Patents Assigned to University of Akron
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Patent number: 11726132Abstract: A failure detection system for an energy network includes a radio frequency (RF) receiver adapted to be coupled with or in close proximity to the energy network, the RF receiver providing an amplitude modulated RF signal; an RF amplifier receiving the amplitude modulated RF signal and providing an amplified signal; an envelope detector receiving the amplitude modulated RF signal and providing a demodulated envelope signal; an optional algorithm implementation system receiving the demodulated envelope signal, where the optional algorithm implementation system processes the demodulated envelope signal by one or more of a Fast Fourier transform (FFT) trigger system and a phase-locked loop (PLL) trigger system; and a signature output that is the overall output signal of the failure detection system, wherein the signature output is adapted to indicate whether the energy network is experiencing partial discharge.Type: GrantFiled: May 27, 2021Date of Patent: August 15, 2023Assignee: The University of AkronInventors: Yilmaz Sozer, Jose Alexis De Abreu-Garcia, Mohammad Arifur Rahman
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Patent number: 11715834Abstract: A fuel cell catalyst for oxygen reduction reactions including Pt—Ni—Cu nanoparticles supported on nitrogen-doped mesoporous carbon (MPC) having enhanced activity and durability, and method of making said catalyst. The catalyst is synthesized by employing a solid state chemistry method, which involves thermally pretreating a N-doped MPC to remove moisture from the surface; impregnation of metal precursors on the N-doped MPC under vacuum condition; and reducing the metal precursors in a stream of CO and H2 gas mixture.Type: GrantFiled: December 27, 2019Date of Patent: August 1, 2023Assignees: Toyota Motor Engineering and Manufacturing North America, Inc., The University of AkronInventors: Li Qin Zhou, Kan Huang, Hongfei Jia, Xiaochen Shen, Zhenmeng Peng, Hisao Kato
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Patent number: 11674885Abstract: A method to detect and assess microorganism influenced corrosion includes measuring current flow between a test electrode and a control electrode in a split chamber zero resistance ammeter apparatus and calculating a predictive difference in mass loss between the test electrode and the control electrode based on that current over time; and measuring the resistance, Rpit, of a surface of the subject metal to assess pitting corrosion using an electrochemical impedance spectroscopy apparatus.Type: GrantFiled: October 15, 2020Date of Patent: June 13, 2023Assignee: The University of AkronInventors: Chelsea Monty-Bromer, John Senko, Anwar Sadek, Sai Prasanna Chinthala
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Patent number: 11678033Abstract: A multi-purpose imaging and display system includes a display; a detector coupled to the display and having a field of view; and a filter communicating with the detector. The field of view is imaged by the detector through the filter, the filter configured to be sensitive to a first frequency spectrum, so the detector displays only objects within the field of view on the detector that emit one or more frequencies within the first frequency spectrum. The detector and filter can work together in different operational states or modes for acquiring image data of a target object under investigation. A computing device can be included to process acquired image data, and communication interfaces can be employed to achieve networking of multiple systems. A peripheral interface allows a plurality of peripheral devices to be selectively added to tailor the data acquisition and display capabilities of the imaging and display system.Type: GrantFiled: June 14, 2021Date of Patent: June 13, 2023Assignee: The University of AkronInventor: Yang Liu
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Patent number: 11661477Abstract: In various embodiments, the invention relates to poly(propylene fumarate) (PPF)-based star-shaped copolymers synthesized using a core-first approach that uses a multi-functional alcohols as an initiator, and Mg(BHT)2(THF)2 as catalyst for controlled ring opening copolymerization (ROCOP) of maleic anhydride (MAn) with propylene oxide (PO). In some embodiments, these star-PPF copolymers have lower viscosities than their linear analogs, allowing a decrease in DEF fraction in resin formulation, as well as the use of higher molecular weights. These star-shape PPF can be used to prepare PPF:DEF resins containing as much as 70% by weight of the multi-arm PPF star copolymers, and have a low complex viscosity of high Mn star PPF resin that affords rapid printing with a Mn nearly eight times larger than the largest linear PPF oligomer printed previously.Type: GrantFiled: September 10, 2019Date of Patent: May 30, 2023Assignee: THE UNIVERSITY OF AKRONInventors: Matthew L. Becker, Gaelle Le Fer
