SK282711B6 - Composite stratified material and its use for coins, chips and to kens - Google Patents

Abstract

Composite stratified material comprising a core layer of a ferritic chrome steel that is plated on both sides with a steel consisting of (mass %): chrome 16.0 to 18.0, nickel 10.0 to 12.0 and copper 3.5 to 4.5, as well as of selectably other elements, the rest being essentially iron, and its use for manufacturing coins, chips, tokens and related objects.

Description

The invention relates to the use of a multilayer metal material with a core layer which is clad on both sides with a steel layer for the production of coins, medals and tokens.

BACKGROUND OF THE INVENTION

JP 04066651 and US 27 75 520 disclose stainless chromium-nickel alloys as coin materials for monolayer coins comprising 17.8 wt% chromium, 12.8 wt% nickel and 3 wt% copper.

EP-A 0 343 701 discloses a multilayer metal material for the production of coins, which may, inter alia, comprise a core layer of ferritic chromium steel which is clad on both sides with a layer of austenitic steel of chromium and nickel.

Where it has been stressed in the past that the value of the curative coins corresponds to the nominal value of the coin, this requirement determines the choice of metal. Gold, silver and non-precious metals, as well as alloys, were used. In the course of industrialization since the mid-19th century, tiny coins were increasingly circulated, in which the material was chosen on the one hand in accordance with the possibilities of economical production and on the other hand according to the optical appearance.

Nickel and certain copper alloys were often used. Recently, the demand for cost-effective coins has been increasing. During this development, various types of stainless steels have already been processed into coins. In particular, ferritic X 6 Cr 17 (German material No. 1.4016) and austenitic X 5 CrNi 18 12 (German material No. 1.4303) are used.

Further expansion of stainless steels as coin material has been slowed by milling problems. Because of the hardness, which in practice is only about 140 to 160 HV30, an average of about 150 HV30 for the soft annealed condition, the embossed images were relatively flat but very abrasion resistant and the coins were resistant to corrosion for a long time, such as described in "Coinage Materials, XVII Mint Directors' Conference Madrid 1992".

Even the bluish tint of ferritic stainless steel, in particular, prevents equivalence of appearance with coin materials that are perceived rather than white, such as silver or nickel, or their alloys.

In contrast to mechanical coin checking devices used in the past, electrical conductivity is inductively measured inductively at different frequencies, i.e. at different distances from the outer surface, by means of conventional electronic coin checking devices in addition to diameter and thickness. In this way, it is possible to distinguish particularly well multilayer materials and to separate them from foreign coins and counterfeits.

This has proven to be another important criterion in the preparation of coin materials that material properties such as density, electrical conductivity and magnetic behavior must be set within a very narrow acceptable range.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a corrosion-resistant material which, due to the state of the art, is easier to stamp at the same time in a color visually perceived as white or silver and capable of being processed into coins.

SUMMARY OF THE INVENTION

The present invention is based on the use of a multilayer metal material consisting of a core layer of ferritic chromium steel which is clad on both sides with a steel layer, wherein the steel used for cladding the core layer contains, by weight, chromium 16.0-18.0 nickel 10.0 to 12.0 copper 3.5 to 4.5, the remainder being iron as well as production-related impurities, which additionally contains one or more of the following% by weight: manganese max. 1.5 silicon max. 0.4 carbon max. 0,02 nitrogen max. 0,02 sulfur max. 0.01 phosphorus max. 0,03 molybdenum max. 1.0 titanium max. 0.03 niobium max. 0.05 aluminum max. 0.1 cobalt max. 0,3 boron max 0,003 as a material for production of minted coins, medals and tokens.

In this case, it is preferred that the thickness of the clad layers is 10 to 30% of the total thickness of the multilayer composite.

Surprisingly, it has been found that the multi-layer material of this steel in the soft annealed state has the desired color tone perceived as white or silver, and its hardness can be kept well below 140 HV30 and, as a rule, even below 120 HV30.

These, on average, 20% lower hardness values compared to the prior art stainless steel for coin semi-finished products allow a much deeper and more plastic embossed image. Nevertheless, the abrasion resistance determined in the test on the control coins in the drum is comparable to the noble metal coins X 6 Cr 17 and X 5 CrNi 18 12 and about a factor of 3 higher than those of conventional copper-based materials such as CuΑ1 ₆ 2ί ₂ ·

Comparability with other noble materials has also been demonstrated in the test of resistance to oxide layer formation in an aggressive laboratory atmosphere, more than 10% NaCl solution and under the effect of artificial sweat.

The required certain distinction from other coins and counterfeits in today's coin checking devices is particularly certain with such a layered composite when, according to the invention, it has a core layer of ferritic chromium steel which is coated on both sides with a steel of this kind.

The invention is explained in more detail by way of example.

DETAILED DESCRIPTION OF THE INVENTION

Example

Copper-alloyed stainless steel having the composition (% by weight) was melted:

chrome 17.35 nickel 10.25 copper 3.65 manganese 0.67 silicon 0.30 carbon 0,014 nitrogen 0,015

sulfur 0.003 phosphorus 0.012 molybdenum 0.49 titanium <0.010 niobium 0.010 aluminum 0.0120 cobalt 0.001 boron 0.002, the remainder being iron as well as production-related impurities.

The steel was hot rolled first and then cold rolled to a 2.07 mm thick strip. Coin blanks having a diameter of 25.30 mm were pressed from this cold strip. These had the desired silver-white hue.

The diameter was 24.85 mm after engraving. The piece weight of these plates was 8.10 g, the density was 7.98 g / cm ³ . By soft annealing, the hardness of 117 HV30 could be adjusted without coarse grain formation, followed by easy stamping, which was determined when stamping control coins.

These coins were compared in a 24 hour experiment in a drum with coins made of materials such as normally stainless steel X 6 Cr 17 and X 5 CrNi 18 12, with weight loss of 0.1% for all three materials. Coins from a much more common CuAl ₆ Ni ₂ copper material, on the other hand, led to a triple value.

Even in the corrosion test in an aggressive laboratory atmosphere, 10% NaCl solution and under the effect of artificial sweat, the coin material according to the invention changed only slightly after three weeks.

The strips of this embodiment were clad on both sides on X 6 Cr 17 ferritic chromium steel, with a layer thickness of 20% each of the total thickness, resulting in some distinguishability from other coins and counterfeits in today's coin control apparatus.

A further feature of the present invention to be mentioned is that the coin material of the present invention is characterized by trouble-free recyclability using today's steel technology, not only when used as a separate component, but also when used as a component. composite along with ferritic chromium steel.

as material for the production of minted coins, medals and tokens.

Use according to claim 1, wherein the thickness of the clad layers is 10 to 30% of the total thickness of the multilayer material.

Use of Claim 1 or 2, wherein the core layer is of X 6 Cr 17 material.

End of document

Claims (1)

PATENT CLAIMS Use of a multilayer metal material consisting of a core layer of ferritic chromium steel which is clad on both sides with a steel layer, wherein the steel to be used for cladding the core layer contains in% by weight: chromium 16.0 to 18.0 nickel 10, 0 to 12.0 Copper 3.5 to 4.5, the remainder being iron as well as impurities imparted, which additionally contains one or more of the following components in% by weight: