Patents by Inventor Jeffrey Morse
Jeffrey Morse 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).
-
Publication number: 20240110415Abstract: A multipoint lock including a pivoting lock bolt including a fixed pivot point and a sliding pivot point, a translating lock bolt, a linkage coupled to and configured to pivot the pivoting lock bolt and to translate the translating lock bolt, an actuation mechanism configured to actuate the linkage and to effect pivoting of the pivoting lock bolt and translation of the translating lock bolt, and an input mechanism configured to receive user input and transmit the user input to the actuation mechanism, the user unput including shifting the input mechanism between an unlocked position and a locked position.Type: ApplicationFiled: March 29, 2023Publication date: April 4, 2024Applicant: Pella CorporationInventors: Jeremy Goldstein, Andrew Morse, Benjamin Edwards, Steve Johnson, Jeffrey Bernath
-
Patent number: 10658156Abstract: A system and method for generating a plurality of scan profiles based on a desired implant pattern and the uniformity of the spot beam is disclosed. The system scans the spot beam and records the number of ions as a function of position. This is referred to as the linear uniformity array. The desired implant pattern and the linear uniformity array are then combined to generate a composite pattern array. This array contemplates the non-uniformity of the scanned beam and allows the system to create scan profiles that compensate for this. The software may be executed on the controller disposed in the implantation system, or may be executed on a different computing device.Type: GrantFiled: February 1, 2019Date of Patent: May 19, 2020Assignee: Applied Materials, Inc.Inventors: Stanislav S. Todorov, Jeffrey Morse, John Sawyer
-
Patent number: 10628058Abstract: Embodiments of the invention are directed to systems, methods, and computer program products for verifying, storing, and transferring data within an entity. The system is configured for receiving data from one or more source systems, generating a metadata, exposure, and control statement for the data, transferring the data and the metadata, exposure, and control statement to a system of origination, logically classifying the data in the system of record into one or more domains, transferring the data into one or more authorized data sources associated with the one or more domains, receiving a request from a user associated with a target system to retrieve a set of data from the one or more authorized data sources, and transferring the set of data from the one or more authorized data sources to the target system.Type: GrantFiled: April 26, 2017Date of Patent: April 21, 2020Assignee: BANK OF AMERICA CORPORATIONInventors: Mary Kathleen Riley, Renee Marie Melin, Todd David Abbott, Timothy Lamonte Atwell, Edward W. Carroll, Paresh Bhagwandas Chande, Michele Barker Fasciana, Douglas David Foley, Bryan L. Ford, Christopher Ryan Galloway, James Grae Garrison, Brian P. Gibbons, Kecia Marie Heidebrecht, Gayle Tawanda Jackson, Jeffrey Morse Larmondra, Kimberly Lynn Lewis, Srinivasa D. Madireddi, Gautam Suryakant Nipanikar, Michael Harold Perry, Laurie Readhead, Prakash Srinivasan, Kyle S. Sorensen, Constance Jones Suarez, Jeffrey Roger Walls
-
Publication number: 20070098896Abstract: A system of fabricating a composite membrane from a membrane substrate using solvent-less vapor deposition followed by in-situ polymerization. A first monomer and a second monomer are directed into a mixing chamber in a deposition chamber. The first monomer and the second monomer are mixed in the mixing chamber providing a mixed first monomer and second monomer. The mixed first monomer and second monomer are solvent-less vapor deposited onto the membrane substrate in the deposition chamber. The membrane substrate and the mixed first monomer and second monomer are heated to produce in-situ polymerization and provide the composite membrane.Type: ApplicationFiled: December 4, 2006Publication date: May 3, 2007Inventors: Kevin O'Brien, Stephan Letts, Christopher Spadaccini, Jeffrey Morse, Steven Buckley, Larry Fischer, Keith Wilson
-
Publication number: 20070031586Abstract: Disclosed herein is a metal hydride fuel storage cartridge having integrated resistive heaters that can be used in conjunction with fuel cells such as MEMS-based fuel cells. The cartridge is fabricated using micromachining methods and thin/thick film materials synthesis techniques.Type: ApplicationFiled: October 10, 2006Publication date: February 8, 2007Inventors: Jeffrey Morse, Alan Jankowski, Conrad Yu
-
