Download PDF
Altair > Case Studies > Developing Ultra-Lightweight, High Performance Road Bikes with IoT
Altair Logo

Developing Ultra-Lightweight, High Performance Road Bikes with IoT

Technology Category
  • Infrastructure as a Service (IaaS) - Virtual Private Cloud
  • Networks & Connectivity - Ethernet
Applicable Industries
  • Aerospace
  • Life Sciences
Applicable Functions
  • Product Research & Development
  • Quality Assurance
Use Cases
  • Additive Manufacturing
  • Manufacturing Process Simulation
Services
  • Testing & Certification
The Challenge
Rolo Bikes, a company founded by Adam Wais and Anders Annerstedt, aimed to fill a gap in the market for ultra-high performance bicycles tailored to individual rider requirements. The challenge was to develop a high-performance, ultra-lightweight composite bike frame that exhibited world-leading strength and stiffness attributes while keeping weight to an absolute minimum. The design team at Rolo wanted to optimize the structure and find the ideal layout of carbon fiber that did not use any unnecessary material. However, the team lacked the in-house computer-aided engineering (CAE) expertise required to accurately analyze and optimize the frame. The objective was to achieve world-leading performance for weight, stiffness, and comfort, and to develop an efficient and cost-effective virtual testing process to analyze the performance of future bike frames.
About The Customer
Rolo Bikes is a company founded by Adam Wais and Anders Annerstedt, based in Sweden. The founders believed that the cycling industry was becoming stale, with nothing truly exciting hitting the marketplace. They spotted a gap in the market for a range of ultra-high performance bicycles that are tailored to the individual requirements of each rider. By combining a passion for cycling with a unique set of design and business expertise gained in other industries, the team founded Rolo Bikes with the aim of developing the best performing bicycles available. The company is now in a position to provide advisory services based on this work to other companies in the cycling industry.
The Solution
Rolo Bikes approached Altair ProductDesign due to its familiarity with the HyperWorks suite and expertise in the application of CAE techniques to optimize carbon fiber structures. Altair ProductDesign utilized a three-step approach to optimize the carbon fiber frame. The shape, thickness, direction, and location of each layer of composite material were fine-tuned until an optimum solution had been reached. Each stage was performed using HyperWorks' structural analysis solver, OptiStruct. The stages included Free-Size Optimization, Size Optimization, and Shuffle Optimization. At the end of this process, HyperWorks was utilized again to analyze and validate the optimized frame against the CEN and Zedler tests, and assess fatigue performance. The resulting composite ‘layup’ created a component that is manufacturable for Rolo’s meticulous hand layup construction process employed in its European based manufacturing center, all within cost targets.
Operational Impact
  • As a result of the project, Rolo Bikes now has a comprehensive and highly accurate set of virtual test jigs which can be used to analyze the performance of any bicycle frame against industry standard performance metrics. This capability has allowed the company’s design team to significantly decrease its future development time by cutting down its reliance on expensive prototyping and physical testing processes. The optimized design was feasible from a manufacturing point of view, something that was missing from the original baseline. Looking to the future, the accuracy of Rolo’s virtual test rigs is set to improve as the design team develops its library of verified material data. This has significantly enhanced the performance of its own range of products and positioned Rolo Bikes and Altair ProductDesign to provide advisory services to other companies in the cycling industry.
Quantitative Benefit
  • Weight of the frame reduced from 829g to 710g
  • Significantly decreased future development time by cutting down reliance on expensive prototyping and physical testing processes
  • Stiffness and durability performance enhanced significantly over the target values

Related Case Studies.

Contact us

Let's talk!

* Required
* Required
* Required
* Invalid email address
By submitting this form, you agree that IoT ONE may contact you with insights and marketing messaging.
No thanks, I don't want to receive any marketing emails from IoT ONE.
Submit

Thank you for your message!
We will contact you soon.