Datasheet updated

2024-01-11 10:32
(supersedes all previous editions)

SAF™ 2906 is a high-alloy duplex (austenitic-ferritic) stainless steel with excellent corrosion resistance in caustic environments and environments with chlorides. SAF™ 2906 characteristics:

  • Excellent resistance to caustic environments, also in the presence of contaminants such as chlorides
  • Excellent resistance to intergranular corrosion
  • Excellent resistance to pitting and crevice corrosion
  • High resistance to stress corrosion cracking (SCC)
  • Good weldability
  • Very high strength. The proof strength is about three times as high as for conventional austenitic stainless steels.

Standards

  • UNS: S32906
  • EN Number: 1.4477

Product standards

  • Seamless tube and pipe: ASTM A789, A790
  • Bar steel: ASTM A479
  • Plate: ASTM A240

Approvals

  • Approved by the American Society of Mechanical Engineers (ASME) for use in accordance with ASME Boiler and Pressure Vessel Code, Section VIII, div. 1 and 2.
  • PED (Pressure Equipment Directive) PED 2014/68/EU and AD2000 Merkblatt W2: Particular Material Appraisal (PMA), Austenitic-ferritic steel SAF™ 2906.

Chemical composition (nominal)

Chemical composition (nominal) %
C Si Mn P S Cr Ni Mo Cu N
≤0.030 0.3 1.0 ≤0.030 ≤0.015 29 7 2.3 ≤0.80 0.35

Applications

Typical applications for SAF™ 2906 are:

  • Caustic soda production: the material is suitable for use in piping systems from the cells up to the evaporation plant. It is also an excellent choice for very aggressive conditions, such as the evaporator tubes, in both diaphragm and membrane process.
  • Alumina production: heat exchanger tubes and piping in the digestion of alumina
  • Environments where high resistance to pitting and crevice corrosion is required

Corrosion resistance

Caustic environment

SAF™ 2906 has, owing to its high chromium content, a very good resistance in caustic environments. For pure caustic soda, the performance of SAF™ 2906 can be observed in the iso-corrosion diagram (0.1 mm/year), see Figure 1. In the production of caustic soda, however, impurities in the form of chlorides and chlorates are present. Usually, in the caustic soda manufacturing process Ni200 or high nickel alloys are used, especially in critical equipment such as the evaporators.

Results of corrosion tests in sodium hydroxide (NaOH) containing different amounts of sodium chloride (NaCl) and sodium chlorate (NaClO3 ), similar to the content found in the evaporation plants of diaphragm and membrane processes, are presented in Table 1, 2 and Figure 2. The results clearly indicate the good performance of SAF™ 2906 in caustic environments.

Table 1. Performance in caustic environments - Diaphragm process
Grade Environment Temperature, °C (°F) Corrosion rate
mm/year
SAF™ 2906 10% NaOH, 2% NaCl, 800 ppm ClO3- 100 (212) < 0.01
Boiling < 0.01
50% NaOH, 7% NaCl, 800 ppm ClO3- 100 (212) < 0.01
Boiling 0.016
Sanicro® 28 10% NaOH, 2% NaCl, 800 ppm ClO3- 100 (212) < 0.01
Boiling < 0.01
50% NaOH, 7% NaCl, 800 ppm ClO3- 100 (212) < 0.01
Boiling 0.34
Ni200 10% NaOH, 2% NaCl, 800 ppm ClO3-
100 (212) < 0.01
Boiling < 0.01
50% NaOH, 7% NaCl, 800 ppm ClO3- 100 (212) < 0.01
Boiling 0.15
Table 2. Performance in caustic environments - Membrane process
Grade Environment Temperature Corrosion rate
mm/year
SAF™ 2906 32%NaOH + 30 ppm Cl- + 20 ppm NaClO3 Boiling < 0.01
50%NaOH + 30 ppm Cl- + 20 ppm NaClO3 Boiling < 0.01
Ni200 32%NaOH + 30 ppm Cl- + 20 ppm NaClO3 Boiling < 0.01
50%NaOH + 30 ppm Cl- + 20 ppm NaClO3 Boiling < 0.01

fig-1 rev 1.png

Figure 1. Iso- corrosion diagram for SAF 2906 in pure NaOH, naturally aerated solution.

fig-2 rev 1.png

Figure 2. Corrosion rates in a mixture of 50% NaOH, 7% NaCl, 800 ppm ClO3-, boiling solution.

