ALLOYS AND COMPOSITE MATERIALS
ALLOYS AND
COMPOSITE MATERIALS
Department of
Mechanical Engineering
MEA-SY
(01)Aayush Singh 11911345
(11)Rohan Arwari 11910498
(14)Atharva Yewale 11911264
(17)Harsh Baheti 11910928
Instructor: Prof. Rahul Waikar
Course: Mechanical and System
Engineering
Date: 07/12/2020
Alloy –
·
An alloy is
a combination of metals or metals combined with one
or more other elements.
·
An alloy may be
a solid solution of metal elements (a single
phase, where all metallic grains (crystals) are of the same composition) or
a mixture of metallic phases (two or more solutions, forming
a microstructure of different crystals within the metal).
History of Alloy –
Bronze, an alloy of copper and tin, was the first alloy discovered,
during the prehistoric period now known as the Bronze Age.
Characteristics of Alloy –
·
An alloy is a mixture or
metallic solid solution composed of two or more elements.
·
An alloy’s properties are
usually different from those of its component elements.
·
Alloy constituents are usually
measured by mass.
·
Unlike pure metals, most
alloys do not have a single melting point; rather, they have a melting range in
which the substance is a mixture of solid and liquid.
·
Examples of alloys include
materials such as brass, pewter, phosphor bronze, amalgam, and steel.
·
Complete solid solution alloys
give single solid phase microstructure. Partial solutions give two or more
phases that may or may not be homogeneous in distribution, depending on thermal
history. An alloy’s properties are usually different from those of its
component elements.
·
Alloy constituents are usually
measured by mass.
·
An alloy is usually classified
as either substitutional or interstitial, depending on its atomic arrangement.
·
In a substitutional alloy, the
atoms from each element can occupy the same sites as their counterpart.
·
In interstitial alloys, the
atoms do not occupy the same sites. Alloys can be further classified as
homogeneous (consisting of a single phase), heterogeneous (consisting of two or
more phases), or intermetallic (where there is no distinct boundary between
phases).
·
Unlike pure metals, most
alloys do not have a single melting point; rather, they have a melting range in
which the substance is a mixture of solid and liquid. However, for most alloys,
there is one particular proportion of constituents, known as the “eutectic
mixture,” at which the alloy has a unique melting point.
How is Alloying Done?
·
Alloying a metal is done by combining it with one or more other
elements.
·
The most common and oldest alloying process is performed by heating the
base metal beyond its melting point and then
dissolving the solutes into the molten liquid, which may be possible even if
the melting point of the solute is far greater than that of the base.
·
For example, in its liquid state, titanium is a very strong
solvent capable of dissolving most metals and elements. In addition, it readily
absorbs gases like oxygen and burns in the presence of nitrogen. This increases
the chance of contamination from any contacting surface, and so must be melted
in vacuum induction-heating and special, water-cooled, copper crucibles.
·
However, some metals and solutes, such as iron and carbon, have very
high melting-points and were impossible for ancient people to melt. Thus,
alloying (in particular, interstitial alloying) may also be performed with one
or more constituents in a gaseous state, such as found in a blast furnace to
make pig iron (liquid-gas), nitriding, carbonitriding or
other forms of case hardening (solid-gas),
or the cementation process used
to make blister steel (solid-gas).
·
It may also be done with one, more, or all of the constituents in the
solid state, such as found in ancient methods of pattern welding (solid-solid), shear steel (solid-solid),
or crucible steel production
(solid-liquid), mixing the elements via solid-state diffusion.
Types of Alloys
–
There are basically four
different types of alloys:
·
Aluminium Alloys – Although aluminium alone isn’t the strongest metal, it is used in
combination with other metals to create conductive, heat, and tarnish resistant
alloys. Aluminium is used in many essential mechanical components including car
engines, airplane body panels, and boat hulls.
·
Nickel Alloys – When Nickel and other metals come in contact with specific chemicals,
they react in a way that produces electricity. This process has been harnessed
in batteries worldwide and continuing research in the field has led to the
promise of electric cars.
·
Stainless Steel Products – All steel alloys are actually made from iron and carbon. The carbon
prevents the iron from oxidizing. Chromium and Nickel are added as well to
produce stainless steel. There are four classes of alloy steel: structural
steels, magnetic alloys, tool and die steels, and heat-resisting stainless
steel. Consumers are very familiar with the last type since refrigerators,
sinks, forks, knives, and my other products are made from stainless steel.
