Search Results

Standard

Self-Sealing Breakaway Valves for Crash-Resistant Aircraft Fuel Systems

2012-01-03

HISTORICAL

AIR1616A

This document defines design, performance, and test criteria for self-sealing breakaway valves.

Standard

SELF-SEALING BREAKAWAY VALVES FOR CRASH-RESISTANT AIRCRAFT FUEL SYSTEMS

1983-04-04

HISTORICAL

AIR1616

This document defines design, performance, and test criteria for self-sealing breakaway valves.

Standard

SELF-SEALING BREAKAWAY VALVES FOR CRASH-RESISTANT AIRCRAFT FUEL AND OIL SYSTEMS

2007-12-04

HISTORICAL

ARP1616A

This document defines design, performance, and test criteria for self-sealing breakaway valves for use in crash-resistant aircraft fuel systems.

Standard

RECOMMENDED MATERIALS AND PRACTICES FOR USE WITH CRYOGENIC PROPELLANTS

1965-01-10

HISTORICAL

AIR839

Standard

PERFORMANCE TESTING OF GAS TURBINE LUBE OIL FILTER ELEMENTS

1994-07-01

HISTORICAL

AIR1666

This SAE Aerospace Information Report (AIR) reviews performance testing parameters for noncleanable, often referred to as disposable, aircraft gas turbine engine lubricant filter elements.

Standard

Optical equipment safety in fuel tanks

2018-11-15

WIP

ARP7977

This project aims to develop a framework of requirements which support safe installation and operation of optical devices within an aircraft fuel tank, specifically: 1: To determine optical power and energy limits which ensure safe operation of optical installations within an aircraft fuel tank over aircraft life and under all phases of flight, taking the limits provided in IEC 60079-28:20015 as a starting point. 2: To demonstrate optical and electrical power and energy equivalences, where possible. 3: To determine requirements for optical installations, including bonding and electrostatic discharge for non-conductive components such as optical fibres. 4: To provide guidelines for analysis of the hazards presented by the typical internal components of optical devices, such as failure modes of photo diodes and cells.

Standard

Nozzles and Ports – Gravity Fueling Interface Standards for Civil Aircraft

2012-01-03

CURRENT

AS1852D

This SAE Aerospace Standard (AS) defines the maximum allowable free opening dimensions for airframe fueling ports on civil aircraft that require the exclusive use of gasoline as an engine fuel, and the minimum free opening dimensions for airframe fueling ports on civil aircraft that operate with turbine fuels as the primary fuel type and with gasoline as the emergency fuel type. This SAE Aerospace Standard (AS) also defines the features and dimensions for airframe refueling ports on civil aircraft that require the exclusive use of turbine fuel as an engine fuel. In addition, this document defines the minimum fuel nozzle spout dimensions for turbine fuel ground service equipment, and the maximum fuel nozzle spout diameter for gasoline ground service equipment.

Standard

Nozzles and Ports - Gravity Fueling Interface Standard for Civil Aircraft

1997-08-01

HISTORICAL

AS1852B

This SAE Aerospace Standard (AS) defines the maximum allowable free opening dimensions for airframe fueling ports on civil aircraft that require the exclusive use of gasoline as an engine fuel and the minimum free opening dimensions for airframe fueling ports on civil aircraft that operate with turbine fuels as the primary fuel type. In addition, this document defines the minimum fuel nozzle tip dimensions for turbine fuel ground service equipment and the maximum fuel nozzle tip diameter for gasoline ground service equipment.

Standard

Nozzles and Ports - Gravity Fueling Interface Standard for Civil Aircraft

2006-03-24

HISTORICAL

AS1852C

This SAE Aerospace Standard (AS) defines the maximum allowable free opening dimensions for airframe fueling ports on civil aircraft that require the exclusive use of gasoline as an engine fuel, and the minimum free opening dimensions for airframe fueling ports on civil aircraft that operate with turbine fuels as the primary fuel type and with gasoline as the emergency fuel type. This SAE Aerospace Standard (AS) also defines the features and dimensions for airframe refueling ports on civil aircraft that require the exclusive use of turbine fuel as an engine fuel. In addition, this document defines the minimum fuel nozzle spout dimensions for turbine fuel ground service equipment, and the maximum fuel nozzle spout diameter for gasoline ground service equipment.

