When selecting the materials to use in a product, a lot of factors have to be included in the end decision. Often times, engineers need to consider both the end-user of the product and the people that will be aiding in the production of the piece of infrastructure.Other than offering optimal functionality to the end-user, the materials used in the construction or design should be efficient to use as well as cost-effective.
Fiber-reinforced polymers happen to fit right into this description. The question is, what is an FRP (fiber-reinforced polymer), and how can it benefit your product?
Read on to learn about FRP:
Also referred to as fiber-reinforced plastic, FRP is a composite material that consists of polymer matrix blended alongside a reinforcing material, such as fiber.
In general, the fibers can either be aramid, basalt, or carbon, with paper, asbestos, or wood being used in some cases. The result is typically flexible plastic panels that are made from polyester resin as well as reinforced with fiberglass.
It has a diversity of uses, including in the aerospace, transport, construction and marine sectors, and many others.
To truly understand the formation of FRPs, it is essential to understand how polymers are formed- either through addition polymerization or step-growth polymerization.
Ideally, composite plastics tend to be formed by combining a couple of homogeneous material with different characteristics to come up with a final product that matches the desired material and mechanical properties.
These composite materials can then be subdivided into two, particle reinforced and fiber-reinforced.
The latter option is achieved by incorporating fiber materials into the products, which increases the elasticity and mechanical strength of the plastics.
In comparison, the matrix- which is the core material before fiber reinforcement- is hard but weaker. In a nutshell, the fiber is the key differentiating factor between the FRP and the polymer.
For most of these plastics to be formed, a variety of molding processes might have to be used. Ideally, a tool or mold is typically used to place the constituting dry fiber, the preform fiber, or the fiber that contains specific resin portions.
The first step is using resin to 'wet' the dry fiber before the 'curing' process begins- the matrix and fibers take the shape of the mold or die.
Heat and pressure are also applied occasionally in this stage. Different methods are used, including compression molding, mandrel molding, bladder molding, filament winding, and autoclave.
Ideally, when it comes to developing the design for your product, you need to factor in the time needed for the entire project as well as through each stage of the production.
If you manage to save some time in between the nitty-gritty parts of the project, you also get to save its cost. As long as the quality isn't sacrificed, this will be a step in the right direction.
FRP provides the perfect balance for saving time and offering the ideal durability, strength, and quality. This can easily be linked to its short installation and production time.
FRPs' weight tends to go hand in hand with its short installation requirements. In fact, it is as much as eight times lighter than reinforced concrete.
This also means that it is less labor-intensive to install and remove FRPs, and less equipment is needed.
Since it offers high strength and durability, and resistance to corrosion, FRP tends to require less maintenance.
This reduced need for maintenance means that fewer resources will be used for the maintenance of the ad hoc piece of infrastructure, and the end-user is bound to experience reduced downtimes.
While the initial cost of the materials might be a little bit high than other materials, the long-term savings you can get from FRPs makes the extra cost worth it.
FRPs are typically very versatile. You can use them to do more things than you would have done with other materials.
For instance, you can mold any configuration or piece of equipment, which can further help you create a permanent or temporary mold.
You can make a variety of parts, from circular to rectangular transitions, rods and tubes, channels and bars with minimal tooling costs.
Some products require a certain level of thermal insulation. Depending on the intricate compositions of the FRP, you can enjoy a commendable level of thermal insulation. This can include insulation from fire and even UV radiation.
Glass is typically a great insulation material. When blended with the matrix, it forms glass-reinforced plastics or fiberglass. In comparison to carbon fiber, however, it is less brittle and expensive, but less strong and rigid.
This option offers a lot of beneficial features, from high tensile strength, stiffness, chemical resistance, and temperature tolerance, alongside low weight and low thermal expansion capacities.
Ideally, the carbon atoms tend to form crystals along the long axis of the fiber. Such an alignment fortifies the material by making the ratio of strength to volume quite high.
This fiber component typically results in heat resistant and robust synthetic fibers. It has a variety of uses in a lot of industries.
Both FRP and GRP are two commonly confused terms, but they are quite different. As mentioned above, FRP consists of a composite material that has high strength fibers, which are typically included in a polymer matrix.
Their high strength and lightweight nature makes them quite useful in both commercial and engineering applications. Ideally, they are often used as a substitute for wood and metal.
On the flip side, fiberglass or GRP uses polyester, epoxy, or vinyl as a polymer and is made out of glass fibers. Its uses are in the manufacture of boats, bathtubs, and gliders. GRP is typically a type of FRP and is mainly used for commercial applications.
Fiber-reinforced polymers have revolutionized multiple industries. From being heat-resistant to being lightweight, they are ideal substitutes for conventional construction material.
Contact us to gain access to FRPs for your specific needs.