EP0086507A2 - Method of manufacturing coded coins - Google Patents

Abstract

Small continuous holes are punched at equal intervals in a strip of mint metal, wire portions made of ferromagnetic material are riveted into these holes, and finally coin blanks are punched out of the strip. The metal strip can consist of non-magnetic material or of a laminated material with a ferromagnetic layer included. In this way, coins and stamps can be equipped with one or more exactly arranged coding points which can be used in appropriately designed coin testers, in addition to other test criteria, in order to differentiate low-value foreign coins or counterfeits. The imitation of such a coding would be possible only at an outlay exceeding the face value of the coin, and there can therefore can no longer be any incitement to deception.

Description

The invention relates to a method for producing coins or tokens which have a coding made of ferromagnetic material particles in non-magnetic metallic materials.

Coding coins is intended to improve their machine security. The increase in the price of all services has resulted in goods and service transactions being increasingly carried out using automatic machines, with the value of individual transactions constantly increasing at the same time. With increasing value of the machines stores the one hand, the incentive grows alsifikate to the vending machine fraud by _F, on the other hand, the demand for better security machines of the coins.

The efforts made so far to limit the fraud of the machine by tighter acceptance tolerances of the coin validators or by utilizing additional properties of the coins by a refined test facility have not yet led to resounding success. As experience has shown, it has always been possible to produce corresponding false certificates that cannot be distinguished from the applicable coins even under stricter test conditions. When calling for better Vending machine security must also take into account that cross-border passenger traffic has increased significantly in recent years and that vending machine fraud is also carried out to a considerable extent with inferior coins in foreign currencies.

Therefore, considerations have already been made to produce magnetically and thermoelectrically testable coins from different metals, magnetic or magnetizable metal particles to be embedded, inter alia, in non-magnetic coin metal (DE-OS 26 44 018). These are a large number of proposals without specific information about what a technical implementation could look like. Almost all conceivable connection and _. Processing techniques listed, but not a specific method that would meet the requirements of coin production and the economically viable options of decoding.

With regard to coin production, it must be taken into account that this is a decidedly mass production, with quantities of 1 million per day or even more being expected. In addition, certain specifications of coin production must be observed, such as that coin blanks must be punched out of rolled strip material, knurled and soft-annealed before being minted. There are also a number of work steps for surface treatment.

With regard to the decoding, the introduced material particles or particles made of ferromagnetic materials must have a certain size in order to arrive at usable signals with an economically justifiable test effort. It is also readily apparent that the coding must remain reliable throughout the life of the coins, i.e. over periods of several - decades.

Taking all of these aspects into account, it should be noted that DE-OS 26 44 018 does not provide a sufficiently specific teaching on technical action, that the person skilled in the art will find the basic idea of a magnetically testable coin here, but not information, such as just one of those there mentioned variants could be realized with success.

This gives rise to the task of specifying measures as to how the process mentioned at the outset can be carried out technically and economically. We are looking for a process that corresponds to the particularities of coin production, with which small ferromagnetic material particles can be permanently and invisibly arranged and fastened in a non-magnetic coin blank that are suitable for conveying dual information. It should also be noted that in order to obtain usable signals, the serromagnetic material particles must not be less than certain minimum sizes - and that neither the production process nor the test process may change the properties of the base material and the coding particles.

To solve this problem, it is proposed to punch small through holes in a band made of non-magnetic coin metal at equidistant intervals, to rivet wire sections made of ferromagnetic material into these holes and finally to punch out coin blanks from the band.

All manufacturing steps, including the production of wire sections, are expediently carried out in a coin punching device using a follow-on tool. The diameter of the holes should not be less than the thickness of the tape. In this way, one or more ferromagnetic particles can be introduced into the coin blanks. To rationalize the manufacturing process

driving it is advantageous if a punching device with a multiple follow-up tool is used. In a further embodiment of the inventive concept, it is provided that a strip of non-magnetic coin metal and the required number of wires made of ferromagnetic material are fed to the punching device in cycles. An alloy with essentially 75% copper and 25% nickel is preferably used for the strips, while the wires consist essentially of nickel.

A special development of the method is that the wire in the small holes punched in the strip introduced from the coin metal and thereafter only sections are separated and riveted and that finally the rahtabschnitten with _D regions provided are punched out of the band as coin blanks.

The invention proposes a method which is suitable for the large-scale mass production of coded coin blanks. The process can, of course, with the precision to perform, the more closely for setting acceptance tolerances in the _D ecodiereinrichtungen required. Finally, the process has the advantage that similar coins cannot be produced in any other way, and that the process for producing falsified products is comparatively complex and therefore uninteresting.

