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From Surface Modification to Additive Manufacturing of Components by Solid-State Cold Spray Technology

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A special issue of Materials (ISSN 1996-1944). This special issue belongs to the section "Manufacturing Processes and Systems".

Deadline for manuscript submissions: closed (20 September 2023) | Viewed by 11685

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Special Issue Editor

Dr. Mohammadreza Daroonparvar

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Guest Editor

National Center for Additive Manufacturing Excellence (NCAME), Mechanical Engineering Department, Auburn University, Auburn, AL 36849, USA
Interests: protective coatings; advanced thermal barrier coating systems; high pressure cold spray (HPCS); cold spray additive manufacturing (CSAM); hybrid additive manufacturing; thermal spray coatings; high temperature oxidation; corrosion science; pitting and passivity; electrochemical impedance spectroscopy (EIS)
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Special Issue Information

Dear Colleagues,

In additive manufacturing processes, sources such as electron beams or lasers with high energy are utilized for selectively melting down the powder bed, in which the resulted solidified metal can form the solid component. The most well known metal additive manufacturing methods include selective laser sintering, selective laser melting and electron beam melting. However, as high energy sources are used in these methods, disadvantages such as undesirable phase transformations, and residual stress caused by high processing temperatures, are inevitable. Likewise, most common additive manufacturing processes have been typically utilized to produce complicated Ti, Fe, or Ni-based alloy/super alloy components. Nonetheless, because of melting, these processes are not appropriate processes for producing the components made of non-ferrous alloys like Mg alloys, high-strength Cu, or Al-based alloys. Thus, another additive manufacturing technique is needed to produce the parts made of such non-ferrous materials. Cold spray is a newly developed technology that is able to produce the components via solid-state deposition of powder particles. Compared to traditional deposition processes which use high temperatures (such as prevalent additive manufacturing methods and traditional thermal spray processes), in the cold spray technique, the deposition process typically uses the kinetic energy of the powder particles, before impinging, in place of the thermal energy. The feedstock powder utilized in the CS process keeps its solid state throughout the whole deposition process. The deposition is attained via mechanical interlocking and local metallurgical bonding, which are formed by severe local plastic deformations at particle–substrate interfaces and also at the inter-particle boundaries. As mentioned, the relatively low temperature in the cold spray process averts the common defects occurring in the deposition processes that include high temperatures, like phase transformation, oxidation, residual thermal stress (tensile), grain growth, etc.

The abovementioned remarkable advantages make cold spray technology an effective method for producing coatings with a wide range of materials; they can comprise most metals and their alloys, nanostructured metals, and MMCs. In addition, there is no limitation in the growth of thickness in the cold spray coating process. Hence, besides the application of solid-state cold spray processes for the coating of surfaces and the repairing of structures, they can be employed in with faster build rates (minutes) compared to selective laser melting and electron beam melting processes.

The objective of this Special Issue is to present the latest experimental and theoretical developments in this field, through original research and short communication papers, and review articles from academia and industry around the world.

In particular, the topics of interest include, but are not limited to:

3D printed/additively manufactured coatings and repair of structurally critical components using cold spray technology.
Cold spray additive manufacturing of high entropy alloys, Ti, Al, Fe, Ni based alloys and super alloys, refractory metals, etc.
Improvement of corrosion, wear and high temperature oxidation resistances of additively manufactured cold sprayed components/deposits using post-cold spray treatments.
Modification of mechanical properties of additively manufactured cold sprayed components using post-cold spray treatments.
Application of additively manufactured cold sprayed components/deposits for biomedical applications.
Hybrid additive manufacturing: the combination of cold spray processes and common additive manufacturing methods.

Dr. Mohammadreza Daroonparvar
Guest Editor

Manuscript Submission Information

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Keywords

corrosion
high temperature oxidation
advanced manufacturing
cold spray
wear
bio-medical application
additively manufactured coatings

Published Papers (5 papers)

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Research

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16 pages, 9812 KiB

Open AccessArticle

Influence of Heat Treatment on Microstructure, Mechanical Property, and Corrosion Behavior of Cold-Sprayed Zn Coating on Mg Alloy Substrate

by Zhenpeng Zhou, Xiao Chen, Xiaozhen Hu, Sheng Li, Menglong Lv, Yiting Xie, Hailong Yao, Hongtao Wang and Xiaobo Bai

