LINEAR BEARING CLUTCH

Organization Name

THE JOHNS HOPKINS UNIVERSITY

Inventor(s)

Ryan D. Seery of Washington DC (US)

Matthew S. Bailey of Baltimore MD (US)

Daniel M. Shaefer of Ellicott City MD (US)

LINEAR BEARING CLUTCH - A simplified explanation of the abstract

This abstract first appeared for US patent application 18434896 titled 'LINEAR BEARING CLUTCH

The abstract describes a linear bearing clutch with a first surface featuring a tapered surface, a second surface with a flat or curved surface, one or more contact elements, and a holding device. The first surface allows motion of the contact elements along one direction of the second surface while restricting motion in the opposite direction.

• The linear bearing clutch includes a first surface with a tapered surface.
• The second surface has a flat or curved surface.
• One or more contact elements are present.
• A holding device is used to secure the contact elements.
• The first surface permits motion in one direction of the second surface and restricts motion in the opposite direction.

Potential Applications: - Industrial machinery - Automotive systems - Robotics

Problems Solved: - Control of motion in specific directions - Precision positioning

Benefits: - Enhanced control over movement - Improved accuracy in positioning

Commercial Applications: Title: "Innovative Linear Bearing Clutch for Precision Control in Industrial Machinery" This technology can be utilized in various industries such as manufacturing, automotive, and robotics for precise motion control and positioning accuracy.

Questions about Linear Bearing Clutch: 1. How does the linear bearing clutch improve precision in motion control? 2. What are the potential industrial applications of this technology?

Frequently Updated Research: Stay updated on the latest advancements in linear bearing technology for improved performance and efficiency in various applications.

Original Abstract Submitted

A linear bearing clutch includes a first surface, a second surface, one or more contact elements, and a holding device. The first surface includes a tapered surface. The second surface includes a flat or curved surface. The holding device is configured to hold the one or more contact elements. The first surface is configured to permit motion of the one or more contact elements along a first direction of the second surface and restrict motion of the one or more contact elements in a second direction of the second surface, the second direction being opposite the first direction.