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Grade 316 is the standard molybdenum-bearing grade,
second in importance to 304 amongst the austenitic stainless steels. The
molybdenum gives 316 better overall corrosion resistant properties than Grade
304, particularly higher resistance to pitting and crevice corrosion in
chloride environments.
Grade 316L, the low carbon version of 316 and is immune
from sensitization (grain boundary carbide precipitation). Thus it is
extensively used in heavy gauge welded components (over about 6mm). There is
commonly no appreciable price difference between 316 and 316L stainless
steel.
The austenitic structure also gives these grades
excellent toughness, even down to cryogenic temperatures.
Compared to chromium-nickel austenitic stainless steels,
316L stainless steel offers higher creep, stress to rupture and tensile
strength at elevated temperatures.
Key Properties
These properties are specified for flat rolled product (plate,
sheet and coil) in ASTM A240/A240M. Similar but not necessarily identical
properties are specified for other products such as pipe and bar in their
respective specifications.
Composition
Table 1. Composition ranges for 316L stainless steels.
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316L
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Min
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-
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-
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-
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-
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-
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16.0
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2.00
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10.0
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-
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Max
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0.03
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2.0
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0.75
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0.045
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0.03
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18.0
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3.00
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14.0
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0.10
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Mechanical Properties
Table 2. Mechanical properties of 316L
stainless steels.
Physical Properties
Table 3. Typical physical properties for
316 grade stainless steels.
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316/L/H
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8000
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193
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15.9
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16.2
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17.5
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16.3
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21.5
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500
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740
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Grade Specification Comparison
Table 4. Grade specifications for 316L
stainless steels.
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316L
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S31603
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316S11
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-
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1.4404
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X2CrNiMo17-12-2
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00Cr17Ni13Mo2
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SUS 316L
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Note: These comparisons are approximate
only. The list is intended as a comparison of functionally similar materials not as a schedule of contractual
equivalents. If exact equivalents are needed original specifications must be
consulted.
Possible Alternative Grades
Table 5. Possible alternative grades to 316 stainless
steel.
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317L
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Higher
resistance to chlorides than 316L, but with similar resistance to stress
corrosion cracking.
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Corrosion Resistance
Excellent in a range of atmospheric environments and many
corrosive media - generally more resistant than 304. Subject to pitting and
crevice corrosion in warm chloride environments, and to stress corrosion
cracking above about 60°C. Considered resistant to potable water with up to
about 1000mg/L chlorides at ambient temperatures, reducing to about 500mg/L
at 60°C.
316 is usually regarded as the standard “marine grade
stainless steel”, but it is not resistant to warm sea water. In many marine
environments 316 does exhibit surface corrosion, usually visible as brown
staining. This is particularly associated with crevices and rough surface
finish.
Heat Resistance
Good oxidation resistance in intermittent service to
870°C and in continuous service to 925°C. Continuous use of 316 in the
425-860°C range is not recommended if subsequent aqueous corrosion resistance
is important. Grade 316L is more resistant to carbide precipitation and can
be used in the above temperature range. Grade 316H has higher strength at
elevated temperatures and is sometimes used for structural and
pressure-containing applications at temperatures above about 500°C.
Heat Treatment
Solution Treatment (Annealing) - Heat to 1010-1120°C and
cool rapidly. These grades cannot be hardened by thermal treatment.
Welding
Excellent weld ability by all standard fusion and
resistance methods, both with and without filler metals. Heavy welded
sections in Grade 316 require post-weld annealing for maximum corrosion
resistance. This is not required for 316L.
316L stainless steel is not generally weldable using
oxyacetylene welding methods.
Machining
316L stainless steel tends to work harden if machined too
quickly. For this reason low speeds and constant feed rates are recommended.
316L stainless steel is also easier to machine compared
to 316 stainless steel due its lower carbon content.
Hot and Cold Working
316L stainless steel can be hot worked using most common
hot working techniques. Optimal hot working temperatures should be in the
range 1150-1260°C, and certainly should not be less than 930°C. Post work
annealing should be carried out to induce maximum corrosion resistance.
Most common cold working operations such as shearing,
drawing and stamping can be performed on 316L stainless steel. Post work
annealing should be carried out to remove internal stresses.
Hardening and Work Hardening
316L stainless steel does not harden in response to heat
treatments. It can be hardened by cold working, which can also result in
increased strength.
Applications
Typical applications include:
• Food preparation equipment particularly in chloride
environments.
• Pharmaceuticals
• Marine applications
• Architectural applications
• Medical implants, including pins,
screws and orthopaedic implants like total hip and knee replacements
• Fasteners
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