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New Generation of Anodizing
1.0 Introduction
The practice of anodizing, or controlled
oxidation, of aluminum and aluminum alloys is more than seven
decades old. The primary intent of anodizing aluminum and
aluminum alloy parts is to protect the highly reactive surface
against corrosion in aqueous environments, such as humid air and
sea water. Because the anodic coating can be produced in a
variety of colors, painted anodized parts are used in
architectural applications. Furthermore, because the anodization
process produces a hard ceramic coating, many times harder than
that of the substrate from which it is formed, anodic coatings
are also used to protect aluminum parts from abrasion,
especially sand abrasion.
2.0 Traditional Anodizing
Traditional anodizing is an
electrochemical oxidation process. The part to be anodized is
connected to the positive terminal of a Direct Current (DC)
power source and a nonreactive metal, such as stainless steel,
is connected to the negative terminal. The aluminum part, or the
anode, and the stainless steel cathode are immersed in an
electrolytic bath and a DC voltage is applied across them. The
potential difference is of the order of 20 -100 V and the
current densities are 1-10 A/dm2.
The electrolytic baths comprise aqueous solutions of chromic
acid, orthophosphoric acid, sulfuric acid, oxalic acid, or
combinations thereof. Because the electrolytic baths have
appreciable resistivity and because the anodization process
itself is exothermic the temperature of the electrolytic bath
increases greatly during anodizing.
Since the anodizing process is quite sensitive to temperature,
the bath temperature is controlled rather closely by heat
exchanger or refrigeration equipment. Today's advanced anodizing
technologies include several proprietary hard anodizing
processes that employ a wide range of electrolyte compositions,
operating conditions and a limited aluminum alloy compositions.
The type and thickness of coating obtained greatly depends on
the composition of the electrolytic bath, operating conditions
and alloy compositions. The military specification MIL-A-8625F,
for example, lists at least six types and two classes of
electrolytically formed anodic coatings on aluminum and aluminum
alloys for non architectural applications.
Despite the many decades of experience and the expensive
equipment employed by the traditional anodizing plants, the acid
bath based DC anodizing process has severe limitations.
- By the very nature of the low voltage DC power employed, the
anodic coating is quite porous. Often the volume percent of
pores is as much as 50%.
- Because of the low current densities
employed, it takes many hours to produce a coating of a few tens
of micrometers thick.
- The electrolytic baths comprise
extremely low pH acidic electrolytes and thus the process does
not meet many of today's environmental regulations. The
expensive equipment, such as the electric power supplies and
heat exchanger, makes the process capital intensive.
- The
traditional process, for reasons not quite apparent, cannot be
used for anodizing aluminum alloys containing high
concentrations of Cu and Si.
- Thus, many aerospace and
automotive parts cannot be satisfactorily anodized, if at all. ·
The present process, while appropriate for a limited range of
the wrought aluminum alloys, cannot be used for anodizing other
reactive metals, such as Ti, Zr, Mg, etc., and intermetallic
compounds and metal matrix composites. Thus, most of the
promising aluminum based advanced alloys and composites cannot
be protected by the traditional anodizing process.
- Above all,
the hardness of even the so called hard anodic coatings is far
below the hardness of alpha alumina, the principal component of
the anodic coating. Accordingly, the full strength potential of
the anodic layer cannot be realized by the traditional process.
- Indeed, the other potentially beneficial properties of
aluminum oxide, such as the high thermal and electrical
resistivities and the high dielectric breakdown strength are not
even addressed.
This state of affairs is primarily due to the porosity of the
coating produced by the traditional acid based electrolytic
processes at low power levels, and to certain extent the poor
bonding between the aluminum alloy substrate and the anodic
layer.
3.0 The Microplasmic Process
In recent years, the Microplasmic
Corporation, a start up R&D company of Peabody, MA, U.S.A. has
developed a unique anodizing technology, called the Microplasmic
Process for all types of aluminum alloys. It is an
electrochemical micro arc oxidation process for which a US
patent is pending. A controlled high voltage AC power is applied
to the aluminum part submerged in an electrolytic bath of
proprietary composition. Due to the high voltage and high
current, intense plasma is created by micro arcing at the
specimen surface and this plasma in turn oxidizes the surface of
the aluminum specimen. Thus the process is called Microplasmic
Process. The oxide film is produced by subsurface oxidation and
considerably thicker coatings can be produced.
Much as the traditional process, the Microplasmic process is an
electrochemical process, but there ends the similarity. The
Microplasmic process is radically different from the traditional
anodizing processes in many respects. The distinguishing
features of the process may be summarized as follows.
