Low-loss fibre prepared under high deposition rate by modified c.v.d. technique

Laser cladding by cold-wire feeding is known as an efficient cladding method due to its advantages, such as near 100% material utilization, high deposition rate, and flexible adaptation to the cladding position. However, it has very stringent requirements on the operative conditions, such as a small range of wire feeding rate and precise wire feeding position. The aim of this work was to investigate the laser hot-wire cladding technique, which improved the productivity and stability of the process significantly with respect to laser cold-wire cladding. The external preheating of the filler wire resulted in reduction in required laser power, a low dilution, and a higher deposition rate. A comparison was made between laser cold-wire cladding and laser hot-wire cladding of Inconel 625 on mild steel, with respect to the clad characteristics, microstructure, and hardness. An optimization of the main processing parameters in laser hot-wire cladding, such as the laser power, laser spot size, laser scanning speed, wire feeding orientation and position, wire preheating voltage, and wire feeding rate, was performed. The optimal parameters were used to create a multi-track deposit.

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Technological Features of the Thick Tin Film Deposition by with Magnetron Sputtering Form Liquid-Phase Target

Key Engineering Materials ◽

10.4028/www.scientific.net/kem.781.8 ◽

2018 ◽

Vol 781 ◽

pp. 8-13 ◽

Cited By ~ 3

Author(s):

Mariya Makarova ◽

Konstantin Moiseev ◽

Alexander Nazarenko ◽

Petr Luchnikov ◽

Galina Dalskaya ◽

...

Keyword(s):

Liquid Phase ◽

Magnetron Sputtering ◽

Deposition Rate ◽

Amorphous Structure ◽

Film Deposition ◽

High Deposition Rate ◽

Crucible Material ◽

Tin Films ◽

X Ray ◽

Tin Film

Technological features of obtaining of tin films in a vacuum by liquid-phase target magnetron sputtering were reviewed. With high deposition rate the white color tin coating with amorphous structure is formed on the substrate. X-ray microanalysis of the obtained tin films showed the presence of micro-and nanoparticles of an impurity of the crucible material in the structure of the films. The use of the tantalum crucible with liquid-phase target magnetron sputtering with deposition rate of 3.2 μm / min allows obtaining ultra-pure, continuous, homogeneous tin film on a stationary substrate without impurity material of the crucible.

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Effect of Forming Environments on Microstructure of GH4169 Superalloy Fabricated Using High-Deposition-Rate Laser Metal Deposition

Chinese Journal of Lasers ◽

10.3788/cjl202047.0802004 ◽

2020 ◽

Vol 47 (8) ◽

pp. 0802004

Author(s):

赵轩 Zhao Xuan ◽

隋尚 Sui Shang ◽

李祚 Li Zuo ◽

孙楚 Sun Chu ◽

陈静 Chen Jing

Keyword(s):

Deposition Rate ◽

Metal Deposition ◽

High Deposition Rate ◽

Laser Metal Deposition ◽

Gh4169 Superalloy

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Facilitating TiB2 for Filtered Vacuum Cathodic Arc Evaporation

Coatings ◽

10.3390/coatings10030244 ◽

2020 ◽

Vol 10 (3) ◽

pp. 244

Author(s):

Tomasz L. Brzezinka ◽

Jeff Rao ◽

Jose M. Paiva ◽

Ibon Azkona ◽

Joern Kohlscheen ◽

...

Keyword(s):

Electrical Resistivity ◽

Deposition Rate ◽

Axial Magnetic Field ◽

Electrical Potential ◽

Base Material ◽

Hard Coatings ◽

Grain Structure ◽

High Deposition Rate ◽

Bulk Hardness ◽

Arc Evaporation

TiB2 is well established as a superhard coating with a high melting point and a low coefficient of friction. The brittle nature of borides means they cannot be utilised with arc evaporation, which is commonly used for the synthesis of hard coatings as it provides a high deposition rate, fully ionised plasma and good adhesion. In this work, TiB2 conical cathodes with non-standard sintering additives (carbon and TiSi2) were produced, and the properties of the base material, such as grain structure, hardness, electrical resistivity and composition, were compared to those of monolithic TiB2. The dependence of the produced cathodes’ electrical resistivity on temperature was evaluated in a furnace with an argon atmosphere. Their arc–evaporation suitability was assessed in terms of arc mobility and stability by visual inspection and by measurements of plasma electrical potential. In addition, shaping the cathode into a cone allowed investigation of the influence of an axial magnetic field on the arc spot. The produced cathodes have a bulk hardness of 23–24 GPa. It has been found that adding 1 wt% of C ensured exceptional arc-spot stability and mobility, and requires lower arc current compared to monolithic TiB2. However, poor cathode utilization has been achieved due to the steady generation of cathode flakes. The TiB2 cathode containing 5 wt% of TiSi2 provided the best balance between arc-spot behaviour and cathode utilisation. Preventing cathode overheating has been identified as a main factor to allow high deposition rate (±1.2 µm/h) from TiB2-C and TiB2-TiSi2 cathodes.

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