Search Results

Standard

High Temperature Materials for Exhaust Manifolds

1999-08-01

HISTORICAL

J2515_199908

A subcommittee within SAE ISTC Division 35 has written this report to provide automotive engineers and designers a basic understanding of the design considerations and high temperature material availability for exhaust manifold use. It is hoped that it will constitute a concise reference of the important characteristics of selected cast and wrought ferrous materials available for this application, as well as methods employed for manufacturing. The different types of manifolds used in current engine designs are discussed, along with their range of applicability. Finally, a general description of mechanical, chemical, and thermophysical properties of commonly-used alloys is provided, along with discussions on the importance of such properties.

Standard

WOODRUFF KEY SLOTS AND KEYWAYS

1959-05-31

HISTORICAL

J503_195905

Standard

Valve Guide Information Report

2017-12-20

CURRENT

J1682_201712

This SAE Information Report provides: a Types of valve guides and their nomenclature b Valve guide alloy designations and their chemistries c Valve guide alloy metallurgy d Typical mechanical and physical properties of guide alloys e Typical dimensional tolerances of valve guides and their counterbores f Recommended interference fits g Installation procedures h Application considerations

Standard

VALVE GUIDE INFORMATION REPORT

1993-09-10

HISTORICAL

J1682_199309

This SAE Information Report provides: a Types of valve guides and their nomenclature b Valve guide alloy designations and their chemistries c Valve guide alloy metallurgy d Typical mechanical and physical properties of guide alloys e Typical dimensional tolerances of valve guides and their counterbores f Recommended interference fits g Installation procedures h Application considerations

Standard

Abrasive Wear

2018-01-09

CURRENT

J965_201801

An enormous economic loss, as well as a waste of natural resources, is incurred world-wide as a result of wear of components and tools. Any effort expended in an attempt to reduce this loss is indeed worthwhile. The purpose of this SAE Information Report is to present the current state of knowledge of abrasive wear. This report, therefore, covers wear, or the undesired removal of metal by mechanical action, caused by abrasive particles in contact with the surface. It does not concern metal-to-metal wear or wear in the presence of an abrasive free lubricant. Abrasive wear occurs when hard particles, such as rocks, sand, or fragments of certain hard metals, slide or roll under pressure across a surface. This action tends to cut grooves across the metal surface, much like a cutting tool. Abrasive wear is of considerable importance in any part moving in relation to an abrasive.

Standard

ABRASIVE WEAR

1966-08-01

HISTORICAL

J965_196608

An enormous economic loss, as well as a waste of natural resources, is incurred world-wide as a result of wear of components and tools. Any effort expended in an attempt to reduce this loss is indeed worthwhile. The purpose of this SAE Information Report is to present the current state of knowledge of abrasive wear. This report, therefore, covers wear, or the undesired removal of metal by mechanical action, caused by abrasive particles in contact with the surface. It does not concern metal-to-metal wear or wear in the presence of an abrasive free lubricant. Abrasive wear occurs when hard particles, such as rocks, sand, or fragments of certain hard metals, slide or roll under pressure across a surface. This action tends to cut grooves across the metal surface, much like a cutting tool. Abrasive wear is of considerable importance in any part moving in relation to an abrasive.

Standard

Cleanliness Rating of Steels by the Magnetic Particle Method

2018-01-09

CURRENT

J421_201801

This SAE Recommended Practice provides a rating procedure for the cleanliness rating of steels by the magnetic particle method. The procedure is based on counting the number of indications (frequency) and employs a weighted value to obtain a severity factor. The method outlined is similar to that described in SAE Aerospace Material Specification AMS 2301.

Standard

CLEANLINESS RATING OF STEELS BY THE MAGNETIC PARTICLE METHOD

1977-11-01

HISTORICAL

J421B_197711

This SAE Recommended Practice provides a rating procedure for the cleanliness rating of steels by the magnetic particle method. The procedure is based on counting the number of indications (frequency) and employs a weighted value to obtain a severity factor. The method outlined is similar to that described in SAE Aerospace Material Specification AMS 2301.

