Patents by Inventor Athanasios Iliopoulos
Athanasios Iliopoulos 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: 20220048255Abstract: An additive manufacturing device includes a container bed configured to contain material powder; a printing bed over which material is deposited and heat applied; one or more heating elements configured to hold material on the printing bed and material on the container bed at temperatures higher than ambient; one or more actuators; and a two-dimensional array of heat deposition devices configured for a 2D space filling movement by the one or more actuators in a plane generally perpendicular to an optical axis of the heat deposition devices.Type: ApplicationFiled: August 16, 2021Publication date: February 17, 2022Inventors: Athanasios Iliopoulos, John G. Michopoulos, John C. Steuben, Benjamin D. Graber, Andrew J. Birnbaum
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Patent number: 11119466Abstract: A method for flexible functionally tailorable slicing for additive manufacturing includes the steps of receiving and parsing an input model of an object to be additively manufactured; reconstructing a domain boundary of the object; computing individual layer boundaries of the object; constructing, for each layer, layer domains from respective enclosing boundaries; computing, for each layer, a perimeter shell and a volumetric infill by finding level sets of a field function selected by a user; collecting and arranging into a coherent sequence each perimeter shell and volumetric infill; and formatting the coherent sequence as motion commands for an additive manufacturing system.Type: GrantFiled: December 1, 2017Date of Patent: September 14, 2021Assignee: The Government of the United States of America, as represented by the Secretary of the NavyInventors: John Michopoulos, Athanasios Iliopoulos, John Steuben
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Patent number: 10639847Abstract: A method and apparatus for volumetric manufacture of three-dimensional physical objects from a precursor material based on plans, specifications, or virtual models. A build domain is provided comprising an enclosed three-dimensional wire grid in which the wires are connected to one or more electric power sources configured to controllably and addressably apply power to one or more individual wires to cause the wires to dissipate heat produced by Joule heating to the surrounding precursor material situated within the build domain, and to further allow for the control of the three-dimensional heat distribution and accordingly temperature distribution within the build domain. By activating and deactivating one or more predetermined subsets of the wires in the build domain, the precursor can be caused to melt and/or solidify so as to form a three-dimensional object within the build domain.Type: GrantFiled: January 23, 2018Date of Patent: May 5, 2020Assignee: The Government of the United States of America, as represented by the Secretary of the NavyInventors: Andrew J. Birnbaum, Athanasios Iliopoulos, John Steuben, John G. Michopoulos
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Publication number: 20180215094Abstract: A method and apparatus for volumetric manufacture of three-dimensional physical objects from a precursor material based on plans, specifications, or virtual models. A build domain is provided comprising an enclosed three-dimensional wire grid in which the wires are connected to one or more electric power sources configured to controllably and addressably apply power to one or more individual wires to cause the wires to dissipate heat produced by Joule heating to the surrounding precursor material situated within the build domain, and to further allow for the control of the three-dimensional heat distribution and accordingly temperature distribution within the build domain. By activating and deactivating one or more predetermined subsets of the wires in the build domain, the precursor can be caused to melt and/or solidify so as to form a three-dimensional object within the build domain.Type: ApplicationFiled: January 23, 2018Publication date: August 2, 2018Applicant: The Government of the United States of America, as represented by the Secretary of the NavyInventors: Andrew J. Birnbaum, Athanasios Iliopoulos, John Steuben, John G. Michopoulos
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Publication number: 20180157243Abstract: A method for flexible functionally tailorable slicing for additive manufacturing includes the steps of receiving and parsing an input model of an object to be additively manufactured; reconstructing a domain boundary of the object; computing individual layer boundaries of the object; constructing, for each layer, layer domains from respective enclosing boundaries; computing, for each layer, a perimeter shell and a volumetric infill by finding level sets of a field function selected by a user; collecting and arranging into a coherent sequence each perimeter shell and volumetric infill; and formatting the coherent sequence as motion commands for an additive manufacturing system.Type: ApplicationFiled: December 1, 2017Publication date: June 7, 2018Inventors: John Michopoulos, Athanasios Iliopoulos, John Steuben
