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M. Tool Steels Weld Data. Moly High Speed Tool Steels.

Advanced TIP TIG Welding
TIP TIG Welding is always better quality than TIG and 100 to 500% faster with superior quality than TIG - MIG - FCAW.

 
 
   




(M) Moly High Speed
Tool Steels. M1- M46.



M Steels. ASTM A600 UNS T 11301 TO 46
Lower cost than TUNGSTEN High Speed tool steels
M Rockwell range 60 - 70 HRC
M Steels low toughness
M Steels Deep Hardening with minimum distortion
M Steels High Red Hardness for high speed cutting
M Steels low impact strength and notch sensitive
M Steels Machinability 40 to 50% of (W) steels
M Steels Harden temperature 2150 - 2225F (2200F) (1204C)
M Steels Anneal 1600F 871 C
M1-M2-M3-M4-M6-M7-M10-M30-M33-M34-M36-M41-44
Temper all these steels at 1000 - 1100 F
M42 - 43 - 46 - 47 Temper 975 - 1050 F ( 525 - 565C)



WELDING. TIG is ideal process.

Weld preheat / postheat and interpass temp 950 - 1050 F
Welding don't exceed 1000 (537C) Interpass temp.
Welding small repairs preheat to 300F (150C)
Welding type M1 filler for "edge cutting tools HRC 60
Welding type M36 filler provides both hardness and toughness.
Weld post heat at draw tempering temp
After weld cool to 400F (200C) then temper 1000F per hr/inch
If hard surface not required consider E312 - E9018 or E11018
Use lowest amps, short arc length short bead, air cool

Consumables
Eureka 1216
UTP A69
MG 700
Eutectic 5 - 6 HSS
Allstate HSS
Weldmold 966
Certanium 211


      M1


      Rockwell Hardness Range
      HRC

      France Z85DCWV
      UK BM1
      Germany 1.3346

      C 0.88 max
      Cr 4.0
      Mo 9.2
      W 2.1
      V 1.3
      Hardness 60-65 hrc

      M2

      France - Z85WDCV
      Germany DIN 1.3346
      UK- BM2
      Japan SKH9
      Sweden 2722
      Hardness 60-65 hrc

      M3 Class 1Germany 1.3342
      France Z90WDCV
      M3 Class 2

      Japan SKH 52-53
      France Z120WDCV
      Germany 1.3344

      C 1.2
      Cr 4.5
      Mo 6.5
      W 6.7
      V 3.7

       

 


Brittleness:The ease at which the weld or metal will break or crack without appreciable deformation. When a metal gets harder it becomes more brittle. Preheat, inter-pass temp controls and post heat all are designed to reduce the potential for brittleness.



GENERAL CONSIDERATIONS FOR WELDING TOOL STEELS:
  • Ensure base metals are clean avoid tool marks.

  • Remove all sharp edges and tight corners in weld areas.

  • Use Dye pen to check for surface cracks.

  • Majority of tool steels will be weld repaired in the Hardened condition

    A hardness test will determine if steel is hard or annealed.

      To weld massive tool parts with large amounts of weld "anneal first"

      • Steels in the annealed condition metal can be removed with an oxy acet/fuel torch.

      • Steels in the hardened condition use grinding/carbon arc rather than oxy fuel or plasma to remove metal.

      • Discoloration glazing of steel while grinding indicates damage.

      • Preheating before grinding or oxy cutting prevents damage

      • ALL TOOL STEELS MUST BE PRE HEATED BEFORE WELDING.

      • Pre heat prevents cracking, distortion stresses and shrinking.

      • Annealed or hardened steels the steel must be pre heated.

      • If base metal hardened yet not tempered anneal temper first.

      • Preheat hardened steels don't exceed temper temperature.

      • Hardened steels if temper unknown >25mm use 300 to 400F preheat.

      • Annealed steels, preheat at maximum pre heat recommendation.



        If steels are quenched and tempered to match tool steel properties, the
        electrode selection and heat treatment recommendations critical.


      Hardness:The resistance of the metal or the weld to penetration. Hardness is related to the strength of the metal. A good way to test the effectiveness of the weld procedure after the weld and heat treatment is complete, test the
      hardness of weld and the base metal surrounding the weld.



