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Standard

CORROSION PREVENTIVE COMPOUND, TOPSIDE VEHICLE CORROSION PROTECTION

1989-06-01

HISTORICAL

J1804_198906

This specification covers corrosion preventive compounds for spray application to vehicle body cavities

Standard

Corrosion Preventive Compound, Topside Vehicle Corrosion Protection

2016-04-05

CURRENT

J1804_201604

This specification covers corrosion preventive compounds for spray application to vehicle body cavities

Standard

Corrosion Preventive Compound, Underbody Vehicle Corrosion Protection

2003-09-25

HISTORICAL

J1959_200309

This specification covers underbody corrosion preventive compounds for application to vehicle underbodies.

Standard

Corrosion Preventive Compound, Underbody Vehicle Corrosion Protection

2016-04-05

CURRENT

J1959_201604

This specification covers underbody corrosion preventive compounds for application to vehicle underbodies.

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

Laboratory Corrosion/Fatigue Testing of Vehicle Suspension Coil Springs

2007-06-15

HISTORICAL

J2800_200706

This lab test procedure should be used when evaluating the combined corrosion and fatigue performance for a particular coating system, substrate, process and design. The test is intended to provide an A to B comparison of a proposed coil spring design versus an existing field validated coil spring when subjected to the combined effects of corrosion and fatigue. The corrosion mechanisms covered by this test include general, cosmetic and pitting corrosion. Fatigue testing covers the maximum design stress and/or stress range of the coil spring design (typically defined as excursion from jounce to rebound positions in a vehicle). The effects of gravel and heat are simulated by pre-conditioning the springs prior to fatigue testing. Time dependant corrosion mechanisms such as stress corrosion cracking are not addressed with this test.

Standard

Laboratory Corrosion/Fatigue Testing of Vehicle Suspension Coil Springs

2016-04-01

CURRENT

J2800_201604

This lab test procedure should be used when evaluating the combined corrosion and fatigue performance for a particular coating system, substrate, process and design. The test is intended to provide an A to B comparison of a proposed coil spring design versus an existing field validated coil spring when subjected to the combined effects of corrosion and fatigue. The corrosion mechanisms covered by this test include general, cosmetic and pitting corrosion. Fatigue testing covers the maximum design stress and/or stress range of the coil spring design (typically defined as excursion from jounce to rebound positions in a vehicle). The effects of gravel and heat are simulated by pre-conditioning the springs prior to fatigue testing. Time dependant corrosion mechanisms such as stress corrosion cracking are not addressed with this test.

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

Performance Test Procedure - Ball Joints and Spherical Rod Ends

2012-10-15

CURRENT

J1367_201210

The purpose of this test procedure is to provide a uniform method of testing commercial spherical rod end bearings to determine their performance characteristics under specific application situations. This procedure is an extension of the dimensional requirements for spherical rod end bearings as set forth in SAE J1120 and J1259. The loads, number of cycles, definition of failure, etc., are to be agreed to by the user and supplier. This procedure can also be used as the basis for testing ball joints covered by SAE J490.

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

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 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.