Hard Magnetic alloys: Part One

Magnetically hard materials can be permanently magnetized by a strong magnetic field. Steel and special alloys, which contain various amounts of aluminum, nickel, cobalt, and copper, are used to make permanent magnets.

Magnet steels, now largely obsolete, included plain high-carbon (0.65 to 1%) steels or high-carbon (0.7 to 1%) compositions containing 3.5% chromium-chromium magnet steels; 0.5% chromium and 6% tungsten-tungsten magnet steel; or chromium, tungsten, and substantial cobalt (17 or 36%) – cobalt magnet steels.

They were largely replaced by ternary alloys of iron, cobalt, and molybdenum, or tungsten. Comol has 17% molybdenum, 12% cobalt, and 71% iron. Indalloy and Remalloy have similar compositions: about 20% molybdenum, 12% cobalt, and 68% iron. Chromindur has 28% chromium, 15% cobalt, and the remainder iron, with small amounts of other elements that give it improved strength and magnetic properties.

In contrast to Indalloy and Remalloy, which must be processed at temperatures as high as 1250°C, Chromindur can be cold-formed. Some cobalt magnet steels contain 1.5 to 3% chromium, 3 to 5% tungsten, and 0.50 to 0.80% carbon, with high cobalt. Alfer magnet alloys, first developed in Japan to save cobalt, were iron-aluminum alloys. MK alloy had 25% nickel, 12% aluminum, and the balance iron, close to the formula Fe2NiAl.

Currently, in accordance with international classification standards, hard magnetic materials can be divided into hard magnetic alloy materials, hard magnetic ceramic materials and bonded hard magnetic materials. The three categories of hard magnetic materials can be classified into the following subcategories:

1. Main hard magnetic materials:

2. Hard magnetic ceramic materials

Hard magnetic ceramic material (MOnFe2O3; M refers to Barium, Strontium and plumbum; while n can be any other element within the range of 4.5-6.5)

3. Bonded hard magnetic materials

Table 1: Common properties of main hard magnetic materials