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11 results on '"Coating temperature"'

2. Influence of Coating Temperature on Online Preparation and Tensile Properties of Zn Coated Silica Fiber.

Author

ZHAO Jinkai, WANG Hong, JIA Jinsheng, SUN Yong, KONG Zhuang, and LIU Bo

Subjects
MECHANICAL drawing, SILICA fibers, IMAGE processing software, SURFACE coatings, LIQUID metals, SCANNING electron microscopy
Abstract

In this paper, Zn coated silica fiber was prepared online by molten metal method, and the influence of coating temperature on the surface quality and mechanical properties of Zn coated silica fiber was explored. The coating coverage rate was calculated using image processing software. The coating thickness, grain size, and roughness were measured using scanning electron microscopy, polarizing microscopy, and laser confocal microscopy, respectively. It is found that as the coating temperature increases, the coating coverage rate and coating thickness decrease, the solidification time of coating is prolonged, the grain size increases, and the roughness of coating gradually increases. The breaking force was measured by tensile testing machine. The maximum breaking force of Zn coated silica fiber increases by 139% compared with bare fiber. [ABSTRACT FROM AUTHOR]

Published
2023

3. Toward Efficient Cold Spraying of Inconel 718: Understanding the Influence of Coating and Particle Impact Temperatures.

Author

Ortiz-Fernandez, Roberto and Jodoin, Bertrand

Subjects
*INCONEL, *SPRAYING, *INDUCTION heating, *COATING processes, *TEMPERATURE control, *SURFACE coatings, *METAL spraying
Abstract

The production of Inconel 718 coatings using the cold spray process is often challenging due to the limited plastic deformation of particles upon impact associated with its mechanical properties. This leads to the requirement of high spray parameters to achieve dense coating build-up that may result in high and complex residual stresses that can also affect negatively the substrate and lead to nozzle clogging. In this work, the role of the coating and particle impact temperatures is investigated while ensuring they are decoupled from the particle impact velocity. This allows starting to explore potential ways to produce a sound and quality Inconel 718 coating at reduced spray parameters. To decouple and evaluate the role of the particle impact temperature, powder preheating units with downstream injection are used to decouple the particle impact temperature from the particle impact velocity. Three initial particle temperatures are studied: 25, 400 and 750 °C. The effect of the coating temperature on the deposition process is investigated by controlling this temperature independently of the gas stagnation temperature through the use of induction heating. Deposition efficiency, porosity, and micro-hardness are used to assess the coating quality. The coating time–temperature history is measured to better understand its influence on the deposition of Inconel 718. In this work, an enhanced understanding of the effect of both particle and coating temperatures on the coating process is obtained, and the findings allow the establishment of a potential approach to produce dense coatings using reduced spray parameters. [ABSTRACT FROM AUTHOR]

Published
2023
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4. A scalable dry chemical method for lithium borate coating to improve the performance of LiNi0.90Co0.06Mn0.04O2 cathode material.

Author

Tan, Xinxin, Peng, Wenjie, Duan, Hui, Wang, Zhixing, Guo, Huajun, Luo, Gui, Yuan, Rongzhong, Li, Xinhai, and Wang, Jiexi

Abstract

The washing process is an important working procedure for the industrial production of Ni-rich layered cathode materials. By washing, the most of residual lithium could be removed efficiently, but the surface corrosion of the cathode materials would be apparent. Therefore, coating is necessary to repair the surfaces of the cathode materials. In this study, we introduce a dry chemical process for LBO coating to improve the surface properties of Ni-rich materials (LiNi0.90Co0.06Mn0.04O2) after washing. Particularly, the effect of subsequent sintering temperature on the structure and uniformity of the coating layer as well as the electrochemical performance of as-prepared cathodes is investigated systematically. When the coating temperature is 300 °C, a uniform LBO coating layer is easily formed on the surface of the cathodes, helping to repair unstable surface of the washed LiNi0.90Co0.06Mn0.04O2 material. The coated LiNi0.90Co0.06Mn0.04O2 material shows a discharge capacity of 222.0 mAh g−1 with 88.1% of capacity retention after 100 cycles at 1C. The thermal stability can also be improved. The improved performance of LiNi0.90Co0.06Mn0.04O2 material should be ascribed to the LBO coating layer which can restrain the structure deterioration and surface impedance by diminishing the direct contact of the cathode materials and the electrolyte. [ABSTRACT FROM AUTHOR]

Published
2022
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6. Diffusion and reaction behavior of palladium coating and copper matrix prepared using a halogen-free direct coating process.

