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Statements

Subject Item
dbr:Microstructures_in_3D_printing
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Microstructures in 3D printing
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3D printing introduced ways of complex structure design which cannot be realized by traditional processing methods. The use of microstructures, where the thickness of each strut scale of tens of microns ranges from 0.2mm to 0.5mm, has the capabilities necessary to change the physical properties of objects (metamaterials) such as: elasticity, resistance, hardness. In other words, these capabilities allow physical objects to become lighter or flexible. The pattern has to adhere to geometric constraints (shape regulations), thickness constraints (minimum thickness control), or can be enforced using optimization methods (microstructure shape and topological optimization). There are many innovations occurring in this field and many 3d printers are being researched and built just to specialize i
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dbc:3D_printing dbr:Elasticity_(physics) dbr:Edge_space dbr:Computed_axial_lithography dbr:Laminated_object_manufacturing dbr:Innovations_(journal) dbr:Metamaterials dbr:Poisson's_ratio dbr:3D_printing dbr:Finite_element_method dbr:Voxels dbr:Selective_laser_sintering dbr:Shear_modulus dbr:Bulk_modulus dbr:Microstructure dbr:CAD dbr:Geometric_term_of_location dbr:Hardness dbr:Fused_filament_fabrication dbr:Stereolithography dbr:Liquid_additive_manufacturing dbr:Young's_modulus n15:Printed_red_bear.jpg dbr:Interpolation n15:3D-printed_Microstructure.jpg dbr:Robocasting dbr:Microstructures dbr:Isotropy
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3D printing introduced ways of complex structure design which cannot be realized by traditional processing methods. The use of microstructures, where the thickness of each strut scale of tens of microns ranges from 0.2mm to 0.5mm, has the capabilities necessary to change the physical properties of objects (metamaterials) such as: elasticity, resistance, hardness. In other words, these capabilities allow physical objects to become lighter or flexible. The pattern has to adhere to geometric constraints (shape regulations), thickness constraints (minimum thickness control), or can be enforced using optimization methods (microstructure shape and topological optimization). There are many innovations occurring in this field and many 3d printers are being researched and built just to specialize in building such structures.
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