      WELDING TOOL STEELS:

      With all tool steels the first weld consideration should be does the weld require the same hardness as the base.

      Is the metal to be welded in the annealed or hardened condition.

      Use lowest possible weld current, (smallest electrode diamaeter)

      No weaves use stringer beads.

      Peen each weld after completion,

      Ensure parts are clean.

      Avoid excess joint restraints.


      Ductility:
      The amount that a metal or weld will deform without breaking. Measured on welds by the % of elongation in a 2 inch 51 mm test piece. An E71T-1 flux cored electrode should result in a minimum of 20% elongation. An E70S--6 MIG weld should produce approx 22%.

      TOOL STEELS AND SMAW ELECTRODE DATA.

      SMAW Electrodes most versatile weld process for tool steels.

      Electrode 3/32 2.5mm amperage 50 to 80 amps DCSP

      Electrode 1/8 3.2.5mm amperage 70 to 115 amps DCSP

      Electrode 5/32 4mm amperage 100 to 150 amps DCSP

      Most tool and die SMAW electrodes use AC-DC Positive.

      Flux cored good for welds which benefit from high weld depositions.

      GTAW, TIG good for small precise welds.

      • Don't use oxy fuel to weld.
      • Ask. Is the weld for joining or does the weld require a
        specific mechanical property ( hardness or machinability)?
      • Use smallest electrodes possible.
      • Peen each weld bead.
      • Avoid arc strikes.
      • Consider run on plates.
      • Avoid craters.
      • Try to use stringers rather than weaves.
      • If possible for the firsts pass (butter pass) consider the E312 electrode except for water hardened steels.
      • For water hardened steels use E11018 instead of E312 for butter pass.
      • When using E312 use only one layer to avoid shrink cracks.
      • If excessive hardness not required in weld use E312 then an E9018-6 or E11018-

         

      • FOR LARGE COMPONENTS THAT REQUIRE BOTH STRENGTH AND HARDNESS
      • First use E312 followed by E11018-G followed by the tool steel.
      • Try to provide a minimum of 3 layers of tool steel weld to a minimum depth of 3mm.
      • If the repairs are on annealed steels remember the electrode selected must respond to heat treatment after weld.
      • The weld hardness will depend on the preheat/interpass temperatures plus weld procedures.
      • The weld hardness will depend on the chemistry of the selected electrode along with the base metal dilution.
      • The weld hardness will depend on the post heat treatment and cooling rate time.
      • To join components, and prevent cracks preheat and deposit ductile electrodes.
      • To prevent cracks, limit carbon pickup in first pass, (use low current narrow stringer beads) also if possible stress relieve.
      • To minimize the potential for underbead cracks, preheat and limit heat input during the
        weld.
      • To prevent underbead cracks provide uniform cooling, with immediate stress relief.
      • Fast heating or concentrated heating can cause cracks.


        Toughness:
        The ability of the metal or weld sample at a predetermined temperature to withstand a shock.The test for toughness measures the impact of a pendulum
        on a notched specimen. You may see that the required impact properties for the metal
        or weld are 20ft-lbf @ -20 F (27 j @ -29C)
        reheat at maximum pre heat recommendation.


      TOOL STEELS, PRE HEAT BASICS


      M-T-H-D2 Pre heat 900F (482C)

      • All other tool steels preheat at 350F (176C)
      • Preheat "slowly" The higher the alloy content the slower the preheat.
      • Preheat, the more complex the part shape the slower the preheat.
      • Preheat. High alloy steels avoid oxy fuel use ovens or electric.
      • Preheat. Use insulation around part to retain heat.
      • Preheat. Maintain preheat during welds, don't exceed preheat temp.

       

      The "yield and tensile strength". The stress that can be applied to a base metal or weld without "permanent deformation" of the metal. The "tensile strength". The ultimate tensile strength, the maximum tensile strength that the metal or weld can with stand before "failure



      TOOL STEELS AND PRACTICES TO AVOID CRACKING.

      • Annealed steels preheat, for the weld stress relieve, machine harden temper.
      • Hardened steels, pre heat, weld temper then grind finish.