·
Gold Alloys –
Many different types of jewellery that’s ‘gold’ isn’t actually pure gold, but
actually an alloy. That’s because gold is incredibly malleable, making it next
to impossible to form durable jewellery with. Gold itself is used in
manufacturing electronics due to the same malleability and because it is
electrically conductive.
Chemical
Reactions of Alloys –
·
A
chemical reaction between Au25 and Ag44 in solution will give rise to alloys of
AgAu and AuAg composition. The reaction can be represented as:
Au25
+ Ag44 → AgAu24 + AuAg43
Alloy Examples –
Examples of alloys include stainless steel, brass, bronze, white gold,
18k gold, and sterling silver. Although exceptions exist, most alloys are
named for their primary or base metal, with an indication of other elements in
order of mass percent.
·
Stainless Steel: Iron alloy, which typically contains chromium, nickel, and other elements
to resist rust or corrosion.
·
Steel: The
name given to an alloy of iron with carbon, usually with other elements, such
as nickel and cobalt. The other elements add a desired quality to the steel,
such as hardness or tensile strength.
·
Brass: a
mixture of copper with zinc and sometimes other elements. Brass is hard and
durable, making it suitable for plumbing fixtures and machined parts.
·
Bronze: is an alloy consisting primarily of copper, commonly with about
12–12.5% tin and often with the addition of other metals and sometimes
non-metals or metalloids such as arsenic, phosphorus or silicon. These
additions produce a range of alloys that may be harder than copper alone, or
have other useful properties, such as stiffness, ductility, or machinability.
·
18k Gold: this is 75% gold. The other elements typically
include copper, nickel, or zinc. This alloy retains the colour and lustre of
pure gold, yet is harder and stronger, making it better suited for jewellery.
·
Sterling Silver: is 92.5% silver with copper and other metals.
Alloying silver makes it harder and more durable, although the copper tends to
lead to greenish-black oxidation (tarnish).
·
Electrum: Some alloys, like electrum, occur naturally. This
alloy of silver and gold was highly prized by ancient man.
·
Meteoritic Iron: While meteorites may consist of any number of
materials, some are natural alloys of iron and nickel, with extra-terrestrial
origins. These alloys were used by ancient cultures to make weapons and tools.
·
Amalgams: These are mercury alloys. The mercury makes the alloy
much like a paste. Amalgams may be used in dental fillings, with the
mercury intact, although another use is to spread the amalgam and then heat it
to vaporize the mercury, leaving a coating of another metal.
·
Pewter: an alloy of tin, with other elements such as copper,
lead, or antimony. The alloy is malleable, yet stronger than pure tin, plus it
resists the phase change of tin that can make it crumble at low temperatures.
Common Alloys and their Applications –
|
Alloy |
Composition |
Applications |
|
Babbitt Metal |
Tin: 90%, Antimony: 7%, & Copper: 3% |
Used in bearings due to its low measure of friction
with steel |
|
Bell Metal |
Copper: 77% & Tin: 23% |
Casting of bells |
|
Brass |
Mainly Copper with up to 50% Zinc |
Inexpensive Jewellery, hose nozzles & couplings |
|
Bronze |
Mainly Copper with up to 12% Tin |
Coins & medals, heavy gears, tools electrical
hardware |
|
Coin Metal |
|
Used in USA for making coins |
|
Duralumin |
Aluminium: 95%, Copper: 4%, Manganese < 1%,
Magnesium: 0.5% |
Aircraft, boats, railroad cars, and machinery
because of its high strength and resistance to corrosion |
|
Gun Metal |
Copper: 85 – 90%, Tin: 8 – 12% & Zinc: 1 – 3% |
|
|
Monel |
Nickel: 60%, Copper: 33% & Iron: 7% |
Corrosion-resistant containers |
|
Phosphor Bronze |
Bronze with a small amount of phosphorus |
Springs & boat propellers |
|
Solder Metal |
Lead: 50% & Tin: 50% |
Joining two metal to each other |
|
Sterling Silver |
Silver: 92.5% & Copper: 7.5% |
Jewellery & art objects |
|
Type Metal |
Lead: 75-95%, Antimony: 2-18% & Tin in trace
quantities |
Used to make type characters for printing, also used
to make decorative objects like statuettes and candlesticks |
Composite Material –
·
A composite
material is a combination of two materials with different physical and chemical
properties.