Publication number: 20070020391Abstract: A system of fabricating a composite membrane from a membrane substrate using solvent-less vapor deposition followed by in-situ polymerization. A first monomer and a second monomer are directed into a mixing chamber in a deposition chamber. The first monomer and the second monomer are mixed in the mixing chamber providing a mixed first monomer and second monomer. The mixed first monomer and second monomer are solvent-less vapor deposited onto the membrane substrate in the deposition chamber. The membrane substrate and the mixed first monomer and second monomer are heated to produce in-situ polymerization and provide the composite membrane.Type: ApplicationFiled: July 14, 2006Publication date: January 25, 2007Inventors: Kevin O'Brien, Stephan Letts, Christopher Spadaccini, Jeffrey Morse, Steven Buckley, Larry Fischer, Keith Wilson
-
Publication number: 20060057039Abstract: Disclosed is a chemical microreactor that provides a means to generate hydrogen fuel from liquid sources such as ammonia, methanol, and butane through steam reforming processes when mixed with an appropriate amount of water. The microreactor contains capillary microchannels with integrated resistive heaters to facilitate the occurrence of catalytic steam reforming reactions. Two distinct embodiment styles are discussed. One embodiment style employs a packed catalyst capillary microchannel and at least one porous membrane. Another embodiment style employs a porous membrane with a large surface area or a porous membrane support structure containing a plurality of porous membranes having a large surface area in the aggregate, i.e., greater than about 1 m2/cm3. Various methods to form packed catalyst capillary microchannels, porous membranes and porous membrane support structures are also disclosed.Type: ApplicationFiled: August 2, 2005Publication date: March 16, 2006Inventors: Jeffrey Morse, Alan Jankowski
-
Publication number: 20060057450Abstract: A microreactor comprising a silicon wafer, a multiplicity of microchannels in the silicon wafer, and a catalyst coating the microchannels. In one embodiment the catalyst coating the microchannels comprises a nanostructured material. In another embodiment the catalyst coating the microchannels comprises an aerogel. In another embodiment the catalyst coating the microchannels comprises a solgel. In another embodiment the catalyst coating the microchannels comprises carbon nanotubes.Type: ApplicationFiled: April 28, 2005Publication date: March 16, 2006Inventors: Jeffrey Morse, David Sopchak, Ravindra Upadhye, John Reynolds, Joe Satcher, Alex Gash
-
Publication number: 20060000548Abstract: Described herein are processes for fabricating microfluidic fuel cell systems with embedded components in which micron-scale features are formed by bonding layers of DuPont Kapton™ polyimide laminate. A microfluidic fuel cell system fabricated using this process is also described.Type: ApplicationFiled: June 14, 2005Publication date: January 5, 2006Inventors: Jeffrey Morse, Alan Jankowski, Robert Graff, Kerry Bettencourt
-
Publication number: 20050260485Abstract: A phosphoric acid fuel cell system comprising a porous electrolyte support, a phosphoric acid electrolyte in the porous electrolyte support, a cathode electrode contacting the phosphoric acid electrolyte, and an anode electrode contacting the phosphoric acid electrolyte.Type: ApplicationFiled: April 28, 2005Publication date: November 24, 2005Inventors: David Sopchak, Jeffrey Morse, Ravindra Upadhye, Jack Kotovsky, Robert Graff
-
Publication number: 20050255369Abstract: Described herein are processes for fabricating microfluidic fuel cell systems with embedded components in which micron-scale features are formed by bonding layers of DuPont Kapton™ polyimide laminate. A microfluidic fuel cell system fabricated using this process is also described.Type: ApplicationFiled: June 14, 2005Publication date: November 17, 2005Inventors: Jeffrey Morse, Alan Jankowski, Robert Graff, Kerry Bettencourt
-
Publication number: 20050207953Abstract: A chemical microreactor with a high aspect ratio. In one embodiment the chemical microreactor has a chemical microreactor section with channels having a height and with spacings having a width. There is a high aspect ratio of the height to the width. The high aspect ratio in one embodiment is more than substantially 5:1. The high aspect ratio in another embodiment is more than substantially 10:1. The high aspect ratio another embodiment is more than substantially 15:1. The high aspect ratio in one embodiment is substantially 20:1.Type: ApplicationFiled: July 20, 2004Publication date: September 22, 2005Inventors: Ravindra Upadhye, Jeffrey Morse, David Sopchak, Mark Havstad, Robert Graff
-
