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Standard

HIGH STRENGTH, LOW ALLOY STEEL

1962-06-01

HISTORICAL

J410A_196206

Standard

HIGH STRENGTH, LOW ALLOY STEEL

1969-10-01

HISTORICAL

J410C_196910

Standard

HIGH STRENGTH, LOW ALLOY STEEL

1984-06-01

HISTORICAL

J410_198406

Standard

HIGH-STRENGTH, HOT-ROLLED STEEL PLATES, BAR AND SHAPES

1988-12-01

HISTORICAL

J1442_198812

This recommended practice covers five levels of high-strength carbon and high-strength, low-alloy steel plates, bars, and shapes for structural use.

Standard

HIGH STRENGTH, QUENCHED, AND TEMPERED STRUCTURAL STEELS

1988-12-01

HISTORICAL

J368_198812

Standard

CARBON AND ALLOY STEELS

1980-10-01

HISTORICAL

J411_198010

Standard

Carbon and Alloy Steels

1997-09-01

HISTORICAL

J411_199709

This SAE Information Report describes the processing and fabrication of carbon and alloy steels. The basic steelmaking process including iron ore reduction, the uses of fluxes, and the various melting furnaces are briefly described. The various types of steels: killed, rimmed, semikilled, and capped are described in terms of their melting and microstructural differences and their end product use. This document also provides a list of the commonly specified elements used to alloy elemental iron into steel. Each element’s structural benefits and effects are also included. A list of the AISI Steel Products Manuals is included and describes the various finished shapes in which steel is produced.

Standard

CARBON AND ALLOY STEELS

1981-06-01

HISTORICAL

J411_198106

Standard

CARBON AND ALLOY STEELS

1989-11-01

HISTORICAL

J411_198911

This document describes the processing and fabrication of carbon and alloy steels. The basic steelmaking process including iron ore reduction, the uses of fluxes, and the various melting furnaces are briefly described. The various types of steels: killed, rimmed, semikilled, and capped are described in terms of their melting and microstructural differences and their end product use. This document also provides a list of the commonly specified elements used to alloy elemental iron into steel. Each element's structural benefits and effects are also included. A list of the AISI Steel Products Manuals is included and describes the various finished shapes in which steel is produced.

Standard

PRODUCT ANALYSIS—PERMISSIBLE VARIATIONS FROM SPECIFIED CHEMICAL ANALYSIS OF A HEAT OR CAST OF STEEL

1984-06-01

HISTORICAL

J409_198406

Standard

PRODUCT ANALYSIS - PERMISSIBLE VARIATIONS FROM SPECIFIED CHEMICAL ANALYSIS OF A HEAT OR CAST OF STEEL

1990-12-01

HISTORICAL

J409_199012

Supplementary to the heat or cast analysis, a product analysis may be made on steel in the semifinished or finished form. For definitions and methods of sampling steel for product chemical analysis, refer to SAE J408. A product analysis is a chemical analysis of the semifinished or finished steel to determine conformance to the specification requirements. The range of the specified chemical composition is normally expanded to take into account deviations associated with analytical reproducibility and the heterogeneity of the steel. Individual determinations may vary from the specified heat or cast analysis ranges or limits to the extent shown in Tables 1 through 5. The several determinations of any element in a heat or cast may not vary both above and below the specified range except for lead. Tables 1 through 5 provide permissible limits for various steel forms and composition types.

Standard

PRODUCT ANALYSIS - PERMISSIBLE VARIATIONS FROM SPECIFIED CHEMICAL ANALYSIS OF A HEAT OR CAST OF STEEL

1988-12-01

HISTORICAL

J409_198812

Standard

SAE NUMBERING SYSTEM FOR WROUGHT OR ROLLED STEEL

1977-11-01

HISTORICAL

J402B_197711

Standard

CHEMICAL COMPOSITIONS OF SAE ALLOY STEELS

1980-10-01

HISTORICAL

J404_198010

Standard

CHEMICAL COMPOSITIONS OF SAE ALLOY STEELS

1991-02-01

HISTORICAL

J404_199102

In 1941, the SAE Iron and Steel Division in collaboration with the American Iron and Steel Institute made a major change in the method of expressing composition ranges for the SAE steels. The plan, as now applied, is based in general on narrower ladle analysis ranges plus certain product (check) analysis allowances on individual samples, in place of the fixed ranges and limits without tolerances formerly provided for carbon and other elements in SAE steels (reference J408). To avoid the possibility of confusion and conflict between SAE and AISI steel designations, all proposed changes in compositions, additions, or deletions of numbers will be coordinated between the two organizations. The compositions in this SAE Standard may apply to open hearth and basic oxygen, or electric furnace steels. Grades shown in Tables 1A and 1B with prefix letter E are normally made by the electric furnace process with maximum limits of 0.035% phosphorus and 0.040% sulfur.

Standard

CHEMICAL COMPOSITIONS OF SAE ALLOY STEELS

1977-11-01

HISTORICAL

J404J_197711

Standard

CHEMICAL COMPOSITIONS OF SAE ALLOY STEELS

1970-04-01

HISTORICAL

J404G_197004

Standard

CHEMICAL COMPOSITIONS OF SAE CARBON STEELS

1984-05-01

HISTORICAL

J403_198405

Standard

CHEMICAL COMPOSITIONS OF SAE CARBON STEELS

1988-12-01

HISTORICAL

J403_198812

Standard

CHEMICAL COMPOSITIONS OF SAE CARBON STEELS

1994-05-01

HISTORICAL

J403_199405

In 1941, the SAE Iron and Steel Division, in collaboration with the American Iron and Steel Institute, made a major change in the method of expressing composition ranges for the SAE steels. The plan, as now applied, is based in general on narrower cast or heat analysis ranges plus certain product analysis allowances on individual samples, in place of the fixed ranges and limits without tolerances formerly provided for carbon and other elements in SAE steels. To avoid the possibility of confusion and conflict between SAE and AISI steel designations, all proposed changes in compositions or additions or deletions of numbers will be coordinated between the two organizations. For years the variety of chemical compositions of steel has been a matter of concern in the steel industry.