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Impact-Activated Ink Release for Advanced Inkjet Printing using Liquid Crystal Substrates

TS-071744 — The Need Current inkjet printing technologies are limited by the need for inks with specific viscosity and ejection properties, which restricts the range of printable materials and compromises print resolution due to droplet splashing. There is a significant need for a printing method that enables…

College: College of Engineering (COE)
Inventors: Wang, Xiaoguang "William"; Zhang, Meng
Licensing Officer: Randhawa, Davinder

Smart Liquid Crystal Sensor for Real-Time Shear Flow Visualization

TS-070520 — The Need Accurate, real-time mapping of shear forces in fluid environments remains a challenge, particularly in applications requiring passive, non-invasive, and long-term monitoring. Existing technologies often rely on active sensors that require power, are difficult to integrate into sensitive sys…

College: College of Engineering (COE)
Inventors: Wang, Xiaoguang "William"; Chen, Boyuan; Kara, Ufuoma; Weible, Alan
Licensing Officer: Randhawa, Davinder

Metal Matrix Composites Reinforced by High Entropy Alloys

TS-063364 — Experience the future of advanced materials—our metal matrix composites offer a revolutionary approach to meeting the demands of modern industries. Elevate your products, enhance performance, and reduce costs with our groundbreaking technology. For a closely related technology, please visit https://oied.osu.edu/find-technologies and type "T2017-051" in the search field.

In the aerospace, defense, and automotive industries, there is a pressing demand for advanced materials that combine low weight, high strength, exceptional wear resistance, and superior high-temperature performance. Traditional methods using ceramic particles as reinforcements in aluminum matrix c…

College: College of Engineering (COE)
Inventors: Luo, Alan; Huang, Xuejun; Zhang, Jianyue
Licensing Officer: Zinn, Ryan

Fast-charging anodes for lithium-ion batteries

TS-063224 — The Need In the rapidly evolving landscape of electric vehicle (EV) technology, there exists a pressing commercial need for rechargeable lithium-ion batteries (LiBs) that can not only deliver high charge capacities and power densities but also address the critical issues of capacity fading and safe…

College: College of Engineering (COE)
Inventors: Kim, Jung Hyun; Jiao, Xinwei "Jocelyn"; Yap, Jun Wei; Yu, Chanyeop
Licensing Officer: Randhawa, Davinder

Design Features of Dissimilar Material-Reinforced Blanks and Extrusions for Forming

TS-037334 — A method for reinforcing formed metal parts with fiber and/or metallic reinforcement.

To date, a key method of lightweighting automobiles has been “down-gauging” sheet metal components or changing to a “lightweight” material such as aluminum from steel. Reducing sheet metal gage has a limitation in formed metal components based upon strength, stiffness, ener…

College: College of Engineering (COE)
Inventors: Dapino, Marcelo; Detwiler, Duane; Gingerich, Mark; Hahnlen, Ryan; Headings, Leon; Sheldon, Allen
Licensing Officer: Zinn, Ryan

Stretchable and Flexible E-Fiber Wire Antennas

TS-014971 — A new process to fabricate stretchable and flexible wire antennas with conductive fibers (E-fibers)

Current processes to manufacture flexible, mechanically durable antennas on E-fibers yield non-stretchable prototypes and lack fine print details. The geometric accuracy of printed antennas is less than 1 mm, and the devices are prone to failure due to fatigue and wear from deformation. The antenn…

College: College of Engineering (COE)
Inventors: Volakis, John; Kiourti, Asimina
Licensing Officer: Randhawa, Davinder