Publication number: 20050106450Abstract: An improved structure for gas diffusion electrodes and gas diffusion layers whereby fine gradients of porosity and hydrophobicity promote efficient gas transport, water removal and overall enhanced performance of Membrane Electrode Assemblies constructed with these components.Type: ApplicationFiled: September 30, 2004Publication date: May 19, 2005Inventors: Emory Castro, Yu-Min Tsou, Maria Cayetano, Jeffrey Morse, Michael Schneider, Hua Deng
-
Publication number: 20050064256Abstract: A MEMS-based fuel cell package and method thereof is disclosed. The fuel cell package comprises seven layers: (1) a sub-package fuel reservoir interface layer, (2) an anode manifold support layer, (3) a fuel/anode manifold and resistive heater layer, (4) a Thick Film Microporous Flow Host Structure layer containing a fuel cell, (5) an air manifold layer, (6) a cathode manifold support structure layer, and (7) a cap. Fuel cell packages with more than one fuel cell are formed by positioning stacks of these layers in series and/or parallel. The fuel cell package materials such as a molded plastic or a ceramic green tape material can be patterned, aligned and stacked to form three dimensional microfluidic channels that provide electrical feedthroughs from various layers which are bonded together and mechanically support a MEMS-based miniature fuel cell. The package incorporates resistive heating elements to control the temperature of the fuel cell stack.Type: ApplicationFiled: September 27, 2004Publication date: March 24, 2005Inventors: Jeffrey Morse, Alan Jankowski
-
Publication number: 20050016832Abstract: Metallic films are grown with a “spongelike” morphology in the as-deposited condition using planar magnetron sputtering. The morphology of the deposit is characterized by metallic continuity in three dimensions with continuous and open porosity on the submicron scale. The stabilization of the spongelike morphology is found over a limited range of the sputter deposition parameters, that is, of working gas pressure and substrate temperature. This spongelike morphology is an extension of the features as generally represented in the classic zone models of growth for physical vapor deposits. Nickel coatings were deposited with working gas pressures up 4 Pa and for substrate temperatures up to 1000 K. The morphology of the deposits is examined in plan and in cross section views with scanning electron microscopy (SEM).Type: ApplicationFiled: July 1, 2003Publication date: January 27, 2005Inventors: Alan Jankowski, Jeffrey Hayes, Jeffrey Morse
-
Publication number: 20020176796Abstract: The present invention relates to methods and treatment systems for inactivation of microbes and/or nucleic acids in biological fluids, especially platelet compositions without completely damaging antigens, enzymes and membrane functions. In accordance with the method of the invention, a biological fluid is illuminated with a light source having at least one wavelength within a range of 170 to 2600 nm to inactivate microbes in the composition and inactivate nucleic acids inside cells without destroying proteins (enzymes) and membrane functions.Type: ApplicationFiled: February 4, 2002Publication date: November 28, 2002Applicant: PurePulse Technologies, Inc.Inventors: Jeffrey Morse Holloway, Kenton Salisbury, William H. Cover, Mark Landers
-
Patent number: 6139716Abstract: A wet chemical process for etching submicron patterned holes in thin metal layers using electrochemical etching with the aid of a wetting agent. In this process, the processed wafer to be etched is immersed in a wetting agent, such as methanol, for a few seconds prior to inserting the processed wafer into an electrochemical etching setup, with the wafer maintained horizontal during transfer to maintain a film of methanol covering the patterned areas. The electrochemical etching setup includes a tube which seals the edges of the wafer preventing loss of the methanol. An electrolyte composed of 4:1 water: sulfuric is poured into the tube and the electrolyte replaces the wetting agent in the patterned holes. A working electrode is attached to a metal layer of the wafer, with reference and counter electrodes inserted in the electrolyte with all electrodes connected to a potentiostat. A single pulse on the counter electrode, such as a 100 ms pulse at +10.Type: GrantFiled: May 18, 1999Date of Patent: October 31, 2000Assignee: The Regents of the University of CaliforniaInventors: Anthony M. McCarthy, Robert J. Contolini, Vladimir Liberman, Jeffrey Morse
-
Patent number: D538299Type: GrantFiled: December 6, 2005Date of Patent: March 13, 2007Inventor: Jeffrey A. Morse
-
Patent number: D553769Type: GrantFiled: December 6, 2005Date of Patent: October 23, 2007Inventor: Jeffrey A. Morse
-
Patent number: D562735Type: GrantFiled: December 6, 2005Date of Patent: February 26, 2008Inventor: Jeffrey A. Morse