Browse Technologies by  


UPN Ref Technology
134 Radar system
The Innovation describes a military radar system used to identify airborne objects in the space surrounding an aircraft. Existing systems often use a rotating antenna to scan regions surrounding the aircraft. This method can produce delays in detection, since it neglects large areas for significant periods of time. Alternate methods for detecting other aircraft would require unlikely universal adoption. The uniqueness of the invention lies in the use of a probe that covers the entire area of interest simultaneously, thus optimizing the time for detecting a foreign object.
View Technology
90 Variable Torque Electrical Motor
The Variable Torque Electrical Motor (VTEM) is designed to convert variable input electrical power into a varying output mechanical torque. The value of electrical power input to the device determines the specific value of the output mechanical torque.
View Technology
83 High integrity, anti-corrosion and mechanical protection ultrathin coating that cures in seconds (No VOC, HAP, isocyanides, 100% solids)
A UV curable, high integrity sustainable system that can be used as a repair coating on existing coated surfaces or on carbon & stainless steel, aluminum, concrete, glass, fiberglass, plastics and more. Cures in 10 seconds or less upon application of UV lamp. This is a 100% solids liquid coating that does not contain solvents, VOC, HAP, isocyanides and can be customized to meet specific performance needs such as anti-corrosion, anti-fouling, anti-graffiti, chemical and mechanical resistance, flow assurance and more.
View Technology
65 Additives for the plastics industry
Unique organic polymer particles which are able to absorb and carry a variety of liquid chemical actives. These particles are robust and can be easily compounded into commercial thermoplastics, liquid polymers, polyester resin and rubber to either positively fragrance plastics or as a means of providing recycled plastic odour neutralisation.
View Technology
61 New superhydrophobic coatings
The technology consists of very strong superhydrophobic coatings that repel a variety of liquids and oils leaving the surface completely dry and clean.
View Technology
57 New processing technologies for high-performance thermoplastic composites
The cost effective manufacturing processes enable automated production of high-performance thermoplastic composite parts and their joining into a geometric complex shape.
View Technology
34 Specialized vacuum-assisted resin transfer method for infusing fabric-based composites
Novel manufacturing methods for the creation of carbon or glass composite materials and structures through the use of a specialized vacuum assisted resin transfer method. This process yields a stronger composite than standard infusion processes. Results are near the same as composites made by autoclaving woven or non-woven materials however the time and costs are substantially less than autoclaved composites.
View Technology
33 Electrospun glass and carbon nanofiber technology
A new electrospun glass and carbon fiber technology which creates a non-woven fabric. One application is to use the fabric in interlaminar applications to significantly increase the strength, impact and fatigue resistance of composites. The non-woven material also has uses in the filtration and medical devices. The technology substantially reduces material weight and production costs.
View Technology
31 Biopolymers-based advanced meltblown manufacturing process and products
An advanced manufacturing process with a robust patent portfolio and trademarks for long-term value. High value end meltblown non-woven products for scalable niche markets. Microbial control platforms integrated to specialty non-woven fiber products (roll-goods or finished products on an OEM basis to large customers).
View Technology
23 Making adhesives surfaces reversible
Thermo-expandable microspheres (TEMs), which consist of an outer shell of copolymer thermoplastic resin encapsulating a liquid hydrocarbon, when the heat trigger is applied at command the microspheres expand to over 100 times their volume, acting as a pressure activator to cleanly break the bond at the interface, and the cohesive structure. A key part of the patented technology is the functionalization of the TEMs surfaces, e.i. a conducting material is applied onto the polymeric shells of the microspheres. This additional layer enables quicker ways to get the heat to the TEM surface without damaging the material itself.
View Technology
slider