Sliding Wear And Fretting Behaviour Of Electrodeposited Gamma Phase Zinc Nickel Coatings As A Replacement For Electrodeposited Cadmium Coatings

Sliding Wear and Fretting Behaviour of Electrodeposited [gamma]-phase Zinc-nickel Coatings as a Replacement for Electrodeposited Cadmium Coatings

Author : Lisa Lee

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Page : pages

File Size : 49,92 MB

Release : 2017

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"Electrodeposited Zn-Ni coatings is used as a sacrificial corrosion protective coating for steel in the automotive industry. Recently, the aerospace industry has taken an interest in these coatings due to the increasing restrictions on cadmium. Many studies have been made on improving the plating process and corrosion properties of Zn-Ni coatings. Although these coatings encounter tribological situations, there is still an information gap on their tribological behaviour. Therefore, the tribological behaviour of Zn-Ni coatings are studied in terms of fretting and sliding wear in this work and are compared with cadmium.Tribological studies of the fretting and sliding wear behaviour on Zn-Ni and Cd coatings were conducted. For Zn-Ni coating, studies showed that the surface morphology had a strong effect on the velocity accommodation mechanisms. In the stick or partial slip regime, the smoother and dense coating formed cracks on the surface in order to accommodate wear, whereas for the rougher coating, only asperities of the coating were deformed, as the morphology of the coating allowed some degree of elastic deformation. In the mixed slip and the gross slip regimes, shearing of the third bodies accommodated the velocity in both cases. When slipping occurred, the rougher coating also showed higher wear, as the morphology of the coating allowed easier detachment, as cracks and through thickness defects were present where the agglomerates of the coating meets. When compared with Cd coatings, the material properties affected the fretting behaviour strongly. Cadmium coating remained in the partial slip regime despite changing the displacement amplitude, due to the mechanical properties and crystal structure of cadmium. Plastic flow of the coating material accommodated the velocity for cadmium coating, as cadmium has a hexagonal crystal structure and is very ductile. Although cadmium remained in the stick and partial slip regime, increasing the displacement amplitude increased the friction and wear of the coating. When a high displacement amplitude was used, cadmium coating was removed from the center of the contact and the substrate was exposed.Sliding wear studies of the effect of normal load, surface morphology and humidity for Zn-Ni coatings were conducted and the results were compared with Cd. Formation of an oxide layer appeared to have a strong effect on the sliding wear behaviour, the smoother and dense coating was subjected to test performed in various humidity conditions. At high humidity, a continuous nanocrystalline ZnO film was formed on the surface of the wear track, which helped mitigate wear and stabilize the friction. This is because velocity was accommodated through shearing of the nanocrystalline film. In contrast, at zero humidity level, a prow formed due to adhesive wear behaviour. Velocity was accommodated by ploughing of the wear track and shearing of the particles. When tests were performed in high humidity, increasing the normal load caused breaking of the oxide layer that was formed on the wear track, which resulted in more adhesive wear. At low normal loads, the rougher coating showed more wear than the smoother coating. At the highest normal load, the wear of the smoother coating became more severe as the lack of a continuous oxide film caused more adhesive wear. The rougher coating was less sensitive to increase of initial Hertzian contact stress, as the surface morphology of the coating allowed some degree of elastic and plastic deformation. When compared to Cd, humidity also affected the sliding wear behaviour of Cd due to change in the composition of the third bodies. Decreasing the humidity was beneficial to cadmium but detrimental to Zn-Ni. Due to material properties, a lower CoF was observed for cadmium, while a higher wear resistance was observed in Zn-Ni coating." --



Sliding Wear and Fretting Behaviour of Electrodeposited Γ-phase Zinc-nickel Coatings as a Replacement for Electrodeposited Cadmium Coatings

Author : Lisa Lee

Publisher :

Page : pages

File Size : 14,52 MB

Release : 2017

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ISBN :