         

      • DECARBURIZATION = LOSS OF CARBON CAUSES SURFACE SOFTENING.
      • Coating surface with Borax prevents decarburization.


        TEMPERING
        FOLLOW AFTER QUENCHING TO REDUCE HARDENING STRESSES.

      • High temper provides more toughness with less hardness.
      • Tempering at low end provides max hardness (max wear) with less toughness.
      • Tempering above Temper range reduces toughness.
      • For large repairs on hardened steels use the electrode temper requirements.
      • Welding on hardened steels not tempered cracking will occur.



        Brittleness: The ease at which the weld or metal will break or crack without appreciable deformation. When a metal gets harder it becomes more brittle. Preheat, inter-pass temp controls and post heat all are designed to reduce the potential for brittleness.




        STRESS RELIEVING (SR) BASIC GUIDELINES:
        • STRESS RELIEF - CONTROLLED HEATING & COOLING TO REDUCE STRESS.
        • STRESS RELIEF MACHINED PARTS FOR DIMENSIONAL STABILITY.
        • STRESS RELIEF SLOW HEATING AND COOLING REQUIRED
        • CONFIRM WITH CODE SPECIFICAIONS FOR STRESS RELIEF REQUIREMENTS.

         

        Fatigue: The ability of a metal or weld to withstand repeated loads. Fatigue failures occur at stress levels less than the metal or weld yield strength. Some things that can influence fatigue failure:

        • Excess weld profiles.
        • Welds with undercut.
        • FCAW or SMAW slag inclusions.
        • Lack of weld penetration.
        • Excess weld heat, typically from multi-pass welds without inter-pass temp controls.
        • Items to a part that adds restraint while welding.
        • Items added to a part that can concentrate stresses in a specific location.
        • Incorrect selection of filler metal, weld too weak or weld too strong.

           

            STRESS RELIEVING

          TYPICAL STRESS RELIEF SOAK TIME
          ONE HOUR PER INCH OF THICKNESS

          SR HEAT & COOL RATE PER HOUR 400oF 204oC DIVIDE THICKER PART
          PARTS OF DIFFERENT THICKNESSES
          SR MAX TEMP DIFFERENCE 75oF 24oC
          STRESS RELIEF CARBON STEELS 1100oF 593oC
          TO 1250oF 677oC
          STRESS RELIEF CARBON 0.5% Mo
          1100oF 593oC TO 1250oF 677oC
          SR 1% CHROME 0.5% Mo
          1150oF 621oC TO 1325oF 718oC
          SR 1.25 % CHROME 0.5% Mo
          1150oF 621oC TO 1325oF 718oC
          SR 2% CHROME 0.5% Mo
          1150oF 621oC TO 1325oF 718oC
          SR 2.25 % CHROME 1% Mo
          1200oF 649oC TO 1375oF 746oC
          SR 5% CHROME 0.5% Mo
          1200oF 649oC TO 1375oF 746oC
          SR 7% CHROME 0.5% Mo
          1300oF 704oC TO 1400oF 760oC
          SR 9% CHROME 1% Mo
          1300oF 704oC TO 1400oF 760oC
          SR 12% CHROME 410 STEEL
          1550oF 843oC TO 1600oF 871oC
          SR 16% CHROME 430 STEEL
          1400oF 760oC TO 1500oF 815oC
          SR 9% NICKEL
          1025oF 552oC TO 1085oF 585oC
          FOR 300 SERIES STAINLESS SR WILL
          RESULT IN CARBIDE PRECIPITATION
          WITH LOW CARBON 300 SERIES
          MAX SR 1050oF 566oC
          SR 400 SERIES CLAD STAINLESS
          1100oF 593oC TO 1350oF 732oC
          SR CLAD MONEL INCONEL Cu NICKEL
          1150oF 621oC TO 1200oF 649oC
          STRESS RELIEF MAGNESIUM AZ31B 0
          500oF 260oC 15 MIN
          STRESS RELIEF MAGNESIUM AZ31B
          H24 300oF 149oC 60 MIN

          HK31A H24 550oF 288oC 30 MIN

          HM21A T8-T81 700oF 371oC 30 MIN

          MAGNESIUM WITH MORE THAN 1.5%
          ALUMINUM STRESS RELIEF
          MAGNESIUM CAST ALLOYS AM100A
          500oF 260oC 60 MIN
          AZ-63A 81A 91C & 92A
          500oF 260oC 60 MIN
           
            
           


          If steels are quenched and tempered to match properties electrode
          selection and heat treatment recommendations critical.



