JPS5833303B2 - iron-nickel alloy - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a Ni47-53%-Fe alloy,
In particular, it relates to a soft magnetic metal material with a high squareness ratio (Br/B1o) and a low coercive force (Hc).

The 50% Ni to iron alloy is used as a toroidal-shaped magnetic core formed by a wound iron core in saturable reactors, magnetic amplifiers, and the like.

By the way, the 50% Ni-iron magnetic core used in magnetic amplifiers etc. has particularly high saturation magnetic flux density among its magnetic properties.
Moreover, it had the feature of a large squareness ratio (Br/B1o).

However, Br is the residual magnetic flux density, and Blo is the magnetic flux density in a 10 oersted magnetic field.

Conventional 50% Ni-Fe alloy production consists of Ni and F
After weighing a desired amount of e and melting it in a vacuum melting furnace, magnetic anisotropy is imparted by cold rolling and further magnetic heat treatment is performed.

However, with the conventional 50% Ni-Fe alloy, it is necessary to strictly control the magnetic heat treatment process, and if this is neglected, either B r / B 1o or Hc will deteriorate, reducing reliability and productivity. It became a problem.

The present invention was made in view of these points, and it
By containing AI as a subcomponent in the main component of i-Fe, a soft magnetic material with high Br/'B16° and low Hc without impairing workability, whose magnetic properties are not affected much by magnetic heat treatment conditions. It provides:

The present invention has Ni47-53%, A/! 1.15% or less (0
), Mn is 1.5% or less (does not contain O), and the balance is substantially Fe, and among the magnetic properties, B r /
B 10 is 0.97 or more, ESto is 14,0OOG
The above is an iron-nickel alloy characterized by an Hc of 0.150e or less.

Examples of the present invention will be described below.

An alloy containing Ni, Fe, Mn, and AA as shown in Table 1 is melted by vacuum melting, and cold rolled to a thickness of 0.1 m at a rolling reduction of 95% or more. Inner diameter 25
I made a rolled iron core with an outer diameter of 35 meters and a length of 10 meters.

These wound cores are heated to 1010°C, 1050°C, 1100°C.
Br/B1o, Blo, respectively, after magnetic annealing for 30 min (in H2) at °C.

Hc was measured.

The measurement results for Samples 1 to 8 are shown in Figure 1, a''h, respectively.

Sample 1 is a conventional Fe-Ni alloy that does not contain aluminum, and as is clear from Fig. 1a, B r /B 1°≧
In order to satisfy He≦0.15 (Oe) at 0.97, the heat treatment temperature must be within a narrow temperature range centered around 1050°C (approximately 20°C
smaller).

However, when 0.04% of l is added as in sample 2,
As is clear from Fig. 1, the heat treatment temperature to obtain the same properties was expanded to about 50°C, and samples 3 to 8, in which the amount of Al3 added was increased, were In addition, in a wider temperature range from around 1030°C to over 1100°C, Br/B1o≧0.97,
Hc≦o, 1s(Oe) is satisfied.

That is, the addition of Al allows for looser temperature control during heat treatment, which has the advantage of facilitating manufacturing and improving yield.

If Al exceeds 1.15%, cold working becomes extremely difficult and cracks occur, and as seen in sample 6, the BIO becomes less than 14.0 OOG, making it unusable.

Therefore, the maximum amount of A added is 1.15%.

Mn in this alloy composition is a desulfurizing agent that removes S mixed as an impurity in the alloy.

The presence of S in the Fe-Ni alloy deteriorates hot workability, so Mn is added to render it harmless as MnS. However, as the amount of Mn added increases, Hc increases. .5% or less is desirable.

Note that if the Ni content is 47% or less, the He content is large and the iron loss increases, making it difficult to use as a wound core for a magnetic amplifier or the like.

When the Ni content is 53% or more, 13to is low and the squareness ratio is poor.

The present invention has been described above, and according to the present invention, a stable 50% Ni-Fe alloy with a high squareness ratio and low coercive force is used.
Furthermore, since the heat treatment temperature can be varied over a wide range, the yield is improved and it is effective in terms of reliability and productivity.

[Brief explanation of the drawing]

FIG. 1 shows the characteristics of Br/B1o and He in the example in relation to the heat treatment temperature, and a=h shows the characteristics of samples 1 to 8, respectively.

Claims (1)

[Claims] lNi 47-53%, AAJ, 15% or less (not including 0), Mn 1.5% or less (not including 0), remainder substantially F
An alloy consisting of e, the magnetic property Br/BIO is 0.97
With the above, Blo is 14,0OOG or more and Hc is 0.15
An iron-nickel alloy characterized by being 0e or less.