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Electrodeposited Zn-Ni coatings is used as a sacrificial corrosion protective coating for steel in the automotive industry. Recently, the aerospace industry has taken an interest in these coatings due to the increasing restrictions on cadmium. Many studies have been made on improving the plating process and corrosion properties of Zn-Ni coatings. Although these coatings encounter tribological situations, there is still an information gap on their tribological behaviour. Therefore, the tribological behaviour of Zn-Ni coatings are studied in terms of fretting and sliding wear in this work and are compared with cadmium.Tribological studies of the fretting and sliding wear behaviour on Zn-Ni and Cd coatings were conducted. For Zn-Ni coating, studies showed that the surface morphology had a strong effect on the velocity accommodation mechanisms. In the stick or partial slip regime, the smoother and dense coating formed cracks on the surface in order to accommodate wear, whereas for the rougher coating, only asperities of the coating were deformed, as the morphology of the coating allowed some degree of elastic deformation. In the mixed slip and the gross slip regimes, shearing of the third bodies accommodated the velocity in both cases. When slipping occurred, the rougher coating also showed higher wear, as the morphology of the coating allowed easier detachment, as cracks and through thickness defects were present where the agglomerates of the coating meets. When compared with Cd coatings, the material properties affected the fretting behaviour strongly. Cadmium coating remained in the partial slip regime despite changing the displacement amplitude, due to the mechanical properties and crystal structure of cadmium. Plastic flow of the coating material accommodated the velocity for cadmium coating, as cadmium has a hexagonal crystal structure and is very ductile. Although cadmium remained in the stick and partial slip regime, increasing the displacement amplitude increased the friction and wear of the coating. When a high displacement amplitude was used, cadmium coating was removed from the center of the contact and the substrate was exposed.Sliding wear studies of the effect of normal load, surface morphology and humidity for Zn-Ni coatings were conducted and the results were compared with Cd. Formation of an oxide layer appeared to have a strong effect on the sliding wear behaviour, the smoother and dense coating was subjected to test performed in various humidity conditions. At high humidity, a continuous nanocrystalline ZnO film was formed on the surface of the wear track, which helped mitigate wear and stabilize the friction. This is because velocity was accommodated through shearing of the nanocrystalline film. In contrast, at zero humidity level, a prow formed due to adhesive wear behaviour. Velocity was accommodated by ploughing of the wear track and shearing of the particles. When tests were performed in high humidity, increasing the normal load caused breaking of the oxide layer that was formed on the wear track, which resulted in more adhesive wear. At low normal loads, the rougher coating showed more wear than the smoother coating. At the highest normal load, the wear of the smoother coating became more severe as the lack of a continuous oxide film caused more adhesive wear. The rougher coating was less sensitive to increase of initial Hertzian contact stress, as the surface morphology of the coating allowed some degree of elastic and plastic deformation. When compared to Cd, humidity also affected the sliding wear behaviour of Cd due to change in the composition of the third bodies. Decreasing the humidity was beneficial to cadmium but detrimental to Zn-Ni. Due to material properties, a lower CoF was observed for cadmium, while a higher wear resistance was observed in Zn-Ni coating.





Electrodeposited Zinc-Nickel as an Alternative to Cadmium Plating for Aerospace Application

Author : National Aeronautics and Space Adm Nasa

Publisher : Independently Published

Page : 32 pages

File Size : 17,15 MB

Release : 2019

Category : Science

ISBN : 9781792693229

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Book Description

Corrosion evaluation studies were conducted on 4130 alloy steel samples coated with electrodeposited zinc-nickel and samples coated with electrodeposited cadmium. The zinc nickel was deposited by the selection electrochemical metallizing process. These coated samples were exposed to a 5-percent salt fog environment at 35 plus or minus 2 C for a period ranging from 96 to 240 hours. An evaluation of the effect of dichromate coatings on the performance of each plating was conducted. The protection afforded by platings with a dichromate seal was compared to platings without the seal. During the later stages of testing, deposit adhesion and the potential for hydrogen entrapment were also evaluated. Mcmillan, V. C. Marshall Space Flight Center NASA-TM-103551, NAS 1.15:103551 ...



