A fiber-reinforced composite (FRC) is a composite building material that consists of three components:[1] [2]
This is a type of advanced composite group, which makes use of rice husk, rice hull,rice shell, and plastic as ingredients. This technology involves a method of refining, blending, and compounding natural fibers from cellulosic waste streams to form a high-strength fiber composite material in a polymer matrix. The designated waste or base raw materials used in this instance are those of waste thermoplastics and various categories of cellulosic waste including rice husk and saw dust.
FRC is high-performance fiber composite achieved and made possible by cross-linking cellulosic fiber molecules with resins in the FRC material matrix through a proprietary molecular re-engineering process, yielding a product of exceptional structural properties.
Through this feat of molecular re-engineering selected physical and structural properties of wood are successfully cloned and vested in the FRC product, in addition to other critical attributes to yield performance properties superior to contemporary wood.
This material, unlike other composites, can be recycled up to 20 times, allowing scrap FRC to be reused again and again.
The failure mechanisms in FRC materials include delamination, intralaminar matrix cracking, longitudinal matrix splitting, fiber/matrix debonding, fiber pull-out, and fiber fracture.[1]
Difference between wood plastic composite and fiber-reinforced composite:
| Features | Plastic lumber | Wood plastic composite | FRC | Wood | |
|---|---|---|---|---|---|
| Recyclable | |||||
| House Construction | |||||
| Water Absorption | 0.00% | 0.8% and above | 0.3% and below | 10% and above |
| Tensile Strength | ASTM D 638 | 15.9 MPa | |
| Flexural Strength | ASTM D 790 | 280 MPa | |
| Flexural Modulus | ASTM D 790 | 1582 MPa | |
| Failure Load | ASTM D 1761 | 1.5 KN - 20.8 KN | |
| Compressive Strength | 20.7MPa | ||
| Heat Reversion | BS EN 743 : 1995 | 0.45% | |
| Water Absorption | ASTM D 570 | 0.34% | |
| Termite Resistant | FRIM Test Method | 3.6 |
The appropriate "average" of the individual phase properties to be used in describing composite tensile behavior can be elucidated with reference to Fig. 6.2. Although
this figure illustrates a plate-like composite, the results that follow are equally applicable to fiber composites having similar phase arrangements. The two phase
material of Fig. 6.2 consists of lamellae of
\alpha
\beta
l\alpha
l\beta
V\alpha
V\beta
| V | ||||
|
| V | ||||
|
Case I: Same stress, different strain
A tensile force F is applied normal to the broad faces (dimensions Lx L) of the phases. In this arrangement the stress borne by each of the phases (= F/
L2
\varepsilon\alpha
\varepsilon\beta
\vartrianglel\alpha=\varepsilon\alphal\alpha
\vartrianglel\beta=\varepsilon\betal\beta
The total elongation of the composite,
\vartrianglelc
\vartrianglelc=N\vartrianglel\alpha+N\vartrianglel\beta
and the composite strain
\varepsilonc
\varepsilonc
| \vartrianglelc | |
| N(l\alpha+l\beta) |
V\alpha\varepsilon\alpha+V\beta\varepsilon\beta
| \sigmal( | V\alpha | + |
| E\alpha |
| V\beta | |
| E\beta |
r)
Composite modulus
| E | ||||
|
Case II: different stress, same strain
Fibers that are aligned parallel to the tensile axis, the strains in both phases are equal (and the same as the composite strain), but the external force is partitioned
unequally between the phases.
F=F\alpha+F\beta=NL(\sigma\alphal\alpha+\sigma\betal\beta)
\sigmac=\left(
| \sigma\alphal\alpha | + | |
| l\alpha+l\beta |
| \sigma\betal\beta | |
| l\alpha+l\beta |
\right)=\sigma\alphaV\alpha+\sigma\betaV\beta
Ec=V\alphaE\alpha+V\betaE\beta
When the fiber is aligned parallel to the direction of the matrix and applied the load as the same strain case. The fiber and matrix has the volume fraction
Vf
Vm
\sigmaf
\sigmam
\varepsilonf
\varepsilonm
Ef
Em
\varepsilonf
\varepsilonf
\varepsilonc
In stage 1, when the fiber and matrix both deform elastically, the stress and strain relation is
\sigmac=VfEf\varepsilonf+VmEm\varepsilonm=\varepsilonc(VfEf+VmEm)
Ec=VfEf+VmEm
In stage 2, when the stress for the fiber is bigger than the yield stress, the matrix starts to deform plastically, and the fiber are still elastic, the stress and strain relation is
\sigmac=VfEf\varepsilonf+Vm\sigmam(\varepsilonm)=VfEf\varepsilonc+Vm\sigmam(\varepsilonc)
Ec=VfEf+Vm\left(
| d\sigmam | |
| d\varepsilonc |
\right)
In stage 3, when the matrix the fiber both deform plastically, the stress and strain relation is
\sigmac=Vf\sigmaf(\varepsilonf)+Vm\sigmam(\varepsilonm)=Vf\sigmaf(\varepsilonc)+Vm\sigmam(\varepsilonc)
Ec=Vf\left(
| d\sigmaf | |
| d\varepsilonc |
\right)+Vm\left(
| d\sigmam | |
| d\varepsilonc |
\right)
Since some fibers do not deform permanently prior to fracture, stage 3 cannot be observed in some composite.
