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6 Tips to Reduce Laser Powder Bed Fusion (L-PBF) Costs

Learn how to minimize costs when it comes to making metal parts with L-PBF technology.

When it comes to conventional manufacturing, the general rule of thumb is that the more complex the part, the higher the costs. That’s not the case with additive manufacturing technologies such as laser powder bed fusion (L-PBF). Intricate designs with free-form surfaces, undercuts, or internal shapes aren’t the main price-driving factors. Instead, cost mostly comes from volume. The more metal powder required in the design, the higher the price.

To effectively lower L-PBF costs, optimizing designs to minimize volume is essential. It’s also important to rethink the strategy for producing the part. To help you do that, here are six ways to help reduce costs.

1. Use Topology Optimization

Topology optimization uses algorithmic models to optimize the material layout within certain specifications. Those specifications can be related to symmetry, material properties, load conditions, etc. In short, it’s an excellent technique to lower volumes and reduce the costs of metal additive manufacturing.

Metal additive manufacturing can get expensive when large volumes are needed, so topology optimization software is well worth using when designing metal parts.

2. Design Lattices

A lattice is an interlaced structure of repeated patterns. Think of the hexagons of a honeycomb or the crisscrossing beams of a bridge. Within L-PBF, lattices are an excellent way to produce strong and lightweight parts. Lattices can be used instead of solid volume, resulting in significant cost savings. Designing lattices can be automated via CAD programs. Through additive manufacturing, it is relatively easy to print the structures – regardless of their complexity.

Lattices in a 3D printed cube

A solid cube vs. one with lattices

Topology optimization and lattices can be used together. Research shows that the two techniques are especially effective when combined. A 2019 study showed that using lattices and deploying topology optimization reduced costs by 54 percent. The weight of the part and the production time also dropped in half.

Want some more design insights? Check out the L-PBF design guide.

3. Fillet Corners

It’s usually good practice to fillet (round) all sharp edges in your design. One reason to do this is because corners are where stress concentrations occur. Another reason is to reduce costs. Filleting outside edges results uses slightly less metal powder. Filleting isn’t a massive cost reduction but savings can add up over time. Plus, eliminating stress concentrations reduces the chance of part failure, which prevents unexpected cost overruns.

4. Understand the Different Metal Powders

Earlier in this guide, we mentioned how volume is one of the key drivers of price. That’s true, but the metal powder type also affects the price. Depending on the project, certain metals will need to be used due to the various mechanical properties offered by each type. Furthermore, powder variants combine metal types or provide different levels of purity.

Choosing the most affordable metal type with all the necessary mechanical properties helps reduce costs. Global metal prices fluctuate due to economic conditions, but here’s how the main metal types stack up in comparative prices.

5. Rethink Quantity

This isn’t a design tip but rather a strategic one. With additive manufacturing, producing smaller batches of units is significantly cheaper than conventional manufacturing. That’s because additive manufacturing eliminates the need for tooling. With the cost of tool design and tool production out of the equation, manufacturing costs per unit remain almost constant – as seen in the below graph. With the lower upfront costs and fast lead times, additive manufacturing has become especially popular for prototyping, tooling, jigs, fixtures, and on-demand end-use parts.

The additive manufacturing cost

This graph also shows that as expensive as conventional manufacturing can initially be, the cost per unit drops when more units are produced. Maybe your production numbers ensure that additive manufacturing is always the ideal manufacturing technology. However, this chart shows it’s essential to know when that cost curve might shift in the other direction. When that’s about to happen, it’s best to be prepared and rethink the ideal production method for your project.

6. Get Near-Real-Time Prices on Iterations

Costs shouldn’t be a black box. When you’re experimenting with different materials, modified designs, and other factors, the last thing you want to do is wait around to see what kind of impact there is on price. Fortunately, the days of sending a design and waiting for a manual quote are over.

With MakerVerse, for example, it’s possible to upload a design and get an instant quote. When you change the different options related to materials, finishes, and more, prices are immediately updated. If you change the design, it can easily be re-uploaded for a new instant quote.

Next Steps

Additive manufacturing technology is constantly evolving. Existing techniques continuously improve while completely new technologies are being developed. All this means is that additive manufacturing is never static. It’s a dynamic technology where staying on top of the latest trends is beneficial to find price-optimizing opportunities.

See how much you can save on the MakerVerse platform.

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