DOCSLIB.ORG

Product Capability List

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Product Capability List Nabtesco Aerospace, Inc. FAA Repair Station HV6R601N EASA Certification 145.4917 Contact (425) 602-8400 for information regarding repairs AC Type Part Nomenclature Nabtesco P/N Customer P/N Brake Metering Valve 1316200-x 10-62029-x Press. Reducer Bypass Valve 1704600-x 10-62255-x 737 Elevator Feel Shift Module 1705800-x S251A225-x MLG Shimmy Damper N/A 273A3610-x MLG Safety Valve 1416500-x S257T440-x Spoiler Actuator 1583100-x S251A204-1 737MAX Elevator Feel Shift Module 1705800-x S251A225-x MLG Shimmy Damper N/A 273A3610-x Outboard Aileron Lockout Actuator 5500300-x 60B80050-x NLG Steering Actuator 5500400-x 60B80053-x Flap Load Relief Actuator 5500500-x 60B80032-x 747 Flap Load Relief Actuator 5500700-x 60B80080-x Flap Load Relief Actuator 5500800-x 60B800105-x Bulk Cargo Door Snubber 1705900-x 60B00310-x Thrust Reverser Isolation Valve 1417200-x S271T528-x Inboard Aileron PCU 1579100-x S251U110-x Outboard Aileron PCU 1579200-x S251U120-x Inboard Spoiler PCU 1579300-x S251U130-x 747-8 Outboard Spoiler PCU 1579400-x S251U140-x Pitch Augmentation Control Servo 1581000-x S252T704-x Nose Gear Steering Actuator 5500400-x 60B80053-x Snubber Assy. Bulk Cargo Door 1705900-x 60B00310-x Elevator Feel Shift Module 1705800-x S251A225-x Aileron PCU 1527700-x S251N114-x Aileron PCU 1540600-x S251N114-x Yaw Damper Servo Actuator 1529200-x S251N313-x 757 Yaw Damper Servo Actuator 1536600-x S252T704-x Yaw Damper Servo Actuator 1540500-x S252T704-x Reservoir Fill Selector Valve 1320600-x S271T463 Thrust Reverser Isolation Valve 1417200-x S271T528-x Outboard Aileron Lockout Actuator 5500300-x 60B80050-x Flap Load Relief Actuator 5500500-x 60B80032-x Inboard Spoiler PCA N/A 252T1301-x Outboard Spoiler PCA N/A 252T1401-x Inboard Spoiler PCA 1542500-x S252T303-x Outboard Spoiler PCA 1542600-x S252T3034-x Yaw Damper Servo Actuator 1527100-x S252T704-x 767 Yaw Damper Servo Actuator 1536600-x S252T704-x Yaw Damper Servo Actuator 1540500-x S252T704-x MLG Door Latch Actuator N/A S271T461-x 767 Reservoir Fill Selector Valve 1320600-x S271T463-x Thrust Reverser Isolation Valve 1417200-x S271T528-x MLG Door Actuator N/A 273T4551-x Elevator Feel Shift Module 1705800-x S251A225-x MLG Safety Valve 1416500-x S257T440-x Flaperon PCU 1544100-x S251W110-x Flaperon PCU 1567700-x S251W110-x 777 Aileron PCU 1544200-x S251W120-x Elevator PCU 1544300-x S251W220-x Reservoir Fill Selector Valve 1320600-x S257T440-x C400 MLG Actuator 1521200-x 9912053-x C500 MLG Actuator 1523100-x 9912053-x MLG Actuator 1541800-x 9912397-x NLG Actuator 1541900-x 9912370-x C525 Flaperon Actuator 1542000-x 9912365-x Speed Brake PCU 1542100-x 9912375-x MLG Actuator 1547800-x 9912465-x NLG Actuator 1523200-x 9912063-x C550 Speed Brake PCU 1535500-x 9912344-x Flaperon Actuator 1535000-x 9912007-x MLG Actuator 1523100-x 9912111-x MLG Actuator 1550000-x 9912537-x MLG Actuator 1556600-x 9912569-x C560 NLG Actuator 1523200-x 9912120-x NLG Actuator 1548500-x 9912485-x NLG Actuator 1549300-x 9912491-x MLG Actuator 1525700-x 9914170-x NLG Actuator 1524700-x 9914085-x C650 Spoiler Actuator 1524800-x 9914155-x MLG Locking Side Brace Mech 1525500-x 9914169-x C680 Speed Brake PCU 1560800-x 9914651-x CJ2 MLG Actuator 1556700-x 9912573-x ERJ 170-195 Multi-Function Spoiler Actuator 414800-x 414800SCD-x IB Elevator Actuator Assy 1536400-x BLG7004-x MD-11 OB Elevator Actuator Assy 1536500-x BLG7005-x Leading Edge Slat Actuator 1538200-x BRG0012-x MLG Parking Brake Control Valve 1319200-x 92250-00803-x S92 MLG Master Brake Cylinder 1549600-x 92250-00802-x DHC8 Spoiler Actuator 1556000-x 8SC0113-x.