Standard

CLEANLINESS RATING OF STEELS BY THE MAGNETIC PARTICLE METHOD

1993-05-01

HISTORICAL

J421_199305

This SAE Recommended Practice provides a rating procedure for the cleanliness rating of steels by the magnetic particle method. The procedure is based on counting the number of indications (frequency) and employs a weighted value to obtain a severity factor. The method outlined is similar to that described in SAE Aerospace Material Specification AMS 2301.

Standard

MAGNETIC PARTICLE INSPECTION

1991-03-01

HISTORICAL

J420_199103

The scope of this SAE Information Report is to provide general information relative to the nature and use of magnetic particles for nondestructive testing. The document is not intended to provide detailed technical information, but will serve as an introduction to the theory and capabilities of magnetic particle testing, and as a guide to more extensive references.

Standard

MAGNETIC PARTICLE INSPECTION

1981-03-01

HISTORICAL

J420_198103

Standard

Magnetic Particle Inspection

2018-01-10

CURRENT

J420_201801

The scope of this SAE Information Report is to provide general information relative to the nature and use of magnetic particles for nondestructive testing. The document is not intended to provide detailed technical information, but will serve as an introduction to the theory and capabilities of magnetic particle testing, and as a guide to more extensive references.

Standard

LIQUID PENETRANT TEST METHODS

1983-06-01

HISTORICAL

J426_198306

Standard

LIQUID PENETRANT TEST METHODS

1988-12-01

HISTORICAL

J426_198812

Standard

LIQUID PENETRANT TEST METHODS

1978-06-01

HISTORICAL

J426C_197806

Standard

OIL-TEMPERED CHROMIUM-VANADIUM VALVE SPRING QUALITY WIRE AND SPRINGS

1994-06-01

HISTORICAL

J132_199406

This SAE Recommended Practice covers the mechanical and chemical requirements of oil-tempered chromium-vanadium valve spring quality wire used for the manufacture of engine valve springs and other springs used at moderately elevated temperatures and requiring high fatigue properties. It also covers the processing requirements of spring fabricated from this wire.

Standard

Oil-Tempered Chromium-Vanadium Valve Spring Quality Wire and springs

1998-06-01

CURRENT

J132_199806

This SAE Recommended Practice covers the mechanical and chemical requirements of oil-tempered chromium-vanadium valve spring quality wire used for the manufacture of engine valve springs and other springs used at moderately elevated temperatures and requiring high fatigue properties. It also covers the processing requirements of spring fabricated from this wire.

Standard

Oil-Tempered Carbon-Steel Valve Spring Quality Wire and Springs

1998-06-01

CURRENT

J351_199806

This SAE Recommended Practice covers the physical and chemical requirements of oil- tempered carbon-steel valve spring quality wire used for the manufacture of engine valve springs and other springs requiring high-fatigue properties. This document also covers the processing requirements of springs fabricated from this wire.

Standard

OIL-TEMPERED CARBON-STEEL VALVE SPRING QUALITY WIRE AND SPRINGS

1994-06-01

HISTORICAL

J351_199406

This SAE Recommended Practice covers the physical and chemical requirements of oil-tempered carbon-steel valve spring quality wire used for the manufacture of engine valve springs and other springs requiring high-fatigue properties. This document also covers the basic processing requirements of springs fabricated from this wire.

Standard

Hydrogen Embrittlement Testing of Ultra High Strength Steels and Stampings by Acid Immersion

2023-03-08

CURRENT

J3215_202303

This standard describes a test method for evaluating the susceptibility of uncoated cold rolled and hot rolled Ultra High Strength Steels (UHSS) to hydrogen embrittlement. The thickness range of materials that can be evaluated is limited by the ability to bend and strain the material to the specified stress level in this specification. Hydrogen embrittlement can occur with any steel with a tensile strength greater than or equal to 980 MPa. Some steel microstructures, especially those with retained austenite, may be susceptible at lower tensile strengths under certain conditions. The presence of available hydrogen, combined with high stress levels in a part manufactured from high strength steel, are necessary precursors for hydrogen embrittlement. Due to the specific conditions that need to be present for hydrogen embrittlement to occur, cracking in this test does not indicate that parts made from that material would crack in an automotive environment.