5 Reasons to use Fiber-Reinforced Polymer (FRP)

Aug. 18, 2025

5 Reasons to use Fiber-Reinforced Polymer (FRP)

When selecting a building material for an infrastructure project, there are a few key factors to consider before making a decision. Engineers must be sure to make selections that will benefit both the people within their agency, who will be working with the material, as well as the project’s end users.

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One such material is fiber-reinforced polymer (FRP), which can be hugely beneficial for both builders and users. Read more below to find out how this unique material can work for you.

1. Production and Installation Time

When developing the design for your overall infrastructure plan, it’s important to factor in the amount of time that will be needed not only for the whole project, but also for each step within the process. Obviously, saved time translates to saved costs, but you certainly don’t want to sacrifice quality for efficiency. FRP can provide an ideal balance, helping to save valuable production time while still providing the necessary quality, strength and durability. Below, compare the production and installation time of FRP to that of precast concrete:

As you can see from the chart, FRP’s total production time is 15 days less than that of precast concrete. This translates to more than two weeks’ worth of saved labor costs and overall downtime for infrastructure development. FRP also requires less total installation time than precast concrete — almost five days less, on average.

Thanks to this shorter installation time, engineers using FRP don’t have to complete their work solely during the workweek. Instead, they can opt to do installation work on the weekends, too, when there is less traffic congestion and end users will experience less inconvenience and fewer interruptions to their commutes.

2. Weight

Going hand-in-hand with a quicker installation time is FRP’s weight. FRP is known for being lightweight. In fact, it’s about eight times lighter than reinforced concrete — meaning FRP is also less labor-intensive to use and install, and requires less equipment. This material also requires less labor during removal processes. See below to compare the total weight of FRP to the total weight of precast concrete.

As you can see from the chart, FRP is significantly lighter than precast concrete, with an FRP panel weighing about 5,000 lb and a precast concrete panel weighing nearly 41,000 lb. Using a lighter material makes it easier on your workers, saves on labor costs and places less stress on the infrastructure. The lower the weight of the material being used, the less wear and tear the infrastructure will experience as a whole.

3. Corrosion and Maintenance

Offering high durability and strength, as well as reliable resistance to corrosion, FRP is long-lasting and mitigates the need for ongoing maintenance. The lack of frequent maintenance and repairs helps to save on expensive labor and material costs and also prevents inconvenience to end users, since repair downtime is minimized.

And, since FRP is long-lasting and resistant to corrosion, the long-term costs end up being less as well.

Though FRP does have a slightly higher price point per square foot at initial installation, the material allows for many benefits in terms of long-term cost savings. Because FRP causes less stress on the infrastructure and is more durable than other materials, it diminishes the need for costly repairs or reconstruction down the road. For example, bridges and platforms constructed from materials such as reinforced concrete, steel, or wood often fall apart 15 to 20 years after initial installation — requiring extremely expensive repairs or even a whole new investment to rebuild from scratch. FRP, however, is built to last and won’t experience corrosion over time like many other construction materials.

4. cost savings

FRP structures are highly reliable and low-maintenance, but they shouldn’t be considered maintenance-free. Repairs requiring field service will need to be performed on rare occasions. Performing yearly routine inspections (at minimum) will help ensure potential issues can be caught before they become a problem. If an issue has been identified and reported (ex. cracks, crazing, discoloration, excessive wear, etc.), a field service technician will be sent out to complete the repair.

As mentioned, structures made from steel, concrete and wood are prone to regular repair work, as well as those made with brick and tile – that’s also where FRP can come in. Fiberglass can be used for patch repairs on bridge decking and liners can be applied to culverts, pumps, storage tanks and pipes to protect less-resistant materials from future damage. FRP can even be used for wrapping bridge piers and columns.

Repairs made with FRP add up to long-term cost savings. Since the material is corrosion-resistant and has a much longer service life, it’s a great option to use when repairing and protecting existing structures. Take a look at our brief case study to learn more about how FRP repairs reduce costs.

5. design flexibility

FRP is ideal for any type of job that requires customization, as it is engineered to meet exact specifications. Regardless of complexity, engineers can create panels of all different sizes and shapes. This allows for aesthetic versatility, as there is a range of possible colors. It is also possible to add functional features to facilitate a smooth and easy installation process.

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FRP offers a wide range of unique benefits — short production and installation time, light weight, long-term cost savings, corrosion resistance, and superior longevity. An ideal material for use in almost any infrastructure project, FRP is very dynamic, making it the perfect choice for all types of infrastructure — including vehicle, pedestrian, and trail bridges, cantilever sidewalks, rail platforms, waterfront frameworks, storage tanks and pipes, stairs and handrails, and much more.

