DE9114313U1 - Coin acceptor - Google Patents

Description

PATENT ATTORNEYS

DR.-ING. H. !" ^T FGENDANK 1-1973)

HAUCK, GRAALFS, WEHNERT, DOPING, BEINES, SIEMONS HAMBURG - MUNICH - DÜSSELDORF

36 494-19

PATENT AND LAWYER, NEUER WALL 41, 2000 HAMBURG 36 EDO GRAALFS, Dipl.-Ing.

NORBERT SIEMONS, Dr. Dipl.-Ing. HEIDI REICHERT, Attorney-at-Law Neuer Wall 41, 2000 Hamburg 36

National Rejectors, Inc. GmbH Phone (040) 36 67 55, Fax 49-40-364039

To FrUChthof Telex 2&Pgr;769 inpat d

HANS HAUCK, Dipl.-Ing.

2150 Buxtehude werner wehnert, Dipi.-ing.

Mozartstrasse 23, 8000 Munich 2 Telephone (089) 53 92 36, Fax 49-89-531239 Telex 5216553 pamu d

WOLFGANG DÖRING, Dr.-Ing. ULRICH BEINES, Dr. rer. nat., Dipl.-Chem. Mörikestraße 18, 4000 Düsseldorf 30 Telephone (0211) 45 07 85, Fax 49-211-4543283 Telex 858 40 44 dopa d

DELIVERY ADDRESS/PLEASE REPLY TO: HAMBURG, 14 November 1991

Coin acceptor

The invention relates to a coin validator according to the preamble of claim 1.

Electronic coin validators mainly work with inductive and/or optical probes. In the case of the inductive probe, a magnetic coil is usually part of an oscillator and its magnetic field interacts with the coin rolling along the coin track. This results in a dampening of the oscillator circuit with corresponding changes in amplitude, frequency and phase position. Normally, the frequency or phase change is used to compare the measured value with

Patent Attorneys ■ European Patent Attorneys ■ Authorized Representatives before the European Patent Office

Attorney: admitted to the Hamburg courts

Deutsche Bank AG Hamburg, No. 05 '28197 (Bl/ IiOO -OO 0C'| · Postgiro Hamburg 28 42-206 Dresdner bank 4G HimDU'y, No. ±33 ö0 15 (F>LZ 200 800 00)

to compare it with a target value so that, if necessary, a counterfeit or an inadmissible foreign coin can be eliminated.

Optical sensors work as a light barrier that is crossed by the coin as it rolls past. However, optical sensors are also known that detect the light reflected by a coin, for example to determine a specific coin edge, such as knurling.

In addition to the material properties, the diameter of the coins is also a typical measurement value. Optical and inductive sensors are also used to measure diameters. In inductive measurement, the effective coil surface is directed at the embossing and the covered area is evaluated. In this well-known method, the material properties are naturally included in the measurement value depending on the frequency selected. A larger or smaller diameter can be simulated by using a different material for the disc to be tested. In optical detection, the coin passes through at least two or more photo paths or light barriers and the times that pass from passing through one path to passing through the other path are determined, since these times

- 3 represent an indicator of the diameter.

There are many foreign coins with a relatively low value that are made of a similar material to the coins being accepted and also have approximately the same thickness and diameter. By simply manipulating the edge of the coin, such coins can be brought to the "correct" diameter. This can be done, for example, by sticking a plastic film on. Alternatively, a ring made of plastic, cardboard or the like can be pushed onto the coin. Such counterfeits naturally cannot be optically discriminated against, because the optical sensors work independently of the material. The inductive measurements also do not achieve the desired result. The small non-metallic portion of the counterfeit coin cannot usually be detected. In addition, it is possible to generate the desired genuine signal using a metal foil.

In the case of foreign coins with a larger diameter, this can be brought to the "correct" size by turning or grinding. Such manipulated coins have no knurling. Since the inductive sensors used work in an integrated manner, the knurling can be simulated by means of targeted dimensional tolerances.

The invention is therefore based on the object of creating a coin tester with which even counterfeits can be detected which differ only slightly from genuine coins in terms of material and, if applicable, thickness and which are adapted to the diameter of the genuine coin by various manipulations.