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Patent number: 9311566Abstract: A method and system for measuring and determining the full-field spatial distributions of strain tensor field components in a two or three-dimensional space, as a consequence of deformation under generalized loading conditions. One or more digital cameras may be used to acquire successive images of a deforming body with optically distinctive features on its surface. A method for determining the location of characteristic points of the surface features and another one for tracking these points as deformation occurs. Elongations between neighboring points on the vicinity of a location of interest are computed. The elongation between points is calculated even though discontinuities may exist between them. Strain tensor fields are directly calculated as a tensor approximation from these elongations without determining or using the displacement vector distributions.Type: GrantFiled: August 2, 2013Date of Patent: April 12, 2016Assignees: George Mason Research Foundation, Inc., The United States of America, as Represented by the Secretary of the NavyInventors: Athanasios Iliopoulos, John G. Michopoulos
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Patent number: 9046353Abstract: A method and system for measuring full field deformation characteristics in three dimensions of a body upon which a pattern of visible marks has been applied. The method includes receiving images of the pattern of marks from at least two digital video cameras as the specimen deforms. A computer processor identifies the centroids of each of the two camera images of the body in a first frame, matches the centroids of the marks in the two images, and generates a three-dimensional representation of the centroids based on the two images, and repeats these steps for the images from the two cameras in a subsequent frame. The computer processor calculates the displacement vector between a three dimensional representation of the centroids and the subsequent three dimensional representation of the centroids, and calculates full field displacement and strain fields based on the displacement vector.Type: GrantFiled: August 2, 2012Date of Patent: June 2, 2015Assignee: The United States of America as represented by the Secretary of the NavyInventors: John G. Michopoulos, Athanasios Iliopoulos, Nikos P. Andrianopoulos
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Patent number: 8978480Abstract: A recursive hexapod testing machine for mechanical testing of deformable material specimens under six degrees of freedom multiaxial loading. The machine includes a fixed base, a movable base connected to the fixed base at by a hexapod arrangement of six linearly extendable actuator linkages, with an end of each linkages attached to the movable base and the other end of the linkage attached to the fixed base. Each actuator linkage includes a hydraulic cylinder and piston, a digitally-controlled electro-hydraulic servo-valve for actuating the hydraulic cylinder in response to a digital command string, a load cell in line between the piston and the universal joint attached to the movable base, a linear variable displacement transducer for measuring extension of the piston, and a magneto-resistive position transducer for measuring a position of the piston. The servo-valves extend each hydraulic cylinder a predetermined amount to effect a desired motion of the material specimen.Type: GrantFiled: August 2, 2012Date of Patent: March 17, 2015Assignees: The United States of America, as represented by the Secretary of the Navy, The United States of America as represented by the Secretary of AgricultureInventors: John G. Michopoulos, John C. Hermanson, Athanasios Iliopoulos
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Patent number: 8884954Abstract: A computer implemented method for directly determining parameters defining a Weierstrass-Mandelbrot (W-M) analytical representation of a rough surface scalar field with fractal character, embedded in a three dimensional space, utilizing pre-existing measured elevation data of a rough surface in the form of a discrete collection of data describing a scalar field at distinct spatial coordinates, is carried out by applying an inverse algorithm to the elevation data to thereby determine the parameters that define the analytical and continuous W-M representation of the rough surface. The invention provides a comprehensive approach for identifying all parameters of the W-M function including the phases and the density of the frequencies that must greater than 1. This enables the infinite-resolution analytical representation of any surface or density array through the W-M fractal function.Type: GrantFiled: August 10, 2012Date of Patent: November 11, 2014Assignee: The United States of America, as represented by the Secretary of the NavyInventors: John G. Michopoulos, Athanasios Iliopoulos
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Publication number: 20140037217Abstract: A method and system for measuring and determining the full-field spatial distributions of strain tensor field components in a two or three-dimensional space, as a consequence of deformation under generalized loading conditions. One or more digital cameras may be used to acquire successive images of a deforming body with optically distinctive features on its surface. A method for determining the location of characteristic points of the surface features and another one for tracking these points as deformation occurs. Elongations between neighboring points on the vicinity of a location of interest are computed. The elongation between points is calculated even though discontinuities may exist between them. Strain tensor fields are directly calculated as a tensor approximation from these elongations without determining or using the displacement vector distributions.Type: ApplicationFiled: August 2, 2013Publication date: February 6, 2014Inventors: Athanasios Iliopoulos, John G. Michopoulos
