Coatings and surface engineering. Industry oriented research/Pinnete- ja pinnatehnoloogiaalastest uuringutest.
Veinthal, Renno ; Kulu, Priit ; Zikin, Arkadi 等
1. INTRODUCTION
Basic documents of the European Technology Platform for Advanced
Engineering Materials and Technologies (EuMat) have emphasized a
critical role of competition between companies of advanced engineering
materials including multifunctional materials, materials for extreme
conditions, hybrid and multi-materials. Among them are coatings able to
support the development of new goods and products by radical improvement
in the characteristics of widely used conventional materials, by
substitution of traditional materials with most eco-efficient ones and
by replacement and of rare and/or scarce materials with less critical or
expensive alternatives [1]. Areas of research interest of the Department
of Materials Engineering (DME) of TUT are closely related to the trends
of EuMaT, including coatings and surface engineering, recycling and
reuse.
In many industrial processes such as in crushing, conveying, mixing
and separating in the field of mining, steel and iron industry, cement
industry, coal power plants, overground and underground working,
recycling and environmental protection, the wear of instruments and
other work equipment plays a significant role and also contributes to
the costs. The choice of materials, which can increase wear resistance
of work instruments, is highly important. One successful method for
increasing instrument lifespan is surface treatment. The process of
surface treatment helps to control friction and wear, improve corrosion
resistance and reduce costs [2,3].
One of the most economical methods for surface treatment (to
improve the service life and efficiency of metal parts subjected to
wear) is hardfacing. However, hardfacing by welding is best defined as
the process of deposition by one of the various welding techniques; a
layer or layers of metal of specific properties is deposited on certain
areas of metal parts that are exposed to wear. The possibility to apply
such weld overlay coatings selectively and in different thicknesses to
suit exact requirements makes hardfacing by welding also a very
economical method of combating wear.
The basic research in the field of coating and surface engineering
at DME of TUT has three main targets:
--production of cermet powders, as components of spray powders;
--technology of thermal sprayed, PTA welded and PVD coatings;
--testing and characterization of tribosystems.
2. MAIN RESEARCH AREAS
2.1. Cermet powders for composite coatings
Research in the field of thick hard coatings is oriented to the
production of composite powder coatings based on recycled cermet powders
and commercial Ni- and Fe-based alloy powders and aimed to applications
in such cost-sensitive areas as mining, energy production etc.
To produce the hardmetal/cermet powders from used hardmetal/cermets
parts, the high-energy mechanical milling with a semi-industrial
disintegrator system DS-350 (for preliminary milling) and a laboratory
disintegrator system DSL-175 (for final milling to produce the powder
with particle size of 20-100 [micro]m) was used. Grindability, chemical
composition, particles granularity and angularity were studied by
sieving analysis, laser granulometry, SEM analysis and mathematical
methods [4]. Potential application areas of novel powder compositions
and mixtures for thermal spray have been determined [5,6].
2.2. Thermal spray
Composite coatings, produced by HVOF spraying on the basis of iron
self-fluxing alloy powders with WC-Co reinforcement (ranging from 25 up
to 50 vol%) were studied [5]. Post treatment (laser cladding) was
applied to improve the properties of sprayed coating [6].
The microstructural analysis, mechanical characterization and
tribo-testing (in abrasion, erosion and impact wear conditions) of the
spray fused coatings were performed. For comparison, the nickel
self-fluxing alloy based coatings were studied and advantages of
Fe-based coatings, reinforced by WC-Co hardmetal, were demonstrated
considering the formation of structure with optimal properties (Fig. 1).
Experiments with other reinforcements ([Cr.sub.3][C.sub.2]-Ni and
TiC-NiMo) are in progress, being more prospective for applications at
elevated temperatures.
Plasma transferred arc (PTA) hardfacing process is one of the most
promising and cost-efficient technologies for the production of thick
wear-resistant coatings [7,8]. This technology emerged from the basic
principles used in traditional welding surfacing techniques. Compared to
these processes, PTA hardfacing provides a higher deposition rate and a
relatively low dilution. Also the PTA hardfacing technique allows the
deposition of a wider compositional spectrum of metallic and composite
coatings since the coating consumables used are in powder form and not
in wire or as-cast rod form [7].
Hardfacing by PTA welding is a well-established process, widely
used in industry, offering high range of wear-protective coatings. Most
commonly fabricated coatings are metal matrix composites (MMCs),
consisting of a Ni-, Co- or Fe-based matrix, reinforced with hard
ceramic particles like tungsten carbides. However, high market
requirements lead to permanently increasing prices for WC. Consequently,
high requirements also lead to an increase in the waste of cemented
tungsten carbide. Therefore, research and development of alternative
solutions, such as reusing or recycling hardmetal scraps containing
tungsten carbide, has become important in recent years [8,9]. It has
been shown that hardmetal scrap can also be successfully applied using
PTA hardfacing process, providing good wear resistance [10]. Figure 2
shows a SEM micrograph of recycled WC-Co reinforced hardfacing.
