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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

GUIDELINES FOR LABORATORY CYCLIC CORROSION TEST PROCEDURES FOR PAINTED AUTOMOTIVE PARTS

1993-10-13

HISTORICAL

J1563_199310

These guidelines are intended for those engineers and scientists who evaluate the corrosion performance of painted automotive parts in laboratory cyclic tests. The guidelines are intended to help ensure that the results of the tests can be used to reach conclusions concerning the variables under study without being confounded by the test procedure itself. The guidelines also serve as a means to assist users of this type of test in obtaining good inter-laboratory agreement of results.

Standard

Guidelines for Laboratory Cyclic Corrosion Test Procedures for Painted Automotive Parts

2016-04-05

CURRENT

J1563_201604

These guidelines are intended for those engineers and scientists who evaluate the corrosion performance of painted automotive parts in laboratory cyclic tests. The guidelines are intended to help ensure that the results of the tests can be used to reach conclusions concerning the variables under study without being confounded by the test procedure itself. The guidelines also serve as a means to assist users of this type of test in obtaining good inter-laboratory agreement of results.

Standard

Helical Springs: Specification Check Lists

2004-10-11

HISTORICAL

J1122_200410

The following SAE Recommended Practice furnishes sample forms for helical compression, extension and torsion springs to provide a uniform method for specifying design information. It is not necessary to fill in all the data, but sufficient information must be supplied to fully describe the part and to satisfy the requirements of its application. For detailed information, see “Design and Application of Helical and Spiral Springs - SAE HS 795”, also “Helical Compression and Extension Spring Terminology - SAE J1121”. Both of these documents use SI (metric) Units in accordance with the provisions of SAE TSB 003, as does SAE J1122. Here, however, the U.S. Customary Units (in, lb, psi) have been added in parentheses after each SI Unit for the convenience of the user who must furnish specifications on a project where all requirements are listed in non-metric terms.

Standard

Helical Springs: Specification Check Lists

2016-08-02

CURRENT

J1122_201608

The following SAE Recommended Practice furnishes sample forms for helical compression, extension and torsion springs to provide a uniform method for specifying design information. It is not necessary to fill in all the data, but sufficient information must be supplied to fully describe the part and to satisfy the requirements of its application. For detailed information, see “Design and Application of Helical and Spiral Springs - SAE HS 795”, also “Helical Compression and Extension Spring Terminology - SAE J1121”. Both of these documents use SI (metric) Units in accordance with the provisions of SAE TSB 003, as does SAE J1122. Here, however, the U.S. Customary Units (in, lb, psi) have been added in parentheses after each SI Unit for the convenience of the user who must furnish specifications on a project where all requirements are listed in non-metric terms.

Standard

METHOD FOR EVALUATING MATERIAL SEPARATION IN AUTOMOTIVE SEALERS UNDER PRESSURE IN STATIC CONDITIONS

1996-03-01

HISTORICAL

J1864_199603

This SAE Recommended Practice sets forth a method for measuring pressure-induced separation in automotive sealers and determining the likelihood of equipment failure due to this separation, also known as "caking."

Standard

METHOD OF VISCOSITY TEST FOR AUTOMOTIVE TYPE ADHESIVES, SEALERS, AND DEADENERS

1995-08-01

HISTORICAL

J1524_199508

This SAE Recommended Practice contains a series of test methods for use in measuring the viscosity of automotive-type adhesives, sealers, and deadeners. The test methods which are contained in this document are as follows: 1.1 Brookfield® Method 1.2 Castor-Severs Rheometer or Pressure Flowmeter 1.3 Penetrometer 1.4 Capillary Rheometer 1.5 Plate Rheometers

Standard

Method for Evaluating Material Separation in Automotive Sealers Under Pressure in Static Conditions

2021-01-07

CURRENT

J1864_202101

This SAE Recommended Practice sets forth a method for measuring pressure-induced separation in automotive sealers and determining the likelihood of equipment failure due to this separation, also known as "caking."

Standard

Method for the Determination of Expansion and Water Absorption in Automotive Sealers

2002-01-25

HISTORICAL

J1918_200201

This SAE Recommended Practice sets forth methods for determining total expansion gravimetrically and volumetrically, calculating vertical expansion and measuring the water absorption of cut and uncut sealer beads.