Pitting and crevice corrosion

SAF™ 2906 has a carefully balanced composition with a high chromium and nitrogen content and a moderate amount of molybdenum. This gives the material a high resistance to localized corrosion caused by chlorides. The PRE number (Pitting Resistance Equivalent) is an index for comparing pitting corrosion resistance.

The PRE is defined as, in weight-PRE = %Cr + 3.3 x %Mo + 16 x %N
A very severe test for pitting or crevice corrosion is the ASTM G48 test, i.e. immersion in 6% FeCl3. Results for pitting test according to modified method A and crevice corrosion testing according to method B, are presented in Table 3. The crevice corrosion test was performed with a crevice specified in the MTI-2 procedure, where an artificial crevice is mounted on the sample with a torque of 0.28 Nm. The critical pitting temperature (CPT) and the critical crevice temperature (CCT) are the temperatures where pitting or crevice corrosion starts to develop on the material.

Table 3. PRE, CPT and CCT values
Grade PRE (min.) CPT, °C (°F) CCT, °C (°F)
SAF™ 2906 41.5 75 (167) 42.5 (109)
SAF™ 2507 42.5 80 (176) 50 (122)
SAF™ 2205 35 30 (86) 18 (64)
ASTM 316L 26 <10 (50) <10 (50)

Potentiostatic tests in solutions with different chloride contents are reported in Figure 3. Figure 4 shows the effect of increased acidity. In both cases the applied high potential, 600 mV SCE, corresponds to very harsh conditions, thus resulting in conservative data with a lower critical temperature compared with most practical situations.

fig-3 rev 1.png

Figure 3. Critical pitting temperature (CPT) at varying concentrations of sodium chloride, from 3 to 25% (potentiostatic determination at +600 mV SCE with surface ground to 600 grit paper).

fig-4 rev 1.png

Figure 4. Critical pitting temperature (CPT) in 3% NaCl with varying pH (potentiostatic determination at +600 mV SCE with surface ground to 600 grit paper).

Stress corrosion cracking (SCC)

SAF™ 2906 has excellent resistance to chloride induced stress corrosion cracking (SCC). The resistance of various alloys to stress corrosion cracking (SCC) determined by constant load testing in aerated 40% CaCl2 , pH 1.5, at 100°C (210°F), (modified ASTM G36 method) is shown in Figure 5.

fig-5 rev 1.png

Figure 5. Constant load testing of SAF™ 2906 and some other alloys in 40% CaCl2 , pH 1.5, at 100°C (212°F). Time to failure vs. applied stress in percentage of tensile strength is shown. Filled symbol: cracking, unfilled symbol: no cracking.

Nitric acid

Due to its balance of chromium and molybdenum, SAF™ 2906 presents good resistance to nitric acid. The iso- corrosion diagram, see Figure 6, shows the performance of the material compared to SAlleima2RE10, a high purity austenitic grade widely used for nitric acid.

2909diagram2 rev 1.png

Figure 6. Iso- corrosion diagram for SAF™ 2906 and Alleima® 2RE10 in a naturally aerated, stagnant solution of nitric acid. The curves represent a corrosion rate of 0.1 mm/year.

Fabrication

Bending

The force needed for bending SAF™ 2906 is higher than that for standard austenitic stainless steels which is a natural consequence of the higher yield strength.

Expanding

Compared with austenitic stainless steels, SAF™ 2906 has a higher proof and tensile strength. This must be kept in mind when expanding tubes into tubesheets. Normal methods can be used, but the expansion requires higher initial force and should be undertaken in a one step operation. As a general rule, tube to tubesheet joints should be welded to ensure a leak free joint.

Machining

Being a dual phase material (austenitic-ferritic) SAF™ 2906 will present a different wear picture from that of a single phase material like Alleima® 2RE69. The cutting speed must therefore be lower than that recommended for austenitic grades. Further information is available on request.

Forms of supply

Seamless tube and pipe

SAF™ 2906 can be supplied as seamless tube and pipe. Tubes can be supplied straight or U-bent.

Other forms of supply:

  • Fittings and flanges
  • Plate, sheet and strip
  • Bar steel
  • Forged products

Heat treatment

The tubes are normally delivered in the heat treated condition. If additional heat treatment is needed after further processing, the following is recommended.

Solution annealing

1040-1080°C (1900-1980°F), rapid cooling in air or water.

Mechanical properties

The following figures apply to material in the solution annealed condition. If SAF™ 2906 is exposed for prolonged periods to temperature ranges exceeding 280°C (540°F), the microstructure changes, which results in a reduction in toughness. This does not necessarily affect the behavior of the material at the operating temperature. The listed values are guaranteed for tube and pipe.

