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Industry growth in the field of coil coatings has been impressive as several of the articles abstracted below attest. The advantages inherent in coil coatings from the points of view of economy, adaptability to automation, and adaptability of the final product to fabrication are impressive ones that industry is taking full advantage of. There are, to be sure, some problems associated with the use of precoated steel, such as destruction of the coating during weldability, but techniques have been devised, including mechanical fastening, to circumvent such problems.

International Paint Protective Coatings supplied anti‐corrosion paints for the structural steelwork of the Meadowhall Centre in South Yorkshire, winner of a 1991 European Steel Design Award from the European Convention of Structural Steelwork. The European Design Awards competition is held every two years and Awards are only presented to projects of outstanding merit.

At the risk of possibly boring some of our readers, we would again like to draw attention to the possible dangers — still not completely proven — of working with lead chromate based pigments. Our latest source of information is a recent report issued by the British Colour Makers' Association.

Self-cleaning surfaces have received a great deal of attention recently, both in theoretical studies and commercial applications. Lotus flowers are a symbol of purity in Asian cultures; even though they grow in muddy waters, they remain clean and uncontaminated. The “self-cleaning” surface of their leaves is hydrophobic and rough, showing a micro- and nano-scale morphology. The micro-reliefs of lotus leaves are mimicked by using polyvinylidene fluoride (PVDF) film and the nano-scale peaks on top of the micro-reliefs are implemented by a reaction between CH₃SiCl₃ and the reactive groups of the PVDF film treated by oxygen plasma. A lotus leaf-like surface of the PVDF film is clearly observed by scanning electron microscopy (SEM) and atomic force microscopy (AFM). Elemental composition analysis by x-ray photoelectron spectroscopy (XPS) reveals that the material of the nanostructure of the PVDF film is polymethylsiloxane. The superhydrophobic property of the mimicked self-cleaning surface is validated by the water contact and sliding angles on the lotus leaf-like PVDF film, which are 165°and 4°, respectively. In this case, water drops can easily move off the PVDF surface, carrying dust away and leaving a clean surface

The purpose of this is to study the effects of organic sealing on the structure and performance of the micro-arc oxidation (MAO) film of 7075 aluminum alloy.

The 7075 aluminum alloy was treated by micro-arc oxidation technology, then the MAO films were sealed by polyvinylidene fluoride (PVDF) solutions with different concentrations to forms a MAO/PVDF composite coating on the surface of the 7075 aluminum alloy matrix.

The results show that the MAO/PVDF film thickness increased to 24.8 um. When the PVDF concentration was 8 g/L, and the sealed film reached best corrosion resistance and wear resistance.

The effects of different concentrations of PVDF on microarc oxidation properties of 7075 aluminum alloy were studied.

This study aims to investigate the morphology and physicochemical properties of BiOBr/Polyvinylidene fluoride (PVDF) composite membranes and the differences in the properties of BiOBr/PVDF composite membranes made by adding different precursor ratios during the casting process.

In this paper, sodium bromide and Bi(NO3)3 were used as precursors for the preparation of BiOBr photocatalysts, and PVDF membranes were modified by using the phase conversion method in conjunction with the in situ deposition method to produce BiOBr/PVDF hydrophilic composite membranes with both membrane separation and photocatalytic capabilities.

The characterization results confirmed that the composites were successfully and homogeneously co-mingled in the PVDF membranes. The related performance of the composite membrane was tested, and it was found that the composite membrane with the optimal precursor incorporation ratio had good photocatalytic efficiency and antipollution ability; the removal efficiencies of methyl orange, rhodamine B and methylene blue were 80.43%, 85.02% and 86.94%, respectively, in 2.5 h. The photocatalytic efficiency of composite membranes with different precursor ratios increased and then decreased with the increase of the precursor addition ratio.

The composite membrane is prepared by phase conversion method with in situ deposition method, and the BiOBr material has unique advantages for the degradation of organic dyes. The comprehensive experimental data can be known that the composite membrane prepared in this paper has high degradation efficiency and good durability for organic dyes.

A novel grafted temperature-responsive ReO₄⁻ Imprinted composite membranes (Re-ICMs) was successfully prepared by using polyvinylidene fluoride (PVDF) resin membranes as substrates, this study aimed to separate and purify ReO effectively.

Re-ICMs were synthesized by PVDF resin membranes as the substrate, acrylic acid (AA), acrylamide (AM), ethylene glycol dimethacrylate (EGDMA) were functional monomers. The morphology and structure of Re-ICMs were characterized by scanning electron microscope and Fourier transform infrared spectroscopy.

The maximum adsorption capacity toward ReO₄⁻ was 0.1,163 mmol/g and the separation decree had relation to MnO₄⁻ was 19.3. The optimal operation conditions were studied detailedly and the results as follows: the molar ratios of AA, AM, EGDMA, ascorbic acid, NH4ReO₄, were 0.8, 0.96, 0.02, 0.003 and 0.006. The optimal time and temperature were 20 h and 40°C, respectively. The Langmuir and pseudo-second-order models were fit these adsorption characteristics well.

Rhenium (Re) is mainly used to chemical petroleum and make superalloys for jet engine parts. This study was representing a technology in separate and purify of Re, which provided a method for the development of the petroleum and aviation industry.

This contribution provided a novel method to separate ReO₄⁻ from MnO₄⁻. The maximum adsorption capacity was 0.1163 mmol/g at 35°C and the adsorption equilibrium time was within 2 h. Meanwhile, the adsorption selectivity rate ReO₄⁻/MnO₄⁻ was 19.3 and the desorption rate was 78.3%. Controlling the adsorption experiment at 35°C and desorption experiment at 25°C in aqueous solution, it could remain 61.3% of the initial adsorption capacity with the adsorption selectivity rate of 13.3 by 10 adsorption/desorption cycles, a slight decrease, varied from 78.3% to 65.3%, in desorption rate was observed.

This study aims to investigate the material extrusion additive manufacturing (MEAM) deposition parameters for creating viable 3-D printed polyvinylidene fluoride (PVDF) structures with a balanced mix of mechanical and electrical properties.

Different combinations of deposition conditions are tested, and the influence of these parameters on the final dimensional accuracy, semi-crystalline phase microstructure and effective mechanical strength of MEAM homopolymer PVDF printed parts is experimentally assessed. Considering printed part integrity, appearance, print time and dimensional accuracy, MEAM parameters for PVDF are suggested.

A range of viable printing parameters for MEAM fabricated PVDF Kynar 740 objects of different heights and in-plane length dimensions was determined. For PVDF structures printed under the suggested conditions, the mechanical response and the microstructure development related to Piezoelectric response are reported.

This research first reports on a range of parameters that have been confirmed to facilitate effective MEAM printing of 3-D PVDF objects, presents effects of the individual parameters and gives the mechanical and microstructure properties of PVDF structures fabricated under the suggested deposition conditions.

This paper describes design, theoretical, and experimental analysis of a polyvinylidene fluoride (PVDF) tactile sensor, which could be integrated with an endoscopic grasper. The sensor exhibited high force sensitivity and linearity. Finite element analysis was employed to study the structural analysis of the tactile sensor with various load application and the results of this modelling are presented as the shear stress distribution and deformation contours. A comparison was made between the theoretical modeling and the experimental results.