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Performance Alloys®

 

 

...World Wide Distributor of Beryllium-Free Copper Alloys...
    Manufacturer of Standard & Custom Components

mold making components, molders, alloys

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mold making components, molders, alloys

INFORMATION ABOUT HARDNESS

Copper Alloys versus Tool Steel

There are a number of FACTS that need to be considered in understanding  the Hardness of Copper Alloys in comparison to Tool Steels as well as other metal alloys.

Precipitation Hardening

Typically, Copper Alloys are "age" or precipitation hardening alloys. This means that when the alloy is manufactured, a time and temperature controlled process is performed on the product that yields the "initial hardness" of the product.

An Increase in Hardness over the initial Hardness

Continued heating of the Copper Alloy to temperatures, in combination with the passage of time, will  further influence the hardness of copper alloys. Copper alloys that are heated to temperatures below the "final" aging temperature used during making the product, will normally have a continued "aging" effect which actually raises the hardness level and adds toughness.

"Overaging" & Annealing

Heating a copper alloy to temperatures above the "final age" used at manufacture will cause the material to "overage", which has an annealing or softening effect. Heating Copper Alloys to their "critical" temperature, generally about 1600 Degrees F, followed by a rapid quench in water will normally "anneal" the copper alloy completely.

The Published Hardness Values of MoldStar Products

For convenience as well as what industry is accustomed too, we publish the Hardness Values in Rockwell "C". These published values are actually the results of testing either on the Rockwell "B" or Brinell (3000kg.) scales, then using Conversion data based on ASTM140 and/or ASM Vol. 11 Reference Tables. This is also because the Rockwell"C" test is known to be the least accurate in ranges less than 40 combined with "C" testing being the most applicable to Tool Steels, and not Copper Alloys.

Not a Factor

It is important to understand that it is the actual temperature that the alloy reaches, rather than the "environmental" temperature that influences the hardness. "Environmental" temperatures have little influence, if any.

 

 

Thermal 
Conductivity at 680 F
Btu/(ft•hr•°F)

Thermal 
Diffusivity
at 680 F
ft2/hr

Brinell Hardness
3,000 kg

Density
lbs/cu.in.

MoldStar® 150 150 2.32 210 (94R/B) .315
MoldStar® 90 90 1.76 292 (30R/C) .320
MoldStar® 18 36 .97 192 (92R/B) .269
MoldStar® 21 25 .62 286 (29R/C) .260
MoldStar® 22 25 .62 308 (32R/C)

.255

Aluminum QC7 80 2.44 167 (500kg) .101
Beryllium Copper-0.5%  (C17510) 125 2.32

157-210 (500kg)

.319
Beryllium Copper-2.0%  (C17200) 60 1.16 300-380 .297
Tool Steel P20 20 0.39 265-345 .284
Tool Steel H13 17 0.31 350-530 .284
Stainless Steel 7 0.16 150-190 .284

 

Click here for HARDNESS CONVERSION TABLE

Click here for More Information on ELEVATED TEMPERATURE EXPOSURE

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Disclaimer

While the information contained is deemed reliable, no warranties are expressed or implied. For specific information regarding an application please call 1-800-272-3031 or e-mail us at sales@moldstar.com


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