Thermal spraying, Wires, rods and cords for flame and arc spraying. Classification. Technical supply conditions

Reconditioning materials by thermal spray metalizing is a rapidly growing field. In this paper we conducted a comparative study of three methods of metal deposition: flame spraying, atmospheric plasma spraying, arc spraying. This was done considering two of the properties of layers obtained in metalizing process: surface adhesion strength and porosity. The result of ultrasound examination by immersion shows that adhesion obtained through APS method is better than the others two obtained through AS and FS methods.

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Arc Spraying 3Cr13 Molten Drop Impact Stress Numerical Analysis

The Open Materials Science Journal ◽

10.2174/1874088x01307010001 ◽

2013 ◽

Vol 7 (1) ◽

pp. 1-7

Author(s):

C.H. Li ◽

S. Wang ◽

T.T. Zhao ◽

Y.C. Ding

Keyword(s):

Residual Stress ◽

Theoretical Model ◽

Thermal Spraying ◽

Drop Impact ◽

Arc Spraying ◽

Coating Materials ◽

Impact Stress ◽

The Matrix ◽

Change Temperature ◽

Pressure Stress

In the thermal spraying process, the process for the molten metal particles to hit against matrix to form coating experiences great change temperature. Since the coating materials has different thermal physical properties with the matrix materials, the residual stress is surely left in the coating. Much bigger residual stress not only restricts coating thickness but also primarily affects coating binding strength. Having analyzed reason for residual stress in the thermal spraying coating and matrix, the theoretical model of arc spraying 3Cr13 molten drop impact stress is built and numerical simulation is done for this theoretical model. The result indicates that: the faster the molten drop speed is, the greater the pressure that matrix produces. When the molten drop's collision speed is 100m/s, it is not obvious for the matrix's pressure stress and when the collision speed is increased to 200m/s, the pressure stress produced in the matrix can maximize 5500Mpa; the faster the molten drop's collision speed is, the higher extent the molten drop's flattening is, which is more beneficial to increase coating’s bonding strength. The radius for the molten drop in the radius of 35μm becomes 80~110μm after collision and the flat ratio of the molten drop particle is about 3. The theoretical analysis is consistent with the experiment result.

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Evolution of TSA/TSZ coatings: a review on recent advances on cold gas spraying for steel corrosion protection

Corrosion Reviews ◽

10.1515/corrrev-2020-0102 ◽

2021 ◽

Vol 0 (0) ◽

Author(s):

Vicente Albaladejo-Fuentes ◽

Ana María Martos ◽

Javier Sánchez ◽

Irene Garcia-Cano

Keyword(s):

Corrosion Protection ◽

Thermal Spraying ◽

Steel Corrosion ◽

Cost Effective ◽

Relevant Information ◽

Flame Spraying ◽

Arc Spraying ◽

Recent Advances ◽

Cold Gas

Abstract For decades, zinc- and aluminum-based coatings have been considered the best material choice for steel corrosion protection since they may act as a protective barrier and show sacrificial behavior. These coatings are often prepared by galvanizing methods. However, their application by thermal spraying techniques (wire arc spraying, WAS and flame spraying, FS) has been proved as a cost-effective solution for the preparation of long-term corrosion-resistant coatings. This review selectively collects the most relevant information about the application and performance of these two techniques on Zn and Al coatings for corrosion protection. The report summarizes separately the Zn and Al data from the effect of the spraying parameters on coating properties on the one hand, and the results shown in long-term studies carried out in relevant and real exposure conditions, on the other. Finally, this review includes a description and comparison of the most recent advances found out with the novel and emerging spray technique, cold gas spray, for the deposition of Zn and Al coatings for corrosion protection purposes. Nevertheless, the use of this technique has not reached the stage of wide industrial application yet and therefore its long-term performance is unknown, which suggests that there is still room for further development.

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Structure and Selected Properties of Arc Sprayed Coatings Containing In-Situ Fabricated Fe-Al Intermetallic Phases

Metals ◽

10.3390/met8121059 ◽

2018 ◽

Vol 8 (12) ◽

pp. 1059 ◽

Cited By ~ 10

Author(s):

Tomasz Chmielewski ◽

Piotr Siwek ◽

Marcin Chmielewski ◽

Anna Piątkowska ◽

Agnieszka Grabias ◽

...

Keyword(s):

Protective Coatings ◽

Composite Coatings ◽

Thermal Spraying ◽

Intermetallic Phases ◽

Arc Spraying ◽

Coating Materials ◽

Two Phases ◽

Sprayed Coatings ◽

Spraying Process

The paper presents the results of research on the production by means of arc spraying of composite coatings from the Fe-Al system with participation of in-situ intermetallic phases. The arc spraying process was carried out by simultaneously melting two different electrode wires, aluminum and steel. The aim of the research is to create protective coatings with a composite structure with a significant participation of FexAly as an intermetallic phases reinforcement. The synthesis of intermetallic phases takes place during the (in-situ) spraying process. Currently most coatings involving intermetallic phases are manufactured by different thermal spraying methods using coating materials in the form of prefabricated powders containing intermetallic phases. The obtained results showed the local occurrence of intermetallic phases from the Fe-Al system, and the dominant components of the structure have two phases, aluminum solid solutions in iron and iron in aluminum. The participation of intermetallic phases in the coating is relatively low, but its effect on the properties of the coating material is significant.