Author

Su, Hui, Li, Shaolin, Song, Kexing, Zhou, Yanjun, Cao, Jun, Cao, Fei, Gao, Yan, Ge, Chenyang, and Li, Jiyuan

Subjects
*COATING processes, *STACKING faults (Crystals), *PALLADIUM, *EDGE dislocations, *COPPER, *CRYSTAL defects, *ARYLATION, *FIRE resistant polymers
Abstract

Herein, a palladium-coated copper wire was prepared using a halogen-free direct coating process, and the effects of the coating temperature on the morphology of the palladium coating and the mechanical properties of the wire were studied. The structural characteristics of the coating and copper matrix as well as the diffusion, reaction, and bonding characteristics of the elements at the copper–palladium interface were investigated. Results show that the deposition rate of palladium and the aggregation of palladium grains were accelerated with increasing coating temperature, promoting the formation of large palladium particles on the surface of the palladium-coated copper wire. The strength of the coated wire decreases and the elongation increases with increasing coating temperature. At 400 °C, the thickness of the coating was approximately 51 nm coating, consisting of approximately 4 nm nanocrystals. The improvement in plasticity was attributed to the distortionless recrystallized subgrain nucleus formed by the cell structure comprising dislocation tangles in the copper matrix, which reduces the matrix dislocation density. Positive and negative edge dislocations were present in the coating, and the two dislocation lines of the edge dislocation dipole offset each other. Numerous crystal defects were found in the copper–palladium bonding interface zone. Moreover, copper unidirectionally diffuses into the palladium coating, forming the intermetallic-compound CuPd in the interface bonding zone. Furthermore, the formation of twins was caused by the change in the stacking order of atoms due to the stacking fault occurring on the crystal surface, and the thickness of the diffusion zone was approximately 9 nm. [Display omitted] • A uniform Pd coating with a thickness of 51 nm was obtained. • Diffusion and reaction behavior of Pd coating on Cu wire were explored. • Formation mechanism of Pd coating morphology was proposed. • Effect of temperature on the mechanical properties of the wire was discussed. [ABSTRACT FROM AUTHOR]

Published
2023
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7. Mechanical particle coating using ethylcellulose nanoparticle agglomerates for preparing controlled release fine particles; effect of coating temperature on coating performance.

Author

Kondo, Keita, Ando, Chihiro, and Niwa, Toshiyuki

Subjects
*ETHYLCELLULOSE, *CONTROLLED release drugs, *THEOPHYLLINE, *COMPOSITE particles (Composite materials), *MATERIAL plasticity
Abstract

Graphical abstract Abstract This study describes the effect of coating temperature on the performance of mechanical particle coating using ethylcellulose, which was done to produce controlled-release particles (diameters less than 100 μm) with different release rates. First, theophylline crystals were spheronized using a mechanical powder processor, yielding theophylline spheres (used as core particles). Second, ethylcellulose aqueous dispersion was powdered by spray-freeze drying to prepare colloidal agglomerates (used as coating powder). Finally, the spheres and agglomerates were mechanically mixed at various temperatures using the processor to produce composite particles. The ethylcellulose agglomerates were pulverized during processing to coat the theophylline spheres effectively. When the coating temperature was higher than the glass transition temperature (T g) of ethylcellulose, the amount of coated polymer increased significantly due to plastics deformation, causing thickening of the coated layer. The porosity of the coated layer decreased upon coalescence of coated polymer particles due to plastic deformation, which prevented the appearance of cracks in the film during curing. Therefore, controlled-release fine particles with various release rates can be produced effectively by mechanical particle coating at temperatures higher than the T g of the polymer. [ABSTRACT FROM AUTHOR]

Published
2019
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8. Substrate temperature dependent opto-electronic properties of perfume atomized CdO thin films.

Author

Ravikumar, M., Chandramohan, R., Valanarasu, S., Manogowri, R., and Kathalingam, A.

Subjects
*CADMIUM oxide, *THIN films, *OPTOELECTRONICS, *SUBSTRATES (Materials science), *ATOMIZATION, *TEMPERATURE effect
Abstract

CdO films were prepared by perfume atomizer technique. The prepared films showed cubic crystal structure. SEM image of the films indicated that there is an increase in grain size with substrate temperature. Optical absorption studies revealed that increase of substrate temperature can improve the absorption property of the films. Optical band gap of the film attained maximum value of 2.36 eV for the temperature at 350°C. I-V characteristics of films have shown an improvement in conductivity of the films with increase of substrate temperature and obtained photocurrent of 4.07×10-4 A for the film coated at 350°C. [ABSTRACT FROM AUTHOR]