Materials 2022, 15(19), 6721; https://0-doi-org.brum.beds.ac.uk/10.3390/ma15196721 - 27 Sep 2022

Cited by 1 | Viewed by 1181

Abstract

The influence of post-process heat treatment on cold-sprayed Zn coatings on the Mg alloy substrate was investigated at different temperatures (150, 250, and 350 °C) and times (2, 8, and 16 h). Phase, microstructure, microhardness, and tensile strength of Zn coatings were analyzed before and after heat treatment. Corrosion properties of Zn coatings after heat treatment were investigated in simulated body fluid by using potentiodynamic polarization and immersion testing. Results show that although the heat treatment presented little effect on phase compositions of Zn coatings, the full width at half maxima of the Zn phase decreased with the heat temperature and time. Zn coatings presented comparable microstructures before and after heat treatment in addition to the inter-diffusion layers, and the inter-diffusion layer was dependent on the heat temperature and time. Both the thickness and the microhardness of inter-diffusion layers were increased with the heat temperature and time, with the largest thickness of 704.1 ± 32.4 μm and the largest microhardness of 323.7 ± 104.1 HV_0.025 at 350 °C for 2 h. The microhardness of Zn coating was significantly decreased from 70.8 ± 5.6 HV_0.025 to 43.9 ± 12.5 HV_0.025, with the heat temperature from the ambient temperature to 350 °C, and was slightly decreased with the heat time at 250 °C. Although the tensile strength of Zn coating was slightly increased by heat treatment, with the highest value of 40.9 ± 3.9 MPa at 150 °C for 2 h, excessive heat temperature and time were detrimental to the tensile strength, with the lowest value of 6.6 ± 1.6 MPa at 350 °C for 2 h. The heat temperature and heat time presented limited effects on the corrosion current and corrosion ratio of the Zn coatings, and Zn coatings before and after heat treatment effectively hindered the simulated body fluid from penetrating into the substrate. The corrosion behavior of Zn coatings was discussed in terms of corrosion products and microstructures after immersion. Full article

(This article belongs to the Special Issue From Surface Modification to Additive Manufacturing of Components by Solid-State Cold Spray Technology)

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16 pages, 6380 KiB

Open AccessArticle

Application of Mass Finishing for Surface Modification of Copper Cold Sprayed Material Consolidations

by Matthew A. Gleason, Bryer C. Sousa, Kyle Tsaknopoulos, Jack A. Grubbs, Jennifer Hay, Aaron Nardi, Christopher A. Brown and Danielle L. Cote

Materials 2022, 15(6), 2054; https://0-doi-org.brum.beds.ac.uk/10.3390/ma15062054 - 10 Mar 2022

Cited by 8 | Viewed by 2386

Abstract

The surface roughness of additively manufactured (AM) components can have deleterious effects on the properties of the final part, such as corrosion resistance and fatigue life. Modification of the surface finish or parts produced by AM processes, such as cold spray, through methods such as mass finishing, can help to mitigate some of these issues. In this work, the surface evolution of as-produced copper cold sprayed material consolidations was studied through mass finishing. Three different copper powders attained by different production methods and of different sizes were used as feedstock. The surface topography of the cold spray deposits was measured as a function of the mass finishing time for the three copper cold spray samples and analyzed in terms of relative area and complexity, revealing an inverse correlation relating material removal rate and hardness/strength of the cold sprayed deposits. The material removal rate was also affected by the quality of the cold spray deposition, as defined by deposition efficiency (DE). Large initial drops in relative area and complexity are also likely due to the removal of loosely bonded powders at the start of mass finishing. Based on this study, the cold spray parameters that affect the rate of mass finishing have been explored. Full article

(This article belongs to the Special Issue From Surface Modification to Additive Manufacturing of Components by Solid-State Cold Spray Technology)

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22 pages, 6305 KiB

Open AccessArticle

Experimental and Numerical Investigations of Titanium Deposition for Cold Spray Additive Manufacturing as a Function of Standoff Distance

by Wojciech Żórawski, Rafał Molak, Janusz Mądry, Jarosław Sienicki, Anna Góral, Medard Makrenek, Mieczysław Scendo and Romuald Dobosz

Materials 2021, 14(19), 5492; https://0-doi-org.brum.beds.ac.uk/10.3390/ma14195492 - 23 Sep 2021

