UNIQUE
CHARACTERISTICS
- Vacuum-Arc
Remelt manufacturing process.
- 40
HRc hardness.
- Uniform
hardness throughout, even in
heavy sections.
- When
welded, NAK leaves no witness
lines after re-aging.
Uniform grain structure with
no pin holes, inclusions or
hard spots.
- Machines
up to 50% faster than 30 HRc
P20 mold steels.
- Never
needs stress relieving, even
after heavy machining.
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BENEFITS
- Welding
Due to low carbon content, age
hardening, and the availability of NAK
weld rod, hardness is lowered in the
heat-affected zone during the welding
process. NAK55 can be re-aged to 40
HRc with no distortion or stress put
into the mold. Polish, texture and
wear in the weld are indistinguishable
from adjoining "parent
steel" on the finished product.
- Machining
Machines up to 50% faster than P20 to
a superior surface with negligible
dimensional change. Positive rake
cutters with concave, chip breaking
inserts
work best, and last up to twice as
long as with P20 mold steels.
- EDM
The soft recast layer (approximately
32 HRc) is much thinner and is easier
to
remove than steels with a recast layer
that is equivalent to their "as
quenched" hardness. With NAK55,
no post EDM stress relieving is ever
needed.
- Stability
Age hardening eliminates the stresses
inherent in quenched and tempered
steels. NAK55 is dimensionally stable
and predictable over many years of
heating and cooling cycles.
- Surface
Enhancements
VAR processing with uniform grain
structure facilitates superior nickel,
chrome, titanium, and other coatings.
Unique chemistry responds extremely
well to ion-nitriding.
- Texturing
and Polishing
Exceptionally clean steel with uniform
grain structure polishes beautifully
allowing superior texturing and photo
etching.
- Wear
Higher hardness ensures molds have a
longer life than those made from P20,
particularly in gate, runner, and
parting line areas.
The
uniform, refined grain structure of
NAK55
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TYPICAL
CHEMISTRY
- Carbon
0.15%
- Copper
1.00%
- Sulfur
0.10%
- Nickel
3.00%
- Silicon
0.30%
- Aluminum
1.00%
- Manganese
1.50%
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MECHANICAL
PROPERTIES
- Tensile
Strength 182,000 psi
- Yield
Strength (.2% offset)
146,500 psi
- Reduction
of Area 39.8%
- Elongation
in 2"(longitudinal) 15.6%
- Modulus
of Elasticity (room temp.)
30.00 x 106psi
- Charpy
V-notch Impact Strength:
- Longitudinal 7.2 ft./lb.
- Transverse 5.6 ft./lb.
- Hardness 40 HRc
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PHYSICAL
PROPERTIES
Coefficient
of Thermal Expansion (x 10-6in/in/F°)
- 68°F
to 212°F 6.3
- 68°F
to 392°F 7.0
- 68°F
to 572°F 7.5
Coefficient
of Thermal Conductivity
(BTU/ft•hr•F°)
- At
200°F 23.9
- At
400°F 24.4
Magnetic
Properties
- Maximum
Magnetic Permeability 380
- Saturated
Magnetism (Gauss) 16,350
- Residual
Magnetism (Gauss) 8,500
- Coercive
Force (Oersted) 14.0
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GENERAL
DESIGN GUIDELINES
- Compressive
Strength
NAK55 possesses excellent resistance
to surface deformation by compressive
force. Its resistance to surface
deformation equals that of H-13 steel
at like hardness.
- Stability
NAK55 is not quenched to achieve
hardness. Therefore, it does not have
the
stresses inherent in quenched and
tempered steels. NAK55
never needs stress relieving due to
heavy machining because of uniform
hardness throughout! It
has excellent dimensional stability
during mold construction and while in
service. Even after long mold runs,
cool-down, and subsequent re-heating,
the material maintains dimensional
stability.
- Operating
Temperature Ranges
NAK55 is a precipitation hardening
steel. The formation of the
precipitates occurs at a temperature
range between 932° and 968°F.
Exposure to temperatures below the
original precipitation hardening
temperature has no effect on the grain
structure of the steel. Therefore,
even molds in service at high
operating temperatures maintain
dimensional stability. Similarly,
nitriding or Physical Vapor Deposition
(PVD) treatments done below the
precipitation hardening temperature
range do not cause distortion.
This is a tremendous advantage over
typical mold steels that have been
tempered at low temperatures to
maintain hardness.
