Individual Blade Control for Helicopter Rotor Blade One/Rev Vibration Reduction. Phase 1

Results of a Phase- SBIR study directed at the use of Individual Blade Control (IBC) for 1/rev helicopter rotor vibration reduction are described. Past approaches, analytical studies, and current technology for 1/rev vibration reduction are surveyed, and then a notional scheme for implementing an IB...

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1. Verfasser:	McKillip, Robert M., Jr
Format:	Report
Sprache:	eng
Schlagworte:	ACCELEROMETERS ACTUATORS AERODYNAMIC LOADING AEROELASTICITY ALLOYS COMPUTERIZED SIMULATION CONTROL THEORY DYNAMIC LOADS FATIGUE LIFE FLAPS(CONTROL SURFACES) FLIGHT MANEUVERS HELICOPTER ROTORS Helicopters HOVERING MATHEMATICAL MODELS MOMENTS PROTOTYPES REDUCTION REQUIREMENTS ROTOR BLADES(ROTARY WINGS) SHEAR STRESSES SMA(SHAPE MEMORY ALLOY) SMART MATERIALS TEST AND EVALUATION TRAILING CONTROL SURFACES VIBRATION
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creator	McKillip, Robert M., Jr
description	Results of a Phase- SBIR study directed at the use of Individual Blade Control (IBC) for 1/rev helicopter rotor vibration reduction are described. Past approaches, analytical studies, and current technology for 1/rev vibration reduction are surveyed, and then a notional scheme for implementing an IBC-based control device using shape memory alloys (SMA) is introduced. In order to quantify the required performance from this scheme, investigations into the sources of 1/rev vibration, and possible methods for its control are simulated using an aeroelastic analysis. Actuation concepts using SMA wires are analyzed, with engineering support from limited benchtop conceptual test models. Finally, implementation issues are discussed, and a plan for continued work leading to prototype development for this system is outlined. The results from this Phase 1 study indicate that the proposed innovative scheme for providing active 1/rev vibration control for helicopter rotors should lead to a practical system, that would be developed and prototyped under a follow-on Phase 2 program. (AN)
format	Report
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Phase 1</title><source>DTIC Technical Reports</source><creator>McKillip, Robert M., Jr</creator><creatorcontrib>McKillip, Robert M., Jr ; CONTINUUM DYNAMICS INC PRINCETON NJ</creatorcontrib><description>Results of a Phase- SBIR study directed at the use of Individual Blade Control (IBC) for 1/rev helicopter rotor vibration reduction are described. Past approaches, analytical studies, and current technology for 1/rev vibration reduction are surveyed, and then a notional scheme for implementing an IBC-based control device using shape memory alloys (SMA) is introduced. In order to quantify the required performance from this scheme, investigations into the sources of 1/rev vibration, and possible methods for its control are simulated using an aeroelastic analysis. Actuation concepts using SMA wires are analyzed, with engineering support from limited benchtop conceptual test models. Finally, implementation issues are discussed, and a plan for continued work leading to prototype development for this system is outlined. The results from this Phase 1 study indicate that the proposed innovative scheme for providing active 1/rev vibration control for helicopter rotors should lead to a practical system, that would be developed and prototyped under a follow-on Phase 2 program. (AN)</description><language>eng</language><subject>ACCELEROMETERS ; ACTUATORS ; AERODYNAMIC LOADING ; AEROELASTICITY ; ALLOYS ; COMPUTERIZED SIMULATION ; CONTROL THEORY ; DYNAMIC LOADS ; FATIGUE LIFE ; FLAPS(CONTROL SURFACES) ; FLIGHT MANEUVERS ; HELICOPTER ROTORS ; Helicopters ; HOVERING ; MATHEMATICAL MODELS ; MOMENTS ; PROTOTYPES ; REDUCTION ; REQUIREMENTS ; ROTOR BLADES(ROTARY WINGS) ; SHEAR STRESSES ; SMA(SHAPE MEMORY ALLOY) ; SMART MATERIALS ; TEST AND EVALUATION ; TRAILING CONTROL SURFACES ; VIBRATION</subject><creationdate>1995</creationdate><rights>APPROVED FOR PUBLIC RELEASE</rights><oa>free_for_read</oa><woscitedreferencessubscribed>false</woscitedreferencessubscribed></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><link.rule.ids>230,780,885,27567,27568</link.rule.ids><linktorsrc>$$Uhttps://apps.dtic.mil/sti/citations/ADA294694$$EView_record_in_DTIC$$FView_record_in_$$GDTIC$$Hfree_for_read</linktorsrc></links><search><creatorcontrib>McKillip, Robert M., Jr</creatorcontrib><creatorcontrib>CONTINUUM DYNAMICS INC PRINCETON NJ</creatorcontrib><title>Individual Blade Control for Helicopter Rotor Blade One/Rev Vibration Reduction. Phase 1</title><description>Results of a Phase- SBIR study directed at the use of Individual Blade Control (IBC) for 1/rev helicopter rotor vibration reduction are described. Past approaches, analytical studies, and current technology for 1/rev vibration reduction are surveyed, and then a notional scheme for implementing an IBC-based control device using shape memory alloys (SMA) is introduced. In order to quantify the required performance from this scheme, investigations into the sources of 1/rev vibration, and possible methods for its control are simulated using an aeroelastic analysis. Actuation concepts using SMA wires are analyzed, with engineering support from limited benchtop conceptual test models. Finally, implementation issues are discussed, and a plan for continued work leading to prototype development for this system is outlined. The results from this Phase 1 study indicate that the proposed innovative scheme for providing active 1/rev vibration control for helicopter rotors should lead to a practical system, that would be developed and prototyped under a follow-on Phase 2 program. 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Phase 1</btitle><date>1995-05-31</date><risdate>1995</risdate><abstract>Results of a Phase- SBIR study directed at the use of Individual Blade Control (IBC) for 1/rev helicopter rotor vibration reduction are described. Past approaches, analytical studies, and current technology for 1/rev vibration reduction are surveyed, and then a notional scheme for implementing an IBC-based control device using shape memory alloys (SMA) is introduced. In order to quantify the required performance from this scheme, investigations into the sources of 1/rev vibration, and possible methods for its control are simulated using an aeroelastic analysis. Actuation concepts using SMA wires are analyzed, with engineering support from limited benchtop conceptual test models. Finally, implementation issues are discussed, and a plan for continued work leading to prototype development for this system is outlined. The results from this Phase 1 study indicate that the proposed innovative scheme for providing active 1/rev vibration control for helicopter rotors should lead to a practical system, that would be developed and prototyped under a follow-on Phase 2 program. (AN)</abstract><oa>free_for_read</oa></addata></record>
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subjects	ACCELEROMETERS ACTUATORS AERODYNAMIC LOADING AEROELASTICITY ALLOYS COMPUTERIZED SIMULATION CONTROL THEORY DYNAMIC LOADS FATIGUE LIFE FLAPS(CONTROL SURFACES) FLIGHT MANEUVERS HELICOPTER ROTORS Helicopters HOVERING MATHEMATICAL MODELS MOMENTS PROTOTYPES REDUCTION REQUIREMENTS ROTOR BLADES(ROTARY WINGS) SHEAR STRESSES SMA(SHAPE MEMORY ALLOY) SMART MATERIALS TEST AND EVALUATION TRAILING CONTROL SURFACES VIBRATION
title	Individual Blade Control for Helicopter Rotor Blade One/Rev Vibration Reduction. Phase 1
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