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Publication number: 20140025353Abstract: A computer implemented method for obtaining an analytical representation of an internal structure and spatial properties distribution of a selected physical domain includes identifying d-dimensional correspondences of measured spatial properties or field distributions; and applying an inverse algorithm to the d-dimensional spatial properties or field distributions to calculate the Weierstrass-Mandelbrot (W-M) fractal model to thereby determine parameters defining an analytical and continuous Weierstrass-Mandelbrot (W-M) representation.Type: ApplicationFiled: June 12, 2013Publication date: January 23, 2014Applicant: The Government of United States of America, as represented by the Secretary of the NavyInventors: John G. Michopoulos, Athanasios Iliopoulos
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Publication number: 20130063570Abstract: A method and system for measuring full field deformation characteristics in three dimensions of a body upon which a pattern of visible marks has been applied. The method includes receiving images of the pattern of marks from at least two digital video cameras as the specimen deforms. A computer processor identifies the centroids of each of the two camera images of the body in a first frame, matches the centroids of the marks in the two images, and generates a three-dimensional representation of the centroids based on the two images, and repeats these steps for the images from the two cameras in a subsequent frame. The computer processor calculates the displacement vector between a three dimensional representation of the centroids and the subsequent three dimensional representation of the centroids, and calculates full field displacement and strain fields based on the displacement vector.Type: ApplicationFiled: August 2, 2012Publication date: March 14, 2013Inventors: John G. Michopoulos, Athanasios Iliopoulos, Nikos P. Andrianopoulos
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Publication number: 20130055825Abstract: A recursive hexapod testing machine for mechanical testing of deformable material specimens under six degrees of freedom multiaxial loading. The machine includes a fixed base, a movable base connected to the fixed base at by a hexapod arrangement of six linearly extendable actuator linkages, with an end of each linkages attached to the movable base and the other end of the linkage attached to the fixed base. Each actuator linkage includes a hydraulic cylinder and piston, a digitally-controlled electro-hydraulic servo-valve for actuating the hydraulic cylinder in response to a digital command string, a load cell in line between the piston and the universal joint attached to the movable base, a linear variable displacement transducer for measuring extension of the piston, and a magneto-resistive position transducer for measuring a position of the piston. The servo-valves extend each hydraulic cylinder a predetermined amount to effect a desired motion of the material specimen.Type: ApplicationFiled: August 2, 2012Publication date: March 7, 2013Applicants: The US in the name of the Secretary of Agriculture, The Government of the US, as represented by the Secretary of the NavyInventors: John G. Michopoulos, John C. Hermanson, Athanasios Iliopoulos
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Publication number: 20130050210Abstract: A computer implemented method for directly determining parameters defining a Weierstrass-Mandelbrot (W-M) analytical representation of a rough surface scalar field with fractal character, embedded in a three dimensional space, utilizing pre-existing measured elevation data of a rough surface in the form of a discrete collection of data describing a scalar field at distinct spatial coordinates, is carried out by applying an inverse algorithm to the elevation data to thereby determine the parameters that define the analytical and continuous W-M representation of the rough surface. The invention provides a comprehensive approach for identifying all parameters of the W-M function including the phases and the density of the frequencies that must greater than 1. This enables the infinite-resolution analytical representation of any surface or density array through the W-M fractal function.Type: ApplicationFiled: August 10, 2012Publication date: February 28, 2013Inventors: John Michopoulos, Athanasios Iliopoulos
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Publication number: 20100310128Abstract: A computer-implemented method for measuring full field deformation characteristics of a deformable body. The method includes determining optical setup design parameters for measuring displacement and strain fields, and generating and applying a dot pattern on a planar side of a deformable body. A sequence of images of the dot pattern is acquired before and after deformation of the body. Irregular objects are eliminated from the images based on dot light intensity threshold and the object area or another geometrical cutoff criterion. The characteristic points of the dots are determined, and the characteristic points are matched between two or more of the sequential images. The displacement vector of the characteristic points is found, and mesh free or other techniques are used to estimate the full field displacement based on the displacement vector of the characteristic points. Strain tensor or other displacement-derived quantities can also be estimated using mesh-free or other analysis techniques.Type: ApplicationFiled: June 3, 2010Publication date: December 9, 2010Inventors: Athanasios Iliopoulos, John G. Michopoulos, Nikos Andrianopoulos