A cloth of woven carbon fiber filaments, a common element in composite materials
Composite materials (or composites for short) are engineered materials made
from two or more constituent materials with significantly different physical or chemical properties and which remain separate and
distinct on a macroscopic level within the finished structure.
Background
Plywood is a common composite material many people encounter in their everyday life
The most primitive composite materials comprised straw and mud in
the form of bricks for building construction; the Biblical book of
Exodus speaks of the Israelites being oppressed by
Pharaoh, by being forced to make bricks without
straw. The ancient brick-making process can still be seen on Egyptian tomb
paintings in the Metropolitan Museum of Art[1]. The most advanced examples
perform routinely on spacecraft in demanding environments. The most visible applications pave our roadways in the form of either
steel and aggregate reinforced portland cement or asphalt concrete. Those composites closest to our personal hygiene form our shower stalls and bath tubs
made of fiberglass. Solid surface, imitation granite and cultured marble sinks and counter
tops are widely used to enhance our living experiences.
There are two categories of constituent materials: matrix and reinforcement. At least one portion of each type is required.
The matrix material surrounds and supports the reinforcement materials by maintaining their relative positions. The
reinforcements impart their special mechanical and physical properties to enhance the matrix properties. A synergism produces
material properties unavailable from the individual constituent materials, while the wide variety of matrix and strengthening
materials allows the designer of the product or structure to choose an optimum combination. Engineered composite materials must
be formed to shape. The matrix material can be introduced to the reinforcement before or after the reinforcement material is
placed into the mold cavity or onto the mold surface. The matrix material experiences a melding event, after which the part shape
is essentially set. Depending upon the nature of the matrix material, this melding event can occur in various ways such as
chemical polymerization or solidification from the melted state.
A variety of molding methods can be used according to the end-item design requirements. The principal factors impacting the
methodology are the natures of the chosen matrix and reinforcement materials. Another important factor is the gross quantity of
material to be produced. Large quantities can be used to justify high capital expenditures for rapid and automated manufacturing
technology. Small production quantities are accommodated with lower capital expenditures but higher labor and tooling costs at a
correspondingly slower rate.
Most commercially produced composites use a polymer matrix material often called a resin solution. There are many different
polymers available depending upon the starting raw ingredients. There are several broad categories, each with numerous
variations. The most common are known as polyester, vinyl
ester, epoxy, phenolic, polyimide, polyamide, polypropylene,
PEEK, and others. The reinforcement materials are often fibers but also commonly ground
minerals.
Molding methods
In general, the reinforcing and matrix materials are combined, compacted and processed to undergo a melding event. After the
melding event, the part shape is essentially set, although it can deform under certain process conditions. For a thermoset
polymeric matrix material, the melding event is a curing reaction that is initiated by the application of additional heat or
chemical reactivity such as an organic peroxide. For a thermoplastic polymeric matrix material, the melding event is a
solidification from the melted state. For a metal matrix material such as titanium foil, the melding event is a fusing at high
pressure and a temperature near the melt point.
For many molding methods, it is convenient to refer to one mold piece as a "lower" mold and another mold piece as an "upper"
mold. Lower and upper refer to the different faces of the molded panel, not the mold's configuration in space. In this
convention, there is always a lower mold, and sometimes an upper mold. Part construction begins by applying materials to the
lower mold. Lower mold and upper mold are more generalized descriptors than more common and specific terms such as male side,
female side, a-side, b-side, tool side, bowl, hat, mandrel, etc. Continuous manufacturing processes use a different
nomenclature.
The molded product is often referred to as a panel. For certain geometries and material combinations, it can be referred to as
a casting. For certain continuous processes, it can be referred to as a profile.
Open molding
A process using a rigid, one sided mold which shapes only one surface of the panel. The opposite surface is determined by the
amount of material placed upon the lower mold. Reinforcement materials can be placed manually or robotically. They include continuous fiber forms fashioned into textile constructions and chopped fiber. The matrix is generally a resin, and can
be applied with a pressure roller, a spray device or manually. This process is generally done at ambient temperature and atmospheric pressure. Two
variations of open molding are Hand Layup and Spray-up.