In order to produce different coding patterns, the arrangement at a different point from the center of the coin as a variable size is available for single-point coding Disposal; while with a two- or multi-point coding, in addition to the number of coding points, their arrangement on different radii and the different angular position to one another can be used. For coins made of the same basic material and the same external dimensions, there are therefore enough possible variations so that, even internationally, sufficiently large distances can always be maintained between two adjacent codes.

In conventional coin production, after stamping out, the edge of the coin is generally compressed by a knurling device, followed by soft annealing of the coin blanks in preparation for minting. In the case of coin blanks which are produced by the method according to the invention, this annealing can be used and controlled in such a way that not only is the low hardness required for the embossing achieved, but also, if necessary, diffusion between the base material and the riveted material made of ferromagnetic material, which further improves their integration into the base material.

Furthermore, it is proposed to use a layer material known per se in the method for coding coins as a band for coin production, which in addition to layers made of non-magnetic material has at least one continuous layer made of ferromagnetic material. A three-layer material is expediently used in which the inner core layer consists of ferromagnetic material. Furthermore, it may be advantageous to use a three-layered material in which the two outer cover layers of ferromagnetic ^- consist material.

In this way, the advantages of coding by riveting wire sections are combined with the advantages of the layered material and it is now possible - apart from the usual testing for dimensions and weight the coins - two further properties, each of which can be checked individually and in particular in the combination are very difficult to imitate, to distinguish the coins from false certificates.

Surprisingly, it has been found that the ferromagnetic layers of the tape do not interfere to the extent to be feared with the signals generated by the ferromagnetic coding particles and that despite the influence of the ferromagnetic layer on the test result during decoding, signals still useful for evaluation are obtained will.

Coins of this type have the further advantage that, in those machines which are not yet set to check the coding, they have at least the machine security achieved with the layer material. Further details can be found in German patents 15 74 275, 17 58 594, 17 74 498 and 17 83 169.

With the last proposed coins, depending on the equipment of the coin validator, i.e. Depending on the requirements for machine safety, the laminate property or the coding or both properties, use them for testing.

The attached photo shows an enlarged micrograph of a vertical section through a coin coded according to the invention, the darker areas on the left and right edge of the picture belonging to the non-magnetic coin metal, while the lighter area in the center of the picture shows the riveted ferromagnetic material. It can be clearly seen that the latter is seamlessly embedded in the coin metal and that the embossing on the top of the micrograph is perfectly formed in the transition area.

Claims (12)

1. A process for the production of coins or tokens which have a coding made of ferromagnetic material particles in non-magnetic metallic materials, characterized in that small continuous holes punched into equidistant intervals in a strip of non-magnetic coin metal, wire sections of ferromagnetic material riveted into these holes and finally coin blanks are punched out of the tape. 2. The method according to claim 1, characterized in that all manufacturing steps including the production of wire sections are carried out by means of a follow-up tool in a coin punching device. 3. The method according to claim 1 or 2, characterized in that the diameter of the holes is not less than the thickness of the band. 4. The method according to any one of claims 1 to 3, characterized in that more than one ferromagnetic particle is introduced into the coin blanks. 5. The method according to any one of claims 1 to 4, characterized in that a rigid device with a multiple follow-up tool is used. 6. The method according to any one of claims 1 to 5, characterized in that a band of non-magnetic coin metal and the required number of wires made of ferromagnetic material of the punching device are fed in cycles. 7. The method according to any one of claims 1 to 6, characterized in that strips made of an alloy with essentially 75% copper and 25% nickel and essentially nickel wires are used. 8. A method according to any one of claims 1 to 7, characterized in that the wire in the small punched holes introduced from the coin metal in the strip and only then separated sections and riveted and that finally are with _D rahtabschnitten regions provided the tape as coin blanks punched out . 9. The method according to any one of claims 1 to 8, characterized in that the coin blanks are soft annealed after the Räncieln in a manner known per se, the soft annealing being controlled such that a diffusion between the base material and the riveted material made of ferromagnetic material is achieved. 10. The method according to any one of claims 1 to 9, characterized in that a strip material known per se for coin production is used as the strip which, in addition to layers made of non-magnetic material, has at least one continuous layer made of ferromagnetic material. 11. The method according to claim 9, characterized in that with a three-layer material, the inner core layer consists of ferromagnetic material. 12. The method according to claim 9, characterized in that with a three-layer material, the two outer cover layers consist of ferromagnetic material.

Images