Load more

Recommended publications
  • Application to the Flight
    Journal name 000(00):1–13 A Methodology for Vehicle and Mission ©The Author(s) 2010 Reprints and permission: Level Comparison of More Electric sagepub.co.uk/journalsPermissions.nav DOI:doi number Aircraft Subsystem Solutions - Application http://mms.sagepub.com to the Flight Control Actuation System Imon Chakraborty∗ and Dimitri N. Mavris† Aerospace Systems Design Laboratory, Georgia Institute of Technology, Atlanta, GA 30332, USA Mathias Emeneth‡ and Alexander Schneegans§ PACE America Inc., Seattle, WA 98115, USA Abstract As part of the More Electric Initiative, there is a significant interest in designing energy-optimized More Electric Aircraft, where electric power meets all non-propulsive power requirements. To achieve this goal, the aircraft subsystems must be analyzed much earlier than in the traditional design process. This means that the designer must be able to compare competing subsystem solutions with only limited knowledge regarding aircraft geometry and other design characteristics. The methodology presented in this work allows such tradeoffs to be performed, and is driven by subsystem requirements definition, component modeling and simulation, identification of critical or constraining flight conditions, and evaluation of competing architectures at the vehicle and mission level. The methodology is applied to the flight control actuation system, where electric control surface actuators are likely to replace conventional centralized hydraulics in future More Electric Aircraft. While the potential benefits of electric actuation are generally accepted, there is considerable debate regarding the most suitable electric actuator - electrohydrostatic or electromechanical. These two actuator types form the basis of the competing solutions analyzed in this work, which focuses on a small narrowbody aircraft such as the Boeing 737-800.
    [Show full text]
  • Setting up Ailerons and Flaperons on a DLG (Discus Launch Glider) by Andy Kunz
    Setting up Ailerons and Flaperons on a DLG (Discus Launch Glider) by Andy Kunz Originally Posted by kgantz: While waiting for parts to be delivered I am still reading a lot about how to initially set up ailerons / flaperons. One of the best descriptions I've found is this post in the DLG forum. After reading this post, I understand that flaperon trim and aileron trim are handled separately by the radio. This is not obvious to people who have not done this before but, I guess because you are working with 1 moving surface but it has 2 jobs, trimming has to work a little differently for each job! So now my question is, on the Spektrum radios-- DX 9 in my case, is the aileron portion of the adjustment done with Dual Rates as suggested by the poster or is there a different way. Reply by AndyKunz: The logic is that one is a roll trim, the other is a camber trim. You'll find that we're pretty consistent with that sort of thing throughout the radio. Use the Dual Rates to adjust travel based on a switch, for instance in launch mode vs. thermal mode vs. landing mode. If it doesn't need to change based on a switch, do it with Servo Travel instead of Dual Rates. If you are working on a V-Tail or Elevon model, then you would use Dual Rates to adjust the ratio between pitch and roll/yaw. Use Servo Travel to adjust the maximum amount in the highest position of the Dual Rates switch.
