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Summary
SX 316 is an improved version of SX 304, with the
addition of molybdenum and a slightly higher nickel
content. The resultant composition of SX 316 gives the
steel much increased corrosion resistance in many
aggressive environments. The molybdenum makes
the steel more resistant to pitting and crevice
corrosion in chloride-contaminated media, sea water
and acetic acid vapour's. The lower rate
of general corrosion in mildly corrosive environments
gives the steel good atmospheric corrosion resistance
in polluted marine atmospheres.
SX 316 offers higher strength and better creep
resistance at higher temperatures than SX 304.
SX 316 also possesses excellent mechanical and
corrosion properties at sub-zero temperatures.
When there is a danger of corrosion in the
heat-affected zones of weldments, the low-carbon
variety SX 316L should be used. SX 316 Ti, the
titanium-stabilised version, is used for its
resistance to sensitization during prolonged exposure
in the 550oC-800oC temperature
range.
Typical
Applications
Because of its superior corrosion and oxidation
resistance, good mechanical properties and
fabricability, SX 316 has applications in may sectors
of industry. Some of these include:
Tanks and storage vessels for corrosive liquids.
Specialised process equipment in the chemical, food,
paper, mining, pharmaceutical and petroleum
industries.
Architectural applications in highly corrosive
environments.
Chemical
Composition (ASTM A 240)
| |
C |
Mn |
P |
S |
Si |
Cr |
Ni |
Mo |
Ti |
SX316
SX316L
SX316Ti |
0.08 max
0.03 max
0.08 max |
2.0
max |
0.045
max |
0.030
max |
1.0
max |
16.0
to
18.0 |
10.0
to
14.0 |
2.00
to
3.00 |
-
0.5 max
5X%C |
Typical
properties in the annealed condition
The properties quoted in this publication are typical
of mill products and unless indicated must not be
regarded as guaranteed minimum values for
specification purposes.
1.
Mechanical properties at room temperature
| |
SX316 |
SX316L |
SX316Ti |
| |
Typical |
Minimum |
Typical |
Minimum |
Typical |
Minimum |
| Tensile
Strength, MPa |
580 |
515 |
570 |
485 |
600 |
515 |
| Proof Stress
(0.2 % offset), MPa |
310 |
205 |
300 |
170 |
320 |
205 |
| Elongation
(Percent in L = 5.65 So) |
55 |
40 |
60 |
40 |
50 |
40 |
| Hardness (Brinell) |
165 |
- |
165 |
- |
165 |
- |
| Erichsen Cup
Test Value mm |
8 - 10 |
- |
10 - 11 |
- |
- |
- |
| Endurance
(fatigue) limit, MPa |
260 |
- |
260 |
- |
260 |
- |
2.
Properties at elevated temperatures
The values given refer to SX 316 and SX 316 Ti only as
strength values for SX 316L fall rapidly above 425oC.
Short
Time Elevated Temperature Tensile Strength
| Temperature, C |
600 |
700 |
800 |
900 |
1000 |
| Strength, MPa |
460 |
320 |
190 |
120 |
70 |
Creep
data
Stress for a creep rate of 1% in 10 000 h
| Temperature, oC |
550 |
600 |
650 |
700 |
800 |
| Stress, MPa |
160 |
120 |
90 |
60 |
20 |
Recommended
Maximum Service Temperature
(Oxidising conditions)
Continuous
Service
925oC
Intermittent
Service
870oC
3.
Properties at Sub-Zero Temperatures
(SX 316)
| Temperature |
oC |
-78 |
-161 |
-196 |
| Proof Strength
(0.2% Offset) |
MPa |
400 |
460 |
580 |
| Tensile Strength |
MPa |
820 |
1150 |
1300 |
| Impact Strength
(Charpy V-Notch) |
J |
180 |
165 |
155 |
4.
Corrosion Resistance
4.1
Aqueous
For
specific conditions, consult Macsteel VRN technical
staff. As a rough guide, the following examples
are
given for pure acid-water mixtures.
| TemperatureoC |
20 |
80 |
| Concentration,
(-% by mass) |
10
20
40
60
80 100 |
10
20
40
60
80 100 |
| Sulphuric Acid |
0
1
2
2
1
0 |
2
2
2
2
2
2 |
| Nitric Acid |
0
0
0
0
0
1 |
0
0
0
0
1
2 |
| Phosphoric Acid |
0
0
0
0
1
2 |
0
0
0
0
1
2 |
| Formic Acid |
0
0
0
1
1
0 |
0
0
1
1
1
0 |
Key:
0 = resistant -
corrosion rate less than 100 mm/year
1 = partly resistant
- corrosion rate 100 m to 1000
mm/year
2 = non resistant - corrosion rate
more than 1000 mm/year
4.2
Atmospheric
The performance of SX 316 compared with other metals
in various environments is shown in the
following table. Corrosion rate is based on a 5
year exposure.
| Environment |
Corrosion
Rate (mm/year) |
| SX
316 |
Aluminium-3S |
Mild
Steel |
| Rural |
0.0025 |
0.025 |
5.8 |
| Marine |
0.0076 |
0.432 |
34.0 |
| Marine-Industrial |
0.0051 |
0.686 |
46.2 |
Note:
For corrosion resistance of SX 316 relative to
other types, see the section in Comparative Data.
4.3
Thermal Processing
4.3.1 Annealing.
Heat from 1 010oC to 1 120oC and
cool rapidly in air or water. The best corrosion
resistance is obtained when the final annealing
temperature is above 1 070oC.
4.3.2 Stress
relieving. Heat from 200 - 400oC
and air cool.
4.3.3 Hot working
Initial forging and
pressing:
1150 - 1200oC
Finishing
temperature:
above 900oC
For upsetting operations, forgings
should be finished
between:
930 and 980oC
All hot working operations should be followed by
annealing.
Note:
Soaking times to ensure uniformity of temperature are
up to 12 times that required for the same
thickness of mild steel.
Cold
Working
SX 316/316L, being extremely tough and ductile, can be
readily fabricated by cold working. Typical operations
include bending, forming, deep drawing and upsetting.
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