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Patent number: 11646441Abstract: A shear-thickening electrolyte solution includes a polar solvent; an electrolyte dissolved in said polar solvent; and ceramic filler dispersed in said polar solvent, said ceramic filler having an aspect ratio, length to width, of greater than 1:1 and being functionalized to provide terminal end groups that interact with the polar solvent to form a solvation layer around said ceramic filler and support the suspension of said ceramic filler in said polar solvent.Type: GrantFiled: August 12, 2019Date of Patent: May 9, 2023Assignee: The University of AkronInventors: Yu Zhu, Kewei Liu
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Publication number: 20230080523Abstract: In various embodiments, the present invention is directed to a facile one-pot reverse emulsion process to assemble core-shell nanoparticles (CS-SMNPs) into bright and noniridescent photonic supraballs. In one or more embodiments, the present invention is directed to core-shell nanoparticles having an inner high refractive index (RI) core and an outer low RI shell. In one or more embodiment, the present invention includes core-shell nanoparticles using high RI (˜1.74) melanin cores and low-RI (˜1.45) silica shells. In various embodiments, these nanoparticles may be self-assembled into bright and noniridescent supraballs using a scalable one-pot reverse emulsion process. According to various embodiments of the present invention, it is possible to generate a full spectrum of structural colors with the combination of only two ingredients, synthetic melanin and silica.Type: ApplicationFiled: September 13, 2022Publication date: March 16, 2023Applicant: THE UNIVERSITY OF AKRONInventors: Ali DHINOJWALA, Ming XIAO, Ziying HU, Matthew SHAWKEY, Nathan GIANNESCHI
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Patent number: 11597843Abstract: In various embodiments, the present invention is directed to a melanin composition extracted from black knot fungus (Apiosporina morbosa) using an acid-base extraction technique. In one or more embodiments, the melanin composition is extracted from the black outer layer of a black knot fungus by obtaining a powder including a black outer part of one or more black knot fungus, adding a quantity of an aqueous solution comprising one or more base, heating the mixture to solubilize a melanin in the aqueous solution to form a black alkaline supernatant containing said melanin, adding one or more acids to said black alkaline supernatant until the melanin precipitates out of said black alkaline supernatant, said melanin precipitate further comprising proteins, carbohydrates, and lipids; collecting the melanin precipitate and adding one or more acids to hydrolyze some or all of said proteins, carbohydrates, and lipids and produce the melanin composition.Type: GrantFiled: December 28, 2020Date of Patent: March 7, 2023Assignee: The University of AkronInventors: Ali Dhinojwaqla, K Zin Htut, Saranshu Singla, Runyao Zhu, Christopher Maurer
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Patent number: 11542359Abstract: A photoresponsive polyurethane including a hard segment, a soft segment, and a photoresponsive group that is selected from a coumarin group or a coumarin derivative and an alkoxyphencyl group or an alkoxyphencyl.Type: GrantFiled: August 24, 2017Date of Patent: January 3, 2023Assignee: The University of AkronInventors: Abraham Joy, Kaushik Mishra, Yen-Ming Tseng
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Patent number: 11515750Abstract: A permanent magnet machine includes a machine housing and a stator disposed within the machine housing. The machine housing has an inner surface that extends between a first housing end and a second housing end along a central longitudinal axis. The stator has a stator core having an exterior surface and an interior surface, each extending between a first face and a second face along the central longitudinal axis. The stator core defines a plurality of openings that extend from the first face towards the second face.Type: GrantFiled: December 6, 2018Date of Patent: November 29, 2022Assignees: STEERING SOLUTIONS IP HOLDING CORPORATION, THE UNIVERSITY OF AKRONInventors: Kenneth Webber, Delynn Streng, Iftekhar Hasan, Yilmaz Sozer, Alejandro J. Pina Ortega, Jeffrey T. Klass, Mohammed R. Islam
