What Is Metal Additive Manufacturing? Written by: BigRep Published on: May 13, 2025 Estimated reading time: 9 minute(s) Metal additive manufacturing is reshaping production across industries. By building components layer by layer, manufacturers are breaking free from traditional machining constraints to create stronger and more intricate parts than ever before. The technology has matured past prototyping. Aerospace engineers now print complex engine components, medical device makers produce custom implants, and automotive teams create optimized parts that cut assembly time in half. This shift marks a fundamental change in manufacturing approaches. So, why are we at BigRep, an industrial leader in large-format plastic 3D printing, talking about metal AM? While plastic additive manufacturing offers key advantages like lower costs, faster prototyping, parts with excellent strength-to-weight ratios, and a wide range of material options, metal AM may be better suited for specific high-performance applications. Both technologies play important roles in the evolving world of manufacturing and understanding where each excels helps manufacturers make smarter choices. In this article, we explore where metal additive manufacturing delivers results, which industries are seeing success, and how to assess its potential for your applications. How Does Metal Additive Manufacturing Work? Metal additive manufacturing, also known as metal 3D printing, builds parts layer by layer using advanced computer-controlled processes. Unlike traditional methods that cut or shape metal from a solid block, metal AM deposits or fuses fine metal powders to create highly complex and durable components with minimal material waste. As a subset of additive manufacturing (learn more about additive manufacturing here), metal AM follows the same principles but focuses exclusively on metal-based materials for high-strength, precision applications. The process starts with a digital 3D model, which is sliced into thin layers. Depending on the technology used, a high-powered laser, electron beam, or binder material selectively fuses metal particles together, forming the final structure. Technologies in Metal Additive Manufacturing The distinct metal additive manufacturing processes are suited to different production requirements. Technology Best for Common Materials 1. Powder Bed Fusion (PBF)High-precision parts in aerospace, medical, and automotive industriesTitanium, aluminum, stainless steel, Inconel, cobalt-chrome2. Directed Energy Deposition (DED)Repairing and adding material to existing parts; manufacturing large, near-net-shape componentsNickel alloys, stainless steel, titanium3. Binder JettingHigh-volume production of complex metal partsStainless steel, bronze, Inconel4. Metal Extrusion (Bound Metal Deposition)Affordable metal part production and rapid prototypingStainless steel, copper5. Cold Spray (CS)Repairing and coating existing metal parts; producing high-strength, corrosion-resistant surfacesAluminum, copper, titanium6. Sheet Lamination (Ultrasonic Additive Manufacturing - UAM)Embedding electronics or sensors inside metal components; creating hybrid multi-material structuresAluminum, titanium, copper7. Laser Metal Deposition (LMD)Aerospace and industrial repairs; surface enhancements like wear-resistant coatingsNickel alloys, steel, titanium 1. Powder Bed Fusion (PBF) High-powered lasers or electron beams scan across a bed of metal powder, melting each layer in a controlled chamber. Production teams choose this method when part quality and precision are critical. Engineers in medical device firms and aerospace manufacturers rely on PBF for low-volume production of complex components. 2. Directed Energy Deposition (DED) Think of it as precision welding on a robotic arm. A nozzle deposits material while simultaneously melting it with a focused heat source. Maintenance teams use this to repair expensive machinery parts, while manufacturers use it to add features to existing components. 3. Binder Jetting Works like a standard printer but with metal powder. A print head deposits binding agent precisely where needed, layer by layer. The green part then goes into a furnace for sintering. Production managers pick this method when they need higher volumes at lower costs. 4. Metal Extrusion (Bound Metal Deposition) Similar to plastic 3D printing, but using metal-filled filaments. After printing, parts go through debinding and sintering. Design firms and small manufacturers choose this for its simplicity and office-friendly setup. 5. Cold Spray (CS) Shoots metal particles at supersonic speeds to build up surfaces without melting. Repair shops use this where heat could damage sensitive parts. 6. Sheet Lamination (UAM) Stacks and bonds metal sheets using ultrasonic welding, then machines them to shape. Electronics manufacturers use this to embed components within metal parts. 7. Laser Metal Deposition (LMD) Feeds metal powder or wire into a focused laser beam for precise material addition. Aerospace maintenance teams rely on this for critical repairs where accuracy matters. Applications of Metal Additive Manufacturing From heavy industry to medical labs, metal additive manufacturing opens new possibilities for design teams pushing technical boundaries. 1. Aerospace & Defense With metal additive manufacturing, engineers can now print complex engine parts that reduce aircraft weight and expand fuel efficiency. The advanced cooling channels inside printed turbine components can extend part life while improving thermal performance. For military applications, teams print specialized tools and UAV components on-site, cutting supply chain delays. 2. Automotive & Racing Racing teams have embraced automotive metal additive manufacturing. Formula 1 engineers are printing topology-optimized chassis parts that maintain strength while reducing weight. Production lines now use printed jigs and tools to streamline assembly. Even hypercar manufacturers are utilizing the technology, with Bugatti's titanium brake caliper marking a milestone in large-format metal printing. 3. Medical Innovation Surgeons and medical device makers are seeing the amazing benefits of metal 3D Printing. It's now routinely used for printed titanium implants matched to patient anatomy. Custom hip replacements and spinal implants improve patient outcomes through better fit and integration. Surgical instruments are also making a great leap forward. To improve precision, surgeons use lightweight, biocompatible, 3D-printed stainless steel and titanium tools. There are also advancements in regenerative medicine. Researchers are exploring 3D-printed scaffolds to aid bone growth and tissue engineering. 