FABRICATION
- MACHINING
Machinability
is the term used to denote the machining performance of
a material by a cutting tool. Due to their difference
in properties when compared with carbon steels, slightly
different techniques are required when machining stainless
steels. The relative machinability of Columbus Stainless
steels in the annealed condition compared with carbon
steels (100) is: ferritic grades - 70 and austenitic grades
- 50. This difference is due to stainless steels being
tough rather than hard with a tendency to seize and gall.
Columbus
ferritic grades are usually supplied in the annealed condition
and due to their toughness their machining characteristics
are more similar to low alloy carbon steels rather than
mild steels. Due to the difference in conductivity, care
must be taken to ensure adequate removal heat from the
workpiece and the tool. Overheating can result in blunting
of the tool and localized burning of the workpiece surface.
Columbus
austenitic grades are also normally supplied in the annealed
condition and of more importance than their increased
hardness over carbon steel, is the large difference between
proof and tensile strengths. This increased ductility
tends to produce stringy chips during machining and due
to rapid work hardening can lead to problems. Heavier
feeds and slower speeds are employed to reduce tool build
up and minimise work hardening. Where possible it is recommended
that cutting tools with chip breakers or curlers be used,
especially for the high alloy grades such as types 309
and 310 where exceptionally tough and stringy chips are
produced. As conductivity is even lower than for ferritic
grades, heat removal is of greater importance.
When
machining stainless steels note must be taken of the following:
1.
The machining equipment must be sturdy and rigid with
up to 50% more power than equipment used for mild steels.
2.
Machine tools and the workpiece must be firmly held to
prevent vibration and chatter.
3.
Cutting tools, either high speed steel or carbide must
be kept sharp at all times, sharpening at regular intervals
being preferable to sharpening when blunt.
4.
Good lubricants should be used, especially for heavy cuts
at relatively slow speeds. Thinning with paraffin is recommended
for higher speed finishing cuts to keep the workpiece
and tools as cool as possible.
5.
The depth of cut must be such as to prevent the tool from
riding in the workpiece. This is particularly important
with austenitic grades to avoid work hardening and burnishing.
6.
The largest possible tool must be used in order to dissipate
heat.
7.
Interrupted cutting must be avoided where possible as
a greater degree of work hardening occurs as the tool
enters the workpiece. The prime rule should be "get
in and get out" with all tooling.
TOOL GEOMETRY
Tool
geometries are similar for both austenitic and ferritic
grades and the summarized below for HSS:
DRILLING:
Cutting edge angel ± 135°, point angel ±
138°, lip relief angle varies from 16° for 3mm
diameter to 8° for 25mm diameter.
REAMING:
Rake angle 3° to 8°, margin width 0.125 to 0.35mm,
relief angles primary 4° to 6°, secondary double
primary chamfer angle 30° to 35°, chamfer relief
angle 4° to 5°, helix angle ± 7°, lead
angle ± 2°.
TAPPING:
Straight fluted for > 12mm holes, spiral fluted for
smaller holes hook/rake angle 15° to 20°, back
relief angle 10°, chamfer angle/length plug taps 9°
to 10° (3.5 to 4.5 threads) taper taps 4° to 5°,
(8 to 10 threads).
DIE
THREADING:
Rake angle 20° to 30°, throat angle 20° to
25°, face angle 1.5°.
SINGLE
POINT TURNING:
Back rake angle ferritics 5°, austenitic 0°, side
rake angle ferritics 8°, austenitics 10° to 15°,
end relief, side relief and end cutting edge angles all
5°.
FORM
TURNING:
Back rake angle 4° to 10°, end relief angles 7°
to 10°, side relief and clearance angles 1° to
5°.
CUT
OFF TOOLS:
Back rake angle 6° to 10°, end relief angle 7°
to 10°, side relief angle 2° to 3°, end cutting
edge angle 10° to 15° for small diameters and
shallow cuts, decreasing to 5° for larger diameters.
CUTTING
FLUIDS
Sulphurised,
chlorinated or sulphur-chlorinated mineral oils and emulsifiable
oils are used. In cases of high pressure the latter must
contain sulphonated or chlorinated additions.
CLEANING
After
machining it is essential to remove the cutting fluid
and degrease the workpiece. This is usually done with
conventional degreasing agents or solvents. In situations
where the workpiece has been subjected to excessive heating
or where maximum corrosion resistance is required, it
may be necessary to passivate and/or pickle and passivate.
If this is required refer to the section on post Fabrication
Treatment.
Info by : http://www.askzn.co.za/tech/tech_fab_machin.htm
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