TAKING PRODUCT DEVELOPMENT TO A WHOLE NEW…
LAYER?
3D PRINT WITH A
PURPOSE
Using DMLS, FDM, and SLA 3D Printing, our team of Engineers will take your concept and upgrade it.
Conceptualize
Explore potential implementations for Additive Manufacturing techniques/technology.
Design
CAD Design implementing AM Technologies such as Lattice, Topology Optimization, and Porocity.
Prototype
Print designed model in prototype low volume run, test and redesign as required.
Design Review
Review design changes with customer and iterate as required.
Production Readiness
Assist customer with transition to production where required.
Production Impimentation
Complete transition to production from LRP to FRP.
Customer ships us physical part and delivers CAD model/Assembly .
Receive Current Part
Explore redesign opportunities and establish path forward.
Evaluate and Conceptualize
CAD Design implementing AM Technologies such as Lattice, Topology Optimization, and Porocity.
Redesign
Print prototypes and review design changes with customer and iterate as required.
Prototype and Test
Customer signoff on redesign
Customer Approval
Assist customer in transition from prototype to FRP
Volume Solution
ADDITIVE MANUFACTURING IS
MORE THAN JUST PRESSING PRINT…
LET US SHOW YOU WHAT IT CAN DO
ADDITIVE MANUFACTURING
TECHNOLOGIES
LATTICE STRUCTURE
Lattice structures in 3D printing denote intricate, interconnected patterns within objects, optimizing strength-to-weight ratios and material utilization. Leveraging specialized design software, these structures offer diverse benefits, including enhanced strength, minimized weight, cost-effective material usage, and tailored functionalities, catering to a wide array of applications across industries.
TOPOLOGY OPTIMIZATION
Topology optimization is an advanced technique used in engineering and design within 3D printing, focusing on refining and streamlining the internal structure of objects. By employing algorithms, it optimizes the distribution of material, creating lightweight, high-strength components that match specific performance criteria. This technology enhances efficiency, reducing material usage while maintaining structural integrity, and is adaptable across various industries seeking robust, lightweight designs for their products.
POROCITY
Porocity refers to deliberately incorporating voids or empty spaces within 3D-printed structures. This technique strategically introduces gaps or pores into objects, enhancing their properties such as reduced weight, improved flexibility, or increased surface area. By controlling these voids, it enables customization for specific applications, offering advantages like enhanced material efficiency and tailored functionalities across diverse industries, including aerospace, biomedical, and manufacturing.