WEBINAR 

The 3D-Printed Gyroid:
Improving Structurally Demanding Applications

BigRep Logo white

The 3D-Printed Gyroid:
Improving Structurally Demanding Applications

WATCH NOW

The 3D-Printed Gyroid: Improving Structurally Demanding Applications

Learn how gyroid infill can improve mechanical properties and reduce material usage and weight in Additive Manufacturing, ranging from renewable energy to biomedical applications.

OVERVIEW

TITLE: THE 3D-PRINTED GYROID: IMPROVING STRUCTURALLY DEMANDING APPLICATIONS

DURATION: 60 min.

SPEAKERS:

  • Jörg Alber (M.Sc.), Phd candidate at the Technical University Berlin (DE)
  • Alex Moss (M.Eng.), Phd candidate at the University of Bristol (UK) and CATAPULT – Offshore Renewable Energy
  • Ana Pais (M.Sc.), Mechanical engineer at FEUP/INEGI- Institute of Science and Innovation in Mechanical and Industrial Engineering of Porto (PT)

REGISTER FOR THIS WEBINAR TO LEARN ABOUT

  • 3D Printed Rotor Blades for a Research Wind Turbine
    Presented by Jörg Alber
    This study combines the design, 3d printing, and testing of a wind turbine for research and teaching purposes. The objective is additive manufacturing 1 m long rotor blades using the Gyroid infill as an alternative to conventional methods, such as CNC milling or lamination.
    Publication
  • Upscaling Design of Printed Lattice Structures: Hip Bones to Turbine Blades
    Presented by Alex Moss
    Through combining topology optimization, cellular structures, and additive manufacturing, improved structural efficiency and manufacturability are applicable to many new research areas. What opportunities can be seized, utilizing materials, manufacturing, and structural design knowledge to print optimized lattices at scale?
    Publication
  • Gyroid Infills for Structural Optimization and Biomedical Applications
    Presented by Ana Pais
    Functionally graded cellular structures allow for many possibilities in the field of structural optimization and implant design in order to avoid stress shielding. The gyroid shape is particularly suitable for permeability, cell growth, and proliferation. This presentation shows ways of combining 3D printing and numerical simulation to achieve new designs for biomedical implants with a higher success rate.
    Publication

WATCH THE ON-DEMAND WEBINAR NOW

The 3D-Printed Gyroid: Improving Structurally Demanding Applications

Learn how gyroid infill can improve mechanical properties and reduce material usage and weight in Additive Manufacturing, ranging from renewable energy to biomedical applications.

OVERVIEW

TITLE: THE 3D-PRINTED GYROID: IMPROVING STRUCTURALLY DEMANDING APPLICATIONS

DURATION: 60 min.

SPEAKERS:

  • Jörg Alber (M.Sc.), Phd candidate at the Technical University Berlin (DE)
  • Alex Moss (M.Eng.), Phd candidate at the University of Bristol (UK) and CATAPULT – Offshore Renewable Energy
  • Ana Pais (M.Sc.), Mechanical engineer at FEUP/INEGI- Institute of Science and Innovation in Mechanical and Industrial Engineering of Porto (PT)

REGISTER FOR THIS WEBINAR TO LEARN ABOUT

  • 3D Printed Rotor Blades for a Research Wind Turbine
    Presented by Jörg Alber
    This study combines the design, 3d printing, and testing of a wind turbine for research and teaching purposes. The objective is additive manufacturing 1 m long rotor blades using the Gyroid infill as an alternative to conventional methods, such as CNC milling or lamination.
    Publication
  • Upscaling Design of Printed Lattice Structures: Hip Bones to Turbine Blades
    Presented by Alex Moss
    Through combining topology optimization, cellular structures, and additive manufacturing, improved structural efficiency and manufacturability are applicable to many new research areas. What opportunities can be seized, utilizing materials, manufacturing, and structural design knowledge to print optimized lattices at scale?
    Publication
  • Gyroid Infills for Structural Optimization and Biomedical Applications
    Presented by Ana Pais
    Functionally graded cellular structures allow for many possibilities in the field of structural optimization and implant design in order to avoid stress shielding. The gyroid shape is particularly suitable for permeability, cell growth, and proliferation. This presentation shows ways of combining 3D printing and numerical simulation to achieve new designs for biomedical implants with a higher success rate.
    Publication

WATCH THE ON-DEMAND WEBINAR NOW

Cookie Consent with Real Cookie Banner