About Additive Manufacturing
Additive manufacturing, also referred to as 3D printing, is a broadly used term to describe industrial processes by which three-dimensional objects are manufactured through:
- a controlled deposition of raw material (typically in powdered, melted, or liquid state); and
- induced transformation into a solid state.
Common additive manufacturing processes (ISO / ASTM52900-15) are described in the table below.
Technique |
Powder bed |
Binder jetting |
Directed energy deposition |
Material extrusion |
Sheet lamination |
Photo polymerization |
Material jetting |
---|---|---|---|---|---|---|---|
Description |
Thermal energy selectively fuses regions of a powder bed. |
A liquid bonding agent is deposited to join powder materials. |
A nozzle mounted on a multi-axis arm deposits melted material. |
Material is drawn via a nozzle, where it is heated. It is deposited layer by layer. |
Sheets of material are bonded to form an object. |
Liquid photopolymer is selectively cured by light-activated polymerization. |
Droplets of build materials are selectively deposited. |
Material Form |
Powder |
Powder |
Powder or wire |
"Solid" material |
"Solid" material |
Liquid resin |
Ink |
Material |
Metal Plastic |
Metal Plastic Ceramics |
Metal |
Plastic Composite |
Paper Metal |
Plastic (photopolymer resin) |
Plastic |
Processes Terms |
Selective laser sintering (SLS) Selective laser melting (SLM) Electron beam melting (EBM) Direct metal laser sintering (DMLS) |
Binder jetting (BJ) Inkjet powder printing Multi jet fusion (MJF) |
Laser cladding Direct energy deposition (DED) Laser metal deposition (LMD) Laser engineered net shape (LENS) Laser or electron beam wire deposition |
Fusion deposition modeling (FDM) |
Laminated object manufacturing (LOM) Paper lamination technology (PLT) Ultrasonic additive manufacturing (UAM) |
Stereo lithography (SLA) Digital light processing (DLP) |
Photopolymer jetting (PolyJet) Multi jet modeling (MJM) |
Additive manufacturing makes it possible to produce complex shapes not subject to the design constraints of more traditional manufacturing methods. Therefore, the functional requirements of a part become the primary focus of the design effort. However, additive manufacturing processes have their own challenges. For example, thermal strains induced by the manufacturing process can produce residual stresses large enough to cause failure during printing or during the in-service life of a part.
Some of the main objectives of an additive manufacturing simulation are to:
- Predict the residual stresses in a part.
- Minimize the gap between the designed and manufactured part through process optimization.
- Evaluate how a manufactured part performs under realistic loading conditions in an assembly with other components.
At the core of the Abaqus/Standard additive manufacturing technology is the toolpath-mesh intersection moduleāa powerful geometry-based engine that takes process toolpath data as input and intersects it with an arbitrary mesh.
Abaqus/Standard provides two methods for the simulation of an additive manufacturing process: a thermomechanical simulation and an eigenstrain-based simulation.
Abaqus/Standard offers general-purpose simulation capabilities that allow you to define appropriate boundary conditions, loads, interactions, constraints, and material models required to capture the physics of additive manufacturing processes. In addition, special analysis techniques are available for the simulation of additive manufacturing processes that take into account machine information and process parameters, such as laser power, layer thickness, and toolpath. Abaqus also allows you to perform postprocessing simulations and in-service performance validations for printed parts.