FRP pipe: an effective solution for wastewater management

Fibre-reinforced plastic (FRP) is a composite material composed of a polymer matrix strengthened by fibres, also referred to as fibre-reinforced polymer.

Commonly employed fibres include carbon, glass, basalt or aramid. In some cases, other fibres like wood, asbestos, and paper have been utilised. While vinyl ester, polyester, epoxy thermosetting plastics are used as matrix materials. In some cases, phenol formaldehyde resins are also used.

Fibreglass-reinforced pipes are experiencing a rapid surge in demand because they play a vital role in the industrial sector. These pipes, made from FRP, are non-metallic and crafted by continuously wrapping fibreglass filament saturated with a specialised combination of epoxy resin and curing chemicals. Their applications range from piping systems to tankers, and various vessels across numerous fields and industries. The global FRP pipe industry is gaining momentum owing to an expansion of the building and construction sector and the benefits of FRP pipe in the construction domain.

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Features of FRP pipes:

• Lightweight

FRP pipes, designed from a combination of 1/10 P.S.C., 1/5 steel, and 1/8 C.I., exhibit a reduced strength-to-weight ratio compared to alternative materials. Their lightweight construction enables easy handling, installation, modification, and repair of FRP pipes.

• Non-corrosive

FRP pipes inherently possess corrosion resistance. In many cases, fibreglass-reinforced plastics stand as the sole material capable of withstanding certain parameters. Additionally, their corrosion resistance, typically coupled with cost efficiency, positions them as the most viable solution. The corrosion resistance of Fibreglass Reinforced Plastic pipes depends on both the overall resin content and the specific resin employed in the pipe's laminate. Thus, a higher resin content equals to increased resistance against corrosion.

FRP pipes offer an excellent solution for transporting corrosive wastewater and sewage. Their smooth inner surface effectively facilitates the flow of various fluids. Corrosion resistance is a crucial attribute in these applications.

• Flexibility

FRP pipes offer versatility in shaping various equipment pieces or configurations using permanent or temporary molds. For instance, constructing ductwork with FRP pipes is highly feasible as it enables the production of different types of rectangular transitions, Tee inlets, circular transitions, flanges, and elbows at a minimal expense. Additionally, Fibreglass Reinforced Plastic pipes are a suitable option for lining both new and existing structures.

Computer software programmes have significantly improved the design of FRP systems. These programmes include various functionalities such as analysing gas flow, chemical composition, liquid flow, and thrust blocks, and providing installation information.

Recent developments transforming the FRP pipe industry:

RPS Composites introduced a robust and durable joint specifically designed for FRP (Fibreglass Reinforced Plastic) piping systems.

RPS Composites, based in Franklin, Ohio, US, has introduced the RPS Grooved Adapter, specially designed for use in combination with RPS fibre-reinforced polymer (FRP) piping systems. This adapter is designed for use with a Victaulic Style 296-A coupling, resulting in a sturdy and dependable joint for FRP piping. As per the RPS, the most appealing feature of the Grooved Adapter is its ease of use, enabling coupling or uncoupling within minutes without requiring any specialised tools or training. Specifically designed for mild corrosive environments such as water, seawater, and wastewater, the RPS Grooved Adapter offers practicality and convenience in its application.

The RPS FRP adapters have undergone rigorous testing and meet the ASME NM.2- Proof of Design qualification test standards. These tests include static pressure, cyclic pressure evaluations, and hydrostatic strength testing.

CPP has successfully installed the tallest Fibre Reinforced Polymer (FRP) stack liner for the Bangladesh-India Friendship Power Company

CPP (Chemical Process Piping), a company specialising in industrial piping solutions producing GRP and FRP-based pipes, has introduced an FRP stack in the FGD (Flue Gas Desulfurisation) plant established by BIFPCL (Bangladesh India Friendship Power Company). This joint venture operates on a 50:50 partnership between the Bangladesh Power Development Board and the National Thermal Power Corporation.

CPP has accomplished Phase I of the Maitree Super Thermal Power Plant project in collaboration with BHEL and Simplex in Bangladesh. Marking a significant achievement, CPP stands as the pioneering entity in this sector by successfully constructing an 800 ft FRP stack for the MW coal-fired power station located in Rampal, Bangladesh. This accomplishment positions CPP as the foremost FRP manufacturer in this region to employ vertical winding technology for filament winding the FRP stack, a pioneering approach adopted for their project in Bangladesh. The project itself represents an environmentally friendly initiative, leveraging supercritical technology for the thermal power plant.

To sum up, the global FRP pipe industry is experiencing growth due to the advantages of these pipes in the construction sector and the rapid growth of the construction and building sector. The potential of FRP pipes in wastewater management will present remunerative growth opportunities to the market in the upcoming years.

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