Patents by Inventor Robert J. Woods
Robert J. Woods has filed for patents to protect the following inventions. This listing includes patent applications that are pending as well as patents that have already been granted by the United States Patent and Trademark Office (USPTO).
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Publication number: 20210215554Abstract: A strain sensor comprising a conductive member having a plurality of elements arranged adjacent to one another, and a non-conductive and elastically deformable material encapsulating the conductive member, wherein, in an equilibrium state, compressive forces cause at least one of the plurality of elements to contact at least a portion of an adjacent element, and wherein, when a strain is applied, a resulting elastic deformation causes at least one of the plurality of elements to space apart from an adjacent element such that the contacted portion decreases or is eliminated. A multi-axis force sensor comprising a sensing array comprising at least two planar sensors arranged radially on a planar substrate in antagonistic pairs, and a compressible member positioned between the substrate and a central portion of the sensing array, the compressible member acting to displace the central portion of the sensing array away from the substrate.Type: ApplicationFiled: May 20, 2019Publication date: July 15, 2021Applicant: President and Follows of Harvard CollegeInventors: Oluwaseun A. Araromi, Conor J. Walsh, Robert J. Wood
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Patent number: 11014804Abstract: Systems and methods for fabricating 3D soft microstructures. The system comprises injecting a pressurized, curable liquid into certain structural layers induces folding and allows the 2D structures to reconfigure into a 3D form In addition to the injection of a curable liquid that permanently reconfigures the structure of the system, in an embodiment this method also allows for the injection of other liquids into certain actuator layers that enable motion in certain portions of the system Furthermore, the system allows for handling of colored fluids that are passed to visualization layers. The method of creating such a system depends on taking advantage of laser machining of the individual layers to influence the behavior of how different portions bend and move.Type: GrantFiled: March 14, 2018Date of Patent: May 25, 2021Assignee: President and Fellows of Harvard CollegeInventors: Nicholas W. Bartlett, Tommaso Ranzani, Sheila Russo, Conor J. Walsh, Michael Wehner, Robert J. Wood
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Patent number: 11001824Abstract: The carbohydrate processing enzyme PNGase F was catalytically inactivated through mutation. Additional mutations yielded a catalytically inactive carbohydrate-binding protein with lectin-like properties including high affinity and specificity N-linked glycans, O-linked glycans, or both.Type: GrantFiled: June 14, 2019Date of Patent: May 11, 2021Assignee: University of Georgia Research Foundation, Inc.Inventors: Kausar N. Samli, Robert J. Woods, Loretta Yang
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Publication number: 20210009975Abstract: Sialic acid recognizing-affinity reagents engineered from the neuraminidase NanB have lectin-like properties and defined specificities for sialic acid.Type: ApplicationFiled: April 24, 2018Publication date: January 14, 2021Inventors: Loretta Yang, Kausar N. Samli, Robert J. Woods, Shengcheng Wu, John C. Cooper, Mallory K. Paul, Matthew J. Saunders, Ziad M. Eletr
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Patent number: 10888222Abstract: A system and a method for testing a visual field of a subject are described. The method includes determining inter-eye distance of the subject. Visual stimuli are displayed on a left display region and a right display region of a two-dimensional display to the subject based on the determined inter-eye distance. The left display region is configured to display content specific to the left eye and the right display region is configured to display content specific to the right eye of the subject. Subject responses to the visual stimuli are tracked. Based on the subject responses, a condition of the visual field of each eye the subject is evaluated and then results of the evaluation describing the subject's visual field condition is reported or stored.Type: GrantFiled: April 20, 2017Date of Patent: January 12, 2021Assignees: CARL ZEISS MEDITEC, INC., CARL ZEISS MEDITEC AGInventors: Matthias Monhart, Maximilian Stocker, Robert J. Wood
