Introduction: Thermal Spray Coatings and their Historical Developments
Page: 1-24 (24)
Author: Shashi Kant*
DOI: 10.2174/9789815223552124010003
PDF Price: $15
Abstract
Thermal spray coatings are a method of surface modification in which
various metallic and non-metallic materials are sprayed in molten, semi-molten, or
even solid state on a prepared substrate. The coating material is present in two forms:
wire or powder. The most common thermal spraying techniques include cold spray,
electric arc spray, plasma spray, detonation gun spray, flame spray, and high-velocity
oxy-fuel spray. The coating's thickness, which is calculated in millimeters or microns
and has distinguishing features from the base material's surface, is acceptable in many
industrial sectors and is ideal for on-site industrial applications. These processes also
offer affordable solutions in many industrial sectors and are capable of providing
surface modification approaches with enhanced surface properties comprising better
texture and high mechanical strength in terms of hardness, scratch resistance, and
porosity. This chapter presents the evolution of coatings developed during the last few
decades using various coating processes and materials for the protection of service
components. Coating measures are developed for use in thermal power plants, gas
steam, and the automotive industry for the treatment of components, able to work in
harsh environments of flue gases and chemicals.
Comprehensive Study on Production Methods and Applications of Functionally Graded Coatings
Page: 25-42 (18)
Author: Abhishek Attal, Santosh Kumar* and Virat Khanna
DOI: 10.2174/9789815223552124010004
PDF Price: $15
Abstract
Surface modification of metal substrates by coatings has remained a
challenging research topic because of the conflicting demands for various properties.
Functionally graded coatings (FGCs) have recently attracted the attention of
researchers all over the globe owing to their mechanical, electrical, thermal and
tribological characteristics in a variety of advanced engineering applications. These
coatings are usually characterized by low porosity, good adhesion and base material
compatibility, which includes temperature and geometry. However, coatings often
experience some problems like variable thermal expansion coefficient (TEC) as
compared to their base metals. Thus, to overcome this issue, the functionally graded
material (FGM) layers may be employed. Hence, the purpose of this chapter is to
describe a general idea of FGM coatings, including classifications of production
methods and their diverse applications
Reliable Surface Modification Techniques
Page: 43-75 (33)
Author: Swarn Singh, Santosh Kumar*, Virat Khanna and Harvinder Singh
DOI: 10.2174/9789815223552124010005
PDF Price: $15
Abstract
Loss of material due to corrosion, erosion, wear and oxidation is a major
problem in various industries. Recently, various surface modification methods have
been employed to improve the service life of distinct engineering parts by improving
their resistance to corrosion, wear and erosion. These methods boost thermal and
biocompatibility in addition to the mechanical and physical qualities. To offer a
thorough review of surface modification techniques, including mechanical, chemical,
and thermal procedures, this chapter has three main objectives. Overall, this chapter
provides a detailed study on working principles, merits, demerits, and applications of
various surface modification techniques.
Recent Trends in Coatings
Page: 76-95 (20)
Author: Shashi Kant*
DOI: 10.2174/9789815223552124010006
PDF Price: $15
Abstract
With the demand for high-fidelity coating involving metallic, multilayer,
protective, and ceramic-based coatings, deposition methods have been introduced to
achieve quality coatings. High temperatures cause erosion-corrosion wear, oxidation,
and hot corrosion in materials operating in corrosive conditions. Among the various
methods used to protect surfaces from deterioration, the method of applying coatings
by high-velocity oxy-fuel spraying deserves special mention because it creates coatings
with increased hardness and resilience, low (less than 1%) porosity, and high erosioncorrosion and wear resistances. Deposition of these coatings using a typical thermal
spray process finds applications in the protection of base material in automobile,
aerospace, orthopaedic, thermal power plant, and gas pipeline sectors. We present the
potentials of the coatings and their respective protective properties. This chapter
provides the optimization and overviews of the use of various recently used coating
materials developed for the application in automotive, power plant, defence, gas and
steam, and orthopaedic sectors.
High-temperature Corrosion of Coal-based Thermal Power Plants, Gas Turbines, and Steam Turbines
Page: 96-126 (31)
Author: Ashish Kumar, Santosh Kumar* and Rupinder Singh
DOI: 10.2174/9789815223552124010007
PDF Price: $15
Abstract
Hot corrosion is a critical challenge in the designing and functioning of
coal-based power plants, gas turbines and steam turbines. The economic loss due to hot
corrosion is very high. Many researchers are working to combat hot corrosion, but only
a few researchers have reduced hot corrosion to some extent by various surface
modification techniques. However, coatings deposited by the thermal spray process
offer better results in combating hot corrosion. Thermal spray techniques are a
promising way to apply dense, defect-free adherent coatings to components, increasing
both their performance and lifetime. Thus, the core objective of this chapter is to
provide a review of different thermal spray coating methods, coating materials,
advantages, and disadvantages. Finally, the most recent industrial advances in thermal
spray technologies to combat corrosion in high-temperature applications are provided.