In stage 4, when the fiber has already become fracture and matrix still deforms plastically, the stress and strain relation is
\sigmac=Vm\sigmam(\varepsilonm)
However, it is not completely true, since the failure fibers can still carry some load.
For discontinuous fibers (also known as whiskers, depending on the length), tensile force is transmitted from the matrix to the fiber by means of shear stresses that develop along the fiber-matrix interface.
Matrix has displacement equals zero at fiber midpoint and maximum at ends relative to the fiber along the interface. Displacement causes interfacial shear stress
\taum
\sigmaf
df
x
\taum(\pidf)dx=\left(
| |||||||||
| 4 |
\right)d\sigmaf
| d\sigmaf | = | |
| dx |
| 4\taum | |
| df |
After only a very small strain, the magnitude of the shear stress at the fiber end becomes large. This leads to two situation: fiber-matrix delamination or matrix having plastic shear.
If matrix has plastic shear: interfacial shear stress
\taum\le\taumy
lc
l>lc
x
\sigmaf
\sigmaf(\varepsilonc)=2
| \taumylc | |
| df |
| lc | = | |
| df |
| \sigmaf(\varepsilonc) | |
| 2\taumy |
The ratio,
| lc | |
| df |
\varepsilonc
df
| tensile | |
| \sigma | |
| f |
/2\taumy
Then calculate average stress. The fraction of the fiber length carrying stress
\sigmaf(\varepsilonc)
| l-lc | |
| l |
| lc | |
| l |
\sigmaf(\varepsilonc)/2
\overline{\sigma}f=\sigmaf(\varepsilon
| \right)\right]+ | |||||
|
| 1 | |
| 2 |
\sigmaf(\varepsilon
|
\right)=\sigmaf(\varepsilon
|
\right)\right] l\gelc
For
l<lc
\sigmamax/2
\sigmamax=2\taumyl/df
| \overline{\sigma} | ||||
|
\sigmaf(\varepsilon
|
\right) l\lelc
The composite stress is modified as following:
\sigmac=Vf\sigmaf(\varepsilon
|
\right)\right]+Vm\sigmam(\varepsilonm) l\gelc
\sigmac=Vf\sigmaf(\varepsilon
|
\right)+Vm\sigmam(\varepsilonm) l\lelc
The above equations assumed the fibers were aligned with the direction of loading. A modified rule of mixtures can be used to predict composite strength, including an orientation efficiency factor,
η0
\sigmac(\varepsilon)=Vm\sigmam(\varepsilon)+η0ηfVf\sigmaf(\varepsilon)
where
ηf
| l | |
| 2lc |
l\leqlc
\left[1-\left(
| lc | |
| 2l |
\right)\right]
l>lc
η0
η0
Appreciable reinforcement can be provided by discontinuous fibers provided their lengths are much greater than the (usually) small critical lengths. Such as MMCs.
If there is fiber-matrix delamination.
\taumy
\muP
\mu
P
| lc | = | |
| df |
| \sigmaf(\varepsilonc) | |
| 2\muP |
This happens in most resin-based composites.
Composites with fibers length less than
lc
There are also applications in the market, which utilize only waste materials. Its most widespread use is in outdoor deck floors, but it is also used for railings, fences, landscaping timbers, cladding and siding, park benches, molding and trim, window and door frames, and indoor furniture. See for example the work of Waste for Life, which collaborates with garbage scavenging cooperatives to create fiber-reinforced building materials and domestic problems from the waste their members collect: Homepage of Waste for Life
Adoption of natural fiber in reinforced polymer composites potentially to be used in automotive industry could significantly help developing a sustainable waste management.[4]
3. Thomas H. Courtney. "Mechanical Behavior of Materials". 2nd Ed. Waveland Press, Inc. 2005.