Tobias A Schaedler from 796 Oak Path Ct, Calabasas, CA 91377, age 46, Phone: (805) 886-4213

Resumes

Manager, Architected Materials Group

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Location:

Los Angeles, CA

Industry:

Research

Work:

Hrl Laboratories, Llc Dec 1, 2009 - Dec 2018
Senior Scientist
Hrl Laboratories, Llc Dec 1, 2009 - Dec 2018
Director, Center For Additive Materials
Hrl Laboratories, Llc Dec 1, 2009 - Dec 2018
Manager, Architected Materials Group
Ge Jul 2007 - Nov 2009
Lead Engineer and Technologist
Uc Santa Barbara Jan 2007 - Jul 2007
Postdoctoral Researcher

Education:

University of Bayreuth 2015 - 2015
Uc Santa Barbara 2001 - 2006
Doctorates, Doctor of Philosophy, Materials Science University of Bayreuth 1998 - 2001

Skills:

Materials Science
Characterization
Microscopy
Tem
R&D
Materials
Scanning Electron Microscopy
Fuel Cells
Simulations
Lithium Ion Batteries
Thermal Management
Modeling
Nanotechnology
Physics
Ceramic Materials
Acoustics
Electroplating
Thin Films
Spectroscopy
Nanomaterials
Research and Development
Jet Engines
Matlab
Afm

Languages:

German
English

Certifications:

Six Sigma Green Belt

Publications

Us Patents

Compressible Fluid Filled Micro-Truss For Energy Absorption

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US Patent:

8353240, Jan 15, 2013

Filed:

Dec 22, 2010

Appl. No.:

12/928947

Inventors:

Tobias A. Schaedler - Santa Monica CA, US
Alan J. Jacobsen - Woodland Hills CA, US
William Carter - Calabasas CA, US
Yu Qiao - San Diego CA, US

Assignee:

HRL Laboratories, LLC - Malibu CA
Regents of the University of CA - Oakland CA

International Classification:

F41H 5/02
F41H 1/00

US Classification:

89 3602, 89 3605, 89920, 89921

Abstract:

A kinetic energy and blast energy absorbing material includes: a micro-truss structure including: a plurality of first struts extending along a first direction; a plurality of second struts extending along a second direction; and a plurality of third struts extending along a third direction; and a compressible fluid comprising a liquid or gel and a nanoporous material, wherein the micro-truss structure contains the compressible fluid.

Durable Thermal Barrier Coating Compositions, Coated Articles, And Coating Methods

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US Patent:

20100159262, Jun 24, 2010

Filed:

Dec 18, 2008

Appl. No.:

12/338329

Inventors:

Ming Fu - Hamilton OH, US
Brian Thomas Hazel - West Chester OH, US
Brett Boutwell - West Chester OH, US
Tobias A. Schaedler - Cincinnati OH, US
Curtis Alan Johnson - Niskayuna NY, US
Don M. Lipkin - Niskayuna NY, US
Douglas G. Konitzer - West Chester OH, US
Venkat S. Venkataramani - Clifton Park NY, US

International Classification:

B32B 15/04
C04B 35/48
C23C 4/10
C23C 14/34

US Classification:

428472, 501134, 427453, 20419215

Abstract:

A composition useful as a thermal barrier coating on a superalloy substrate intended for use in hostile thermal environments. The coating comprises zirconia stabilized in a predominately tetragonal phase. The composition includes a ceramic component consisting essentially of zirconia (ZrO2) or a combination of zirconia and hafnia (HfO2) and a stabilizer component comprising, in combination, a first co-stabilizer selected from YbO1.5, HoO1.5, ErO1.5, TmO1.5, LuO1.5, and combinations thereof, and optionally YO1.5, a second co-stabilizer selected from TiO2, PdO2, VO2, GeO2, and combinations thereof, and a third co-stabilizer comprising TaO2.5. The stabilizer component is present in an amount effective to achieve the predominantly tetragonal phase in the coating.

Durable Thermal Barrier Coating Compositions, Coated Articles, And Coating Methods

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US Patent:

20100159270, Jun 24, 2010

Filed:

Dec 18, 2008

Appl. No.:

12/337971

Inventors:

International Classification:

B32B 15/04
C23C 14/34
B05D 1/36

US Classification:

428640, 428639, 4274192, 2041921, 427454

Abstract:

A composition useful as a thermal barrier coating on a superalloy substrate intended for use in hostile thermal environments. The coating comprises zirconia stabilized in a predominately tetragonal phase. The composition includes a ceramic component consisting essentially of zirconia (ZrO2) or a combination of zirconia and hafnia (HfO2) and a stabilizer component comprising, in combination, a first co-stabilizer selected from YbO1.5, HoO1.5, ErO1.5, TmO1.5, LuO1.5, and combinations thereof, and a second co-stabilizer selected from TiO2, PdO2, VO2, GeO2, and combinations thereof. Optionally, the stabilizer component includes Y2O3. The stabilizer component is present in an amount effective to achieve the predominantly tetragonal phase in the coating.

Net-Shape Structure With Micro-Truss Core

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US Patent:

20130143060, Jun 6, 2013

Filed:

Dec 6, 2011

Appl. No.:

13/312952

Inventors:

Alan J. Jacobsen - Woodland Hills CA, US
Tobias A. Schaedler - Oak Park CA, US
Christopher S. Roper - Santa Monica CA, US

International Classification:

B32B 3/12
B32B 15/02
C25D 5/34
B05D 3/02
B29C 65/00
B32B 7/04
B29C 35/08

US Classification:

428594, 4283044, 4283193, 264425, 427314, 156278, 205209

Abstract:

A curved, three-dimensional, ordered micro-truss structure comprising: a plurality of first struts extending along a first direction; a plurality of second struts extending along a second direction; and a plurality of third struts extending along a third direction, wherein the first, second, and third struts interpenetrate one another at a plurality of nodes, wherein the pluralities of first struts, second struts, third struts, and nodes form a plurality of ordered unit cells within the micro-truss structure, and wherein the plurality of ordered unit cells define a curved surface.