·
When they are
combined they create a material which is specialized to do a certain job, for
instance to become stronger, lighter or resistant to electricity. They can
also improve strength and stiffness.
·
The reason
for their use over traditional materials is because they improve the
properties of their base materials and are applicable in many situations.
History of Composite Material –
·
In 3400 B.C the
first composites were engineered by the Mesopotamians in Iraq.
·
Following this, in
around 2181 B.C the Egyptians started to make death masks out of linen or
papyrus soaked in plaster.
·
In 1200 A.D, the
Mongols began to engineer composite bows which were incredibly effective at the
time.
·
In the 1900s this
new-found knowledge about chemicals led to the creation of various plastics
such as polyester, phenolic and vinyl.
·
The 1930s was an
incredibly important time for the advancement of composites. Glass fibre was
introduced by Owens Corning who also started the first fibre reinforced polymer
(FRP) industry.
·
The
composites on a Boeing 787 Dreamliner in the mid-2000s substantiated
their use for high strength applications.
Types of Composite Material –
Some common composite materials include:
- Ceramic
matrix composite: Ceramic spread out in a ceramic
matrix. These are better than normal ceramics as they are thermal shock
and fracture resistant.
- Metal matrix
composite:
A metal spread throughout a matrix.
- Reinforced
concrete:
Concrete strengthened by a material with high tensile strength such as
steel reinforcing bars.
- Glass fibre
reinforced concrete: Concrete which is poured into a glass fibre
structure with high zirconia content.
- Translucent
concrete:
Concrete which encases optic fibres.
- Engineered
wood:
Manufactured wood combined with other cheap materials. One example would
be particle board. A specialty material like veneer can also be found in
this composite.
- Plywood: Engineered
wood by gluing many thin layers of wood together at different angles.
- Engineered
bamboo:
Strips of bamboo fibre glued together to make a board. This is a useful
composite due to the fact it has higher compressive, tensile and flexural
strength than wood.
- Parquetry: A square of
many wood pieces put together often out of hardwood. It is sold as a
decorative piece.
- Wood-plastic
composite:
Either wood fibre or flour cast in plastic.
- Cement-bonded
wood fibre:
Mineralized wood pieces cast in cement. This composite has insulating and
acoustic properties.
- Fiberglass: Glass fibre
combined with a plastic which is relatively inexpensive and flexible.
- Carbon Fibre
reinforced polymer: Carbon fibre set in plastic which has a
high strength-to-weight ratio.
- Sandwich
panel:
A variety of composites that are layered on top of each other.
- Composite
honeycomb:
A selection of composites in many hexagons to form a honeycomb shape.
- Papier-Mache: Paper bound
with an adhesive. These are found in crafts.
- Plastic
coated paper:
Paper coated with plastic to improve durability. An example of where this
is used is in playing cards.
- Syntactic
foams:
Light materials created by filling metals, ceramics or plastics with micro
balloons. These balloons are made using either glass, carbon or plastic.
Advantages of Composite Material
–
·
Low costs compared to
metals
·
Design Flexibility
·
Resistance to a wide
range of chemical agents
·
Low Weight
·
Durability
·
Electric Insulation
·
High impact strength
Why use
Composites?
·
Weight saving
is one of the main reasons for using composite materials rather than
conventional materials for components. While composites are lighter they can
also be stronger than other materials, for example, reinforced carbon-fibre can
be up to five times stronger than 1020 grade steel and only one fifth of the
weight, making it perfect for structural purposes.
·
Another
advantage of using a composite over a conventional type of material is the
thermal and chemical resistance as well as the electrical insulation
properties. Unlike conventional materials, composites can have multiple
properties not often found in a single material.
·
Fibre
reinforced composites, such as fibre reinforced plastic (FRP composites), are
finding increasing use in the design and manufacture of final products for
commercialization.
Examples of Composite Uses –
- Electrical equipment
- Aerospace structures
- Infrastructure
- Pipes and tanks
- Homes can be framed using plastic
laminated beams
thanks Meghaj
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