Another common problem, which can occur during PTA hardfacing, is
dissolution of primary carbides. Due to the extremely high temperature
during processing, the carbides are often dissolved in the binder phase
and subsequently recrystallized and re-precipitated [11]. This is
especially true when processing chromium carbides as reinforcements
[12,13]. Such structures can decrease corrosion and wear resistance of
the material, skewing its industrial requirements [11]. Application of
cermet particles can help to overcome the problem of carbide
dissolution, and as a result increase wear and corrosion resistance of
hardfacings [13].
Figure 3 shows the microstructures of [Cr.sub.3][C.sub.2] and
cermet particles ([Cr.sub.3][C.sub.2]-Ni) reinforced hardfacings. The
developed coating is characterized by homogeneous distribution of cermet
particles throughout the matrix, where the [Cr.sub.3][C.sub.2]
reinforced coating consists mostly of re-precipitated spine-like phases.
Based on latest research, it can be outlined that PTA hardfacings
is a very promising approach for the production of new industrially
orientated materials for combating wear. As a result of these studies,
the principles for coatings selection under different abrasive wear
conditions are formulated [14,15].
[FIGURE 2 OMITTED]
[FIGURE 3 OMITTED]
2.3. Physical vapour deposition
In the field of thin hard coatings, physical vapour deposited
coatings (mono-, multilayer and composite coatings of TiN, TiAlN, AlTiN;
nanocoating nACo) and different coating systems (hardmetal-coating, high
speed steel (HSS) coating, nitrided steel coating) were studied.
Different commercial coatings (TiN, TiCN, Ti/AlN and nACo) on WC-Co
substrate with different surface roughness were investigated (Fig. 4).
The relationship between surface roughness, coefficient of friction
(CoF) and wear resistance was clarified. To decrease the droplet phase
on the surface and increase the bonding strength of coatings, a research
for optimization of deposition parameters was performed. Besides the
classical WC-Co hardmetal substrates the PVD coatings on TiC-NiMo
cermets were studied. The properties of coatings (adhesion,
nano-hardness, cracking resistance and surface fatigue) using
indendation methods (Rockwell hardness test, cyclic indentation and
impact wear) were studied and recommendations for the use of coatings
for tooling were proposed [16].
[FIGURE 4 OMITTED]
To extend the application areas of thin hard coatings, the duplex
coatings and duplex treatments (PVD coatings on plasma nitrided steel,
laser hardening of PVD coated surfaces) were considered.
As a result of the research related to thin coatings, the
architecture of different coating systems for different loading
conditions is optimized, the technological parameters of deposition and
other technological means for improving coatings quality and performance
are elaborated and the principles for coatings design and selection for
users (toolmakers) are formulated.
A new area of research is coatings based on carbon-diamond coatings
(DC), as well as diamond-like coatings (DLC) along with carbon
nanofibres (CNF) and/or carbon nanotubes (CNT) reinforced coatings.
2.4. Testing and characterization of tribomaterials
Wear and friction are essential processes for bodies in contact,
experiencing relative motion and these phenomena have to be studied at
different levels ranging from the field test, where the final product is
tested in real life conditions (automobile running on highway, for
example), followed by bench test, subsystem test, component test,
simplified component test and model test, where a piece of material,
from which the component is made, is tested [17].
There is a trend of growing interest toward wear testing at high
temperature, testing of coatings and surface layers at micro- and
nanoscale and development of laboratory test methods enabling testing of
materials or components in conditions close to working ones with a high
level of the test conditions control.
High efficiency of thermal processes in energy applications is
realized at high temperatures and therefore materials are to be
evaluated for these conditions. Devices for studying erosion at
temperatures up to 700 [degrees]C are efficiently used. A new device
with the possibility to introduce protective gases, minimizing
oxidation, is being developed. It allows studying the effect of
oxidation on high temperature erosion rates. Another device has been
developed to study the three-body abrasion at temperatures up to 1000
[degrees]C with the possibility to run an experiment for several days
and test 36 samples simultaneously in two abrasives. A device enabling
sliding and abrasive testing at temperatures up to 450 [degrees]C is
equipped by sensors for measuring coefficient of friction to reveal
effect of additives providing self-lubrication properties.
Innovative coatings increase profitability of tribo-systems
exploiting unique properties of structurally arranged coatings (gradient
and composite structures at nano-level). However, testing of coatings
(especially the thin ones) requires additional precise measurements. In
situations of mild wear, the mass loss is often very small in relation
to the total mass of the worn component. For many machine elements it
can be assumed that the wear appears on an atomic scale. A precision
balance typically has a resolution of [10.sup.-6] of the maximum load
(e.g., 0.1 mg resolution at 100 g load), which naturally sets a limit to
the minimum load possible to quantify in relation to the total weight of
the component. In order to monitor the wear rate, an analytical balance
with repeatability of 0.02 mg, tactile and optical surface measuring
station should be used. A new 3-dimensional optical system with improved
precision has been ordered. A new device for surface fatigue testing is
applied for the assessment of coating resistance to repeatable impacts
(usually [10.sup.3]-[10.sup.7] impacts). A ball cratering device
combined with the micro-abrasion tester is used for measuring the
coating thickness, structure analysis and estimation of wear resistance.