- The process employs alkaline electrolytes whose composition is
extremely critical to the coating rate and the properties of the
anodic film that is formed. The pH of the electrolyte is in the
range 8 -12 and is thus environmentally sound.
- The process
employs Alternating Currents at high voltage and high current.
Because of the high voltage, a microplasma surrounds the
electrodes and the oxygen ions produced in the plasma diffuse
through the anodic film into the aluminum substrate to react and
form more anodic film.
- The high voltage and high current allow
the production of anodic films of the same thickness as that of
the traditional process in a fraction of the time.
- Because the
voltages are higher than the breakdown voltage of the film
formed, open channels are not necessary for sustaining the
process and hence dense thick layers of nonporous film can be
readily formed.
- Because the process employs AC power, the
productivity is increased.
- The power from an electrical
utility supply can be used with proper controls to the
electrochemical tank thus making the process less capital
intensive. There is no need for power rectification and waveform
smoothing.
- The temperature of the electrolytic bath need not
be precisely maintained. Indeed, successful coatings can be
obtained even if the temperature excursions are as much as 10-20
oC, further simplifying the process.
- The electrolytic
composition itself is quite variable for different types of
coatings.
- Because of the high density of the coating,
practically there is no change in the dimension of the anodized
part, and a completely finished part can be coated without major
post processing finishing operations. The Microplasmic Process,
however, produces an outer soft coating of about 15% that may be
buffed off; the remaining inner layer, is an extremely hard
ceramic layer.
- Above all, unlike with the traditional
anodization process, aluminum alloy parts of any composition can
be successfully anodized by the Microplasmic Process. Even more
importantly, a variety of ceramic "alloy" coatings, such as
Al2O3.SiO2, Al2O3.MgO, Al2O3..CaO etc. can only be produced by
the Microplasmic Process.
- The Microplasmic Process is also
suited for a hard coating inside surface of a part i.e.
cylindrical, conical or spherical hollow parts. Many coating
processes in the market, like CVD, PVD, IVD, PEPVD, Sputtering,
Thermal Spraying etc. are unable to coat inside surface of a
long part.
4.0 Applications
Because the microplasmic process produces a thick, well bonded
ceramic coating on a variety of reactive light metal alloys, it
can be used for a broad range of applications. The primary
application could be the replacement of heavier metallic alloys
or the more expensive composite materials required by the
aerospace and automotive industries by light metals (e.g., Al,
Ti, Mg, and their alloys) coated by the Microplasmic Process.
Other applications can be divided into the following categories:
Chemical, Mechanical, Thermal, Electrical and Electronics, and
combinations of these.
- Chemical: The ceramic coating can resist both aqueous and
moderately high temperature and is resistant to strong acids and
bases. Thus it can be used in chemical, and food processing
industries.
- Mechanical: The hardness of the film is over 1300
kg/mm2 and thus the film can be used to resist sliding, abrasive
and erosive wear. In addition the friction coefficient is low
and thus can be used in marginally lubricated systems.
- Thermal: The thermal conductivity of the anodic film is much
less than of metals. Thus anodized parts can be used to maintain
uniform distribution of temperature and resist thermal shock.
- Electrical and Electronic: The dielectric breakdown strength of
the Microplasmic film is comparable to that of alpha Al2O3 and
hence can be used as an insulating film on electrical and
electronic components.
Additionally, the Microplasmic Process is also well suited for
hard coating interior surfaces (such as those of hollow
cylindrical and conical parts), recesses, blind holes, threaded
sections, and so on.
Many coating processes in the market, such as Chemical Vapor
Deposition (CVD), Physical Vapor Deposition (PVD), Plasma
Enhanced Physical Vapor Deposition (PEPVD), Sputtering, Thermal
Spraying, etc. are unable to coat the inside surface of a long
part. Thus, where appropriate these expensive coating processes
can be readily replaced by the Microplasmic Process.
Microplasmic Corporation
Contact Information: Microplasmic Corporation 17 Esquire Drive
Peabody, MA, USA Tel (978) 531-9145 Fax (978) 531-3671 Email:
info@microplasmic.com Company Website
http://www.microplasmic.com/ Public Relations Website
http://www.microarcanodizing.com/
About the author:
Jerry Patel: BS degree Mechanical Engineering - Fairleigh
Dickinson University MS degree Engineering Management -
Northeastern University Nannaji Saka, Ph.D: BS - Mechanical
Engineering - Andhra University in India MS - Metallurgical
Engineering - Indian Institute of Technology PH.D - Materials Engineering from -
Department of Materials Science and Engineering at MIT.
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