    [Show full text]
  • An Investigation of the Effects of Flaperon Actuator Failure on Flight Maneuvers of a Supersonic Aircraft
    Research Paper ISSN 2383-4986 International Journal of Aerospace System Engineering http://dx.doi.org/10.20910/IJASE.2016.3.2.1 Vo l . 3, No.2, pp.1-8 (2016) An Investigation of the Effects of Flaperon Actuator Failure on Flight Maneuvers of a Supersonic Aircraft Seyool Oh1†, Inje Cho1, Craig McLaughlin2 1Aircraft Research & Development Division, Korea Aerospace Industries, ltd, KOREA 2Dept. of Aerospace Engineering, The University of Kansas U.S.A. †E-mail:[email protected] Abstract The improvements in high performance and agility of modern fighter aircraft have led to improvements in survivability as well. Related to these performance increases are rapid response and adequate deflection of the control surfaces. Most control surface failures result from the failure of the actuator. Therefore, the failure and behavior of the actuators are essential to both combat aircraft survivability and maneuverability. In this study, we investigate the effects of flaperon actuator failure on flight maneuvers of a supersonic aircraft. The flight maneuvers were analyzed using six degrees of freedom (6DOF) simulations. This research will contribute to improvements in the reconfiguration of control surfaces and control allocation in flight control algorithms. This paper compares the results of these 6DOF simulations with the horizontal tail actuator failures analyzed previously. Key Words : Flaperon, Actuator failure, Flight maneuver, Supersonic aircraft , Combat aircraft only for specific flight phases. Primary control 1. Introduction surfaces are generally built into the aircraft wings In the past, combat aircraft were designed using the and empennage. Typical primary controls include concept of static stability for safety. However, as the elevators on the horizontal tail, rudder on the technologies of aircraft developed and the vertical tail, and ailerons on the wings [3].
    [Show full text]
  • 09 Stability and Control
    Aircraft Design Lecture 9: Stability and Control G. Dimitriadis Introduction to Aircraft Design Stability and Control H Aircraft stability deals with the ability to keep an aircraft in the air in the chosen flight attitude. H Aircraft control deals with the ability to change the flight direction and attitude of an aircraft. H Both these issues must be investigated during the preliminary design process. Introduction to Aircraft Design Design criteria? H Stability and control are not design criteria H In other words, civil aircraft are not designed specifically for stability and control H They are designed for performance. H Once a preliminary design that meets the performance criteria is created, then its stability is assessed and its control is designed. Introduction to Aircraft Design Flight Mechanics H Stability and control are collectively referred to as flight mechanics H The study of the mechanics and dynamics of flight is the means by which : – We can design an airplane to accomplish efficiently a specific task – We can make the task of the pilot easier by ensuring good handling qualities – We can avoid unwanted or unexpected phenomena that can be encountered in flight Introduction to Aircraft Design Aircraft description Flight Control Pilot System Airplane Response Task The pilot has direct control only of the Flight Control System. However, he can tailor his inputs to the FCS by observing the airplane’s response while always keeping an eye on the task at hand. Introduction to Aircraft Design Control Surfaces H Aircraft control
    [Show full text]
  • Recreational Flyer January - February 2010 Elevated: Angus Watt’S Ch-750
    January - February 2010 Recreational Aircraft Association Canada www.raa.ca The Voice of Canadian Amateur Aircraft Builders $6.95 Elevated: Angus Watt's CH-750 Elevated: The original Zenith 701 was designed as an Angus Watt’s Ch-750 ultralight go-anywhere all metal bush plane that could be plans built by anyone with a 4 ft tabletop bending brake and a pair of snips. It was rarely described as a thing of beauty but so well does it fulfill its mission that these planes are found all over the world. They are inexpensive to construct, and because of their leading edge slats they can get in and out of extremely short patches of clear ground. 22 Recreational Flyer January - February 2010 Elevated: Angus Watt’s Ch-750 WITH THE ADVENT of the Light Sport category in and the only part interchangeable with the 701 is the US, Chris Heintz saw the need for an updated the signature Zenith all-flying rudder. Formerly the version, something with a larger cabin, greater skins were all .016” and they are now .020 to handle payload, and the ability to use an array of four the greater mass of the range of possible four stroke stroke engines. The CH 750 was the result and its engines and the 1320 pound gross weight on wheels, lineage is visually apparent but while the new plane 1430 on floats. resembles the 701 it is almost completely different in Chris Heintz correctly surmised that the US construction. CNC fabrication methods have made Light Sport category would be attractive to aging it possible to simplify the design, speed up the con- American pilots who wanted to bargain down to struction, and end up with a larger and faster plane their Sport Pilot category that allows a valid driver’s at only a slight weight penalty.
