NAK55 Steel

NAK55 is a precipitation, or age-hardened mold steel with a through hardness of approximately 40 HRc. NAK55 is ideal for use in plastic and rubber molds and other applications where impact resistance is not critical. It is a super clean, Vacuum-Arc Remelted steel with uniform grain structure, uniform hardness and excellent dimensional stability.

  • 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
NAK55 Steel

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.

NAK55 Chart

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.

TYPICAL CHEMISTRY

  • Carbon 0.15%
  • Copper 1.00%
  • Sulfur 0.10%
  • Nickel 3.00%
  • Silicon 0.30%
  • Aluminum 1.00%
  • Manganese 1.50%
TYPICAL CHEMISTRY

  • 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

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
Sleeve Mold

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.
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

Thin Sections

by 50% when compared with softer steels.

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.

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.

Milling

High-speed steel cutters give excellent results and very smooth machined surfaces. The best results are obtained with cutter geometries incorporating a positive rake angle of 15°–20° and a relief angle of less than 10°.

Carbide cutting tools (P40 grade) will yield excellent results if the effective, positive rake angle of the insert and holder is approximately 8°-15°, and the relief angle is less than 10°. When a negative rake carbide is used, inserting grades with greater toughness than P40 gives better results. In general, a positive rake configuration is superior to a negative rake configuration for milling NAK55.

Note: It is important that the inserts have a concave face with a sharp chip breaking
edge. TiAlN coatings work well.

NAK55 Cutters

Grinding

NAK55 grinds easily. It is recommended that it be ground wet

Drilling

NAK55 drills easily. The cutting speed should be lowered as the drill diameter increases. A smaller than standard twist angle and shorter length will reduce the danger of broken tools. Peck cycles are recommended, as NAK55 is a chip packing material.

Tapping

NAK55 is a 40 HRc steel. The following is recommended to facilitate tapping:

  1. Use a new, sharp, premium grade of tap, TiN coated and spiral pointed.
  2. 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.

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.

General
  1. The die or mold should be free of all oil, rust, scale residue, or any other potential
    contaminates before attempting to weld.
  2. All cracks and surface treatments should be completely removed before attempting
    to weld.
  3. Sharp corners should be rounded to a minimum radius of .120″
  4. 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:

  1. Preheating temperature must be achieved to at least 2″ away in all directions from area to be welded.
  2. 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.
  3. Apply a temperature choke or a surface contact thermometer to accurately measure the preheating temperature.
  4. Re-heat as necessary during welding to maintain the above 600°F range.
Technique
  1. Use DC normal polarity
  2. Use lowest possible amperage for the job
  3. Use backhand welding – weld away
  4. Use smallest diameter rod possible
  5. Weld small beads
  6. Peen weld as necessary
  7. 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.

Conditions
Rod diameter Electrode diameter Current/Amps
.0310″ .0310″ 40~70
.0630″ .0630″ 70~150
.0946″ .0946″ 150~250

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