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Patent number: 11499008Abstract: An end and monomer functionalized poly(propylene fumarate) polymer and methods for preparing this polymer, comprising isomerized residue of a maleic anhydride monomer and a functionalized propylene oxide monomer according to the formula: where n is an integer from more than 1 to 100; R is the residue of an initiating alcohol having a propargyl, norbornene, ketone or benzyl functional group; and R? is a second functional group selected from the group consisting of propargyl groups, 2-nitrophenyl groups, and combinations thereof are disclosed. The end and monomer functional groups allow for post-polymerization modification with bioactive materials using “click” chemistries and use of the polymer for a variety of applications in medical fields, including, for example, 3-D printed polymer scaffold.Type: GrantFiled: February 2, 2018Date of Patent: November 15, 2022Assignee: University of AkronInventors: Matthew Becker, James A. Wilson, Yusheng Chen
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Patent number: 11492317Abstract: The present invention relates to a bio-based polyol comprising a thiol-epoxy reaction product of an epoxidized nut or seed oil derivative, and a thiol-containing reactant. The bio-based polyol of the present invention can then be combined with a diisocyanate or a polymeric isocyanate to create a polyurethane material.Type: GrantFiled: May 4, 2020Date of Patent: November 8, 2022Assignee: The University of AkronInventors: Qixin Zhou, Haoran Wang
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Publication number: 20220315753Abstract: A 3D-printable blend comprising a thermoplastic elastomer and a polymer. The thermoplastic elastomer is selected from poly(styrene-b-isobutylene-b-styrene) (SIBS), poly(St-b-butadiene-b-St) (SBS), poly(St-b-isoprene-b-St) (SIS), and their hydrogenated derivatives. The polymer is selected from polystyrene (PSt), poly(2,6-dimethyl-1,4-phenylene oxide) (PPO) and blends of PSt and PPO. The blends may be made into filaments suitable for use in the production of 3D printed articles.Type: ApplicationFiled: April 1, 2022Publication date: October 6, 2022Applicant: THE UNIVERSITY OF AKRONInventors: Joseph P. Kennedy, Weinan Xu
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Publication number: 20220267627Abstract: In various embodiments, the present invention is directed to photothermal-responsive melanin-based nanocomposites comprising a plurality of natural or synthetic melanin nanoparticles distributed with a polymer matrix suitable for use in anti-counterfeiting, photothermal responsive-communication, sensors, and heat management, among other applications. In some embodiments, the present invention will be an ink, paint, or other coating comprising the photothermal-responsive melanin-based nanocomposites. In some embodiments, the present invention is directed to a written message or design comprising one or more of the photothermal-responsive melanin-based nanocomposites. In some of these embodiments, the written message or design will be comprised of two ore more of the photothermal-responsive melanin-based nanocomposites having different concentrations of natural or synthetic melanin nanoparticles.Type: ApplicationFiled: December 13, 2021Publication date: August 25, 2022Applicant: THE UNIVERSITY OF AKRONInventors: Ali Dhinojwala, Mario Echeverri, Anvay Arun Patil
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Patent number: 11421258Abstract: In various aspects, the present invention is directed to a scalable method of producing rhamnolipids by bacterial fermentation with higher product concentrations, yields and productivities and preventing excessive foaming during the cell growth phase when the cell respiration rate is higher. It has been found that by slowing the growth rate of the bacteria by altering the ratio of the nitrogen source to the non-nitrogen source in the initial fermentation medium and supplementing the nitrogen source, excessive foaming in the growth phase can be prevented. Further, by using the non-nitrogen source as the limiting nutrient that initiates the stationary phase and then supplementing fermentation broth with the nitrogen and carbon sources, the length of the standing phase, and with it the time during which rhamnolipid production occurs can be greatly extended.Type: GrantFiled: August 9, 2019Date of Patent: August 23, 2022Assignee: THE UNIVERSITY OF AKRONInventors: Lu-Kwang Ju, Krutika Invally
