Injection molding has become essential in the creation of aerospace parts due to the high precision of the products, their low weight and their complex shapes. This method allows for the production of parts that meet the performance and safety requirements of the industry. With innovations in materials such as high-performance thermoplastics and composite reinforcements, injection molding of aircraft parts has helped improve fuel efficiency and other aircraft performance. With new technologies such as additive manufacturing and artificial intelligence integration systems in contemporary society, the future of injection molding in aerospace is clear for more efficient design and production of parts for more sustainable solutions in aviation.
To better understand some of the challenges and fan data
critical points facing aerospace parts production, visit our " aerospace parts manufacturing service " site. This page provides an overview of many aerospace components manufactured using injection molding.
Polypropylene (PP)
Polypropylene is one of the most popular plastic materials. It is distinguished by its strength, flexibility and durability, as well as its high resistance to chemicals and electrical currents. It is preferred for disposable medical devices such as syringes and sample containers.
Polystyrene (PS)
Polystyrene is a hard plastic with little or no flexibility. However, it has excellent machinability, good impact resistance and good dimensional stability. It is therefore ideal for creating critical medical components such as Petri dishes, diagnostic parts and culture trays.
Polycarbonate (PC)
Polycarbonate is transparent and has excellent mechanical properties. This tough, engineering-grade thermoplastic offers dimensional stability and flame retardant properties. It is highly compatible with body tissues, making it ideal for manufacturing medical equipment. It is also resistant to impact, high temperatures and UV exposure.
PEEK
Polyetheretherketone (PEEK) is a high-quality thermoplastic that exhibits exceptional mechanical properties, including resistance to harsh environments such as thermal degradation, wear, tracking, and radiation. PEEK is used to create medical and surgical implants by providing exemplary dimensional stability, even after exposure to stress.
Silicone
This chemically inert compound is similar to synthetic rubber and offers exemplary mechanical properties and compatibility with biological tissues. Silicone is the preferred option for medical grade plastic polymers in the production of devices such as connectors, catheters and tubes.