A process using a two-sided mold set that shapes both surfaces of the panel. On the lower side is a rigid mold and on the
upper side is a flexible membrane. The flexible membrane can be a reusable silicone material or an extruded polymer film such as nylon. Reinforcement materials can be placed on the lower mold manually or robotically,
generally as continuous fiber forms fashioned into textile constructions. The matrix is generally a resin. The fiber form may be
pre-impregnated with the resin in the form of prepreg fabrics or unidirectional tapes. Otherwise, liquid matrix material is
introduced to dry fiber forms prior to applying the flexible film. Then, vacuum is applied to the mold cavity. This process can
performed at either ambient or elevated temperature with ambient atmospheric pressure acting upon the vacuum bag. Most economical
way is using a venturi vacuum and air compressor or a vacuum pump.
A process using a two-sided mold set that forms both surfaces of the panel. One the lower side is a rigid mold and on the
upper side is a flexible membrane made from silicone or an extruded polymer film such as nylon. Reinforcement materials can be
placed manually or robotically. They include continuous fiber forms fashioned into textile constructions. Most often, they are
pre-impregnated with the resin in the form of prepreg fabrics or unidirectional tapes. In some instances, a resin film is placed
upon the lower mold and dry reinforcement is placed above. The upper mold is installed and vacuum is applied to the mold cavity.
Then, the assembly is placed into an autoclave pressure vessel. This process is
generally performed at both elevated pressure and elevated temperature. The use of elevated pressure facilitates a high fiber
volume fraction and low void content for maximum structural efficiency.
Resin transfer molding
A process using a two-sided mold set that forms both surfaces of the panel. The lower side is a rigid mold. The upper side can
be a rigid or flexible mold. Flexible molds can be made from composite materials, silicone or extruded polymer films such as
nylon. The two sides fit together to produce a mold cavity. The distinguishing feature of resin transfer molding is that the
reinforcement materials are placed into this cavity and the mold set is closed prior to the introduction of matrix material.
Resin transfer molding includes numerous varieties which differ in the mechanics of how the resin is introduced to the
reinforcement in the mold cavity. These variations include everything from vacuum infusion to vacuum assisted resin transfer
molding. This process can be performed at either ambient or elevated temperature.
Other
Other types of molding include press molding, transfer molding, pultrusion molding, filament winding, casting, centrifugal casting and
continuous casting.
Tooling
Some types of tooling materials used in the manufacturing of composites structures include invar, steel, aluminum, reinforced
silicon rubber, nickle, and
carbon fiber. Selection of the tooling material is typically based on, but not limited to,
the coefficient of thermal expansion, expected number of cycles, end
item tolerance, desired or required surface condition, method of cure, glass
transition temperature of the material being molded, molding method, matrix, cost and a variety of other
considerations.
Mechanics of composite materials
The physical properties of composite materials are generally not isotropic in nature, but
rather are typically orthotropic. For instance, the stiffness of a composite panel will
often depend upon the directional orientation of the applied forces and/or moments. Panel stiffness is also dependent on the
design of the panel. For instance, the fiber reinforcement and matrix used, the method of panel build, thermoset versus
thermoplastic, type of weave, and orientation of fiber axis to the primary force.
In contrast, isotropic materials (for example, aluminium or steel), in standard wrought forms, typically have the same
stiffness regardless of the directional orientation of the applied forces and/or moments.
The relationship between forces/moments and strains/curvatures for an isotropic material can be described with the following
material properties: Young's Modulus, the Shear
Modulus and the Poisson's ratio, in relatively simple mathematical relationships.
