Composite Part Design and Manufacturing

Composite manufacturing is different from traditional manufacturing in several important ways. Composite manufacturing uses layers of various materials, such as polymers, metals, ceramics, and carbon, embedded in a resin matrix to create a material with specific characteristics. Traditional manufacturing, on the other hand, typically involves shaping, cutting, or forming a single material into a desired product. Other differences include material composition, material properties, processing techniques, design flexibility, strength-to-weight ratio, cost, and production rates.

Composites in design refer to engineered materials comprising two or more distinct components with distinct properties combined to achieve specific performance characteristics. These components typically include a reinforcement phase (like fibers or particles) and a matrix (usually a polymer or resin). Composites are renowned for their exceptional strength-to-weight ratios, corrosion resistance, and tailored mechanical properties, making them indispensable in various industries, including aerospace, automotive, energy, and sports equipment. By strategically selecting materials and configuring their arrangement, designers can create composites with customized attributes, enhancing structural integrity, and reducing weight—critical requirements in modern engineering and product development. Composites empower designers to push the boundaries of innovation and efficiency.

Composite fabrication is the process of defining the detailed instructions to manufacture composite parts, including generation of cores, individual flat ply layers, transitions, draping, and splicing features. CDMA provides all of this, plus support for automated ply book generation, seamlessly integrated in the Creo design environment. It allows for precise control over material properties, enabling the creation of strong, durable, and versatile products.

The choice of composite material depends on the specific application and the required properties, such as strength, weight, durability, and environmental considerations. The versatility of composites makes them valuable in various industries from aerospace and automotive to construction and sports equipment.

• Carbon Fiber: A high-strength, lightweight material composed of thin fibers made mostly of carbon atoms. These fibers are combined into a composite material by embedding them in a polymer matrix. Carbon fiber composites are known for their exceptional strength-to-weight ratio, making them ideal for applications requiring rigidity and low weight, such as aerospace, automotive, and sports equipment.
• Kevlar: A synthetic aramid fiber developed by DuPont that is renowned for its remarkable strength and heat resistance. Kevlar fibers are often used in applications where high tensile strength and resistance to abrasion and impact are crucial. These include body armor, bulletproof vests, gloves, and various protective gear.
• Fiberglass: A composite material made of fine glass fibers embedded in a polymer matrix, typically epoxy or polyester resin. It is valued for its high strength, lightweight nature, and corrosion resistance. Fiberglass is commonly used in construction, boat building, automotive parts, and various consumer products, thanks to its versatility and cost-effectiveness.

Creo Simulation users can access the mass properties of composite parts created in the design stage and perform structural analysis of these complex parts, taking into account each ply’s material characteristics and orientation, ensuring that the final parts meet the engineering requirements. Users can employ the software’s draping simulation feature to analyze the ply producibility and create the ply flat patterns.

Composites are valued for their ability to be tailored to specific requirements, making them a versatile choice in many industries where traditional materials may fall short in terms of performance, weight, or durability. The American Composites Manufacturing Association (ACMA) reports that wind energy is the leading consumer (25%), followed by aerospace (20%), sporting goods/recreation (10-12%), automotive (10-12%), compounding for injection molded plastics (5-8%), pressure vessels (5-8%), and construction and infrastructure (5-8%). Other market segments account for approximately 15% and continue to grow, as additional applications are identified.