Electrodeposition of Zinc--nickel Alloys Coatings

Author :

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Page : pages

File Size : 36,37 MB

Release : 1977

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One possible substitute for cadmium in some applications is a zinc--nickel alloy deposit. Previous work by others showed that electrodeposited zinc--nickel coatings containing about 85 percent zinc and 15 percent nickel provided noticeably better corrosion resistance than pure zinc. Present work which supports this finding also shows that the corrosion resistance of the alloy deposit compares favorably with cadmium.



Introduction to Surface Engineering

Author : P. A. Dearnley

Publisher : Cambridge University Press

Page : 798 pages

File Size : 16,8 MB

Release : 2017-01-16

Category : Technology & Engineering

ISBN : 1316785084

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Book Description

This highly illustrated reference work covers the three principal types of surface technologies that best protect engineering devices and products: diffusion technologies, deposition technologies, and other less commonly acknowledged surface engineering (SE) techniques. Various applications are noted throughout the text and additionally whole chapters are devoted to specific SE applications across the automotive, gas turbine engine (GTE), metal machining, and biomedical implant sectors. Along with the benefits of SE, this volume also critically examines SE's limitations. Materials degradation pathways - those which can and those which cannot be mitigated by SE - are rigorously explained. Written from a scientific, materials engineering perspective, this concise text is supported by high-quality images and photo-micrographs which show how surfaces can be engineered to overcome the limits of conventionally produced materials, even in complex or hostile operating environments. This book is a useful resource for undergraduate and postgraduate students as well as professional engineers.



Characterization of Electrodeposited Zn-Ni Alloy Coatings as a Replacement for Electrodeposited Zn and Cd Coatings

Author : Sriraman Kankoduthavanitham Rajagopalan

Publisher :

Page : pages

File Size : 20,34 MB

Release : 2013

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ISBN :

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"Sacrificial metallic coatings, such as those based on Zn and Cd are used to protect steel components against corrosion. Growing environmental and health concerns have limited the use of Cd in any form since Cd plating bath is cyanide based and Cd compounds are carcinogenic. This thesis investigates Zn-Ni as a potential replacement for Cd and Cd based alloy coatings used in aerospace industries and Zn in automotive industries with respect to their tribological, corrosion and tribocorrosion resistance and hydrogen embrittlement susceptibility. In situ tribometry and additional ex situ analyses revealed that Zn-Ni coatings had superior resistance to adhesive wear compared to cadmium coatings. The microhardness of Zn-Ni coatings was higher than Zn and Cd coatings. Hardness on the wear track of Zn-Ni coatings showed the formation of strain hardened tribo layer. Zn-Ni coatings had higher polarization resistance after wear testing as compared to zinc and cadmium coatings. The mass loss due to wear enhanced corrosion was less with Zn-Ni than with Zn and Cd coatings. Zn-Ni coatings are a suitable replacement to Cd coatings when the surfaces are subjected to simultaneous wear and corrosion. Zn-Ni coatings had higher polarization resistance after the 24 hour immersion tests compared to zinc and cadmium coatings. Zn-Ni coatings offer better sacrificial corrosion protection because of low corrosion rates, and are a suitable replacement for Cd coatings. The Passivated Zn-Ni coatings showed lower corrosion resistance when heat treated due to localized damage of passive films while there was no effect of heat treatment on corrosion resistance of as plated Zn-Ni coatings. During the electrodeposition of metals, hydrogen is evolved due to electrolysis. The evolved hydrogen may diffuse outward and become trapped in the substrate/coating interface or migrate inward into the steel lattice causing delayed embrittlement when the component is subjected to stress. This study reports two principal variables for Zn, Zn-Ni, and Cd coatings: (i) quantity of hydrogen absorbed by the coating and substrate, by vacuum thermal desorption (ii) permeability of the coating material to hydrogen, by electrochemical permeation. The findings were analyzed in correlation with microstructural characteristics of both the coating material and the coating/substrate interface. With Zn-Ni, both coating process and coating material combined to significantly reduce the risk of internal hydrogen embrittlement by: (i) introducing the least amount hydrogen during the electrodeposition process, and (ii) by the ease with which hydrogen can be extracted by baking due to the presence of cracks in the coating.Keywords: Zn-Ni, Cd, Cd-Ti, Zn, EIS, insitu tribology, tribocorrosion, hydrogen permeation, TDS" --