You’ve printed a part and it failed. Why?
You meticulously went through all the steps you should. Drawn up your CAD model, loaded up the design domain, ran it through your favorite topology optimization tool, fixed it (with Magics / Netfabb or another) — and printed it with the perfect settings recommended by the print manufacturer.
What happened? Well, there’s a crucial issue in most topology optimization software packages out there—they are missing an important (essential) feature. Most of them do not actually take into account how additive processes behave — which means that optimizations are taking place based on an assumption. And this assumption is invariably incorrect.
It’s the (intuitively sensible) assumption that your 3D printed part will behave the same from all directions. This is called isotropy — but, unfortunately, it is not the case.
So why even bother topologically optimizing with incorrect assumptions, and with tools that you know won’t do the job? Unless you like to invite a whole bunch of testing and insert a critical dose of ‘tacit knowledge’ into your organization — it sounds like a lot of hassle and a lot of risk.
There is a different approach. Additive Aware, from Additive Flow, is a suite of tools that optimize a subject to the nuances of additive manufacturing processes. Formflow software can help de-risk your development cycle — and harness the full potential of AM.
What is Orthotropy, and why it matters.
Orthotropy is a feature of 3D printed parts that behave differently based on the direction they are measured. Most topology optimization tools assume 3D printed parts behave the same in all directions (isotropy) – which means these results are neither accurate nor optimized.
Additive Flow’s topology optimization capability is natively built to be ‘Additive Aware’ – and optimizes shape and material subject to the varying material properties, including orthotropy. If this is not taken into account, parts can fail and opportunities will be missed.
Additive manufacturing is the meeting point of material science, design engineering, production management, and much more. It is so multi-disciplinary that the human mind — no matter how intelligent or skilled — can boggle.
This is where a new breed of tools is needed, to help our boggling minds to make the most of this exciting, if complex, technology.
As a quick material properties refresher:
Isotropy is where a material/part behaves the same way in all directions
Anisotropy is where a material/part behaves differently in one or more direction
Orthotropy is a kind of anisotropy. Orthotropy is related to the word orthogonal, which means “connected to right angles”. So, for additive, generally, the material properties across the 90-degree directional axes of X and Y are equivalent, and Z is different (as Z is usually the build direction).
Additive manufacturing tends to produce parts that are anisotropic along the build axis. This means that 3D printed parts are orthotropic, often weaker, to forces applied perpendicular to the build direction.
If these orthotropic properties are ignored, and engineers use the prevailing isotropic solvers on the market, results will be wrong, because they cannot take into account the actual material properties.
This means isotropic topology optimization is limited — because it is based on the false assumption that materials behave in the same way. The engineer has to choose from two bad options:
–To optimize subject to the weakest direction — hence missing optimization opportunities of additive — missing weight/cost/time-saving gains
–To optimize from an average of the material properties, which can result in key safety factors being missed — it would be certain that the weakness along the build direction was not accounted for — so how could the parts be used without further unnecessary design-test cycles?
For the majority of additive manufacturing processes that are orthotropic, how can engineers be confident about their results — and hence deploying AM in their businesses?
Composites. Orthotropy plays an even greater role with composites, where fiber alignment delivers enhanced engineering properties in specific directions. Additive manufacturing with both chopped and continuous fibers can result in seriously powerful mechanical properties. For example with an FFF process, Carbon filled ABS performed 2x to 4x better along the strongest plane in key mechanical tests vs. pure ABS.
How would the engineer properly design for these compelling material properties along certain axes? Especially when accounting for the fact that the weakness along the build direction for CFF is 50% weaker.
Orthotropic optimization. The orthotropic solvers within Additive Flow’s software stack are able to optimize topologies for single and multi-materials — accommodating both the weakness of build directions and the superpower of composites. For example, the power of the program’s solvers in the application was demonstrated in work with Royal HaskoningDHV — where they saved a further 20% in weight versus alternative isotropic solvers.