4. Energy Sector Power generation requires parts that withstand extreme conditions while maintaining peak efficiency. Modern energy plants now rely on printed heat exchangers with optimized cooling designs to achieve this balance. The wind power industry has also embraced these advances, using printed components to reduce weight in tower assemblies and improve overall turbine performance. 5. Production Tools On factory floors worldwide, manufacturing teams have revolutionized their tooling approach through metal printing. By creating custom tools and fixtures with built-in cooling channels, they've dramatically cut cycle times in injection molding operations. The economics make sense, too - for low-volume production, printing parts directly eliminates expensive traditional tooling costs. Benefits of Metal Additive Manufacturing Manufacturing success depends on balancing quality, cost, and speed. Metal AM brings distinct advantages that help producers meet these challenges: 1. Design Freedom and Complex Geometries Engineers now create internal channels, lattice structures, and complex shapes that traditional machining can't match. Once made from multiple components, parts print as single pieces, cutting assembly steps and failure points. In aerospace, optimized heat exchangers and turbine components showcase what's possible when design limits fall away. Read our Best Practices for Additive Manufacturing Design here 2. Material Efficiency and Sustainability While traditional machining wastes up to 80% of raw material, metal AM builds parts layer by layer, using only what's needed. This approach particularly benefits the aerospace and automotive sectors, where lighter parts mean lower fuel consumption. The ability to recycle metal powders further strengthens the sustainability advantage. 3. Speed and Production Flexibility Metal printing eliminates the need for dedicated tooling, making small batch runs and custom parts viable. Design teams now move from concept to testing in days instead of months. Medical device makers exemplify this shift, delivering custom implants faster than ever while maintaining precise specifications. 4. Part Integration and Performance Printing complex parts as single units improves reliability while reducing assembly time. Automotive manufacturers now print bracket assemblies as one piece, cutting weight and making them stronger. Challenges and Limitations Despite its advantages, metal additive manufacturing faces some hurdles that affect widespread adoption. Here are some of the most pressing limitations: 1. Cost Barriers The manufacturing process demands substantial upfront investment. Beyond expensive machines, companies need specialized facilities, trained staff, and extensive post-processing equipment. Metal powders also carry premium prices, especially for aerospace-grade materials. 2. Production Speed Limits While excellent for prototypes and custom parts, metal AM cannot match traditional manufacturing technologies for high-volume output. Mass production still relies on casting and molding where speed and cost efficiency matter most. Many manufacturers use AM as a complementary technology, focusing on low-volume specialized components. 3. Quality Control The manufacturing industry lacks standardized quality protocols for metal AM. Each part requires thorough testing and validation, particularly in regulated sectors like aerospace and medical. Post-processing adds time and cost - most parts need heat treatment, surface finishing, and precision machining to meet specifications. 4. Material and Safety Challenges Not all metals work with AM systems. Those that do require careful handling - metal powders pose both safety and quality risks. Storage, recycling, and waste management all need specialized procedures to protect workers and maintain consistent print quality. The Future of Metal Manufacturing Metal additive manufacturing continues to evolve rapidly. As costs drop and capabilities expand, more manufacturers are integrating these technologies into their production lines. Improvements in machine learning and automation are tackling current limitations in quality control and post-processing. New materials and faster printing speeds point toward broader adoption in mass production. For manufacturers considering metal additive manufacturing, the message is clear: start exploring applications now. Begin with areas where traditional methods struggle - complex geometries, customized parts, or consolidated assemblies. Test designs, train teams, and build expertise as the technology matures. Success in modern manufacturing demands innovation and practical know-how. Metal additive manufacturing offers new solutions to age-old production challenges while opening doors to designs once thought impossible. About the author: Lindsay Lawson Head of Product Marketing With an MFA in New Genres, Lindsay's background in sculpture and animation eventually led her to the world of 3D printing. She is primarily focused on applications using large-format 3D printing with additional emphasis on post-processing techniques and design for Additive Manufacturing. Related Content Carbon Fiber 3D Printing: How to 3D Print Strong Parts What is carbon fiber 3D printing? Why do you need a large carbon fiber 3D printer? Learn more of how you can print parts strong, stiff parts with a fine surface finish and a high heat deflection with a CF filament. Leveraging 3D Printing for Automotive Customization at AVI Boston AVI Boston seamlessly weaves technology into crafting personalized and bespoke automotive parts like dashboards, radar installations, door panels, and beyond. What puts them ahead of the curve is their expertise in integrating cutting-edge audio and visual systems, elevating both the car’s aesthetics and functionality. How Ford is Optimizing Manufacturing with 3D-Printed Tooling and Fixtures Jigs and fixtures are a mainstay of manufacturing and make production and assembly processes simpler and more reliable, reducing lead times and improving worker safety. Ford Motor Company has compared 3D-printed jigs and fixtures to conventional machining, finding they take less time and cost a fraction to produce.
