Search Results

Standard

SECONDARY FILTERS FOR FLUID SYSTEM RELIABILITY

1994-05-01

HISTORICAL

AIR4057

It discusses the design choices and engineering trade-offs available to the system designer in the efficient selection and application of Last-Chance filters in contrast to main or primary system filters.

Standard

Secondary Filters for Fluid System Reliability

2004-12-01

HISTORICAL

AIR4057A

This SAE Aerospace Information Report (AIR) discusses the design choices and engineering trade-offs available to the system designer in the efficient selection and application of Last-Chance filters in contrast to main or primary system filters.

Standard

Secondary Filters for Fluid System Reliability

2012-09-24

CURRENT

AIR4057B

This SAE Aerospace Information Report (AIR) discusses the design choices and engineering trade-offs available to the system designer in the efficient selection and application of Last-Chance filters in contrast to main or primary system filters.

Standard

PROCEDURE AND METHOD FOR CONDUCTING TEST OF HYDRAULIC COMPONENTS IN CONTAMINATION CONTROLLED SYSTEM

1992-07-01

HISTORICAL

ARP219

This procedure will be generally applicable to three classes of hydraulic components as listed below:

Standard

Procedure and Method for Conducting Test of Hydraulic Components in Contamination Controlled System

2013-12-13

CURRENT

ARP219A

This procedure will be generally applicable to three classes of hydraulic components as listed below:

Standard

FILTER PATCH TESTING PROCEDURES FOR AEROSPACE HYDRAULIC NON-ROTATING EQUIPMENT

1991-11-01

HISTORICAL

ARP1302

These recommendations are written to cover the subject of obtaining filter patch test samples from aerospace hydraulic equipment of the categories shown below. The same procedure shall apply regardless of the unit category.

Standard

PROCEDURE AND METHOD EVALUATION OF FILTER PATCH TESTING FOR AIRCRAFT HYDRAULIC PUMPS

1959-02-01

HISTORICAL

ARP575

These recommendations are written to cover the subject of obtaining filter patch test samples from aircraft hydraulic pumps of the categories shown below. The same procedure shall apply regardless of the pump drive category.

Standard

FILTER PATCH TESTING PROCEDURES FOR AEROSPACE HYDRAULIC PUMPS AND MOTORS

1991-11-01

HISTORICAL

ARP575A

These recommendations are written to cover the subject of obtaining filter patch test samples from aerospace hydraulic units of the categories shown below. The same procedure shall apply regardless of the unit drive category.

Standard

Filter Patch Testing Procedures for Aerospace Hydraulic Pumps and Motors

1999-07-01

CURRENT

ARP575B

This Aerospace Recommended Practice (ARP) sets forth recommendations of SAE Subcommittee A-6C (Fluid Power Distribution Elements) relative to the procedure and methods to be used in the obtaining and evaluation of filter patch tests for aerospace hydraulic pumps and motors. These patches are to be used in a quality control program to insure that units are operating properly prior to delivery to the customer. This is to promote an optimum in cleanliness standards in aerospace hydraulic circuits. It is expected that this will promote a longer service life of the pump or motor.

Standard

HYDRAULIC FLUID CHARACTERISTICS

2011-08-10

HISTORICAL

AIR81

This report discusses the characteristics of hydraulic fluids and evaluates their importance, not only from the standpoint of fluid formulation, but also in their effect on aero-space hydraulic system design and the materials used in the components of the system. In some cases numerical parameter limits are suggested, but, in general, the effect of a parameter is the basic consideration. Not only must the characteristics of the fluid be considered in the design of a hydraulic system in which it is to be used, but also the characteristics of the system will affect the extent of the importance of the various characteristics of the fluid. In each individual system, as it employs a fluid, the characteristics of the fluid must be assessed with their immediate import and weighed in considering their effects on the system design requirements based upon the variables of system environment, function and basic design.

Standard

Aircraft Air Compressor Lubricating Oil

2002-12-16

CURRENT

ARP664

Standard

METHODS FOR EVALUATING CRYOGENIC FILTERS

1975-07-01

HISTORICAL

ARP900

The purpose of this test procedure is to present test methods that can be utilized to evaluate the filtration and operating characteristics of filters that will be utilized in a cryogenic system. The methods presented herein are intended to supplement standard filter testing specifications to allow evaluation of filter performance characteristics in areas that could be affected by extreme low temperatures. The test methods can be utilized to evaluate filters up to and including 60 GPM (330 liters per minute) capacity. If higher flow rate filters are to be evaluated in accordance with the test methods presented herein, it will be necessary to increase the system flow capacity and the size of effluent sampling system.

