General Properties
Alloy 347 is a stabilized, austenitic, chromium steel containing columbium which allows for the elimination of carbide precipitation, and, consequently, intergranualr corrosion. Alloy 347 is stabilized by the additions of chromium and tantalum and offers higher creep and stress rupture properties than alloy 304 and 304L which may also be used for exposures where sensitization and intergranualr corrosion are of concern. The addition of columbium also allows Alloy 347 to have excellent corrosion resistance, even superior to that of alloy 321. 347H is the higher carbon composition form of Alloy 347 and demonstrates improved high temperature and creep properties.
Specifications: UNS S34700 / S34709
Applications:
Alloy 347 is frequently used for the fabrication of equipment, which must be placed in service under severe corrosive conditions, and is also common to the petroleum refining industries. Applications that consistently used Alloy 347 include:
1.High temperature chemical processes
2.Heat exchanger tubes
3.High temperature steam service
4.High pressure steam pipes
5.Radiant superheaters
6.Boiler tubes
7.Heavy duty exhaust systems
8.General refinery piping
Standards:
1.ASTM/ASME: UNS S34700 / S34709
2.EURONORM: FeMi35Cr20Cu4Mo2
3.DIN: 2.4660
4.Offers similar resistance to general, overall corrosion as Alloy 304
5.Used for applications where alloys such as Alloy 304 are vulnerable to intergranualr corrosion
6.Generally used for heavy welded equipment which cannot be annealed and for equipment which is operated between 800 to 150°F (427 TO 816°C)
7.Alloy 347 is preferred over Alloy 321 for aqueous and other low temperature environments
8.Primarily used in high temperature environments where resistance to sensitization is necessary, in turn preventing intergranualr corrosion at lower levels
9.Susceptible to stress corrosion cracking
10.Exhibits oxidation resistance similar to all other 18-8 austenitic stainless steels
Corrosion Resistance:
Weldability
1.Austenitic stainless steels are considered to be the most weldable out of all high alloy steels
2.Can be welded by all fusion and resistance welding processes
3.Annealing temperature range is 1800 to 2000°F
4.May be stress relief annealed within the carbide precipitation range of 800 to 1500°F without any danger of subsequent intergranualr corrosion
5.Cannot be hardened by heat treatment
Heat Treatment
Chemical Properties:
|
C |
Cr |
Mn |
Ni |
P |
S |
Si |
Cb/Ta |
347 |
0.08 max |
min: 17.0 |
2.0 max |
min: 9.0 |
0.04 max |
0.30 |
0.75 |
min:10x C |
347H |
min: 0.04 |
min: 17.0 |
2.0 max |
min: 9.0 |
0.03 max |
0.30 |
0.75 |
min:10x C |
Mechanical Properties:
Grade |
Tensile Strength ksi (MPa) min |
Yield Strength 0.2% ksi offset ksi (MPa) min |
Elongation (% in 50mm) min |
Hardness (Brinell) MAX |
Hardness (Rockwell B) MAX |
347/347H |
75 |
30 |
40 |
201 |
95 |
Physical Properties:
Density |
Coefficient of |
Thermal Conductivity BTU/hr-ft-°F |
Specific Heat BTU/lbm -°F |
Modules of Elasticity (annealed)2-psi |
|
at 68 °F | at 68 – 212°F | at 68 – 1832°F | 68-932°F | at 32 – 212°F | in tension (E) |
0.288 | 9.2 | 11.4 | 14.7 | 0.12 | 28 x 106 |