At 20°C (68°F)

Wall thickness Proof strength Tensile strength Elong.
Rp0.2a) Rm Ab)
mm MPa ksi MPa ksi %
min min. min. min. min.
<10 650 94 800 116 25
≥10 550 80 750 109 25

1 MPa = 1 N/mm2
a) Rp0.2 corresponds to 0.2% offset offset yield strength.
b) Based on L0 = 5.65 √S0 where L0 is the original gauge length and S0 the original cross-section area.

At high temperatures

Metric units
Temperature Wall thickness Proof strength Tensile strength, Elong
Rp0.2 Rm A
°C mm MPa MPa %
min. min. min
100 <10 550 750 25
≥10 500 730 25
200 <10 470 720 25
≥10 430 700 25
300 <10 450 710 25
≥10 410 690 25
Imperial units
Temperature Wall thickness Proof strength Tensile strength Elong
Rp0.2 Rm A
°F in. ksi ksi %
min. min. min.
200 <0.4 80 109 25
≥0.4 73 106 25
400 <0.4 68 104 25
≥0.4 62 101 25
600 <0.4 65 103 25
≥0.4 59 100 25
Recommended design values for SAF™ 2906(UNS S32906) recommended according to ASME Code Case 2295-3
Temperature
Stress
Tube wall thickness <10 mm
Tube wall thickness >10 mm
oF oC ksi MPa ksi MPa
100 38 33.1 228 31.1 214
200 93 33.1 228 31.1 214
300 149 31.5 217 29.6 204
400 204 30.6 210 28.7 197
500 260 30.1 207 28.3 195
600 316 30.1 207 28.3 195

Impact strength

SAF™ 2906 possesses a good impact strength. The ductility to brittle transition temperature is approximately -100°C (-150°F). Figure 7 shows the typical impact energy for SAF™ 2906.

Figure 7. Typical impact energy curve for SAF™ 2906 using half size (5 x 10 mm) Charpy V specimens (average of 3 at each temperature).

Physical properties

Density: 7.7 g/cm3, 0.28 lb/in3

Thermal conductivity

Temperature, °C W/m °C Temperature, °F Btu/ft h°F
20 13 68 7
100 14 200 8
200 16 400 9
300 18 600 10
400 19 800 11

Specific heat capacity

Temperature, °C J/kg °C Temperature, °F Btu/ft h°F
20 470 68 0.11
100 500 200 0.12
200 530 400 0.13
300 560 600 0.14
400 600 800 0.14

Thermal expansion

Mean values in temperature ranges (x10-6) SAF™ 2906 has a coefficient of thermal expansion close to that of carbon steel. This gives SAF™ 2906 definite design advantages over austenitic stainless steels. The values given in the table are average values in the temperature ranges.

Metric units, x10-6/°C

Temperature, °C 30-100 30-200 30-300 30-400
SAF™ 2906 11.5 12.0 12.5 12.5
Carbon steel 12.5 13.0 13.5 14.0
ASTM 316L 16.5 17.0 17.5 18.0

Imperial units, x10-6/°F

Temperature, °F 86-200 86-400 86-600 86-800
SAF™ 2906 6.5 7.0 7.0 7.0
Carbon steel 7.0 7.0 7.5 8.0
ASTM 316L 9.5 9.5 10.0 10.0

Resistivity

Temperature, °C μΩm Temperature, °F μΩinch
20 0.81 68 31.9

Modulus of elasticity, x103

Temperature, °C MPa Temperature,
°F
ksi
20 200 68 29.0
100 194 200 28.2
200 186 400 26.9
300 180 600 26.0

Welding

The weldability of SAF™ 2906 is good. Welding must be carried out without preheating and subsequent heat treatment is normally not necessary. Suitable method of fusion welding is gas tungsten arc welding GTAW/TIG with shielding gas of Ar+2% N2. For tube to tubesheet welding, it is recommended to use Ar+3% N2 as shielding gas to have proper weld metal structure.

For SAF™ 2906, heat input of 0.2-1.5 kJ/mm and interpass temperature of <150°C (300°F) are recommended.

Recommended filler metals

GTAW/TIG welding

Exaton 29.8.2.L wire or strip electrodes are recommended for overlay welding of tubesheets and high-pressure vessels in cases where corrosion resistance, equal to that of SAF™ 2906, is required.


Disclaimer: Recommendations are for guidance only, and the suitability of a material for a specific application can be confirmed only when we know the actual service conditions. Continuous development may necessitate changes in technical data without notice. This datasheet is only valid for Alleima materials.