- Hardness
The precipitates, which account for
the steel’s hardness, begin to grow
in size if the original hardening
temperature range for NAK55 (932°–950°F)
is exceeded for an extended period of
time. This results in a loss of
hardness and toughness, and
accompanying dimensional change.
Re-solution heat-treating and
subsequent precipitation hardening can
recover
hardness and toughness, but
dimensional changes will have
occurred.
- Wear
Properties
NAK55 is a low carbon steel that
acquires hardness by precipitation
hardening. Very small carbide
structures and precipitates are formed
during the hardening process.
Care is required when NAK55 steel
slides against itself in molding
situations. The use of dissimilar
metals, with a 10 HRc point difference
on the mating surfaces, is advisable
in slide situations. Alternatively,
you may change the hardness of the
surface of similar metals by plating,
nitriding, or applying other types of
coatings.
- Shut-Off
Tolerances
The tolerance between mating surfaces
on angle shut-offs is very important,
and proper setting of the mold is
required. The recommended tolerance at
molding temperature is .0008" per
side for ABS, Polypropylene,
Polyethylene, etc. A
.0004"(.01mm) per side clearance
is required for Polyacetals or nylons,
due to their lesser viscosity.
- Ejector
Pin Tolerances
|
Dia.
of Ejector Pin
.200" and below
.201" to .500" |
Recommended
Clearance
.0008"
.0012" |
| Note:
All clearance values are at
molding temperature. |
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- Sharp
Corners
Sharp or square corners serve as focal
points for concentrating stresses that
build up in molds and dies during
operating conditions. A .100"–
.120" radius to all corners is
recommended, especially large box-type
molds. To avoid these stresses, the
thickness of the material backing up a
sharp corner should be increased by
50% when compared with softer steels.
- Thin
Sections
Due to the toughness limitations of
NAK55, it is suggested that other
types of
steel be inserted at thin rising
sections (4-to-1 ratio or more) and
that a radius
be put on the base of rising sections
from the initial design stages.
- Cavity
Depth
Cavity depth should be limited to no
more than 50 – 55% of the block
thickness in high-pressure injection
molds.
- Cooling/Heater
Water Lines
Do not locate cooling or heater lines
directly below the corner of a mold
cavity.
The ideal location
for heating or cooling lines is three
(3) times the hole diameter from the
molding surface. 1.5 times the hole
diameter from the molding surface is
the minimum. Example: a
1/4"diameter waterline should be at
least 3/8" away from
mold surface and preferably
3/4". The distance between lines
should be five (5)
times the line diameter minimum.
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PROCESSING
GUIDELINES
The optimum
cutting conditions for NAK55 vary by
machine tools. Cutting tools
incorporating the recommended geometries
will produce superb finish machined
surfaces, often completely eliminating
grinding. NAK55 does not work harden.
- Use a
new, sharp, premium grade of tap,
TiN coated and spiral pointed.
- Use a
tapping oil or highly chlorinated
sulfurized oil. A mixture of 50%
kerosene and 50% cutting oil also
works well.
- EDM
Copper or graphite electrodes are
suitable, or the steel may be used as
an electrode when burning mating
halves together to achieve a fit.
The recast layer for NAK55 is soft
(approximately 32 HRc). Other low
alloy grades such as P20, or more
highly alloyed steels such as S7 and
H13, have recast layers equivalent to
their high, as-quenched hardness.
Because the EDM white layer must be
removed, the subsequent stoning or
grinding of NAK55 is much easier than
with other steels.
NAK55 may develop a striped pattern
with a low amperage finishing burn.
- Polishing
NAK55 is a Vacuum-Arc Remelted steel
of exceptional cleanliness and as
such, it polishes beautifully.
Normal polishing techniques will yield
excellent results. All stoning
operations should be done with
reciprocating tools.
Note:
No rotary stoning.
NAK55
steel contains uniformly dispersed
manganese sulfides. These sulfides
reduce friction between the
steel and the stones and actually
improve polishability. However, if a
circular motion is used, the sulfides
can be lifted up from the surface
creating the appearance of pits. Therefore,
it is important to use a reciprocating
stoning technique and light pressure
during buffing.
Due to the sulfide content of NAK55,
do not exceed 3000 grit Diamond
Compound.
- Texturing
NAK55 is an ideal steel for photo
etching or texturing. Vacuum-Arc
Remelted processing employs a continuous ingot
casting procedure that nearly
eliminates chemical segregation of the
alloying elements. This results in a
clean, homogenous steel.
The low carbon content of NAK55 is
also advantageous, since carbon is a
potent alloying element and a major
contributor to chemical segregation.
