Lee Elliott

US Patent:

6437232, Aug 20, 2002

Filed:

Mar 23, 2000

Appl. No.:

09/533515

Inventors:

Dean R. Dailey - Torrance CA
Lee E. Elliott - Torrance CA

Assignee:

TRW Inc. - Redondo Beach CA

International Classification:

H01L 31045

US Classification:

136245, 136292, 244173

Abstract:

The power to weight ratio obtained with a spacecrafts solar array ( ) is enhanced by a factor of at least two to five through use of support structure for individual solar panels or solar arrays ( ) containing a curved outwardly bowed surface as deployed that packs essentially flat for storage. Defining a D-shaped wing ( ) in cross-section as deployed, the support structure ( ) for a string of solar cells ( FIG. ) provides greater inertia and thereby greater rigidity than prior designs. One member ( ) to the support structure is relatively flexible. One-hundred and eighty degree strain energy hinges ( ) carried by the other support member ( ) outwardly bows that flexible to define a curved sector when the support structure is released from the stowed condition in which the support structure is held relatively thin and flat.

US Patent:

6735838, May 18, 2004

Filed:

Dec 18, 1998

Appl. No.:

09/216150

Inventors:

Michael J. Triller - Hermosa Beach CA
Lee E. Elliott - Torrance CA

Assignee:

Northrop Grumman Corporation - Los Angeles CA

International Classification:

H04R 1700

US Classification:

29 2535, 298972, 2940705, 29709, 73802

Abstract:

A process for designing spacecraft structural elements ( ) that increases spacecraft structure intrinsic damping to relax stiffness design constraints that are necessary for precision pointing requirements. The process includes specifically designing the spacecraft structural elements ( ) to have a stiffness that is intrinsically not suitable to meet mission pointing performance requirements in order to reduce weight and volume. To overcome this deficiency, the structural elements ( ) are equipped with strain energy control elements ( ) that sense strain in the structural elements ( ) from on-board and external disturbances, and provide actuation of the structural elements ( ) to counteract the sensed strain. The strain energy control elements ( ) can be any suitable control element that senses strain and actuates the structural element ( ), such as piezoelectric electric or electrostrictive control elements. By reducing the stiffness requirements of the structural elements ( ), the control elements ( ) can more readily provide a desired actuation for damping purposes in order to meet pointing performance requirements, and thus the weight and volume of the structural elements ( ) can be reduced over those known in the art.

US Patent:

59798335, Nov 9, 1999

Filed:

Jul 10, 1998

Appl. No.:

9/113442

Inventors:

Howard S. Eller - Redondo Beach CA
Ramon Coronel - Torrance CA
Lee E. Elliott - Rancho Palos Verdes CA
Alfred Barrett - Santa Monica CA

Assignee:

TRW Inc. - Redondo Beach CA

International Classification:

B64G 100
B64G 144

US Classification:

244158R

Abstract:

A spacecraft structure using functionally independent modules assembled around a lightweight core structure to provide a vehicle that is lighter, uses less volume, and is easier to design, manufacture and test than a conventional spacecraft. In the disclosed embodiments, the modules are formed on generally flat panels, which serve as thermal radiators. The modules extend radially from the core structure and are attached to the core structure either in coplanar rows that extend axially along the core structure or in a coplanar set that extends circumferentially around the core structure. Interconnection between modules is achieved through a backbone interface, through which the modules are connected to the core structure. A large number of variant configurations may be implemented using the modular approach, by selecting a core, components and modules of number and size to meet mission requirements. The modular spacecraft may be easily designed and adapted to operate with its radiating modules facing in north-south directions for maximum thermal radiation, or in other orientations as needed for specific missions.

US Patent:

59043172, May 18, 1999

Filed:

Dec 20, 1996

Appl. No.:

8/770478

Inventors:

Lee E. Elliott - Rancho Palos Verdes CA
Alfred Barrett - Santa Monica CA

Assignee:

TRW Inc. - Redondo Beach CA

International Classification:

B64G1/66

US Classification:

244 1N

Abstract:

A technique for reducing the acoustic response of a spacecraft electronics equipment module that is structurally and thermally independent of a core spacecraft structure to which it can be mounted. The module takes the form of a thermal radiation panel on which electronic components are directly mounted. The panel is adjusted in stiffness to reduce its dynamic vibration response to acoustics and launch transients. These adjustments are facilitated by the external mounting of the panel to the core structure, preferably using a statically determinate mount that renders the module even less susceptible to vibration transferred from the core structure. External mounting removes the panel from the primary structure load path, which provides the freedom to adjust the stiffness as desired. The use of smaller than conventional equipment panels renders them less responsive to acoustic vibration because the dimensions of the panels are very much less than the wavelengths of the low-frequency acoustic energy that is of concern when launching the spacecraft. Other steps to minimize the vibration response include adding perforations to the equipment panels, providing an air gap between adjacent panels, adjusting the bending stiffness of the panels to reduce acoustic coupling, and damping the vibrations in the panels.

US Patent:

61472948, Nov 14, 2000

Filed:

Apr 6, 1999

Appl. No.:

9/287543

Inventors:

Dean R. Dailey - Torrance CA
Lee E. Elliott - Torrance CA

Assignee:

TRW Inc. - Redondo Beach CA

International Classification:

H01L 31045
B64G 144

US Classification:

136245

Abstract:

The power to weight ratio obtained with a spacecraft's solar array (3) is enhanced by a factor of at least two to five through use of support structure for individual solar panels or solar arrays (31a-17a) containing a curved outwardly bowed surface as deployed that packs essentially flat for storage. Defining a D-shaped wing (15a) in cross-section as deployed, the support structure (4 & 6) for a string of solar cells (10, FIG. 3) provides greater inertia and thereby greater rigidity than prior designs. One member (4) to the support structure is relatively flexible. One-hundred and eighty degree strain energy hinges (19) carried by the other support member (6) outwardly bows that flexible to define a curved sector when the support structure is released from the stowed condition in which the support structure is held relatively thin and flat.

US Patent:

62930273, Sep 25, 2001

Filed:

May 11, 1999

Appl. No.:

9/309554

Inventors:

Lee E. Elliott - Torrance CA
Michael K. MacKay - Palos Verdes Estates CA
John V. Flannery - Redondo Beach CA

Assignee:

TRW Inc. - Redondo Beach CA

International Classification:

G01B 1124

US Classification:

33546

Abstract:

A technique for measuring distortion in a structure of interest, such as a spacecraft antenna reflector (18), and optionally compensating for the distortion. A first set of targets (22) on the structure (18) is scanned by an attitude transfer system (24) to measure the angular location and range of each target relative to a reference point on another structure (12) having a frame of reference. The orientation of the structure of interest is them determined from the measured locations of the targets. A second set of targets (60 or 82) on the structure of interest is scanned by a figure sensing module (26) located at a reference point on the structure itself. From measured angular locations and ranges of the second set of targets, any shape distortion in the structure of interest can be determined, and distortion may be corrected with the use of actuators (98).