    [Show full text]
  • 10CAG/10CHG/10CG-2.4Ghz 10-CHANNEL RADIO CONTROL SYSTEM
    10CAG/10CHG/10CG-2.4GHz 10-CHANNEL RADIO CONTROL SYSTEM INSTRUCTION MANUAL Technical updates and additional programming examples available at: http://www.futaba-rc.com/faq Entire Contents ©Copyright 2009 1M23N21007 TABLE OF CONTENTS INTRODUCTION ........................................................... 3 Curve, Prog. mixes 5-8 ............................................. 71 Additional Technical Help, Support and Service ........ 3 GYA gyro mixing (GYRO SENSE) ............................... 73 $SSOLFDWLRQ([SRUWDQG0RGL¿FDWLRQ ........................ 4 Other Equipment ....................................................... 74 Meaning of Special Markings ..................................... 5 Safety Precautions (do not operate without reading) .. 5 Introduction to the 10CG ............................................ 7 GLIDER (GLID(1A+1F)(2A+1F)(2A+2F)) FUNCTIONS . 75 &RQWHQWVDQG7HFKQLFDO6SHFL¿FDWLRQV........................ 9 Table of contents........................................................ 75 Accessories ............................................................... 10 Getting Started with a Basic 4-CH Glider ................ 76 Transmitter Controls & GLIDER-SPECIFIC BASIC MENU FUNCTIONS ........ 78 6ZLWFK,GHQWL¿FDWLRQ$VVLJQPHQWV ............................. 11 Model type (PARAMETER submenu) ........................... 78 Charging the Ni-Cd Batteries ................................... 15 MOTOR CUT ................................................................ 79 Stick Adjustments ....................................................
    [Show full text]
  • DESIGN and ANALYSIS of PERFORMANCE PARAMETERS of WING with FLAPERONS Debanjali Dey, R.Aasha #Department of Aeronautical Engineering , KCG College of Technology
    International Journal of Scientific Research and Review ISSN NO: 2279-543X DESIGN AND ANALYSIS OF PERFORMANCE PARAMETERS OF WING WITH FLAPERONS Debanjali Dey, R.Aasha #Department of Aeronautical Engineering , KCG College Of Technology. 1. [email protected] 2. [email protected] ABSTRACT- The main objective of this project is to design a flaperon for a wing and compare the performance characteristic of this flaperon-wing combination with that of conventional wing design that makes use of separate flap and aileron. Theoretical analysis and comparison is performed following which the computational analysis is carried out to validate the results. Further aim is to give a clarity on the fact that the use of this high lift device aids in improvising the aerodynamic characteristics of a wing by experimental testing of the wing design incorporated with flaperon, which is designed using a special methodology. Then, modification of wing design can be done to overcome the drawbacks of flaperons if any. INTRODUCTION - When looking at an aircraft, it is easy to observe that they have a number of common features: wings, a tail with vertical and horizontal wing sections, engines to propel them through the air, and a fuselage to carry passengers or cargo. If, however, you take a more critical look beyond the gross features, you also can see subtle, and sometimes not so subtle, differences. The reasons for these differences, why the designers configured them this way, is quite an intriguing study. Today, 100,000 flights will safely crisscross the planet. At no time in history have our lives been so global and full of possibility.
