We asked Smalley marketing engineer Justyna Rapacz to fill us in on the design of wave springs and their utility to engineers designing products. We turned to Smalley as the inventor of the edge wound ...

Artificial intelligence is colliding with a hard physical limit: the energy and heat of today’s silicon-based chips. As models grow from billions to trillions of parameters, the bottleneck is no ...

The development of new theoretical and experimental methods that allow precise control of thermal energy transport is important across a number of research areas, including highly efficient ...

Understanding the way a wave moves through granular materials—after an earthquake, for example—has vast implications for modern science. After all, scientists use stress wave propagation through ...

Wave springs come in a variety of configurations, dimensions, and materials to deliver precise spring force in up to 50% less axial space than traditional coiled springs in the aerospace, automotive, ...

Discover the power of wave springs and their diverse varieties. This guide covers their functionality, manufacturing process, and wide-ranging applications. Learn how edgewound wave springs optimize ...

Autonomous material-handling vehicle capabilities, such as dynamic navigation, advanced load handling, shared autonomy with remote operator console, fleet control, and WMS integration are all included ...

For the first time, two mathematicians have created a 3-D simulation of the mass transport capabilities of mode-2 waves. Such models will help define how mode-2 waves can carry materials that are ...

Most people probably don’t think about springs until one kinks up or snaps, but most of the world’s springs are pretty crucial. The ones that aren’t go by the name Slinky. We all use and encounter ...

Stress wave propagation through grainy, or granular, materials is important for detecting the magnitude of earthquakes, locating oil and gas reservoirs, designing acoustic insulation and designing ...