Jeffrey M Mendoza

20220364514, Nov 17, 2022

May 12, 2021

17/318898

- Chula Vista CA, US
Kenji Homma - Glastonbury CT, US
Craig Aaron Reimann - Vernon CT, US
Jeffrey Michael Mendoza - Manchester CT, US

Rohr, Inc. - Chula Vista CA

F02C 7/24
G10K 11/16
G10K 11/172

An acoustic attenuation structure for a gas turbine engine includes a periodic structure having a first unit cell, the first unit cell having a first central body and a first axial tube disposed on the first central body and a second axial tube disposed on the first central body, opposite the first axial tube, each of the first axial tube and the second axial tube being in fluid communication with one another through the first central body.

20220366886, Nov 17, 2022

Apr 13, 2022

17/720174

- Winston Salem NC, US
KENJI HOMMA - GLASTONBURY CT, US
CRAIG A. REIMANN - VERNON CT, US
JEFFREY M. MENDOZA - MANCHESTER CT, US
PAUL R. BRAUNWART - HEBRON CT, US

B/E AEROSPACE, INC - Winston Salem NC

G10K 11/162
B64D 11/00

An acoustic supercell may comprise a facesheet having a plurality of perforations, a backplate parallel to the facesheet, a cell wall contacting the facesheet and the back plate, and a periodic structure. The supercell may be custom-tailored to meet specific acoustic wavelength absorption targets. The custom-tailored supercell may be arranged with a plurality of other custom-tailored supercells into an acoustic panel.

20220366888, Nov 17, 2022

May 12, 2021

17/318868

- Charlotte NC, US
Kenji Homma - Glastonbury CT, US
Craig Aaron Reimann - Vernon CT, US
Jeffrey Michael Mendoza - Manchester CT, US

GOODRICH CORPORATION - Charlotte NC

G10K 11/172
B64C 1/40

An acoustic attenuation structure includes a periodic structure having a first unit cell, the first unit cell having a first central body and a first axial tube disposed on the first central body and a second axial tube disposed on the first central body, opposite the first axial tube, each of the first axial tube and the second axial tube being in fluid communication with one another through the first central body.

20220349363, Nov 3, 2022

Jul 18, 2022

17/867140

- Chula Vista CA, US
Peter J. Walsh - Wethersfield CT, US
Danielle L. Grolman - Holden MA, US
Craig Aaron Reimann - Vernon CT, US
Thomas P. Filburn - Granby CT, US
Song Chiou - Irvine CA, US
Jeong-Woo Kim - Glastonbury CT, US
Jeffrey M. Mendoza - Manchester CT, US

F02K 1/82
F23M 20/00
F02C 7/045
G10K 11/168

An acoustic liner includes a first face sheet, a second face sheet spaced from the first face sheet, and a plurality of sidewalls extending between the first face sheet and the second face sheet. The plurality of sidewalls defines a plurality of cells. Each cell of the plurality of cells defines a cavity between the first face sheet and the second face sheet. A bulk absorber is disposed within at least one cell of the plurality of cells. The bulk absorber further defines the cavity of the at least one cell of the plurality of cells. The first face sheet defines a plurality of apertures extending through a thickness of the first face sheet. Each aperture of the plurality of apertures is aligned with a respective cell of the plurality of cells.

20200290207, Sep 17, 2020

Mar 11, 2019

16/297992

- Farmington CT, US
Michael A. Klecka - Coventry CT, US
Abhijit Chakraborty - West Hartford CT, US
Jeffrey Michael Mendoza - Manchester CT, US

United Technologies Corporation - Farmington CT

B25J 11/00
B25J 9/16
B24B 49/16

A process of deburring a workpiece comprising installing a workpiece onto a machine table proximate a robot, the workpiece having a surface, the robot having at least one force sensor and a spindle load sensor associated with a spindle coupled to a cutting tool, the robot having at least one joint configured to be actuated by a joint actuator; the robot being coupled to a controller; generating joint encoder signals with the controller, the joint encoder signals configured to direct the joint actuator; sensing contact forces between the cutting tool of the robot and the surface of the workpiece; determining a deburring path of the cutting tool to deburr the workpiece; and controlling the robotic deburring process by use of the joint encoder signals, a physics based model of burr size and material removal, a nominal trajectory and an actual trajectory of the cutting tool center point position.

20200217272, Jul 9, 2020

Jan 4, 2019

16/240360

- Chula Vista CA, US
Peter J. Walsh - Wethersfield CT, US
Danielle L. Grolman - Holden MA, US
Craig Aaron Reimann - Vernon CT, US
Thomas P. Filburn - Granby CT, US
Song Chiou - Irvine CA, US
Jeong-Woo Kim - Glastonbury CT, US
Jeffrey M. Mendoza - Manchester CT, US

F02K 1/82
G10K 11/168
F02C 7/045
F23M 20/00

An acoustic liner includes a first face sheet, a second face sheet spaced from the first face sheet, and a plurality of sidewalls extending between the first face sheet and the second face sheet. The plurality of sidewalls defines a plurality of cells. Each cell of the plurality of cells defines a cavity between the first face sheet and the second face sheet. A bulk absorber is disposed within at least one cell of the plurality of cells. The bulk absorber further defines the cavity of the at least one cell of the plurality of cells. The first face sheet defines a plurality of apertures extending through a thickness of the first face sheet. Each aperture of the plurality of apertures is aligned with a respective cell of the plurality of cells.

20200183363, Jun 11, 2020

Dec 10, 2018

16/214982

- Farmington CT, US
Michael A. Klecka - Coventry CT, US
Abhijit Chakraborty - West Hartford CT, US
Changsheng Guo - South Windsor CT, US
Jeffrey Michael Mendoza - Manchester CT, US
Edward Marchitto - Canton CT, US

G05B 19/416

A robotic deburring process that automatically, accurately, and efficiently removes burrs from a workpiece. The robotic deburring process uses CAM location data to establish deburring trajectory, physics based machining models to predict burr type and size, and force control functions to compensate inaccuracies due of inaccuracies of robots arms.

20200041974, Feb 6, 2020

Jul 31, 2018

16/050548

- Farmington CT, US
Abhijit Chakraborty - West Hartford CT, US
Sergei F. Burlatsky - West Hartford CT, US
Michael A. Klecka - Coventry CT, US
Jeffrey Michael Mendoza - Manchester CT, US

G05B 19/19
B29C 64/393
G06F 17/50

A method of providing additive manufacturing includes the steps of (a) developing a plurality of layers to result in a final shape product, (b) developing a space filling algorithm to develop a path, (c) estimating a temperature at a location along the path in an existing direction of the path, and (d) comparing the estimated temperature to a desired temperature and altering the existing direction of the path should the estimated temperature differ from the desired temperature by a predetermined amount. An additive manufacturing system is also disclosed.