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G2 Flywheel Module Operated at 41,000 rpm (2005)

McLallin, Kerry L. ; Jansen, Ralph H.

In: CASI

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Publication Date: 2018-06-05

Description: NASA Glenn Research Center s Flywheel Development Team designed, built, and successfully operated the new G2 flywheel to 41,000 rpm on September 2, 2004. This work was supported by the Aerospace Flywheel Technology Program--a NASA Office of Aerospace Technology ETC Program funded by the Energetics Project. The work was performed by a team of civil servants, contractors, and grantees managed by Glenn s Electrical Systems Development Branch, Structural Mechanics and Dynamics Branch, and Space Power & Propulsion Test Engineering Branch. The G2 flywheel was designed to be a low-cost modular testbed for flywheel system integration and component demonstrations.

Keywords: Aircraft Design, Testing and Performance

Type: Research and Technology 2004; NASA/TM-2005-213419

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Flywheel Rotor Safe-Life Technology (2002)

Chang, J. B. ; McLallin, Kerry L. ; Christopher, D. A. ; [et al.]

In: CASI

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Publication Date: 2019-07-10

Description: Since the 1960s, research has been conducted into the use of flywheels as energy storage systems. The-proposed applications include energy storage for hybrid and electric automobiles, attitude control and energy storage for satellites, and uninterruptible power supplies for hospitals and computer centers. For many years, however, the use of flywheels for space applications was restricted by the total weight of a system employing a metal rotor. With recent technological advances in the manufacturing of composite materials, however, lightweight composite rotors have begun to be proposed for such applications. Flywheels with composite rotors provide much higher power and energy storage capabilities than conventional chemical batteries. However, the failure of a high speed flywheel rotor could be a catastrophic event. For this reason, flywheel rotors are classified by the NASA Fracture Control Requirements Standard as fracture critical parts. Currently, there is no industry standard to certify a composite rotor for safe and reliable operation forth( required lifetime of the flywheel. Technical problems hindering the development of this standard include composite manufacturing inconsistencies, insufficient nondestructive evaluation (NDE) techniques for detecting defects and/or impact damage, lack of standard material test methods for characterizing composite rotor design allowables, and no unified proof (over-spin) test for flight rotors. As part of a flywheel rotor safe-life certification pro-ram funded b the government, a review of the state of the art in composite rotors is in progress. The goal of the review is to provide a clear picture of composite flywheel rotor technologies. The literature review has concentrated on the following topics concerning composites and composite rotors: durability (fatigue) and damage tolerance (safe-life) analysis/test methods, in-service NDE and health monitoring techniques, spin test methods/ procedures, and containment options. This report presents the papers selected for their relevance to this topic and summarizes them.

Keywords: Composite Materials

Type: NASA/CR-2002-211810 , TOR-2002(2140)-1 , E-13506

Format: application/pdf

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Evolutionary growth for Space Station Freedom electrical power system (1989)

Zernic, Michael J. ; Mclallin, Kerry L. ; Marshall, Matthew F.

In: CASI

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Publication Date: 2019-07-13

Description: Over an operational lifetime of at least 30 yr, Space Station Freedom will encounter increased space station user requirements and advancing technologies. The space station electrical power system is designed with the flexibility to accommodate these emerging technologies and expert systems and is being designed with the necessary software hooks and hardware scars to accommodate increased growth demand. The electrical power system is planned to grow from the initial 75 kW up to 300 kW. The Phase 1 station will utilize photovoltaic arrays to produce the electrical power; however, for growth to 300 kW, solar dynamic power modules will be utilized. Pairs of 25 kW solar dynamic power modules will be added to the station to reach the power growth level. The addition of solar dynamic power in the growth phase places constraints in the initial space station systems such as guidance navigation and control, external thermal, truss structural stiffness, computational capabilities and storage which must be planned-in in order to facilitate the addition of the solar dynamic modules.

Keywords: SPACECRAFT PROPULSION AND POWER

Type: NASA-TM-102339 , E-5047 , NAS 1.15:102339 , Intersociety Energy Conversion Engineering Conference; Aug 06, 1989 - Aug 11, 1989; Washington, DC; United States

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Aerospace Flywheel Technology Development for IPACS Applications (2001)

Fausz, Jerry ; Bauer, Robert D. ; McLallin, Kerry L. ; [et al.]

In: CASI

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Publication Date: 2019-07-13

Description: The National Aeronautics and Space Administration (NASA) and the Air Force Research Laboratory (AFRL) are cooperating under a space act agreement to sponsor the research and development of aerospace flywheel technologies to address mutual future mission needs. Flywheel technology offers significantly enhanced capability or is an enabling technology. Generally these missions are for energy storage and/or integrated power and attitude control systems (IPACS) for mid-to-large satellites in low earth orbit. These missions require significant energy storage as well as a CMG or reaction wheel function for attitude control. A summary description of the NASA and AFRL flywheel technology development programs is provided, followed by specific descriptions of the development plans for integrated flywheel system tests for IPACS applications utilizing both fixed and actuated flywheel units. These flywheel system development tests will be conducted at facilities at AFRL and NASA Glenn Research Center and include participation by industry participants Honeywell and Lockheed Martin.

Keywords: Spacecraft Propulsion and Power

Type: NASA/TM-2001-211093 , NAS 1.15:211093 , E-12936 , IECEC2001-AT-82 , 36th Intersociety Energy Conversion Engineering Conference; Jul 29, 2001 - Aug 02, 2001; Savannah, GA; United States

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