Published
2017
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9. A novel integrated temperature investigation approach of sprayed coatings during APS process

Author

Xia, Weisheng, Zhang, Haiou, Wang, Guilan, and Yang, Yunzhen

Subjects
*PLASMA spraying, *SUBSTRATES (Materials science), *PYROMETRY, *TRAJECTORIES (Mechanics), *THERMAL properties of metals, THERMAL properties of surface coatings
Abstract

Abstract: Coating temperature is important for the coating reliability and reproducibility during the process of atmospheric plasma spray. A novel measurement and control approach for substrate and coating temperatures is presented. It is based on infrared (IR) pyrometry combined to specific robot spray trajectories in order to avoid harsh environment of spray workshops. The temperature evolution is continuously detected and recorded during preheating, spraying and cooling stages. The two specific factors, periodic average temperature and standard deviation were adopted to evaluate the temperature variation and the fluctuation of the thermal cycle relevant to one robot spray cycle based on the statistical method. These two factors are successful in describing the temperature variation during experimental processing sets. Finally, based on the monitoring system, the influence of Z-type robot spray trajectory parameters, including spray distance, scanning velocity and scanning step on coating temperature characterized by the two factors, is systemically investigated. Experimental results show that average temperature has no evident difference as a function of scanning velocity and no fixed relationship with scanning step, but just is dominated by the heating time of plasma jet and particle flux. Therefore, the selection of optimal scanning velocity just needs to take the temperature fluctuation into consideration. The temperature fluctuation decreases when scanning step increases, but both average temperature and fluctuation decrease with the increasing of spray distance and vice versa. Finally, on the basis of experimental results, a control experiment of sprayed coating temperature is presented to obtain constant temperature cycles by means of adjusting robot trajectories, cooling, among other considered operating parameters. Excellent control performance is observed. [Copyright &y& Elsevier]

Published
2009
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10. Properties and tribological performance of ceramic-base chromium and vanadium carbide composite coatings

Author

Ali Günen, Piers Milner, Mustafa Sabri Gök, Bülent Kurt, Mühendislik ve Doğa Bilimleri Fakültesi -- Metalurji ve Malzeme Mühendisliği Bölümü, and Günen, Ali

Subjects
Coefficient of friction, Vanadium carbide, Tribology, Particle, 02 engineering and technology, Iron compounds, Carbide, Coating, Diffusion, chemistry.chemical_compound, Wear, Die steel, Thermo-reactive deposition, Surface properties, Surface roughness, Diffusion coatings, Composite material, Microstructure, Wear behavior, Friction coefficients, Multidisciplinary, Treatment conditions, General Medicine, Tribological performance, 0205 materials engineering, Mechanism, Carbides, Coating temperature, Chromium carbide, Materials science, Friction, Materials Science, Tool steel, Chromium compounds, Vanadium, chemistry.chemical_element, High-temperature, engineering.material, Indentation hardness, Mechanical characteristics, Hardness, Coatings, 020502 materials, Average surface roughness, Composite coatings, Binary alloys, Niobium Carbides | Salt Baths | Tool Steel, Kinetics, chemistry, Steel, Pack-cementation method, engineering, Metallurgy & Metallurgical Engineering, Coefficient of frictions
Abstract

WOS: 000465193500040, In the current study, the surface of AISI D2 steel was coated with the powder blends of ferro-vanadium (Fe-V) and ferro-chromium (Fe-Cr). The coatings were performed using a thermo-reactive diffusion (TRD) treatment by the pack cementation method at three different temperatures (900 degrees C, 1000 degrees C, and 1100 degrees C) and three different durations (1 h, 2 h, and 3 h). The structural and mechanical characteristics of the coatings were compared between the treatment groups. For this aim, the types of the formed phases, the microstructure, the microhardness, the surface roughness, and the wear and friction performance of the coated samples were examined. XRD analysis found composite carbide coatings including chromium carbide (Cr-C), vanadium carbide (V-C), and chromium vanadium carbide (Cr-V-C). The coatings' thickness was 11.3-23.2 mu m, hardness was 2100-2500 HV, and average surface roughness (R-a) was 0.286-0.550 mu m, depending on the treatment condition. The vanadium containing phase contents of the coatings increased with the elevating coating temperatures. The formed composite coating layers caused a change in the appearance of wear track and wear mechanism on the material surface. After the coating process, there found to be a decrease in the friction coefficient as well as an improvement in the wear resistance up to 7 times. In the composite coating layers, the increase in V-C content in comparison to Cr-C led to an enhancement in wear resistance on the material surface.

Published
2019

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