Standard

Method-Pressure Drop Tests for Fuel System Components

2013-08-09

HISTORICAL

ARP868C

This document provides recommended methods and describes associated equipment and test setups to assist in understanding and conducting pressure drop tests on fuel system components. Background information and suggestions are provided as means of improving accuracy and repeatability of test results. Although written specifically for fuel system components, the methods, equipment and suggestions presented herein apply equally to pressure drop tests of other liquid-handling devices.

Standard

METHOD - PRESSURE DROP TESTS FOR FUEL SYSTEM COMPONENTS

1994-09-01

HISTORICAL

ARP868B

To describe useful methods for conducting pressure drop tests of fuel system components for MIL-F-8615 or similar requirements and to present general suggestions for improving accuracy of test results.

Standard

METHOD - PRESSURE DROP TESTS FOR FUEL SYSTEM COMPONENTS

1983-06-01

HISTORICAL

ARP868A

To describe useful methods for conducting pressure drop tests of fuel system components for MIL-F-8615 or similar requirements; and to present general suggestions for improving accuracy of test results.

Standard

Impact of Changes in Test Dust Contaminants and Particle Counter Calibration on Laboratory Filter Element Performance and Fluid Cleanliness Classes

2003-07-03

HISTORICAL

AIR5455

This SAE Aerospace Information Report (AIR) discusses the impact of the ISO Test Dusts, chosen as replacement contaminants for the Arizona Test Dusts (AC Test Dusts), and the ISO calibration procedure ISO 11171 for automatic particle counters, which replaces the calibration procedure ISO 4402 (1991), on laboratory performance of filter elements utilized in aerospace lubrication, hydraulic and fuel systems, and fluid cleanliness levels determined with automatic particle counters.

Standard

Impact of Changes in Test Dust Contaminants and Particle Counter Calibration on Laboratory Filter Element Performance and Fluid Cleanliness Classes

2012-01-03

CURRENT

AIR5455A

This SAE Aerospace Information Report (AIR) discusses the impact of the ISO Test Dusts, chosen as replacement contaminants for the Arizona Test Dusts (AC Test Dusts), and the ISO calibration procedure ISO 11171 for automatic particle counters, which replaces the calibration procedure ISO 4402 (1991), on laboratory performance of filter elements utilized in aerospace lubrication, hydraulic and fuel systems, and fluid cleanliness levels determined with automatic particle counters.

Standard

Glossary of Terms - Aircraft Ground Refueling and Defueling

2023-09-19

WIP

AIR4783B

This SAE Aerospace Information Report presents a glossary of terms commonly used in the ground delivery of fuel to an aircraft and pertinent terms relating to the aircraft being refueled.

Standard

Fuel and Oil Lines, Aircraft, Installation of

2013-08-09

CURRENT

AS18802

This specification covers the requirements for installation of fuel and oil lines in aircraft, except those lines furnished as part of the engine.

Standard

Fuel and Oil Lines, Aircraft, Installation of

2020-04-22

WIP

AS18802A

This specification covers the requirements for installation of fuel and oil lines in aircraft, except those lines furnished as part of the engine.

Standard

Fuel System Components: General Specification For

2023-05-01

WIP

ARP8615A

This document describes the requirements for air vehicle fuel, vent, and propulsion fuel system functional components.

Standard

Fuel System Components: General Specification For

2011-08-11

CURRENT

ARP8615

This document describes the requirements for air vehicle fuel, vent, and propulsion fuel system functional components.

Standard

Fuel Level Point Sensing

2020-11-30

CURRENT

AIR6325

This report is intended to identify the various existing technologies used for a fuel level sensing system. In addition to sensing technologies, it describes the basic architecture of fuel level sensing systems and their association with fuel gauging system to increase integrity of fuel measurement and management. As the fuel level sensing system is generally based on electrical components within fuel tanks, a specific focus is made on fuel tank explosion safety protection. An overview of the capacitive fuel gauging operation can be found in AIR5691.