Corrosion, Wear, Erosion, and Abrasion in Hydropower Plants by Thermal Spray Coatings
Page: 127-158 (32)
Author: Harvinder Singh*, Manoj Kumar, Satish Kumar and Swarn Singh
DOI: 10.2174/9789815223552124010008
PDF Price: $15
Abstract
Hydropower plants, thermal power plants, offshore, chemical, food
processing, oil sectors, etc., all have difficulties with erosion, abrasion, and corrosion
regularly. These issues impact a variety of hydraulic equipment and pipeline circuit
components (pipelines, elbows, reducers, separators, tees, and seals). One application
where these three issues consistently arise is a hydropower plant. However, one of the
main issues with Indian hydropower facilities is silt erosion in the hydro-turbines and
their parts. Hard particles like quartz, feldspar, and other minerals may be found in
Indian rivers. More than 50% of the quartz in the silt contributes to several issues with
hydro-turbines, including sediment erosion, leaky flow, disruptions in secondary flow,
etc. As a result, these issues have an impact on the hydro-power plant's overall
performance. The numerous failures of the components placed in hydropower facilities'
impulse and response turbines are discussed in this chapter. Additionally, this chapter
provides information on different turbine materials and their characteristics. Based on
silt characteristics, material properties, and flow phenomena in various hydro-turbines,
several numerical models of erosion abrasion are addressed. Different thermal spraying
methods for turbine materials are compared and contrasted. To regulate wear and
safeguard hydro-turbines, this chapter reviews the literature on wear mechanisms,
models, pilot plant loops or rigs/testers, and protective strategies.
Overview of Corrosion in Medical Devices and Detection Methods
Page: 159-193 (35)
Author: Rakesh Kumar*, Pradeep Kumar, Arvind Kumar and Jatinder Kumar
DOI: 10.2174/9789815223552124010009
PDF Price: $15
Abstract
Corrosion is a major issue that can cause implant failure, leading to adverse
reactions in the surrounding tissue and sometimes causing systemic complications.
Several researchers are currently exploring ways to enhance the corrosion resistance of
orthopedic implants, which is essential to improve their performance and longevity.
The most common strategies used to enhance the corrosion resistance of orthopedic
implants are selecting corrosion-resistant materials, surface treatments, coatings, and
improved implant design. Surface treatments, such as passivation, anodization, and
micro-arc oxidation, can also create a thin oxide layer on the surface of implants to act
as a barrier against corrosion. Coatings (hydroxyapatite, diamond-like carbon, metal
oxide coatings) and good implant design can also be used to provide a protective
barrier and alter the surface chemistry. Further research can be focused on developing
new materials and surface treatments that are more corrosion-resistant, as well as
advanced implant designs that can minimize stress concentrations and enhance load
distribution. By implementing these strategies, orthopedic implants can provide better
treatment for patients with a higher level of safety and efficacy. This chapter mainly
focuses on corrosion types, causes, merits, demerits, corrosion detection methods and
remedial actions.
Enhancement of Corrosion and Biocompatibility of Implants by Thermal Spray Coatings
Page: 194-223 (30)
Author: Rakesh Kumar*, Manoj Kumar and Santosh Kumar
DOI: 10.2174/9789815223552124010010
PDF Price: $15
Abstract
In the recent era, distinct metallic materials such as titanium, stainless steel,
titanium alloys, and Co-Cr alloy are widely used for implant manufacturing. But for
successful implantation, these biomaterials require good biocompatibility, corrosion
resistance, low elastic modulus, which is required closer to actual human bone, high
strength, and non-cytotoxic. These biomaterials have primarily been used in specific
applications such as orthopaedic fixation devices, dental implants, and cardiovascular
stents. The corrosion of metal implants, on the other hand, determines the service
period of implantation due to the release of incompatible metal ions into the human
body, which may cause allergic reactions. As a result, the focus of this chapter is
initially on metal biomaterials and their properties. The causes of implant failure are
then highlighted, with a focus on corrosion mechanism details. Finally, various surface
modification techniques, such as thermal-based surface modification techniques, are
discussed in detail, as are their applications in improving corrosion resistance,
biocompatibility, and osseointegration of various biomaterials.
