Pultrusion: Redefining Automotive Composite Components
In a world driven by innovation and technological advancements, one manufacturing process stands at the forefront of composite material production: pultrusion. With its seamless blend of strength, versatility, and efficiency, pultrusion has transformed fiber-creation-reinforced plastics. From towering skyscrapers to lightweight aerospace components, it has become the driving force behind the creation of robust and sustainable composite materials.
So, let’s unravel the captivating world where endless possibilities emerge from the depths of composite innovation.
What is Pultrusion?
Pultrusion is an industrial process that converts reinforced fibers and liquid resin into fiber-reinforced plastic, or fiber-reinforced polymer (FRP).
By passing fiberglass rovings through a resin bath or resin impregnator that completely saturates the reinforcements, the pultrusion technique enables the automated, energy-efficient production of FRP structural forms. The resin solidifies in the heated steel pultrusion die, resulting in a sturdy, lightweight final product that takes the shape of the die.
What are Common Types of Pultrusion Processes?
Here are some types and variations of the pultrusion process:
● Standard Pultrusion
This is the most common type of pultrusion process, in which fiberglass rovings are pulled through a resin bath or impregnator to saturate the reinforcements. The resin-impregnated fibers then pass through a heated steel die for polymerization, resulting in a solid and durable FRP profile.
● Radius-Pultrusion
This is a modified version of the pultrusion process, developed by Thomas GmbH + Co. Technik + Innovation KG, where the steel die moves back and forth along the produced profile during the manufacturing process. This allows for the production of two- and three-dimensional curved profiles, making it beneficial for complex shapes and applications.
● Thermoplastic Pultrusion
In thermoplastic pultrusion, thermoplastic materials are used instead of thermosetting resins. This process involves heating and melting the thermoplastic material, which is then pulled through the steel die to form the desired profile. Thermoplastic pultrusion offers unique advantages, such as recyclability and the ability to reshape the profile after production.
A study by the National Institute of Health demonstrates the medical application of thermoplastic pultruded profiles, including orthodontics and MRI techniques.
● Injection Pultrusion
This process is a variation of thermoplastic pultrusion in which low-viscosity thermoplastic resins are injected into the reinforcement materials during the manufacturing process. This method is ideal for producing complex profiles with varying material properties as it offers precise control over resin distribution.
3 Popular Fibers Used in Pultrusion
Engineers choose fibers based on project goals and performance specifications. Three common fiber reinforcements in FRP manufacturing are explained below.
1. Glass Fiber
Glass fibers are a common and inexpensive fiber reinforcement used in FRPs across industries. These fibers are well-known for their increased tensile strength, dimensional stability, and resistance to creep, impact, and chemical elements. E-glass, a specialty glass fiber, is an excellent electrical insulator. Lightweight and impact-resistant, it is a great option for low-cost, high-impact-resistance reinforcements in pultruded composites.
2. Carbon Fiber
Fibers containing 90% or more carbon content are considered carbon fibers. They are produced from precursors like rayon, pitch, lignin, or polyacrylonitrile. Carbon fiber is less impact-resistant and can cause corrosion, but it has higher tensile strength and a lower weight than other reinforcement materials. After glass fiber, carbon fiber is the second most widely used reinforcement material. These fibers have a wide range of applications, including automotive body parts and hydrogen tanks for fuel cell vehicles. Additionally, it is used in sports and recreation items like fishing rods, golf shafts, tennis rods, hockey sticks, and bicycles.
3. Aramid Fiber (Kevlar)
Aramid fiber is also known as Kevlar. It is a synthetic fiber made from polyamide fibers. It is renowned for its bulletproof properties, impact resistance, high elongation, heat and corrosion resistance, and lightweight properties. Aramid fiber has diverse industrial applications in ballistic protection, sports goods, and electronic casing for cell phones and other portable devices.
Building a Stronger Tomorrow
Pultrusion has revolutionized the world of composite manufacturing, offering precise and efficient methods for creating fiber-reinforced plastics. With its ability to produce consistent profiles with exceptional strength and durability, it has found its way into a wide range of industries, from construction to aerospace. It has unlocked new possibilities for lighter, stronger, and more sustainable materials.
As research and technology continue to advance, we can expect pultrusion to play a more significant role in shaping the future of composite materials, driving innovation, and pushing the boundaries of new opportunities.