Cited by 5 | Viewed by 1922

Abstract

In this research, the cold spray process as an additive manufacturing method was applied to deposit thick titanium coatings onto 7075 aluminium alloy. An analysis of changes in the microstructure and mechanical properties of the coatings depending on the standoff distance was carried out to obtain the maximum deposition efficiency. The process parameters were selected in such a way as to ensure the spraying of irregular titanium powder at the highest velocity and temperature and changing the standoff distance from 20 to 100 mm. Experimental studies demonstrated that the standoff distance had a significant effect on the microstructure of the coatings and their adhesion. Moreover, its rise significantly increased the deposition efficiency. The standoff distance also significantly affected the coating microstructure and their adhesion to the substrate, but did not cause any changes in their phase composition. The standoff distance also influenced the coating porosity, which first decreased to a minimum level of 0.2% and then increased significantly to 9.8%. At the same time, the hardness of the coatings increased by 30%. Numerical simulations confirmed the results of the tests. Full article

(This article belongs to the Special Issue From Surface Modification to Additive Manufacturing of Components by Solid-State Cold Spray Technology)

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12 pages, 3220 KiB

Open AccessArticle

Computing the Fatigue Life of Cold Spray Repairs to Simulated Corrosion Damage

by Daren Peng, Caixian Tang, Neil Matthews, Rhys Jones, Sudip Kundu, R. K. Singh Raman and Alankar Alankar

Materials 2021, 14(16), 4451; https://0-doi-org.brum.beds.ac.uk/10.3390/ma14164451 - 09 Aug 2021

Cited by 9 | Viewed by 2011

Abstract

This paper summarises the findings of an investigation into the durability of cold spray repairs, also known as supersonic particle deposition or SPD repairs, to simulated corrosion damage in AA7075-T7351 aluminium alloy specimens. A feature of this paper is that it is the first to show how to perform the mandatory durability analysis of repaired corroded structures, where the corroded material is first removed by machining and then repaired using cold spray, in a fashion consistent with the requirements delineated in USAF Structures Bulletin EZ-19-01, MIL-STD-1530D, and the US Joint Services Structural Guidelines JSSG2006. Full article

(This article belongs to the Special Issue From Surface Modification to Additive Manufacturing of Components by Solid-State Cold Spray Technology)

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Review

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28 pages, 8419 KiB

Open AccessReview

Solid-State Cold Spray Additive Manufacturing of Ni-Based Superalloys: Processing–Microstructure–Property Relationships

by Alessandro M. Ralls, Mohammadreza Daroonparvar, Merbin John, Soumya Sikdar and Pradeep L. Menezes

Materials 2023, 16(7), 2765; https://0-doi-org.brum.beds.ac.uk/10.3390/ma16072765 - 30 Mar 2023

Cited by 1 | Viewed by 1881

Abstract

Ni-based superalloys have been extensively employed in the aerospace field because of their excellent thermal and mechanical stabilities at high temperatures. With these advantages, many sought to study the influence of fusion-reliant additive manufacturing (AM) techniques for part fabrication/reparation. However, their fabrication presents many problems related to the melting and solidification defects from the feedstock material. Such defects consist of oxidation, inclusions, hot tearing, cracking, and elemental segregation. Consequentially, these defects created a need to discover an AM technique that can mitigate these disadvantages. The cold spray (CS) process is one additive technique that can mitigate these issues. This is largely due to its cost-effectiveness, low temperature, and fast and clean deposition process. However, its effectiveness for Ni-based superalloy fabrication and its structural performance has yet to be determined. This review aimed to fill this knowledge gap in two different ways. First, the advantages of CS technology for Ni-based superalloys compared with thermal-reliant AM techniques are briefly discussed. Second, the processing–structure–property relationships of these deposits are elucidated from microstructural, mechanical, and tribological (from low to high temperatures) perspectives. Considering the porous and brittle defects of CS coatings, a comprehensive review of the post-processing techniques for CS-fabricated Ni superalloys is also introduced. Based on this knowledge, the key structure-property mechanisms of CS Ni superalloys are elucidated with suggestions on how knowledge gaps in the field can be filled in the near future. Full article

(This article belongs to the Special Issue From Surface Modification to Additive Manufacturing of Components by Solid-State Cold Spray Technology)

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