    [Show full text]
  • Designing and Development of Unmanned Aerial Vehicle
    ICAS 2002 CONGRESS DESIGNING AND DEVELOPMENT OF UNMANNED AERIAL VEHICLE MUHAMMAD ASIM Engineering Wing PAF Base Minhas PAKISTAN,43175 [email protected] DR ABID ALI KHAN Aerospace Engg Dept College of Aeronautical Engg Risalpur,24090 National University of Science and Technology [email protected] Keywords: UAV-Ip Abstract in direct combat. Even current high-tech UAV’s such as the Darkstar are limited to non- With the advancement in science and combative missions. In an age when the technology, the aviation industry is increasingly physiological tolerances and physical concentrating on the development of Remotely capabilities of the crew restrain the limits of Piloted Vehicles (RPVs), Unmanned Aerial performance of a modern fighter, the use of a Vehicles (UAVs) and Unmanned Combat Aerial UAV in a combat role deserves some Vehicles (UCAVs). The Unmanned Aerial consideration. Vehicle (UAV) are being used for many years for a variety of different tasks like reconnaissance, bomb damage assessment 2.0 Design Philosophy and Goals (BDA), scientific research, escort EW, decoying guiding SAMs and AAMs, and target practice. The principle goal in the UAV-Ip (Unmanned These UAVs will replace the conventional Aerial Vehicle - Interceptor) design process was aircraft in several roles and even perform novel to create an interceptor, which could super assignments. The hostile battlefield cruise to intercept a target in a minimal time at a environments and difficult access areas can be maximum possible range. The application of monitored without endangering human life. This this aircraft would be defensive in nature, when paper elaborate the designing of UAV that can conventional aircraft are immediately be used as interceptor and can perform unavailable or unable to deploy.
    [Show full text]
  • KOKU-KAN-SANJI-504 Date: 09/18/20 No: KOKU-KAN-SANJI-449 Date: 08/17/21 No: KOKU-KAN-SANJI-276
    (Unofficial Translation) Date: 09/27/18 No: KOKU-KAN-SANJI-614 Date: 08/23/19 No: KOKU-KAN-SANJI-504 Date: 09/18/20 No: KOKU-KAN-SANJI-449 Date: 08/17/21 No: KOKU-KAN-SANJI-276 Director of Air Transport Safety Unit Aviation Safety and Security Department Civil Aviation Bureau of Japan Ministry of Land, Infrastructure, Transport and Tourism Subject: The Detailed Regulations of the Technical Standard to Prevent Objects Falling off Airplanes 1. Purpose. Based on the provisions of the Technical Standard to Prevent Objects Falling off Airplanes (hereinafter referred to as “the Standard”) and in order to bring it into effect, the Detailed Regulations of the Technical Standard to Prevent Objects Falling off Airplanes (hereinafter referred to as “the Detailed Regulations”) is established as follows. 2. Applicability. The applicability of the Detailed Regulations is the same as the Standard. 3. Application for Licenses or Authorization. The application under the provisions of the Standard shall meet the following requirements. However, the operation manual or the maintenance manual of domestic air carriers may contain the following matters in lieu of the application matters. 3-1 Engineering management. 3-1-1 The operators must have a system to collect the information of falling objects, analyze and assess from the engineering aspect, and based on these results, develop countermeasures (inspection, maintenance and others) and implement them under 3-1 of the Standard. 3-1-2 The operators must nominate a person who is to be the supervisor of the system as referred to in the preceding paragraph, and take corrective actions properly under the supervision of the person.