A new device for sliding test in various configurations with controlled
environment (temperature, humidity) has been ordered. The technique
allows single and repeated indentations; single and multi-pass
scratching of the material subjected to as low load as 500 [micro]N is
used for measuring surface layer properties.
A device, enabling adjustment of inertia and rigidity of the
loading system while keeping the load at the same level, is designed and
successfully applied for testing rough coatings for protection of
stamping tools. It also allows measuring vibration parameters (velocity,
acceleration, amplitude) in required directions. The full-scale device
is designed and used for bench tests of chains to study the effect of
chain material, design and test conditions (abrasive, humidity, type of
oil, etc). High-energy disintegrator type impact wear tester is modified
and intensively used to test real components (rock drilling bit inserts,
for example). Centrifugal accelerator is updated to study low angle
(lower than 15[degrees]) erosion that is characteristic of straight
ducts. A drum-type device was built for high-speed sliding wear
conditions with extended length of the wear track, providing time for
restoration of the surface layer between the subsequent sliding events.
Research in the field of residual stresses in materials and
coatings was aimed at the development of the material layer removal
method for the determination of residual stresses and of the method of
residual stresses determination in the multilayered coatings on
cylindrical specimens from an isotropic material (the so-called force
method).
To achieve high impact wear resistance, residual stresses in powder
coatings must be compressive [14]. The residual stresses in PVD coatings
on nickel and steel specimens were determined experimentally (the
residual stresses in mono-layers of Ti, TiN, TiCN, TiAlN, AlTiN and
nACo-(AlTi)N/a-[Si.sub.3][N.sub.4] coatings).
3. Applied research
It has been indicated that despite clear key drivers, large
barriers exist in the application of new technologies. One of the
identified barriers is the lack of understanding between the industrial
and scientific communities, which is also identified as a challenge for
Estonia in general [18].
The improvement of wear resistance of tools by applying
high-technological thin hard coatings is in the scope of interest of
many Estonian metal-working companies and tool-makers. The goal of
applied research is to implement PVD and CVD coatings architecture for
increasing working reliability of cutting tools by studying processes of
advanced coatings pre- and post-treatment and wear mechanisms. Thin hard
coatings are used in many industries, where most important applications
are manufacturing of cutting, punching and forming tools for metal and
wood engineering industries. Perspectives and economic importance of
this research was recently recognized in the study [18] conducted by
Spinverse OY (inducted by the Ministry of Economic Affairs and
Communication) in order to identify the key materials technologies for
Estonian industry. As a result, the Estonian Materials Technology
Program has been launched and a major project "Advanced Thin Hard
coatings in Tooling", concerning the study of wear resistant
materials, coatings and tribological processes, including cutting and
punching tool materials with the development of thin hard coating
architecture, was initiated. As project partners, leading metal-working
companies such as Norma AS, Metaprint OU, Kitman AS, Teratoimituse Eesti
OU and MP & Partners Engineering OU (Trinon) and others are involved
in applied research, performing industrial tests with advanced thin hard
coatings.
Combination of hardmetals and PTA welded coatings, applied to the
parts of soil removal and transfer machines, exposed to abrasive wear is
a competitive solution for several companies producing heavy duty
machinery. An applied research project "WearHard" (also
supported by the Estonian Materials Technology Program) was recently
initiated for the creation of new cost-efficient products with higher
wear resistance, increased service life and new enhanced engineering
designs, by focusing on the research and development of strengthening
technologies, based on recycled hardmetal-based plasma fused coatings
and polymer-ceramic composite materials. Meiren Engineering OU and Paide
Machinery Factory (Paide Masinatehas AS) are involved as project
partners.
doi: 10.3176/eng.2012.3.02
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[18.] Feasibility Study for an Estonian Materials Technology
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Renno Veinthal, Priit Kulu, Arkadi Zikin, Heikki Sarjas, Maksim
Antonov, Vitali Podgurski and Eron Adoberg
Department of Materials Engineering, Tallinn University of
Technology, Ehitajate tee 5, 19086 Tallinn, Estonia;
renno.veinthal@ttu.ee
Received 31 July 2012, in revised form 9 August 2012
Fig. 1. Microstructure of thermal sprayed coatings:
(a) FeCrSiB-20 vol% WC-Co; (b) plasma sprayed laser
remelted selft-fluxing alloy NiCrSiB -20 vol%
(WC-Co) coating.
(a)
Phase areas Area, %
Fe 8.7%
FeCr 30.34%
WC-Co 60.56%
(b)
Phase areas Area, %
W-Ni 15.22%
Fe-Ni 21.97%
Ni 9.52%
Fe-Ni-Cr-Co 42.85%
Note: Table made from bar graph.