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Patent number: 11414645Abstract: The present invention relates to a cell culture support comprising a substrate and a polymeric blend layer bound to the substrate. The polymeric blend layer comprises at least one thermoresponsive polymer and at least one coupling agent. The coupling agent is a non-protein coupling agent that has functional thiol, ester, epoxy, or aldehyde groups. The cell culture support further includes cells supported by the polymeric blend layer, wherein the thermoresponsive polymer provides for temperature induced detachment of the cells and/or cell sheets.Type: GrantFiled: January 4, 2019Date of Patent: August 16, 2022Assignee: The University of AkronInventors: Abdullah Alghunaim, Bi-min Zhang Newby
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Patent number: 11396604Abstract: A coating composition may include a polymeric binder and bacteria that exhibit biologically induced mineralization (BIM) or biologically controlled mineralization (BCM) of calcium carbonate (CaCO3) in the presence of environmental calcium. The bacteria may exhibit BIM or BCM of CaCO3 using the ChaA antiporter protein. The coating formulations may be used to form coatings that exhibit self-healing properties in response to damage, such as a cut, tear, puncture, abrasion, or the like. For example, in response to being exposed to the damage, the bacteria may utilize nutrients, a calcium source, and water to cause precipitation of CaCO3 at the site of the damage. The nutrients, the calcium source, and the water may be provided as part of the coating formulation, as part of another layer of a coating system, from an external source (e.g., an applied spray or wash), or combinations thereof.Type: GrantFiled: May 23, 2019Date of Patent: July 26, 2022Assignees: SWIMC LLC, The University of AkronInventors: Hazel A Barton, Kathleen R. Gisser, Tony A. Rook
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Patent number: 11366030Abstract: A tactile sensor including a first insulating layer, an intermediate layer of conductive soft polymer material, and a second insulating layer. The intermediate layer includes first and second electrically conductive strips located therein and the intermediate layer is positioned above the first insulating layer. The first and second electrically conductive strips are located within the same horizontal plane within the intermediate layer and the first and second electrically conductive strips are connected to an impedance measuring device.Type: GrantFiled: November 8, 2019Date of Patent: June 21, 2022Assignee: The University of AkronInventors: Jae-Won Choi, Md. Omar Faruk Emon
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Patent number: 11339486Abstract: An electrocatalytic material includes a bulk material metal including at least one metal, wherein the bulk material metal is in an amorphous form and includes mesopores. A method for making an electrocatalytic material includes forming an amorphous bulk material metal, and forming mesopores in the amorphous bulk material metal. The bulk material metal may in some instances be selected from an alloy of at least one metal and at least one non-metal selected from phosphorus, boron, nitrogen, carbon, and any combination thereof. The at least one metal may in some instances be selected from iron, cobalt, nickel, copper, zinc, titanium, manganese, molybdenum, niobium, zirconium, and any combination thereof.Type: GrantFiled: March 11, 2020Date of Patent: May 24, 2022Assignee: The University of AkronInventors: Zhenmeng Peng, Fei Hu
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Patent number: 11313012Abstract: A method of making an alloy includes mechanically alloying aluminum with an alloying element to form an alloy. The method may include a subsequent step of compacting the alloy powder to form an aluminum alloy compact. The alloying element may be chromium (Cr), nickel (Ni), molybdenum (Mo), titanium (Ti), manganese (Mn), vanadium (V), niobium (Nb), or silicon (Si).Type: GrantFiled: February 21, 2019Date of Patent: April 26, 2022Assignee: The University of AkronInventors: Rajeev Gupta, Javier Esquivel