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Audemars Piguet: Reducing Development Time with ANSYS Simulation
Technology Category
- Analytics & Modeling - Digital Twin / Simulation
- Cybersecurity & Privacy - Intrusion Detection
Applicable Functions
- Product Research & Development
Use Cases
- Manufacturing Process Simulation
- Virtual Prototyping & Product Testing
The Challenge
Audemars Piguet & Cie, a luxury watch manufacturer, faced a significant challenge in the design and manufacturing of their high-precision watch components, specifically the date display mechanism. This mechanism, which changes the date every 24 hours, needs to advance the date in a way that appears instantaneous to the human eye, usually within 0.015 seconds, and must reveal the correct next date. This is achieved through a complex assembly of a jumper, spring, and trigger cam to rotate the display disk exactly one date step. Traditionally, these fine watch mechanisms were designed using prototyping, a costly and iterative process. While simulation could reduce the need for prototypes, the precise and flexible components within the watch mechanism’s dynamic system required extremely accurate nonlinear dynamics capabilities to characterize correctly.
About The Customer
Audemars Piguet & Cie SA is a Swiss manufacturer of luxury watches, founded in 1875. The company is renowned for developing and crafting precision watches equipped with complex mechanisms. Over the years, Audemars Piguet has pushed the boundaries of watchmaking, developing many firsts in the industry. Today, the company continues to be characterized by Swiss precision and its exceptional timepieces. The company's commitment to innovation and quality is evident in its use of advanced simulation technologies to improve the design and manufacturing process of its watches.
The Solution
Audemars Piguet & Cie adopted ANSYS simulation technology, specifically ANSYS Mechanical and ANSYS LS-DYNA, to address their challenge. The company used ANSYS transient dynamic and explicit solutions to analyze the dynamic behavior of the date display mechanism. They employed nonlinear contact behavior to accurately model the moving mechanism of the date display. This allowed them to analyze and compare the behavior of different design models and improve the mechanism based on simulation results. The simulation results were then compared with real tests which showed outstanding agreement. This approach allowed the company to meet the exacting precision required by the watch industry and launch the model into production without any further prototypes.
Operational Impact
Quantitative Benefit
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