This object is achieved according to the invention by the feature of claim 1.

In the coin tester according to the invention, the magnetic coil is arranged below the coin track so that the magnetic field interacts with the coin edge. In particular, the direction of the main field of the magnetic coil or the effective coil surface is arranged so that the magnetic field direction runs perpendicular to the coin edge. With the help of such an inductive probe, the coin edge is therefore specifically "examined". According to one embodiment of the invention, the frequency is selected so that the magnetic field penetrates the material of the coin. As is known, from a certain frequency onwards a so-called skin effect is obtained, at which the magnetic field no longer penetrates significantly into the material of the coin. If a low frequency is selected, a more or less deep penetration takes place.

so that the material of the coin is also detected. If the edge of the coin is made of non-magnetic material, this results in a relatively large air gap between the material adapted to the genuine coin and the magnetic coil, which has a corresponding effect on the damping. If the edge of the coin to be tested has been turned off, this leads to a more intensive interaction between the coil and the coin material than with a knurled coin, which can also be detected.

With the aid of the measure according to the invention, the shape of the coin edge, the material of the coin edge, its thickness and its knurling are recorded, so that a large number of manipulated discs and coins can be discriminated against.

It is understood that the arrangement of an inductive sensor chosen according to the invention can also be combined with other sensors in order to obtain even greater test reliability.

According to one embodiment of the invention, the magnetic coil is recessed into a lateral extension of the track carrier. For example, the magnetic coil can be

a lateral opening of the lateral extension, whereby according to a further embodiment of the invention it protrudes beyond the free end of the extension and projects into a recess in the main plate. This ensures that the axis of the effective coil surface lies approximately in the center plane of the coin channel, the bottom of which is delimited by the track.

An embodiment of the invention is explained in more detail below with reference to drawings.

Fig. 1 shows schematically the side view of a coin validator according to the invention.

Fig. 2 shows a section through the representation of Fig. 1 along the line 2-2.

A coin validator (not shown in detail) has a track 10 along which a coin 12 rolls. A magnetic coil 14 with a winding 16 is arranged below the track. From the winding 16 it can be seen that the effective coil surface faces the edge of the coin 12.

From Fig. 2 it can be seen that the coil 14 is in a

lateral extension 18 of a track carrier 20 which is attached to a main plate 22. The track carrier 20 is normally hinged and can be pivoted away from the main plate 22. As can be seen, the coil 14 extends beyond the free end of the extension 18 and engages in a recess in the main plate 22. As a result, the axis of the effective coil surface is approximately in the center plane of the channel which is formed by the track carrier 20, the main plate 22 and the track 10.

The coil 14 is part of an oscillator (not shown), the parameters of which change when a coin approaches the coil 14. The oscillator circuit of the oscillator is attenuated, which can be detected using a suitable evaluation circuit (also not shown). The magnetic field oscillating at a certain frequency interacts with the edge of the coin 12, so that it can be detected whether the edge is knurled or not or whether it is made of a non-conductive or non-magnetic material.

Claims (5)

- 8 claims; 1. Coin validator with a coin track to which a magnetic coil operated with alternating voltage is assigned in such a way that the magnetic field of the coil interacts with a coin rolling along the track, and an evaluation circuit which detects the change in a value of the alternating voltage at the magnetic coil and compares the changed value with at least one target value, characterized in that the magnetic coil (14) is arranged below the coin track (10) in such a way that its magnetic field interacts with the edge of the coin. 2. Coin validator according to claim 1, characterized in that the frequency of the alternating voltage is selected so that the magnetic field of the magnetic coil (14) penetrates the material of the coin (12). 3. Coin validator according to claim 1 or 2, characterized in that the main field of the magnetic coil (14) is directed approximately perpendicular to the edge of the coin. 4. Coin validator according to one of claims 1 to 3, characterized in that the magnetic coil (14) is in a lateral extension (18) of the track support (20) is arranged countersunk. 5. Coin validator according to claim 4, characterized in that the magnetic coil (14) extends beyond the free end of the appendix (18) into a recess in the main plate (22).