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Standard

PNEUMATIC SPRING TERMINOLOGY
1989-06-01
HISTORICAL
J511_198906
This pneumatic spring terminology has been developed to assist engineers and designers in the preparation of specifications and descriptive material relating to pneumatic springs and their components. It does not include gas supply or control systems.
Standard

Pneumatic Spring Terminology
2016-04-01
CURRENT
J511_201604
This pneumatic spring terminology has been developed to assist engineers and designers in the preparation of specifications and descriptive material relating to pneumatic springs and their components. It does not include gas supply or control systems.
Standard

Testing Dynamic Properties of Elastomeric Isolators
1999-05-01
HISTORICAL
J1085_199905
These methods cover testing procedures for defining and specifying the dynamic characteristics of simple elastomers and simple fabricated elastomeric isolators used in vehicle components. Simple, here, is defined as solid (non-hydraulic) components tested at frequencies less than or equal to 25 Hz.
Standard

Testing Dynamic Properties of Elastomeric Isolators
2017-02-09
CURRENT
J1085_201702
These methods cover testing procedures for defining and specifying the dynamic characteristics of simple elastomers and simple fabricated elastomeric isolators used in vehicle components. Simple, here, is defined as solid (non-hydraulic) components tested at frequencies less than or equal to 25 Hz.
Standard

Recommended Guidelines for Fatigue Testing of Elastomeric Materials and Components
1998-02-01
HISTORICAL
J1183_199802
The purpose of this SAE Recommended Practice is to review factors that influence the behavior of elastomers under conditions of dynamic stress and to provide guidance concerning laboratory procedures for determining the fatigue characteristics of elastomeric materials and fabricated elastomeric components.
Standard

Recommended Guidelines for Fatigue Testing of Elastomeric Materials and Components
2017-02-13
CURRENT
J1183_201702
The purpose of this SAE Recommended Practice is to review factors that influence the behavior of elastomers under conditions of dynamic stress and to provide guidance concerning laboratory procedures for determining the fatigue characteristics of elastomeric materials and fabricated elastomeric components.
Standard

Coach Joint Fracture Test
2021-01-07
CURRENT
J1863_202101
This SAE Recommended Practice defines a procedure for determining the cleavage strength of an adhesive used for bonding automotive oily metal substrates.
Standard

ELASTOMERIC BUSHING "TRAC" APPLICATION CODE
1994-10-01
HISTORICAL
J1883_199410
The bushing "TRAC" code is intended to be a tool that will aid in the definition of the geometric environment for the test, or use, of an elastomeric bushing.
Standard

Elastomeric Bushing "TRAC" Application Code
2017-02-09
CURRENT
J1883_201702
The bushing "TRAC" code is intended to be a tool that will aid in the definition of the geometric environment for the test, or use, of an elastomeric bushing.
Standard

Recommended Practices for Design and Evaluation of Passenger and Light Truck Coolant Hose Clamped Joints
2003-11-07
HISTORICAL
J1697_200311
This SAE Recommended Practice covers recommended practices for design and evaluation of hose clamped joints primarily in automotive applications. It is intended to: (a) evaluate current joint designs, (b) compare existing designs, (c) aid in the development of new designs, (d) give objective results once weights are set, (e) rate the overall design and individual sections of design, and (f) encourage future research by industry and the OEM's.
Standard

RECOMMENDED PRACTICES FOR DESIGN AND EVALUATION OF PASSENGER AND LIGHT TRUCK COOLANT HOSE CLAMPED JOINTS
1996-07-01
HISTORICAL
J1697_199607
This SAE Recommended Practice covers recommended practices for design and evaluation of hose clamped joints primarily in automotive applications. It is intended to: (a) evaluate current joint designs, (b) compare existing designs, (c) aid in the development of new designs, (d) give objective results once weights are set, (e) rate the overall design and individual sections of design, and (f) encourage future research by industry and the OEM's.
Standard

Technical Report on Low Cycle Fatigue Properties Ferrous and Non-Ferrous Materials
2018-08-24
CURRENT
J1099_201808
Information that provides design guidance in avoiding fatigue failures is outlined in this SAE Information Report. Of necessity, this report is brief, but it does provide a basis for approaching complex fatigue problems. Information presented here can be used in preliminary design estimates of fatigue life, the selection of materials and the analysis of service load and/or strain data. The data presented are for the “low cycle” or strain-controlled methods for predicting fatigue behavior. Note that these methods may not be appropriate for materials with internal defects, such as cast irons, which exhibit different tension and compression stress-strain behavior.
Standard

Technical Report on Low Cycle Fatigue Properties Ferrous and Non-Ferrous Materials
2002-08-13
HISTORICAL
J1099_200208
Information that provides design guidance in avoiding fatigue failures is outlined in this SAE Information Report. Of necessity, this report is brief, but it does provide a basis for approaching complex fatigue problems. Information presented here can be used in preliminary design estimates of fatigue life, the selection of materials and the analysis of service load and/or strain data. The data presented are for the “low cycle” or strain-controlled methods for predicting fatigue behavior. Note that these methods may not be appropriate for materials with internal defects, such as cast irons, which exhibit different tension and compression stress-strain behavior.
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