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Publication number: 20200403193Abstract: Methods and apparatus for fabricating a lightweight high power battery. The battery comprises an active structure including an anode electrode, a cathode electrode, and a separator material arranged between the anode electrode and the cathode electrode, a liquid electrolyte; and a non-metallic pouch arranged to encapsulate the active structure and the liquid electrolyte.Type: ApplicationFiled: March 6, 2019Publication date: December 24, 2020Applicant: President and Fellows of Harvard CollegeInventors: Mihai Duduta, David Clarke, Robert J. Wood, Sebastien de Rivaz
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Patent number: 10813546Abstract: A thermal powered medical device generates power from a temperature differential between a living body and a differential temperature source. The power is supplied to power one or more electrical components of the medical device.Type: GrantFiled: May 29, 2019Date of Patent: October 27, 2020Assignee: WELCH ALLYN, INC.Inventors: Robert J. Wood, Steven D. Baker
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Patent number: 10780591Abstract: A method of making an actuator having a complex internal shape includes providing a core of a shape that defines an internal cavity of an actuator; molding an actuator around the core, wherein the core occupies the internal cavity of the actuator, the cavity having an opening; generating a pressure differential between an exterior surface of the actuator and the internal cavity of the actuator, wherein the external pressure is less than the internal pressure, to expand the actuator cavity; and removing the core through the opening of the expanded actuator cavity.Type: GrantFiled: January 19, 2017Date of Patent: September 22, 2020Assignee: President and Fellows of Harvard CollegeInventors: Kevin C. Galloway, Robert J. Wood, Kaitlyn Becker
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Patent number: 10689044Abstract: A pneumatically powered, fully untethered mobile soft robot is described. Composites consisting of silicone elastomer, polyaramid fabric, and hollow glass microspheres were used to fabricate a sufficiently large soft robot to carry the miniature air compressors, battery, valves, and controller needed for autonomous operation. Fabrication techniques were developed to mold a 0.65 meter long soft body with modified Pneumatic network actuators capable of operating at the elevated pressures (up to 138 kPa) required to actuate the legs of the robot and hold payloads of up to 8 kg. The soft robot is safe to handle, and its silicone body is innately resilient to a variety of adverse environmental conditions including snow, puddles of water, direct (albeit limited) exposure to flames, and the crushing force of being run over by an automobile.Type: GrantFiled: June 30, 2015Date of Patent: June 23, 2020Assignee: President and Fellows of Harvard CollegeInventors: Michael T. Tolley, Robert F. Shepherd, Bobak Mosadegh, Robert J. Wood, George M. Whitesides
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Patent number: 10668825Abstract: An Engine Start and Battery Support Module for a vehicle is provided that utilizes a bank of Ultra Capacitors (UCs) charged with or without running the vehicle's alternator to levels that support both engine starting assistance and hotel load support. The UCs' per-cell charge can be adjusted and raised during periods of low temperatures and even higher during ultralow temperatures. The adjustment, which can be dynamic and/or automatic, increases the UC energy storage capability. Further, the release of energy from the UCs is controlled by a pulse width modulation (PWM) controller based on the DC bus voltage. The UCs can be charged either from an onboard DC/DC converter, an AC hook up, or from smartly switching the banks of UCs between parallel and serial configurations.Type: GrantFiled: July 10, 2018Date of Patent: June 2, 2020Assignee: Ioxus, Inc.Inventors: Robert J. Wood, Chad Hall, Daniel A. Patsos, Jeff Colton, Bryce Gregory
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Publication number: 20200130175Abstract: An artificial muscle system includes a collapsible skeleton, a flexible skin, and a muscle actuation mechanism. The collapsible skeleton is contained inside a volume defined, at least in part, by the flexible skin. The flexible skin and the collapsible skeleton are configured for the flexible skin to provide a pulling force on the collapsible skeleton when a pressure difference exists between the inside of the sealed volume and a surrounding environment to change at least one of the dimensions and thus geometry of the collapsible skeleton. The muscle actuation mechanism includes at least one of the following to deploy or contract the collapsible skeleton: (a) a fluid displacing, releasing, or capturing mechanism configured to increase or decrease fluid pressure inside the sealed volume; and (b) a heating or cooling element configured to change the temperature of fluid in the sealed volume.Type: ApplicationFiled: March 22, 2018Publication date: April 30, 2020Applicants: President and Fellows of Harvard College, Massachusetts Institute of TechnologyInventors: Shuguang Li, Robert J. Wood, Daniela Rus, Daniel M. Vogt, Nicholas W. Bartlett