    [Show full text]
  • Section 1 Introduction
    INSTRUCTION MANUAL FOR AIRPLANE AND HELICOPTER XP6102 6-CHANNEL COMPUTER RADIO SYSTEM TABLE OF CONTENTS TABLE OF CONTENTS TABLE OF CONTENTS ......................2 CHAPTER 1: SOFTWARE FUNCTIONS – AIRPLANE ................11 Transmitter Callouts ..................12 CHAPTER 1: USING THIS MANUAL • INTRODUCTION ..............6 Transmitter Rear ......................13 Using this Manual ....................6 Direct Servo Control (DSC) ........14 R770 Receiver ..........................6 Control Stick Tension Adjustment ..14 Control Stick Length Adjustment ..14 Frequency Notes/ CHAPTER 2: FEATURES ....................6 Aircraft Only Frequencies ..........15 X-6102 Transmitter ....................6 Base Loaded Antenna ..............15 Transmitter Specifications ..........7 Neck Strap Attachment ..............15 System Specifications ................7 CHAPTER 2: CONNECTIONS • CHAPTER 3: COMPONENT AIRPLANE ..................16 SPECIFICATIONS ............7 Installation Requirements ..........16 S537 Ball Bearing Servo ..............7 Connections ..........................17 Airborne Battery Pack ................8 Backup Error Display ................18 Charger Specifications ................8 Receiver Specifications ..............8 CHAPTER 3: INPUT MODE AND Servo Specifications ..................8 FUNCTION • AIRPLANE ....18 Charger ..................................9 Key Input and Display ..............18 Transmitter/Receiver ..................9 System Mode ..........................19 Normal Mode ..........................19 CHAPTER 4: BATTERY
    [Show full text]
  • Phoenix Supplement
    CONSUMER AEROSPACE Phoenix Rocket Launched R/C Aerobatic Glider Assembly and Operation Manual Supplement HIS sheet contains some recent additions to the Phoenix instructions. Please read them before you Tbegin construction of your Phoenix rocket glider. The following three items are very important, and must be done before you fly your Phoenix. Mandatory Additions Trim Rudder Horn Screws OU must trim the screws that Ymount the rudder horn flush with the outside of the nylon plate. If the screws are not trimmed, it is possible for them to hit the L-7 guides on the launcher during lift off. The rudder may be damaged if this happens. The screws may be cut after assembly with a razor saw or a cut off disc in a Moto-Tool. If you use a cut off disc, be very careful to keep the heat generated by the cut off disc from melting the nylon plate. Trim these screws flush with nylon plate Elevator Pushrod Stiffness HERE are 8 pieces of 3/16” square balsa strip provided in the kit. Before you start assembly, examine all T8 pieces. Due to the high speeds encountered during a Phoenix launch, the pushrods need to be both straight and stiff. The stiffest one should be used for the elevator pushrod, and the next stiffest one for rud- der. The remaining pieces are used for the fuselage corner stock. We use the stiffest balsa that we can obtain for the pushrods, but if you feel the pushrods provided in your kit are not stiff enough, please contact us and we will provide substitutes.
    [Show full text]
  • Recent Researches on Morphing Aircraft Technologies in Japan and Other Countries
    Advance Publication by J-STAGE Mechanical Engineering Reviews DOI:10.1299/mer.19-00197 Received date : 4 April, 2019 Accepted date : 3 June, 2019 J-STAGE Advance Publication date : 10 June, 2019 © The Japan Society of Mechanical Engineers Recent researches on morphing aircraft technologies in Japan and other countries Natsuki TSUSHIMA* and Masato TAMAYAMA* *Aeronautical Technology Directorate, Japan Aerospace Exploration Agency 6-13-1 Osawa, Mitaka, Tokyo 181-0015, Japan E-mail: [email protected] Abstract Morphing aircraft technology has recently gained attention of many research groups by its potential for aircraft performance improvement and economic flight. Although the performance of conventional control surfaces is usually compromised in off-design flight conditions, the morphing technique may achieve optimal flight performance in various operations by to adaptively altering the wing shape during flight. This paper aims to provide a comprehensive review on morphing aircraft/wing technology, including morphing mechanisms or structures, skins, and actuation techniques as element technologies. Moreover, experimental and numerical studies on morphing technologies applying those elemental technologies are also introduced. Recent research on these technologies are particularly focused on in this paper with comparisons between developments in Japan and other countries. Although a number of experimental and numerical studies have been conducted by various research groups, there are still various challenges to overcome in individual elemental technologies for a whole morphing aircraft or wing systems. This review helps for researchers working in the field related to morphing aircraft technology to sort out current developments for morphing aircraft. Keywords : Aircraft, Wing morphing, Composites, Smart materials, Flexible skins 1.
    [Show full text]