Technology Category
- Functional Applications - Manufacturing Execution Systems (MES)
Applicable Industries
- Aerospace
- Electronics
Applicable Functions
- Product Research & Development
- Quality Assurance
Use Cases
- Additive Manufacturing
- Rapid Prototyping
Services
- Testing & Certification
About The Customer
Renishaw is a world leader in engineering technologies, with a strong history of innovation in product development and manufacturing. Since its formation in 1973, the company has supplied leading-edge products that increase process productivity, improve product quality and deliver cost-effective automation solutions. Renishaw's laser melting process is an emerging manufacturing technology with a presence in the medical industry, as well as the aerospace and high technology engineering and electronics sectors. Laser melting is a digitally driven additive manufacturing process that uses focused laser energy to fuse metallic powders into 3D objects.
The Challenge
Empire Cycles, in collaboration with Renishaw, aimed to design and manufacture the world's first metal 3D printed bicycle frame. The challenge was to leverage the freedom of additive manufacturing to create a bicycle frame that was not only innovative but also surpassed existing standards in terms of weight and strength. Chris Williams from Empire Cycles had been using Additive Manufacturing components in production for many years, but wanted the opportunity to test it out on a full bicycle product. The team at Renishaw thought that a standard simple part of the bicycle like the seat post would be the best fit for additive manufacturing and weight reduction, as this is a known entity and simple enough to validate and test.
The Solution
The solution involved a process incorporating the concept generation of solidThinking Inspire and Renishaw’s Additive manufacturing technology. The original CAD data was imported into Inspire, and retaining bolts and the seat post were modeled. This enabled the retaining bolts to be fixed and acting forces applied to the end of the seat post. The part was defeatured to maximize the design space, allowing Inspire maximum design freedom. The ideal part shape was then generated using Inspire. A second iteration was carried out using a smaller design space to further refine the shape. The new material layout generated by Inspire provided a concept that not only met the performance targets but was also lighter than the original. Chris then took this model and used his own design know-how to generate suitable geometry around the concept for additive manufacturing.
Operational Impact
Quantitative Benefit
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