EPNM 2012 Metallurgical Considerations in Hot Metalworking Bi-Metal Materials John Banker Vice President Customers & Technology Dynamic Materials Corporation Boulder, CO, USA
EPNM 2012 Introduction Explosion Welding is a proven, robust technology for manufacture of flat clad plates and concentric cylinders Fabrication of these clad components into industrial equipment often requires high temperature metalworking operations Controlling these procedures to simultaneously assure metallurgical quality of the cladding layer, base layer and interface in the fabricated equipment can be challenging
EPNM 2012 Hot Cylinder Forming Commonly used for clad steel >100mm thick Typically performed at approximately- 650 C to 900 C Dependent upon steel composition and thickness
EPNM 2012 Hot Head Forming Commonly used for clad steel >25 mm tk Typically performed at approximately- 500C to 1100 C Dependent upon clad combination, steel type, and thickness
EPNM 2012 Hot Plate Rolling Bang and Roll Typically used to produce clad plates <20 mm tk from thicker clad slabs Performed at approximately- 750 C to 1150 C Dependent upon clad combination, steel type, and thickness
EPNM 2012 Base Metal Metallurgical Concerns Steels are the dominant clad base metal Steel is selected for mechanical strength and toughness Base metal must meet Specification Requirements after hot working, heat treating, and all fabrication work (UTS, YS, Impacts, etc)
EPNM 2012 Typical Steel Hot Working Ranges Figure 4. Iron-Carbon Phase Diagram Typical Structural Steel Carbon Level Austenitic Hot Working Range Ferritic Hot Working Range
EPNM 2012 Typical Steel Heat Treatments to Achieve Required Properties Temperature (°C) Time (min) Austentize Water Quench Cooling + Temper Normalize (still air cooling)
EPNM 2012 Cladding Metal Metallurgical Concerns Corrosion Resistant Alloy (CRA) clad Cladding metal is selected for specific corrosion resistance Cladding metal is rarely considered in design strength calculations High temperature operations must be controlled to assure corrosion performance Key Factors: temperature, time at temperature, heating and cooling rates Time-Temperature-Sensitization Curves show relationships of Corrosion Properties vs Heat Treatments
EPNM 2012 CRA Groups from Hot Working Perspective Stainless Steels : Basic austenitic stainless steels- 304, 316, 321, 347, 317 Super austenitic stainless steels- >= 5% Mo Duplex stainless steels Nickel Alloys Reactive metals- Ti & Zr Refractory metals – Ta & Nb
EPNM 2012 Secondary Phases of Concern in Stainless Steels and Nickel Alloys
EPNM 2012 Austenitic Stainless Steels Carbide Formation Major Concern
EPNM 2012 Increased Alloying – Other Phases
EPNM 2012 Duplex Stainless Steels
EPNM 2012 Nickel Alloys Some Alloys Very Slow or No High Temperature Sensitization Nickel 200: Unalloyed Ni Alloy 400: 60 Ni – 40 Cu Alloy 625: 61 Ni + 22 Cr + 4 Fe Cb + 9 Mo Alloy 825: 42 Ni – 22 Cr – 32 Fe Cu + 3 Mo Others Complex secondary phase development- Example Alloy C Family
EPNM 2012 Nickel Alloy C Family Ni-Cr-Mo
EPNM 2012 Nickel Alloy C Family Ni-Cr-Mo (alt)
EPNM 2012 Reactive & Refractory Metals Commonly used Reactive and Refractory metals exhibit no significant phase changes that affect corrosion performance Titanium alloys Grades 1, 2, 16, 17 Zr alloys 700 & 702 Tantalum and Ta-2.5W
EPNM 2012 Effects of Hot Working on Clad Interface Properties Stainless Steels & Nickel Alloys Diffusion w/in +/- 0.5mm of interface No continuous brittle intermetallics formed Slight decrease in shear strength due to recovery of Cold Work at interface Interface retains toughness Extremely difficult to disbond
EPNM 2012 Reactive Metal Clad Interface Concerns during Hot Working Ti-Fe, Zr-Fe form several brittle intermetallic compounds Exposure to Elevated Temperatures can Degrade Clad Interface Properties
EPNM 2012 Shear Strength of Titanium-Steel
EPNM 2012 Larson-Miller Parameter Titanium – Steel Clad
EPNM 2012 Shear Strength of Zirconium-Steel
EPNM 2012 Reactive Metal Clad Steel Hot Working Considerations Optimum temperature range for Heat Teating and Hot Working Reactive Metal Clad is between 550 o C – 700 o C Avoid unacceptable degradation of interface properties Reduction in base metal yield strength at forming temperature Below steel lower critical temperature Minimize changes to base metal structure and mechanical properties
EPNM 2012
Typical Segmental Ti Clad Head 9 m Diameter x (80 + 3) thick
EPNM 2012 Hot Working Refractory Alloy Clad Tantalum Readily oxidizes in air above 300C Cold working is typical If hot working is mandatory, tantalum must be protected from air Some success with encapsulation in steel
EPNM 2012 Bang & Roll Stainless Steels & Nickel Alloys Typical rolling at 1100 C to 900 C Single slab rolling for clad thickness <10% of total thickness Pack rolling for greater clad % Reliable clad thickness uniformity Reliable product yields Some cladding alloys not possible to achieve both cladding metal and base metal properties Examples: Duplex, Some C-family alloys
EPNM 2012 Bang & Roll Titanium – Steel Clad Considerable tonnage of titanium clad has been produced by single slab Bang & Roll Slabs up to 150mm thick, rolled product down to 5mm thick Good thickness uniformity and rolling control up to 15% clad ratio Difficult to achieve both good bond strength AND base metal of Pressure Vessel Quality Test work by Hardwick indicates that a Nb interlayer may allow higher temperature rolling, possibly reducing the steel quality issues
EPNM 2012 Conclusions Explosion Clad plates can be formed and fabricated into reliable industrial equipment by Hot Metalworking With Proper Selection of Alloys & Procedures, no compromise in Cladding Metal Corrosion Properties Base Metal Mechanical Properties Clad bond quality With the Wrong Procedures, it is easy to make expensive trash quickly