          HARDNESS CONVERSION FOR CARBON AND LOW ALLOY STEELS.
          1000 psi = ksi x 6.894 = MPa

          Steel 0.15 Carbon Tensile 60- 65 ksi 413 448 MPa
          Hardness Br 132

          HRC 43 Br 400 Tensile 201 ksi 1385 MPa
          HRC 44 Br 409 Tensile 208 ksi 1434 MPa
          Steel 0.3 Carbon Tensile 85 ksi 568 MPa
          Hardness Br 172
          HRC 45 Br 421 Tensile 215 ksi 1482 MPa
          HRC 46 Br 432 Tensile 222 ksi 1530 MPa
          Steel 0.5 Carbon Tensile 100 ksi 689 MPa
          Hardness Br 219
          HRC 47 Br 443 Tensile 229 ksi 1578 MPa
          HRC 48 Br 455 Tensile 237 ksi 1634 MPa
          HRC 20 Br 228 Tensile 111 ksi 765 MPa
          HRC 21 Br 233 Tensile 113 ksi 779 MPa
          HRC 50 Br 481 Tensile 255 ksi 1758 MPa
          HRC 52 Br 512 Tensile 273 ksi 1882 MPa
          HRC 23 Br 243 Tensile 117 ksi 806 MPa
          HRC 24 Br 247 Tensile 120 ksi 827 MPa
          HRC 54 Br 543 Tensile 292 ksi 2013 MPa
          HRC 56 Br 577 Tensile 313 ksi 2158 MPa
          HRC 25 Br 253 Tensile 122 ksi 841 MPa
          HRC 26 Br 258 Tensile 125 ksi 861 MPa
          HRC 58 Br 615
          HRC 27 Br 264 Tensile 128 ksi 882 MPa
          HRC 28 Br 271 Tensile 132 ksi 910 MPa
          HRC 29 Br 279 Tensile 132 ksi 910 MPa
          HRC 30 Br 286 Tensile 138 ksi 951 MPa
          HRC 31 Br 294 Tensile 142 ksi 979 MPa
          HRC 32 Br 301 Tensile 145 ksi 999 MPa
          HRC 33 Br 311 Tensile 149 ksi 1027 MPa
          HRC 34 Br 319 Tensile 153 ksi 1054 MPa
          HRC 35 Br 327 Tensile 157 ksi 1082 MPa
          HRC 36 Br 336 Tensile 162 ksi 1116 MPa

           

          HRC 37 Br 344 Tensile 167 ksi 1151 MPa
          HRC 38 Br 353 Tensile 171 ksi 1179 MPa
          HRC 39 Br 362 Tensile 176 ksi 1213 MPa
          HRC 40 Br 371 Tensile 181 ksi 1247 MPa
           
          HRC 41 Br 381 Tensile 188 ksi 1296 MPa
          HRC 42 Br 390 Tensile 194 ksi 1337 MPa
           

           

           


          • DECARBURIZATION = LOSS OF CARBON CAUSES SURFACE SOFTENING.
          • Coating surface with Borax prevents decarburization.

          • ANNEAL HEAT ABOVE CRITICAL TEMP THEN COOL 50F (10C) PER HR TO TEMPER.

          • STRESS RELIEVE BELOW CRITICAL TEMP. TYPICAL 1100-1300F (700C) WITH SLOW COOL. Don't stress relieve a weld on hardened steel.

          • TEMPERING FOLLOW AFTER QUENCHING TO REDUCE HARDENING STRESSES.
          • High temper provides more toughness with less hardness.
          • Tempering at low end provides max hardness (max wear) with less toughness.
          • Tempering above Temper range reduces toughness.
          • With hardened steel let steel cool to 150F (65c) then temper.
          • For large repairs on hardened steels use the electrode temper requirements.
          • Welding on hardened steels not tempered cracking will occur.