Standard

Method for the Determination of Expansion and Water Absorption in Automotive Sealers

2021-01-07

CURRENT

J1918_202101

This SAE Recommended Practice sets forth methods for determining total expansion gravimetrically and volumetrically, calculating vertical expansion and measuring the water absorption of cut and uncut sealer beads.

Standard

Method of Viscosity Test for Automotive Type Adhesives, Sealers, and Deadeners

2021-01-07

CURRENT

J1524_202101

This SAE Recommended Practice contains a series of test methods for use in measuring the viscosity of automotive-type adhesives, sealers, and deadeners. The test methods which are contained in this document are as follows: 1.1 Brookfield® Method 1.2 Castor-Severs Rheometer or Pressure Flowmeter 1.3 Penetrometer 1.4 Capillary Rheometer 1.5 Plate Rheometers

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

PROVING GROUND VEHICLE CORROSION TESTING

1989-05-01

HISTORICAL

J1950_198905

The facilities used by domestic automotive manufacturers to provide accelerated corrosion aging of complete vehicles are described in general. The types of vehicles tested, general test methodology, and techniques used to determine test-to-field correlation are discussed. The different procedures used throughout the industry produce different results on various vehicle coatings, components, and systems. The key to successful interpretation of test results is a thorough understanding of the corrosion mechanisms involved and the effects of test limitations on these mechanisms.

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

Proving Ground Vehicle Corrosion Testing

2016-04-05

CURRENT

J1950_201604

The facilities used by domestic automotive manufacturers to provide accelerated corrosion aging of complete vehicles are described in general. The types of vehicles tested, general test methodology, and techniques used to determine test-to-field correlation are discussed. The different procedures used throughout the industry produce different results on various vehicle coatings, components, and systems. The key to successful interpretation of test results is a thorough understanding of the corrosion mechanisms involved and the effects of test limitations on these mechanisms.

Standard

RECOMMENDED GUIDELINES FOR LOAD/DEFORMATION TESTING OF ELASTOMERIC COMPONENTS

1993-02-01

HISTORICAL

J1636_199302

The purpose of this SAE Recommended Practice is to review factors that influence the behavior of elastomeric components under conditions of loading or deforming at a constant rate and to provide guidance concerning test procedures used to define or specify the load/deformation characteristics of elastomeric components. This characteristic is referred to as Static Stiffness. This is also referred to as a "Static Deflection Test."

Standard

Recommended Guidelines for Load/Deformation Testing of Elastomeric Components

2017-01-05

CURRENT

J1636_201701

The purpose of this SAE Recommended Practice is to review factors that influence the behavior of elastomeric components under conditions of loading or deforming at a constant rate and to provide guidance concerning test procedures used to define or specify the load/deformation characteristics of elastomeric components. This characteristic is referred to as Static Stiffness. This is also referred to as a "Static Deflection Test."

Standard

Standard Rainflow File Format

2018-08-24

CURRENT

J2623_201808

This SAE Standard provides a definition of a rainflow file format. This type of simple text file would contain all relevant information about the rainflow cycle content of a time history. Included information are Comments, Signal Range, Signal Mean, Number of Cycles, Signal Maximum, Signal Minimum. Rainflow cycle counting has become the most accepted procedure for identifying material fatigue relevant cycles in complex variable amplitude load time histories. The cycle counting methods account for the effects of material plasticity and material memory of prior deformation, and the resulting compressed history information is used by durability analysts to estimate the effects of a given service or test history.

Standard

Standard Rainflow File Format

2002-04-30

HISTORICAL

J2623_200204

This SAE Standard provides a definition of a rainflow file format. This type of simple text file would contain all relevant information about the rainflow cycle content of a time history. Included information are Comments, Signal Range, Signal Mean, Number of Cycles, Signal Maximum, Signal Minimum. Rainflow cycle counting has become the most accepted procedure for identifying material fatigue relevant cycles in complex variable amplitude load time histories. The cycle counting methods account for the effects of material plasticity and material memory of prior deformation, and the resulting compressed history information is used by durability analysts to estimate the effects of a given service or test history.