不锈钢板材
A High Carbon Version of 316 Austenitic Stainless Steel making it More Suitable for Elevated Temperature Service.
Available thicknesses for Alloy 316H:
| 3/8" | 1/2" | 5/8" | 3/4" | 1" | |||
|---|---|---|---|---|---|---|---|
| 9.5mm | 12.7mm | 15.9mm | 19mm | 25.4mm | |||
| 1 1/4" | 1 1/2" | 1 3/4" | 2" | ||||
| 31.8mm | 38.1mm | 44.5mm | 50.8mm | ||||
Specification Sheet Overview
for Alloy 316H (UNS S31609) W. Nr. 1.4401:
A High Carbon Version of 316 Austenitic Stainless Steel making it More Suitable for Elevated Temperature Service
General Properties
Alloy 316H (UNS S31609) is a high carbon modification of Alloy 316 developed for use in elevated temperature service. The alloy has higher strength at elevated temperatures and is used for structural and pressure vessel applications at temperatures above 932°F (500°C). The higher carbon content of 316H also delivers higher tensile and yield strength than 316/316L and its austenitic structure provides excellent toughness down to cryogenic temperatures.
The corrosion resistance of Alloy 316H is comparable to Alloy316/316L and is superior to Alloy 304/304L in moderately corrosive environments. It is often used in process streams containing chlorides or halides. The alloy resists atmospheric corrosion, as well as, moderately oxidizing and reducing environments. It also resists corrosion in polluted marine conditions.
Alloy 316H is non-magnetic in the annealed condition. It cannot be hardened by heat treatment, however the material will harden due to cold working. It can be easily welded and processed by standard shop fabrication practices.
Applications
- Chemical and Petrochemical Processing – pressure vessels, tanks, heat exchangers, piping systems, flanges, fittings, valves, and pumps
- Food and Beverage Processing
- Marine
- Medical
- Petroleum Refining
- Pharmaceutical Processing
- Power Generation — nuclear
- Pulp and Paper
- Textiles
- Water Treatment
Standards
ASTM........A 240
ASME........SA 240
Chemical Analysis
Weight % (all values are maximum unless a range is otherwise indicated)
| Element | 316H | 316 | 316L |
|---|---|---|---|
| Chromium | 16.0 min.-18.0 max. | 16.0 min.-18.0 max. | 16.0 min.-18.0 max. |
| Nickel | 10.0 min.-14.0 max. | 10.0 min.-14.0 max. | 10.0 min.-14.0 max. |
| Molybdenum | 2.00 min.-3.00 max. | 2.00 min.-3.00 max. | 2.00 min.-3.00 max. |
| Carbon | 0.04 – 0.10 | 0.08 | 0.030 |
| Manganese | 2.00 | 2.00 | 2.00 |
| Phosphorus | 0.045 | 0.045 | 0.045 |
| Sulfur | 0.030 | 0.030 | 0.030 |
| Silicon | 0.75 | 0.75 | 0.75 |
| Nitrogen | – | 0.10 | 0.10 |
| Iron | Balance | Balance | Balance |
Physical Properties
Density
0.285 lbs/in38.00 g/cm3
Electrical Resistivity
74 Microhm-cm at 20°C29.1 Microhm-in at 68°F
Melting Range
2507 – 2552°F1375 – 1400°C
Specific Heat
0.11 BTU/lb-°F (32 – 212°F)500 J/kg-°K (0 – 100°C)
Modulus of Elasticity
29.0 x 106 psi200 GPa
Thermal Conductivity 212°F (100°C)
8.7 BTU/hr/ft2/ft/°F15 W/m-°K
| Temperature Range | |||
|---|---|---|---|
| °F | °C | in/in °F | cm/cm °C |
| 68-212 | 20-100 | 8.9 x 10-6 | 16.0 x 10-6 |
Mechanical Properties
Values at 68oF (20oC) (minimum values, unless specified)
| Yield Strength .2% Offset |
Ultimate Tensile Strength |
Elongation in 2 in. |
Hardness | ||
|---|---|---|---|---|---|
| psi (min.) | (MPa) | psi (min.) | (MPa) | % | |
| 30,000 | 205 | 75,000 | 515 | 40 | 95 Rockwell B |
316H also has a requirement for a grain size of ASTM No. 7 or coarser.
Corrosion Resistance
In most instances the corrosion resistance of Alloy 316H will be comparable to Alloy 316/316 L and will have superior corrosion resistance to Alloy 304/304L. Process environments that do not attack Alloy 304/304L will not attack this grade. One exception, however, is in highly oxidizing acids such as nitric acid where stainless steels containing molybdenum are less resistant. Alloy 316H performs well in sulfur containing service such as that encountered in the pulp and paper industry. The alloy can be used in high concentrations at temperatures up to 120°F (38°C).
Alloy 316H also has good resistance to pitting in phosphoric and acetic acids. It performs well in boiling 20% phosphoric acid. The alloy can also be used in food and pharmaceutical process industries where it is utilized to handle hot organic and fatty acids where product contamination is a concern.
