Additive Manufacturing
FISBA’s engineering team brings a wealth of experience with deep industry expertise and knowledge to optimize the optical path in laser metal additive manufacturing tools and metrology units for in-process quality control.
FISBA’s engineering team brings a wealth of experience with deep industry expertise and knowledge to optimize the optical path in laser metal additive manufacturing tools and metrology units for in-process quality control.
Scientists and medical professionals rely on polymerase chain reaction (PCR) to quickly replicate DNA samples for various types of genetic analysis. For example, scientists use PCR to increase quantities of DNA from full or partial strands of DNA. This copied DNA allows for detailed research in life science, human health, forensics, and optimizing crops in the lab or field for agricultural applications.
First, an engineer designs a part using CAD software before being converted into a stereolithography (.STL) file showing how to slice the desired three-dimensional object into thin layers. During the build process, uniform layers of powder are spread across the build plate where the laser applies heat to melt them as it raster scans across the plate based on the part’s design. A wide variety of factors ranging from programmed scan paths, laser parameters, and distribution in powder sizing can all impact the resulting part quality. Optical in-situ real-time monitoring of the build process takes place in parallel to ensure the part meets the design criteria for the physical dimensions by observing key process metrics.
FISBA has deep expertise and design engineering experience with high-power laser metal additive manufacturing. Specifically, our product engineering expertise includes:
We are proud to support and be a trusted partner to OEM instrument companies in the additive manufacturing market and invite you to learn more about our collaborative partnership model and How We Work.