Overview of Orthopedic Implant Materials and Associated Problems
Page: 224-249 (26)
Author: Rakesh Kumar*, Meghul Kumar, Mohit Kumar, Gaurav Luthra and Geetesh Goga
DOI: 10.2174/9789815223552124010011
PDF Price: $15
Abstract
Orthopedic Implant is a high-risk medical device. Its main function is
stabilization and fixation of bone but some are functional devices like hip arthroscopy,
knee joint replacement implants, spinal cages, etc. Some common materials used to
manufacture implants are Titanium, Titanium alloy (Ti6Al4V) as per ISO 5832-3,
Stainless Steel-316 as per ISO 5832-1, tantalum, bioabsorbable material like PLLA,
PGA, PLDLA, etc. The implant should have some fundamental properties such as
being biocompatible, corrosion resistant, and having good mechanical properties.
Though the implants have these properties, some complications like bacterial adhesion
cause infection, poor osseointegration, and loosening of the implant. To overcome
these complications, one of the effective and simple solutions is coating. The coating
can enhance osseointegration, reduce infection, increase bone ingrowth and mechanical
strength, etc. The coating of a material with desirable properties over the implant is a
tough and complex process. The antibacterial coating materials are chitosan,
gentamicin, Rifampicin, Titanium oxide, etc. Similarly, the coating material for
osseointegration is hydroxyapatite (HA), extracellular matrix (ECM), magnesium
coating, etc. There are different technique for coating materials like the Dip-Coating
method, magnetron sputtering, sol-gel technique, electrophoretic deposition, etc.
Although coating is the most effective way to overcome some above-mentioned
complications, most of the implants are sold on the market without coating. Coating is
a complicated and costly process. It is still in its niche in research and development,
however, it has a lot of potential for the future. Hence, in this chapter, the author
mainly focuses on orthopedics implant materials, associated problems, and distinct
coating materials techniques, which are discussed in detail.
Cold Spray Coating of Nano Crystallization Material, Method, Properties and Challenges: A Critical Review
Page: 250-274 (25)
Author: Satish Kumar, Santosh Kumar*, Harvinder Singh and Rahul Mehra
DOI: 10.2174/9789815223552124010012
PDF Price: $15
Abstract
In the 1980s, a deposition technique known as cold spray solid-state coating
was created. Cold spray technology, unlike conventional thermal spray techniques, can
maintain the natural properties of the feedstock, prevent damage to the constituent
elements of the substrate and create extremely solid coatings. Nanostructured coatings
have the potential to significantly enhance their properties compared to conventional,
non-nanostructured coatings. Furthermore, surface coating on metal substrates is a very
difficult challenge for the researcher due to the contradictory requirements for various
properties. The ability of cold spray to form coatings with nanostructures has also been
demonstrated to a great extent. This work aims to provide an in-depth analysis of
nanostructured cold-sprayed metal coatings. First, a description of the cold spray
technique is given. Next, the issue of Nano crystallization in standard metal coatings is
discussed. Then, microstructures and properties of nanomaterial-reinforced metal
matrix composite (MMC) coatings and cold-sprayed nanocrystalline metal coatings are
discussed. In conclusion, a summary and future prospects for cold spray technology are
given. To conclude, the process of developing nanostructured metal coatings has been
completed.
Subject Index
Page: 275-280 (6)
Author: Santosh Kumar and Virat Khanna
DOI: 10.2174/9789815223552124010015
Introduction
This comprehensive book explores the techniques, materials, and real-world applications of thermal spray coatings across various industries, including power generation, aerospace, medical, and automotive sectors. Readers will learn about the basic science and engineering aspects of thermal spray technology, its historical developments, and the diverse range of materials used, from metallic to ceramic materials, and nano-crystallization materials. Distinct thermal spray techniques are explained (flame spray, detonation-gun spray, high-velocity oxy-fuel spray, electric arc spray, plasma spray and cold spray). Chapters on advanced topics also give an understanding of crucial material properties such as high temperature corrosion, oxidation, erosion or wear resistance, and biocompatibility. Key features - Contributions from materials science experts with references for each topic - Gives a comprehensive overview of materials and distinct spray techniques used in thermal coatings - Dedicated chapters for applications of thermal coatings in different industries - Covers recent trends and new advances such as surface modification techniques to improve functionality and performance This book is intended as a resource for an in-depth understanding of the fundamentals and applications of thermal spray coatings for students, professionals and researchers in materials science and chemical engineering disciplines.