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Patent number: 10612986Abstract: A printed stretchable strain sensor comprises a seamless elastomeric body and a strain-sensitive conductive structure embedded in the seamless elastomeric body. The strain-sensitive conductive structure comprises one or more conductive filaments arranged in a continuous pattern. A method of printing a stretchable strain sensor comprises depositing one or more conductive filaments in a predetermined continuous pattern into or onto a support matrix. After the depositing, the support matrix is cured to embed a strain-sensitive conductive structure in a seamless elastomeric body.Type: GrantFiled: October 11, 2018Date of Patent: April 7, 2020Assignee: President and Fellows of Harvard CollegeInventors: Jennifer A. Lewis, Joseph T. Muth, Daniel M. Vogt, Ryan L. Truby, Yigit Menguc, David B. Kolesky, Robert J. Wood
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Publication number: 20200079643Abstract: Systems and methods for fabricating 3D soft microstructures. The system comprises injecting a pressurized, curable liquid into certain structural layers induces folding and allows the 2D structures to reconfigure into a 3D form In addition to the injection of a curable liquid that permanently reconfigures the structure of the system, in an embodiment this method also allows for the injection of other liquids into certain actuator layers that enable motion in certain portions of the system Furthermore, the system allows for handling of colored fluids that are passed to visualization layers. The method of creating such a system depends on taking advantage of laser machining of the individual layers to influence the behavior of how different portions bend and move.Type: ApplicationFiled: March 14, 2018Publication date: March 12, 2020Applicant: President and Fellows of Harvard CollegeInventors: Nicholas W. Bartlett, Tommaso Ranzani, Sheila Russo, Conor J. Walsh, Michael Wehner, Robert J. Wood
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Patent number: 10575732Abstract: An example system includes a patch defining a first surface and a second surface opposite the first surface. The first surface is removably attachable to skin of a subject. The patch includes a conductor associated with the first surface, a first sensor configured to determine a temperature of the conductor, and a second sensor configured to determine an additional temperature. The first sensor is separated from the second sensor by material having a known thermal resistance. The patch also includes a transmitter operably connected to the first and second sensors.Type: GrantFiled: December 30, 2016Date of Patent: March 3, 2020Assignee: Welch Allyn, Inc.Inventors: Robert J. Wood, Raymond A. Lia, Jon R. Salvati, Steven D. Baker
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Patent number: 10562260Abstract: A pneumatic artificial muscle (PAM) actuator body can be formed from an elastic material that includes an inflatable chamber and a restraining component, such as flexible, but inextensible fibers, that causes the actuator to contract when the chamber is inflated with fluid (e.g., air or water). The actuator body can be cylindrical or flat. The actuator body can include a sensor layer formed of an elastic material including a microchannel filled with a conductive fluid to sense the expansion of the actuator body. The sensor layer can be configured to expand when the actuator body is inflated causing the electrical resistance of the conductive fluid to change. A sensor layer between the actuator body and restraining component can be used to measure changes in the contraction force of the actuator and a sensor layer outside of the restraining component can be used to measure changes in the length of the actuator.Type: GrantFiled: January 21, 2014Date of Patent: February 18, 2020Assignee: President and Fellows of Harvard CollegeInventors: Yong-Lae Park, Robert J. Wood, Jobim Jose Robinsantos, Eugene C. Goldfield