Alloy 316H performs well in fresh water service even with high levels of chlorides. The alloy has excellent resistance to corrosion in marine environments under atmospheric conditions.
The higher molybdenum content of Alloy 316H assures it will have superior pitting resistance to Alloy 304/304L in applications involving chloride solutions particularly in oxidizing environments.
| Pitting Corrosion Resistance | Crevice Corrosion Resistance | ||
|---|---|---|---|
| PRE | CPT | CCT | |
| 24 | 20±2 | <0 | |
Pitting Resistance Equivelant (PRE) is calculated using the following formula: PRE = %Cr + 3.3 x %Mo + 16 x %N
Corrosion Pitting Temperature (CPT) as measured in the Avesta Cell (ASTM G 150), in a 1M NaCl solution (35,000 ppm or mg/I chloride ions).
Critical Crevice Corrosion Temperature (CCT) is obtained by laboratory tests according to ASTM G 48 Method F.
Fabrication Data
Alloy 316H can be easily welded and processed by standard shop fabrication practices.
Hot Forming
Working temperatures of 1700 – 2200°F (927 – 1204°C) are recommended for most hot working processes. For maximum corrosion resistance, the alloy should be annealed at 1900°F (1038°C) minimum and water quenched or rapidly cooled by other means.
Cold Forming
The alloy is quite ductile and forms easily. Cold working operations will increase the strength and hardness of the alloy and might leave it slightly magnetic.
Welding
Alloy 316H can be readily welded by most standard processes. A post weld heat treatment is not necessary.
Machining
Alloy 316H is subject to work hardening during deformation and is subject to chip breaking. The best machining results are achieved with slower speeds, heavier feeds, excellent lubrication, sharp tooling and powerful rigid equipment.
| Operation | Tool | Lubrication | CONDITIONS | |||||
|---|---|---|---|---|---|---|---|---|
| Depth-mm | Depth-in | Feed-mm/t | Feed-in/t | Speed-m/min | Speed-ft/min | |||
| Turning | High Speed Steel | Cutting Oil | 6 | .23 | 0.5 | .019 | 11-16 | 36.1-52.5 |
| Turning | High Speed Steel | Cutting Oil | 3 | .11 | 0.4 | .016 | 18-23 | 59.1-75.5 |
| Turning | High Speed Steel | Cutting Oil | 1 | .04 | 0.2 | .008 | 25-30 | 82-98.4 |
| Turning | Carbide | Dry or Cutting Oil | 6 | .23 | 0.5 | .019 | 70-80 | 229.7-262.5 |
| Turning | Carbide | Dry or Cutting Oil | 3 | .11 | 0.4 | .016 | 85-95 | 278.9-312.7 |
| Turning | Carbide | Dry or Cutting Oil | 1 | .04 | 0.2 | .008 | 100-110 | 328.1-360.9 |
| Depth of cut-mm | Depth of cut-in | Feed-mm/t | Feed-in/t | Speed-m/min | Speed-ft/min | |||
| Cutting | High Speed Steel | Cutting Oil | 1.5 | .06 | 0.03-0.05 | .0012-.0020 | 16-21 | 52.5-68.9 |
| Cutting | High Speed Steel | Cutting Oil | 3 | .11 | 0.04-0.06 | .0016-.0024 | 17-22 | 55.8-72.2 |
| Cutting | High Speed Steel | Cutting Oil | 6 | .23 | 0.05-0.07 | .0020-.0027 | 18-23 | 59-75.45 |
| Drill ø mm | Drill ø in | Feed-mm/t | Feed-in/t | Speed-m/min | Speed-ft/min | |||
| Drilling | High Speed Steel | Cutting Oil | 1.5 | .06 | 0.02-0.03 | .0008-.0012 | 10-14 | 32.8-45.9 |
| Drilling | High Speed Steel | Cutting Oil | 3 | .11 | 0.05-0.06 | .0020-.0024 | 12-16 | 39.3-52.5 |
| Drilling | High Speed Steel | Cutting Oil | 6 | .23 | 0.08-0.09 | .0031-.0035 | 12-16 | 39.3-52.5 |
| Drilling | High Speed Steel | Cutting Oil | 12 | .48 | 0.09-0.10 | .0035-.0039 | 12-16 | 39.3-52.5 |
| Feed-mm/t | Feed-in/t | Speed-m/min | Speed-ft/min | |||||
| Milling Profiling | High Speed Steel | Cutting Oil | 0.05-0.10 | .002-.004 | 10-20 | 32.8-65.6 | ||
NOTE: The information and data in this product data sheet are accurate to the best of our knowledge and belief, but are intended for informational purposes only, and may be revised at any time without notice. Applications suggested for the materials are described only to help readers make their own evaluations and decisions, and are neither guarantees nor to be construed as express or implied warranties of suitability for these or other applications.