Standard

Methods for Evaluating Cryogenic Filters

2002-03-23

HISTORICAL

ARP900A

The purpose of this test procedure is to present test methods that can be utilized to evaluate the filtration and operating characteristics of filters that will be utilized in a cryogenic system. The methods presented herein are intended to supplement standard filter testing specifications to allow evaluation of filter performance characteristics in areas that could be affected by extreme low temperatures. The test methods can be utilized to evaluate filters up to and including 60 gpm (230 lpm) capacity. If higher flow rate filters are to be evaluated in accordance with the test methods presented herein, it will be necessary to increase the system flow capacity and the size of effluent sampling system.

Standard

Methods for Evaluating Cryogenic Filters

2011-12-19

HISTORICAL

ARP900B

The purpose of this document is to present test methods that can be utilized to evaluate the filtration and operating characteristics of filters that will be utilized in a cryogenic system. The methods presented herein are intended to supplement standard filter testing specifications to allow evaluation of filter performance characteristics in areas that could be affected by extreme low temperatures. The test methods can be utilized to evaluate filters for particle sizes equal to or greater than 5.0 μm and flows up to and including 60 gpm (230 L/min) capacity. If higher flow rate filters are to be evaluated in accordance with the test methods presented herein, it will be necessary to increase the system flow capacity and the size of effluent sampling system from those recommended in this document.

Standard

Methods for Evaluating Cryogenic Filters

2019-12-03

CURRENT

ARP900C

The purpose of this document is to present test methods that can be utilized to evaluate the filtration and operating characteristics of filters that will be utilized in a cryogenic system. The methods presented herein are intended to supplement standard filter testing specifications to allow evaluation of filter performance characteristics in areas that could be affected by extreme low temperatures.

Standard

DEGRADATION LIMITS OF MIL-H-5606 HYDRAULIC FLUID

1963-12-29

HISTORICAL

AIR810

Standard

DEGRADATION LIMITS OF HYDROCARBON-BASED HYDRAULIC FLUIDS, MIL-H-5606, MIL-H-6083, MIL-H-83282, AND MIL-H-46170 USED IN HYDRAULIC TEST STANDS

1994-05-01

HISTORICAL

AIR810B

Standard

Degradation Limits of Hydrocarbon-Based Hydraulic Fluids, MIL-H-5606, MIL-H-6083, MIL-H-83282, and MIL-H-46170 Used in Hydraulic Test Stands

2001-03-01

HISTORICAL

AIR810C

This SAE Aerospace Information Report (AIR) presents data on normally accepted changes in physical properties and contamination levels for military hydraulic fluids used in hydraulic test stands. This information is of importance to all users of hydraulic test stands to assure the performance data obtained on these test stands for specific components will not be adversely affected by excessive changes in fluid properties or contamination levels. The data pertains to fluids conforming to specifications MIL-H-5606, MIL-H-83282, MIL-H-6063, and MIL-H-46170. The guidelines incorporated in the AIR are the general consensus values of knowledgeable professionals. However, the experience and judgement of engineers and operators responsible for the equipment must be relied upon to determine when the hydraulic fluid is to be replaced. This document is essentially a metric document with English units.

Standard

Degradation Limits of MIL-PRF-5606, MIL-PRF-83282, and MIL-PRF-87257 Hydraulic Fluids Used in Hydraulic Test Stands

2020-10-14

CURRENT

AIR810E

This SAE Aerospace Information Report (AIR) presents data on normally accepted changes in physical properties and contamination levels for MIL-PRF-5606, MIL-PRF-83282, and MIL-PRF-87257 hydraulic fluids used in hydraulic test stands. This information is of importance to all users of hydraulic test stands to assure the performance data obtained on these test stands for specific components will not be adversely affected by excessive changes in fluid properties or contamination levels.

Standard

Degradation Limits of Hydrocarbon-Based Hydraulic Fluids, MIL-PRF-5606, MIL-PRF-83282, and MIL-PRF-87257 Used in Hydraulic Test Stands

2013-04-22

HISTORICAL

AIR810D

This SAE Aerospace Information Report (AIR) presents data on normally accepted changes in physical properties and contamination levels for military hydraulic fluids used in hydraulic test stands. This information is of importance to all users of hydraulic test stands to assure the performance data obtained on these test stands for specific components will not be adversely affected by excessive changes in fluid properties or contamination levels. The data pertains to fluids conforming to specifications MIL-PRF-5606, MIL-PRF-83282, and MIL-PRF-87257. The guidelines incorporated in the AIR are the general consensus values of knowledgeable professionals. However, the experience and judgment of engineers and operators responsible for the equipment must be relied upon to determine when the hydraulic fluid is to be replaced.