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Publication number: 20200015920Abstract: A multi-layer, super-planar laminate structure can be formed from distinctly patterned layers. The layers in the structure can include at least one rigid layer and at least one flexible layer; the rigid layer includes a plurality of rigid segments, and the flexible layer can extend between the rigid segments to serve as a joint. The layers are then stacked and bonded at selected locations to form a laminate structure with inter-layer bonds, and the laminate structure is flexed at the flexible layer between rigid segments to produce an expanded three-dimensional structure, wherein the layers are joined at the selected bonding locations and separated at other locations. A layer with electrical wiring can be included in the structure for delivering electric current to devices on or in the laminate structure.Type: ApplicationFiled: July 30, 2019Publication date: January 16, 2020Applicant: President and Fellows of Harvard CollegeInventors: Joshua B. Gafford, Samuel B. Kesner, Conor J. Walsh, Michael Karpelson, Robert J. Wood, Zivthan Dubrovsky, Benjamin I. Goldberg, Kathleen O'Donnell, Michael J. Smith
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Patent number: 10527507Abstract: An elastic strain sensor can be incorporated into an artificial skin that can sense flexing by the underlying support structure of the skin to detect and track motion of the support structure. The unidirectional elastic strain sensor can be formed by filling two or more channels in an elastic substrate material with a conductive liquid. At the ends of the channels, a loop port connects the channels to form a serpentine channel. The channels extend along the direction of strain and the loop portions have sufficiently large cross-sectional area in the direction transverse to the direction of strain that the sensor is unidirectional. The resistance is measured at the ends of the serpentine channel and can be used to determine the strain on the sensor. Additional channels can be added to increase the sensitivity of the sensor. The sensors can be stacked on top of each other to increase the sensitivity of the sensor.Type: GrantFiled: November 27, 2017Date of Patent: January 7, 2020Assignee: President and Fellows of Harvard CollegeInventors: Robert J. Wood, Yong-Lae Park, Carmel S. Majidi, Bor-rong Chen, Leia Stirling, Conor James Walsh, Radhika Nagpal, Diana Young, Yigit Menguc
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Publication number: 20190328305Abstract: A system and a method for testing a condition of a subject's nervous system using virtual reality technology are described. The method includes displaying a visual stimulus to the subject in a virtual reality environment. Eye and body movements of the subject are tracked as the subject focuses on the visual stimulus. The body movements may include head movements. Based on the eye and body movements, the condition of the subject's nervous system is evaluated and then results of the evaluation describing the subject's nervous system condition is reported to a user, such as a clinician, for further analysis thereof.Type: ApplicationFiled: January 18, 2017Publication date: October 31, 2019Applicants: Carl Zeiss Meditec, Inc., Carl Zeiss Meditec AG, Carl Zeiss Meditec AGInventors: Robert J. WOOD, Matthias MONHART, Maximilian STOCKER
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Publication number: 20190313927Abstract: A thermal powered medical device generates power from a temperature differential between a living body and a differential temperature source. The power is supplied to power one or more electrical components of the medical device.Type: ApplicationFiled: May 29, 2019Publication date: October 17, 2019Inventors: Robert J. Wood, Steven D. Baker
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Patent number: 10376326Abstract: A multi-layer, super-planar laminate structure can be formed from distinctly patterned layers. The layers in the structure can include at least one rigid layer and at least one flexible layer; the rigid layer includes a plurality of rigid segments, and the flexible layer can extend between the rigid segments to serve as a joint. The layers are then stacked and bonded at selected locations to form a laminate structure with inter-layer bonds, and the laminate structure is flexed at the flexible layer between rigid segments to produce an expanded three-dimensional structure, wherein the layers are joined at the selected bonding locations and separated at other locations. A layer with electrical wiring can be included in the structure for delivering electric current to devices on or in the laminate structure.Type: GrantFiled: August 4, 2014Date of Patent: August 13, 2019Assignee: President and Fellows of Harvard CollegeInventors: Joshua B. Gafford, Samuel B. Kesner, Conor J. Walsh, Michael Karpelson, Robert J. Wood, Zivthan Dubrovsky, Benjamin I. Goldberg, Kathleen O'Donnell, Michael J. Smith