐templated pores) was prepared successfully, which was derived from a PTFE/glutaraldehyde‐crosslinked‐polyvinyl alcohol (PVAG) composite foam green body. PVAG based in‐situ carbon was analyzed as composed mainly of amorphous carbon. The bubble pores were observed to be interconnected by ice‐templated pores. The porosity of the porous PTFE/C composite MEF reached a remarkable value of 73.35%. Corresponding to m(PTFE)/m(PVA) value of 14/1, 12/1, 10/1 and 8/1, the average pore sizes of the bubble pores were 32.99 μm, 44.31 μm, 47.33 μm, 48.01 μm, and the average sizes of ice‐templated pores were about 2.24 μm, 2.77 μm, 3.02 μm and 3.47 μm, respectively. Meanwhile, the porous PTFE/C composite MEF exhibited near superhydrophobicity in air and the superhydrophobicity under oil. In gravity‐driven W/O emulsion separation tests, the oil flux was up to 3541 L/(h∙m2), and the separation efficiency reached more than 99.52%. After 20 cycles of testing, the oil flux and separation efficiency remained stable. The membrane‐equivalent thickness of the samples from PTFE/C‐m1 to PTFE/C‐m4 were below 3.47 nm, 4.26 nm, 0.58 nm and 0.30 nm, respectively, which was about 10‐7~10‐6 times lower than the height of porous PTFE/C composite MEF. It is reasonable to believe that porous PTFE/C composite MEF could effectively mitigation of the “trade‐off” effect.This article is protected by copyright. All rights reserved.

show abstract

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Design and preparation of polytetrafluoroethylene/carbon (PTFE/C) composite membrane‐equivalent foam for gravity‐driven emulsion separation

Guo,

Lan,

Wang

2023

Polymer International

Self Cite

View full text Add to dashboard Cite

show abstract

“…The boiling point of water is 100 °C at 1 atm, and above this value the water evaporates and water loss occurs during extrusion. On the other hand, a high water content can lead to a loss of the most important properties of collagen, such as mechanical properties, osteoconductivity, and biodegradability [ 20 ]. In the present work, a water content of 73% and an extrusion temperature of 90 °C were found to be optimal for printing TC.…”

Section: Discussionmentioning

confidence: 99%

About 3D Printability of Thermoplastic Collagen for Biomedical Applications

et al. 2022

View full text Add to dashboard Cite

With more than 1.5 million total knee and hip implants placed each year, there is an urgent need for a drug delivery system that can effectively support the repair of bone infections. Scaffolds made of natural biopolymers are widely used for this purpose due to their biocompatibility, biodegradability, and suitable mechanical properties. However, the poor processability is a bottleneck, as highly customizable scaffolds are desired. The aim of the present research is to develop a scaffold made of thermoplastic collagen (TC) using 3D printing technology. The viscosity of the material was measured using a rheometer. A 3D bioplotter was used to fabricate the scaffolds out of TC. The mechanical properties of the TC scaffolds were performed using tension/compression testing on a Zwick/Roell universal testing machine. TC shows better compressibility with increasing temperature and a decrease in dynamic viscosity (η), storage modulus (G′), and loss modulus (G″). The compressive strength of the TC scaffolds was between 3–10 MPa, depending on the geometry (cylinder or cuboid, with different infills). We have demonstrated for the first time that TC can be used to fabricate porous scaffolds by 3D printing in various geometries.

show abstract

“…5,6 For hydrophobic waterproof and breathable membranes, the membrane materials are required to have a hydrophobic surface to provide water resistance, 7,8 a small interconnected pore structure, and high porosity inside the fibers to provide moisture permeability. 9,10 Generally speaking, PTFE waterproof and breathable membranes are widely used in the textile industry, 11−13 filtration media, 14,15 electronics, 16,17 electrical appliances, 18 and healthcare 19,20 due to their excellent chemical resistance, low surface energy, strong hydrophobicity, and thermal stability. 21−25 At present, the preparation methods of WBM mainly include melting extrusion, biaxial stretching, phase separation, flash evaporation, and electrostatic spinning (ES) methods.…”

Section: Introductionmentioning

confidence: 99%

“…Waterproof and breathable fabrics provide comfort and safety to textiles, which can effectively block the penetration of liquids, while quickly expelling evaporated sweat from the body, making them a promising smart textile . Currently, the most widely used WBM on the market are hydrophobic PTFE microporous membranes , and hydrophilic thermoplastic polyurethane (TPU) nonporous membranes. , For hydrophobic waterproof and breathable membranes, the membrane materials are required to have a hydrophobic surface to provide water resistance, , a small interconnected pore structure, and high porosity inside the fibers to provide moisture permeability. , Generally speaking, PTFE waterproof and breathable membranes are widely used in the textile industry, − filtration media, , electronics, , electrical appliances, and healthcare , due to their excellent chemical resistance, low surface energy, strong hydrophobicity, and thermal stability. − At present, the preparation methods of WBM mainly include melting extrusion, biaxial stretching, phase separation, flash evaporation, and electrostatic spinning (ES) methods. , Small pore size, high porosity, a high specific surface area, and customizable surface shape are characteristics of the fibrous membranes created by electrospinning. − While in the configuration of spinning solution of conventional electrospinning, significant amounts of tetrahydrofuran, formic acid, N , N -dimethylformamide (DMF), N , N -dimethylacetamide (DMAc), and other toxic solvents are consumed, , which will not only cause problems with air pollution and water pollution but also obstruct the large-scale production of WBM by electrospinning . The lingering hazardous chemicals can also damage organs and trigger skin allergies. , Therefore, it is crucial to design a green smart solvent WBM that is harmless to the environment. − …”

Section: Introductionmentioning

confidence: 99%

Amphiphobic, Thermostable, and Stretchable PTFE Nanofibrous Membranes with Breathable and Chemical-Resistant Performances for Protective Applications

Liu

et al. 2023

ACS Appl. Polym. Mater.

View full text Add to dashboard Cite

Waterproof and breathable membranes (WBM) have diverse applications in outdoor apparel, wearable electronics, and medical hygiene because they can withstand liquid water penetration while simultaneously transmitting water vapor. Nevertheless, developing potential nontoxic WBM based on ecologically friendly solvents remains a significant issue. Therefore, we prepared polytetrafluoroethylene (PTFE) waterproof and permeable membranes (PWBM) with a remarkable moisture transfer rate of 11.9 kg m −2 d −1 , a high hydrostatic pressure of 81.5 kPa, and an astonishing tensile strain of 554%, so the produced PWBM demonstrates great capabilities. Besides, the obtained PWBM also has outstanding chemical resistance and appealing superhydrophobicity. The development of the subsequent generation of environmentally friendly WBM for protective garments may be therefore beneficial to the successful fabrication of such green smart fibrous membranes.

show abstract

Preparation of porous PTFE/C composite foam and its application in gravity‐driven oil–water separation

Cited by 6 publications

References 53 publications

Design and preparation of polytetrafluoroethylene/carbon (PTFE/C) composite membrane‐equivalent foam for gravity‐driven emulsion separation

Design and preparation of polytetrafluoroethylene/carbon (PTFE/C) composite membrane‐equivalent foam for gravity‐driven emulsion separation

About 3D Printability of Thermoplastic Collagen for Biomedical Applications

Amphiphobic, Thermostable, and Stretchable PTFE Nanofibrous Membranes with Breathable and Chemical-Resistant Performances for Protective Applications

Contact Info

Product

Resources

About