The uniform hardness of NAK55 assures
even and uniformly textured patterns regardless of workpiece size or depth
of cavity. Furthermore, the ability to
easily restore a uniform hardness to
welded areas is a tremendous advantage
for texturing in comparison to other
steels.
- Nitriding
NAK55 contains 1% aluminum and
responds very well to nitriding. There
are many forms of nitriding and each
has advantages. However, for molding
die applications, ion-nitriding, in
particular, is very suitable for
NAK55. When employing standard gas
nitriding do not exceed 950°F.
The ion-nitriding process is done in a
controlled atmosphere. It is clean,
with minimal distortion, and can be done at
temperatures that do not damage NAK55.
Nitriding increases wear resistance
and creates a hard surface ideal for
slides or dies that mold abrasive or
mineral-filled thermoplastics. The
nitrided surface has a hardness over
60 HRc, improved corrosion resistance,
and can be polished to a finer finish
than possible at base metal hardness.
Old logo
milled out. |
Cavity
preheated 600-750°F.
Welded with NAK weld rod.
Post-heated at 950°F for one (1)
hour |
Cavity and
weld ground down. |
Cavity face
polished. |
Now engraved
over welded area!
Design
change capability
(5th engineering change on this
tool)
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WELDING
GUIDELINES
Welding
of NAK55 should be performed employing
only NAK-W Welding Rods. NAK-W Welding
Rods are copper-coated for either TIG or
Heli-Arc welding. Employ only recognized,
safe shop welding practices.
- The
die or mold should be free of all oil,
rust, scale residue, or any other
potential contaminates before
attempting to weld.
- All
cracks and surface treatments should
be completely removed before
attempting to weld.
- Sharp
corners should be rounded to a minimum
radius of .120".
- To
repair a crack, remove sufficient
stock to eliminate the crack and
insure only sound material remains.
Dress the corners where stock was
removed to eliminate any square
corners by rounding to a minimum
radius of .120".
- Preheating
Prior to
making a welding repair, preheat the
piece to be repaired by slowly heating
in a furnace or with a gas burner to
between 600° and 750°F.
Heating from the bottom is recommended
if a gas burner is used.
Uniform temperatures within
the recommended range should be
maintained during the entire period of
time required to complete the repair.
Ideally,
the entire mold should be heated in a
furnace to achieve uniform
temperatures. This is easy to do for
small molds, but may not be practical,
or possible, for large molds.
Localized preheating is the only
option for large molds, and attention
must be paid to the following:
- Preheating
temperature must be achieved to at
least 2" away in all directions
from area to be welded.
- Use
an oxygen-propane gas burner with a
low flame temperature. Heat the
mold carefully and gradually,
maintaining a distance of 18"
between the flame and the mold
surface.
- Apply
a temperature choke or a surface
contact thermometer to accurately
measure the preheating temperature.
- Re-heat
as necessary during welding to
maintain the above 600°F
range.
- Use
DC normal polarity
- Use
lowest possible amperage for the job
- Use
backhand welding - weld away
- Use
smallest diameter rod possible
- Weld
small beads
- Peen
weld as necessary
- Upon
completion of welding, proceed
immediately to post-weld heating
procedure
- Post-Weld
Heating
It is
imperative that the following
procedure be carefully followed to
assure the welded section is
completely restored to a uniform
hardness:
The weld-repaired piece should be
heated to between 860°F-940°F
and held at this range for a minimum
of one (1) hour to re-age. This
re-aging process should be conducted
immediately after welding. Heating
with a furnace is highly recommended, however
a gas burner may be used as a last
resort. If a gas burner is used,
heating from the bottom is
recommended, however the entire welded
area, and as much as 2"
surrounding the weld, must be kept in
the post heat temperature range for a
minimum of one (1) hour. Cool
slowly to room temperature.
Note:
Post-weld heating should be performed
after every three layers of weld buildup
in order to alleviate welding stress and
avoid over-aging of adjacent parent
metal.
| Rod
diameter |
Electrode
diameter |
Current/Amps |
|
.0470" |
.0470" |
40~70 |
| .0630" |
.0630" |
70~150 |
| .0946" |
.0946" |
150~250 |
All
technical and engineering data and
suggested procedures, specifications and applications contained in this publication
are for general information only. Daido
Steel, International Mold Steel and/or
their distributors disclaim any and all
express or implied warranties of
merchantability, suitability for any
particular purpose or use, or freedom from
infringement of any patent, trademark or
copyright. NAK80® is a
registered trademark of International Mold
Steel, Inc. and Daido Steel Limited.
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International Mold Steel, Inc.