Product Description
18.01 Additive Manufacturing in Metals and the Investment Casting Industry
18.02 A Comparison of 3D Printing Technologies Used to Make Investment Casting Patterns
18.03 How will 3D Metal Printing Impact Investment Casting?
18.04 Advancing Sculpture
18.05 Optimizing the Tetrashell Build Structure to Reduce Shell Cracking in the Autoclave with SLA Patterns
18.06 Are Printed Patterns Viable for Production?
18.07 An Investigation into the Effect of Hollowing Printed Investment Casting Patterns to Reduce Shell Cracking in the Autoclave
18.08 Revolutionary Improvements for Investment Castings Through Application of 3D-Printed Ceramic Tooling and Process Aids
18.09 3D Printed Sand Molds – An Opportunity for Investment Casters
18.10 Enhanced Investment Casting Quality Using 3D-Printed Ceramic Filters
18.11 3D Printed Inserts and Mold Cavities That Can Be Used for Producing Wax Patterns
18.12 An Evaluation of Using a Low-Cost Printer for Prototype Investment Casting Patterns
18.13 Digitization & Automation of The Process of Printing Patterns for Investment Casting
18.14 Improvements in the Burnout Process for Printed Patterns
18.16 Evaluation of a Low-Cost Material Extrusion Printer for Investment Casting Applications
18.18 Optimization of an Aerospace Casting: A Case Study
18.19 Rapid, Low Cost Tooling for Small Engine Castings
18.20 CERAMIC FOUNDRY CORES by 3D PRINTING
18.21 A Research and Industry Roadmap: Barriers and Opportunities for Increased, Lower Cost Additive Manufacturing Integration for Investment Casting Foundries
18.22 Novel regular ceramic filter for the lost wax applications
