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Ferritan Alloys Synonyms:
Euro-Alliages, Ferritan, Ferritan C, Ferritan CM, Ferritan TS, Ferritan IN, Ferritan TE-1000, Ferritan lapping- Kwik lap, tool steel sintered titanium carbide alloy, machinable carbide, Ferritan tool, monoblock product, high-speed steel/ titanium carbide matrix, chrome tool steel/ titanium carbide matrix, alloy tool steel/ titanium carbide matrix, stainless steel/ titanium carbide matrix, nickel-chrome/ titanium carbide matrix,
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Ferritan Alloys General Designation:
Chemical Name: Titanium carbide + Chromium - Molybdenum- Carbon- Iron Alloy, & Titanium metal matrix composite
Chemical Formula: TiC + Cr/Mo/C/Fe
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Ferritan Alloys Competitors Old Trade Name:
Ferro-Tic®
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Ferritan Alloys General Description:
A machineable and hardenable alloy/steel bonded titanium carbide. The ultra-hard, rounded titanium carbide grains are uniformly distributed throughout a hardenable steel alloy matrix. Fabrication in the annealed state is accomplished with ordinary tools and equipment, followed by conventional heat treatment to obtain maximum hardness.
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Ferritan Alloys Typical Matrix Alloy Types Available:
Medium alloy tool steel, high chrome tool steel, hot work tool steel, impact resistant tool steel, martensitic stainless, maraging steel, age hardenable martensitic SS, age hardenable nickel base and age hardenable nickel-iron
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Ferritan Alloys Metallic Powder Mixture:
TiC + Cr + Mo + Fe (Carbonyl)
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Major Advantages of Ferritan:
a) A high level of hardness :
The titanium carbide used to manufacture Ferritan is the hardest industrial material after diamond and boron nitride.
b) Resistance to extreme conditions:
Due to its structure and its advanced mechanical characteristics, Ferritan can meet all your expectations in terms of resistance to wear, abrasion, corrosion and temperatures.
c) Lifespan :
The production output that can be achieved using a Ferritan tool between sharpening it is 10 to 30 times higher than for a conventional steel tool.
d) Machinability :
Ferritan can be machined in an annealed state using any conventional method (turning, milling, sawing, grinding, drilling, tapping, etc.). A suitable heat treatment enables the desired characteristics to be obtained.
e) Dimensional stability :
When undergoing hardening heat treatment, Ferritan experiences practically no change in its dimensions.
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Ferritan Alloys Standard Physical Dimension List:
Rectangular flat, Centerless ground rod, Lathe finished rounds, Rectangular flat (milled surface), Larger rectangles, and Larger slender rounds
- Standard Ferritan Grades Available:
This is a table of characteristic values for the various grades
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Ferritan Grades
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TiC% Vol |
Density |
HRC Annealed state |
HRC Treated state |
| C |
45 |
6,60 |
44/46 |
68/70 |
| CM |
45 |
6,45 |
46/48 |
67/69 |
| IN |
45 |
6,50 |
48/50 |
66/68 |
| TS |
40 |
6,80 |
46/48 |
62/64 |
| TE 1000 |
35 |
7,00 |
43/45 |
49/51 |
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Ferritan Alloys Typical Applications:
For high-production tooling, highly wear resistant parts, resistance to environmental attack, high temperatures and severe corrosion, and for additional toughness.
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Ferritan Alloys Packaging Options:
Boxes, drums or to customer specification
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Ferritan Alloys TSCA Inventory Status:
Listed. For further information please call the U.S. Environmental Protection Agency at +1.202.554.1404
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Ferritan Alloys to SARA Section 313: (Chromium - CAS No. 7440-47-3)
We are required to notify you of the presence of this material in greater than minimus quantities under the Emergency Planning and Community Right to Know Act of 1986.
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Ferro-Tic® Alloys CERCLA Status:
Unknown
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Chromium - (CAS No. 7440-47-3) Safety Review by The CDC and NIOSH:
Please visit this NIOSH Safety Card Outside Link
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