Modular Photonic Reflectors

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US Patent:

20220365259, Nov 17, 2022

Filed:

May 17, 2021

Appl. No.:

17/322481

Inventors:

- Malibu CA, US
Phuong Phuc Nam BUI - Thousand Oaks CA, US
Tobias Anton SCHAEDLER - Malibu CA, US
Shanying CUI - Calabasas CA, US

Assignee:

HRL Laboratories, LLC - Malibu CA

International Classification:

G02B 5/02
G02B 1/00
G02B 5/124

Abstract:

A photonic reflector device includes a first layer, a second layer, and a third layer. The first layer, which functions as a retro-reflector, is formed of a first material contacting a second material and having a non-planar interface therebetween. The second layer, which functions as a photonic crystal, includes third and fourth materials that have different refractive indices from one another and are configured such that the second layer has a periodic optical potential along at least one dimension. The third layer, which functions as a Lambertian scatterer, includes a plurality of inclusions in a first matrix material. In combination, the layers may be optimized to synergistically reflect targeted wavelengths and/or polarizations of light.

Semi-Passive Control Of Solidification In Powdered Materials

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US Patent:

20220314316, Oct 6, 2022

Filed:

Jun 10, 2022

Appl. No.:

17/838000

Inventors:

- Malibu CA, US
Tobias A. SCHAEDLER - Oak Park CA, US
Brennan YAHATA - Santa Barbara CA, US
Jacob M. HUNDLEY - Thousand Oaks CA, US
Jason A. GRAETZ - Calabasas CA, US
Adam F. GROSS - Santa Monica CA, US
William CARTER - Calabasas CA, US

International Classification:

B22F 3/10
B33Y 10/00
B33Y 70/00
B29C 64/153

Abstract:

Disclosed herein are surface-functionalized powders which alter the solidification of the melted powders. Some variations provide a powdered material comprising a plurality of particles fabricated from a first material, wherein each of the particles has a particle surface area that is continuously or intermittently surface-functionalized with nanoparticles and/or microparticles selected to control solidification of the powdered material from a liquid state to a solid state. Other variations provide a method of controlling solidification of a powdered material, comprising melting at least a portion of the powdered material to a liquid state, and semi-passively controlling solidification of the powdered material from the liquid state to a solid state. Several techniques for semi-passive control are described in detail. The methods may further include creating a structure through one or more techniques selected from additive manufacturing, injection molding, pressing and sintering, capacitive discharge sintering, or spark plasma sintering.

Insulating Ceramic Panels And Methods Of Forming Insulating Ceramic Panels

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US Patent:

20220267218, Aug 25, 2022

Filed:

Feb 4, 2022

Appl. No.:

17/665337

Inventors:

- Chicago IL, US
Kayleigh Porter - Los Angeles CA, US
Tobias A. Schaedler - Oak Park CA, US

International Classification:

C04B 35/63

Abstract:

Insulating ceramic panels and methods of forming insulating ceramic panels are disclosed herein. The insulating ceramic panels include a plurality of hollow particles and an oxide binder. The plurality of hollow particles are formed from a hollow particle material that includes a metal oxide. The plurality of hollow particles defines an average equivalent particle diameter of at least 10 micrometers (μm) and at most 500 μm. In addition, the plurality of hollow particles defines an average wall thickness that is at least 3% and at most 30% of the average equivalent particle diameter. The oxide binder material attaches each hollow particle to at least one other hollow particle and differs from the hollow particle material. The insulating ceramic panels define a particle-enclosed void volume fraction, which is enclosed within the plurality of hollow particles, and an interstitial void volume fraction, which is defined within an interstitial space among the plurality of hollow particles.

Lightweight Sandwich Structures And Methods Of Manufacturing The Same

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US Patent:

20220234315, Jul 28, 2022

Filed:

Apr 12, 2022

Appl. No.:

17/719101

Inventors:

- Malibu CA, US
Alicia J. Dias - Boston MA, US
Eric C. Clough - Santa Monica CA, US
Tobias A. Schaedler - Oak Park CA, US

International Classification:

B29C 70/68
B32B 3/12
B32B 27/38
B29C 71/00
B29C 33/38
B32B 27/06

Abstract:

A method of forming a sandwich structure including at least partially filling an open volume of an open cellular core with a sacrificial mold material, consolidating the sacrificial mold material to form a sacrificial mold, laying up a composite facesheet on each of at least two surfaces of the open cellular core, co-curing the composite facesheets by applying a consolidation temperature and a compaction pressure to the composite facesheets to form the sandwich structure, and removing the sacrificial mold. The compaction pressure is greater than a compressive strength of the open cellular core and less than a combined compressive strength of the open cellular core and the sacrificial mold.

Tobias A Schaedler

Tobias Schaedler Phones & Addresses

Work

Education

Skills

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Ranks

Industries

Resumes

Resumes

Manager, Architected Materials Group

Publications

Us Patents

Compressible Fluid Filled Micro-Truss For Energy Absorption

Durable Thermal Barrier Coating Compositions, Coated Articles, And Coating Methods

Durable Thermal Barrier Coating Compositions, Coated Articles, And Coating Methods

Net-Shape Structure With Micro-Truss Core

Modular Photonic Reflectors

Semi-Passive Control Of Solidification In Powdered Materials

Insulating Ceramic Panels And Methods Of Forming Insulating Ceramic Panels

Lightweight Sandwich Structures And Methods Of Manufacturing The Same