For the anisotropic material, it requires the mathematics of a second order tensor and can require up to 21 material property
constants. For the special case of orthogonal isotropy, there are three different material property constants for each of Young's
Modulus, Shear Modulus and Poisson's Ratio for a total of 9 material property constants to describe the relationship between
forces/moments and strains/curvatures.
Categories of fiber reinforced composite materials
Fiber reinforced composite materials can be divided into two main categories normally referred to as short fiber reinforced
materials and continuous fiber reinforced materials. Continuous reinforced materials will often constitute a layered or laminated
structure. The woven and continuous fiber styles are typically available in a variety of forms, being pre-impregnated with the
given matrix (resin), dry, uni-directional tapes of various widths, plain weave, harness satins, braided, and stitched.
The short and long fibers are typically employed in compression molding and sheet molding operations. These come in the form
of flakes, chips, and random mate (which can also be made from a continuous fiber laid in random fashion until the desired
thickness of the ply / laminate is achieved).
Failure of Composites
Shock, impact, or repeated cyclic stresses can cause the laminate to separate at the interface between two layers, a condition
known as delamination. Individual fibers can separate from the matrix e.g. fiber
pull-out.
Composites can fail on the microscopic or macroscopic
scale. Compression failures can occur at both the macro scale or at each individual reinforcing fiber in compression buckling.
Tension failures can be net section failures of the part or degradation of the composite at a microscopic scale where one or more
of the layers in the composite fail in tension of the matrix or failure the bond between the matrix and fibers.
Some composites are brittle and have little reserve strength beyond the initial onset of failure while others may have large
deformations and have reserve energy absorbing capacity past the onset of damage. The variations in fibers and matrices that are
available and the mixtures that can be made with blends leave a very broad range of properties that can be designed into a
composite structure.
Examples of composite materials
Fiber Reinforced Polymers or FRPs include Wood comprising
(cellulose fibers in a lignin and hemicellulose matrix), Carbon-fiber reinforced
plastic or CFRP, Glass-fiber reinforced plastic or GFRP (also GRP). If
classified by matrix then there are Thermoplastic Composites, short fiber thermoplastics, long fiber thermoplastics or
long fiber reinforced thermoplastics There are numerous thermoset composites, but
advanced systems usually incorporate aramid fibre and carbon
fibre in an epoxy resin matrix.
Composites can also utilise metal fibres reinforcing other metals, as in Metal matrix
composites or MMC. Ceramic matrix composites include Bone
(hydroxyapatite reinforced with collagen fibers),
Cermet (ceramic and metal) and Concrete. Organic matrix/ceramic
aggregate composites include Asphalt concrete, Mastic
asphalt, Mastic roller hybrid, Dental
composite, Syntactic foam and Mother of Pearl.
Chobham armour is a special composite used in military applications.
Additionally, thermoplastic composite materials can be formulated with specific metal powders resulting in materials with a
density range from 2 g/cc to 11 g/cc (same density as lead). These materials can be used in place of traditional materials such
as aluminum, stainless steel, brass, bronze, copper, lead, and even tungsten in weighting, balancing, vibration dampening, and
radiation shielding applications. High density composites are an economically viable option when certain materials are deemed
hazardous and are banned (such as lead) or when secondary operations costs (such as machining, finishing, or coating) are a
factor.
Engineered wood includes a wide variety of different products such as
Plywood, Oriented strand board, Wood plastic composite (recycled wood fiber in polyethylene matrix), Pykrete (sawdust in ice matrix), Plastic-impregnated or laminated paper or textiles, Arborite, Formica (plastic) and Micarta. Other engineered laminate composites, such as Mallite, use a central
core of end grain balsa wood, bonded to surface skins of light alloy or GRP. These generate
low-weight, high rigidity materials.
Typical Products
Composite materials have gained popularity (despite their generally high cost) in high-performance products such as
aerospace components (tails, wings , fuselages, propellors), boat and
scull hulls, and racing car bodies. More mundane uses
include fishing rods and storage tanks.
See also
External links
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