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Powder wires for resource-saving electric arc spraying

Sel'skohozjajstvennaja tehnika: obsluzhivanie i remont (Agricultural Machinery: Service and Repair) ◽

10.33920/sel-10-2101-02 ◽

2021 ◽

pp. 11-17

Author(s):

V. P. Murzaev ◽

D. B. Slinko ◽

Yu. N. Shchetinin

Keyword(s):

Electrode Materials ◽

Thermal Spraying ◽

Machine Building ◽

Electric Arc ◽

Arc Spraying ◽

Resource Saving ◽

Metal Structures ◽

Wear Resistant Coatings ◽

Heat Resistant ◽

The Cost

One of the promising methods of thermal spraying is the arc spraying. The use of electric arc spraying is particularly eff ective for the protection of metal structures from corrosion, receiving heat resistant, heat-resistant and wear-resistant coatings. This method is also eff ective in the recovery and hardening de tackles tractors, trucks and agricultural machinery. Signifi cantly extend the scope of the arc deposition can be using the new electrode materials in the form of fl ux-cored wires, the cost of which can be reduced by using materials for dying as a band , with factories producing cable products and iron shavings tion of machine-building enterprises.

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Thermal spraying, Wires, rods and cords for flame and arc spraying. Classification. Technical supply conditions

10.3403/02337721u ◽

2015 ◽

Keyword(s):

Thermal Spraying ◽

Arc Spraying

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Development of Thermal Spray Processes for Depositing Coatings on Thermoplastics

Journal of Thermal Spray Technology ◽

10.1007/s11666-020-01147-x ◽

2021 ◽

Author(s):

Kirsten Bobzin ◽

Wolfgang Wietheger ◽

Martin Andreas Knoch

Keyword(s):

Process Parameters ◽

Signal Transmission ◽

Thermal Spraying ◽

Arc Spraying ◽

Coating Application ◽

Critical Areas ◽

Copper Coatings ◽

Layer Deposition ◽

Wire Arc Spraying ◽

Thermal Spray Processes

AbstractThermoplastics combine high freedom of design with economical mass production. Metallic coatings on thermoplastics enable power and signal transmission, shield sensitive parts inside of housings and can reduce the temperature in critical areas by functioning as a heat sink. The most used technical thermoplastics are polyamides (PA), while the described use cases are often realized using Cu. Consequently, several studies tried to apply copper coatings on PA substrates via thermal spraying; so far, this combination is only feasible using an interlayer. In this study, a new approach to metallize thermoplastics via thermal spraying based on validated state-of-the-art predictions of the thermoplastics’ material response at relevant temperatures and strain rates is presented. Using these predictions, high velocity wire-arc spraying was selected as coating process. Furthermore, the process parameters were adapted to realize a continuous coating while also roughening the substrate during coating deposition. The resulting Cu coating on PA6 had a sufficiently high coating adhesion for post-treatment by grinding. The adhesion is achieved by in situ roughening during the coating application. The results indicate that different process parameters for initial layer deposition and further coating buildup are required due to the low thermal stability of PA6.

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Processing Effects on Residual Stress in Ni+5%AI Coatings–Comparison of Different Spraying Methods

Thermal Spray 2000: Proceedings from the International Thermal Spray Conference ◽

10.31399/asm.cp.itsc2000p0351 ◽

2000 ◽

Author(s):

J. Matejicek ◽

S. Sampath ◽

T. Gnaeupel-Herold ◽

H.J. Prask

Keyword(s):

Residual Stress ◽

Thermal Spraying ◽

Stress Generation ◽

Arc Spraying ◽

Twin Wire Arc Spraying ◽

Wire Arc Spraying ◽

Generation Mechanisms ◽

Sprayed Coating ◽

Plasma Sprayed ◽

Steel Substrates

Abstract Properties of thermally sprayed coatings, including residual stress, are controlled by various parameters of the spraying process. This study is focused on three thermal spraying techniques with significantly different particle temperatures and velocities. These are plasma spraying, twin wire arc spraying and high velocity oxy-fuel spraying. For each method, in-flight particle diagnostics was performed. Through-thickness residual stress profiles in Ni+5%A1 coatings on steel substrates were determined nondestructively by neutron diffraction. The stresses range from high tensile in the plasma sprayed coating to compressive in the HVOF one. Various stress generation mechanisms, including splat quenching, peening, and thermal mismatch, are discussed with respect to process parameters and material properties.

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