NetComposites Ltd has transferred the rights and ownership of this website to Gardner Business Media Inc.
On 1st January 2020, NetComposites' media assets including netcomposites.com, newsletters and conferences were transferred to Composites World (Gardner Business Media).
This site is no longer being updated. Please direct all enquiries to email@example.com.
For further details see our joint press release.
Thermwood has added new capabilities to its LSAM Print3D additive manufacturing software, a CAD-based slicing software which operates within Mastercam to generate additive printing programs for Thermwood’s Large Scale Additive Manufacturing (LSAM) systems.
Thermwood reports that unlike most other slicing software which generate net shape programs for small thin print beads and only work with .STL files, LSAM Print 3D works with CAD file formats commonly used in industry, including solids, surfaces and meshes. It is designed for industrial ‘near net shape’ additive manufacturing applications with features tailored to large parts printed at high rates using large print beads.
Near net shape additive manufacturing is a two-step process where the part is first printed at high speed to a size slightly larger than needed and then trimmed to the final size. Net shape software can be made to work for small near net shape parts provided small print beads are used, but doesn’t work for large structures printed at high speed using large print beads. LSAM Print 3D is specifically designed for large scale near net shape industrial applications.
A new concurrent printing feature has been added with which multiple parts can be printed concurrently, improving throughput as well as offering interesting new possibilities.
The system operates by printing the first layer of each part, then the next layer of each part and so on. If all the parts are made essentially the same way, this is a simple process. But in many cases different parts may be printed differently, using different printing parameters and/or layer definitions. One part may be totally solid, the next completely open. One part may have thin walls, the next thick walls. The software allows each part to be independently designed without regard to the others and can still print them concurrently.
The major production improvement that results from this new ability is due in large part to Thermwood’s high output print head and large table sizes. Versions of Thermwood’s print head have been tested at output rates of over 500 lbs/hr. Unlike traditional FDM printing techniques which print slowly onto a heated table in a heated environment, Thermwood’s LSAM machines print at such a high speed that the process must be continuously cooled rather than heated. All the heat in Thermwood’s system comes from the print head. Using Thermwood’s system, the current layer must be cool and stable enough that the new layer doesn’t distort it, but must also be warm enough that it fuses completely with the new layer. With carbon fibre filled ABS for example, even with fan cooling, it requires at least a 1.5 minute wait time between layers. Higher temperature materials can generally be printed at somewhat faster rates but Thermwood’s high speed print head prints most part layers, even large parts, in much less time than that.
Instead of pausing or running slowly to accommodate the minimum wait time between layers, multiple parts can be printed in the same amount of time, provided there is enough available table space. Thus, the faster the print head and the more available table space, the more parts it is possible to print concurrently. With this new feature, the ability of the software to concurrently print dissimilar parts is not a limiting factor.
Many times, really large parts or moulds are made in sections that are then combined into the final structure. Multiple sections of these type of parts can now be printed at the same time, reducing print time for large structures by as much as 80%, while still adhering to the minimum time between layers dictated by the thermoplastic material. In addition to dramatically reducing average print time, there are other important aspects to this new capability, Thermwood explains.
For example, a more complex part can be designed as two or more separate parts and these then printed next to each other or even on top of each other so that they fuse together during the print process. This results in a single complex structure that would be difficult to program and make any other way. Internal supports are no longer restricted to just standard infill patterns.
Current FDM slicing software focuses primarily on the outside shape of a part. Infills may be used on the part interior, but there are real limitations to the use of standard infill patterns. Thermwood’s new software capability can begin printing a part at any layer above the table top.
Another new feature is the ability to design interior walls as part of a CAD part design and have the software recognise these as single bead interior support walls and automatically develop a program to print them as designed. The software has also been taught specific operational characteristics of the of the LSAM machine which it automatically takes into account when generating a slicing program.
Output of the LSAM Print 3D software is a CNC program ready to run on the LSAM print gantry. No additional CAM or post processing software is required.
Image provided by Thermwood
For more information visit: