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Stainless Steel High Ni & Cr Content Low (Controlled) Interstitials Austenitic Nitrogen Strengthened Austenitic Martensitic Ferritic Precipitation Hardened.

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Presentation on theme: "Stainless Steel High Ni & Cr Content Low (Controlled) Interstitials Austenitic Nitrogen Strengthened Austenitic Martensitic Ferritic Precipitation Hardened."— Presentation transcript:

1 Stainless Steel High Ni & Cr Content Low (Controlled) Interstitials Austenitic Nitrogen Strengthened Austenitic Martensitic Ferritic Precipitation Hardened Super Austenitic Super Ferritic Duplex

2 Resistance Welding Lesson Objectives When you finish this lesson you will understand: Learning Activities 1.View Slides; 2.Read Notes, 3.Listen to lecture 4.Do on-line workbook Keywords

3 Argon & Oxygen AOD Furnace Linnert, Welding Metallurgy AWS, 1994 Today, more than 1/2 of the high chromium steels are produced in the AOD Furnace

4 Castro & Cadenet, Welding Metallurgy of Stainless and Heat-resisting Steels Cambridge University Press, 1974 A=Martensitic Alloys B=Semi-Ferritic C=Ferritic

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6 We will look at these properties in next slide! AWS Welding Handbook

7 General Properties of Stainless Steels Electrical Resistivity –Surface & bulk resistance is higher than that for plain- carbon steels Thermal Conductivity –About 40 to 50 percent that of plain-carbon steel Melting Temperature –Plain-carbon:1480-1540 ° C –Martensitic: 1400-1530 ° C –Ferritic: 1400-1530 ° C –Austenitic: 1370-1450 ° C Coefficient of Thermal Expansion –Greater coefficient than plain- carbon steels High Strength –Exhibit high strength at room and elevated temperatures Surface Preparation –Surface films must be removed prior to welding Spot Spacing –Less shunting is observed than plain-carbon steels

8 Static Resistance Comparison Workpieces Electrode Resistance Stainless Steel Plain-carbon Steel Higher Bulk Resistance Alloy Effect Higher Surface Resistance Chromium Oxide Class 3 Electrode Higher Resistance Higher Resistances = Lower Currents Required

9 General Properties of Stainless Steels Electrical Resistivity –Surface & bulk resistance is higher than that for plain- carbon steels Thermal Conductivity –About 40 to 50 percent that of plain-carbon steel Melting Temperature –Plain-carbon:1480-1540 ° C –Martensitic: 1400-1530 ° C –Ferritic: 1400-1530 ° C –Austenitic: 1370-1450 ° C Coefficient of Thermal Expansion –Greater coefficient than plain- carbon steels High Strength –Exhibit high strength at room and elevated temperatures Surface Preparation –Surface films must be removed prior to welding Spot Spacing –Less shunting is observed than plain-carbon steels

10 Weld Nugget Base Metal Only 40 - 50% Heat conduction in SS Less Heat Conducted Away Therefore Lower Current Required Less Time Required (in some cases less than 1/3) Conduction in Plain Carbon Conduction in SS

11 General Properties of Stainless Steels Electrical Resistivity –Surface & bulk resistance is higher than that for plain- carbon steels Thermal Conductivity –About 40 to 50 percent that of plain-carbon steel Melting Temperature –Plain-carbon:1480-1540 ° C –Martensitic: 1400-1530 ° C –Ferritic: 1400-1530 ° C –Austenitic: 1370-1450 ° C Coefficient of Thermal Expansion –Greater coefficient than plain- carbon steels High Strength –Exhibit high strength at room and elevated temperatures Surface Preparation –Surface films must be removed prior to welding Spot Spacing –Less shunting is observed than plain-carbon steels

12 Weld Nugget Base Metal Melting Temp of Plain Carbon Melting Temp of SS Melting Temp of SS is lower Nugget Penetrates More Therefore Less Current and Shorter Time Required

13 General Properties of Stainless Steels Electrical Resistivity –Surface & bulk resistance is higher than that for plain- carbon steels Thermal Conductivity –About 40 to 50 percent that of plain-carbon steel Melting Temperature –Plain-carbon:1480-1540 ° C –Martensitic: 1400-1530 ° C –Ferritic: 1400-1530 ° C –Austenitic: 1370-1450 ° C Coefficient of Thermal Expansion –Greater coefficient than plain- carbon steels High Strength –Exhibit high strength at room and elevated temperatures Surface Preparation –Surface films must be removed prior to welding Spot Spacing –Less shunting is observed than plain-carbon steels

14 Ferritic, Martensitic, Ppt. = 6 - 11% greater expansion Austenitic = 15% greater expansion than Plain Carbon Steel Therefore Warpage occurs especially in Seam Welding Hot Cracking can Occur Dong et al, Finite Element Modeling of Electrode Wear Mechanisms, Auto Steel Partnership, April 10, 1995

15 General Properties of Stainless Steels Electrical Resistivity –Surface & bulk resistance is higher than that for plain- carbon steels Thermal Conductivity –About 40 to 50 percent that of plain-carbon steel Melting Temperature –Plain-carbon:1480-1540 ° C –Martensitic: 1400-1530 ° C –Ferritic: 1400-1530 ° C –Austenitic: 1370-1450 ° C Coefficient of Thermal Expansion –Greater coefficient than plain- carbon steels High Strength –Exhibit high strength at room and elevated temperatures Surface Preparation –Surface films must be removed prior to welding Spot Spacing –Less shunting is observed than plain-carbon steels

16 High Strength High Hot Strength Force Need Higher Electrode Forces Need Stronger Electrodes (Class 3, 10 & 14 Sometimes Used)

17 General Properties of Stainless Steels Electrical Resistivity –Surface & bulk resistance is higher than that for plain- carbon steels Thermal Conductivity –About 40 to 50 percent that of plain-carbon steel Melting Temperature –Plain-carbon:1480-1540 ° C –Martensitic: 1400-1530 ° C –Ferritic: 1400-1530 ° C –Austenitic: 1370-1450 ° C Coefficient of Thermal Expansion –Greater coefficient than plain- carbon steels High Strength –Exhibit high strength at room and elevated temperatures Surface Preparation –Surface films must be removed prior to welding Spot Spacing –Less shunting is observed than plain-carbon steels

18 Oxide from Hot Rolling Oxide Protective Film Chromium Oxide from Hot Rolling must be removed by Pickle Ordinary Oxide Protective Film is not a Problem

19 General Properties of Stainless Steels Electrical Resistivity –Surface & bulk resistance is higher than that for plain- carbon steels Thermal Conductivity –About 40 to 50 percent that of plain-carbon steel Melting Temperature –Plain-carbon:1480-1540 ° C –Martensitic: 1400-1530 ° C –Ferritic: 1400-1530 ° C –Austenitic: 1370-1450 ° C Coefficient of Thermal Expansion –Greater coefficient than plain- carbon steels High Strength –Exhibit high strength at room and elevated temperatures Surface Preparation –Surface films must be removed prior to welding Spot Spacing –Less shunting is observed than plain-carbon steels

20 Austenitic Nitrogen Strengthened Austenitic Martensitic Ferritic Precipitation Hardened Super Ferritic Duplex Super Austenitic Look at Each Grade & Its Weldability

21 Austenitic Contain between 16 and 25 percent chromium, plus sufficient amount of nickel, manganese and/or nitrogen Have a face-centered-cubic (fcc) structure Nonmagnetic Good toughness Spot weldable Strengthening can be accomplished by cold work or by solid-solution strengthening Applications: Fire Extinguishers, pots & pans, etc.

22 AWS Welding Handbook

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24 Pseudobinary Phase Diagram @ 70% Iron


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