ES2205655T3 - PROVISION OF CIRCUITS FOR THE CHECK OF COINS IN A COIN DEVICE. - Google Patents

Abstract

Circuit comprises a signal generator (18) with a primary coil (10) for storage of a periodic emitter signal and a secondary coil (12) coupled inductiveyl with the first coil, so that the electric field between the coils is transversed by falling coins with a third coil (14) inductively coupled to the first coil so that its signal acts on the emitter signal so that they are synchronized.

Description

Circuit layout for checking coins in a coin apparatus.

The invention relates to an arrangement of circuits for checking coins in a coin device according to the preamble of claim 1.

Inductive provisions for checking Coins have been known for a long time. Inductive sensor typical consists of a primary coil and a secondary coil to through whose magnetic field the coins pass. Depending on the configuration takes place a damping of the primary signal and / or secondary. The damping also depends on the frequency of the primary signal chosen. In the case of a high frequency and a non-magnetic material is produced the so-called Kelvin effect, and the damping caused with such a signal allows a assessment of the nature of the surface of the coin. In In the case of low frequencies, the field is entered more in the currency, with which an assessment can be made about the type of material of the inside of the coin and also about its thickness.

In some cases it is important to give the signal of emission a certain curve shape, for example, use a quadrangular or triangular signal. Signals of this type generate a number of harmonics in odd or even number, which in both cases they are buffered by the currency, although with a strong dependence on the frequency. In a previous application (DE 197 26 449) it is used this fact to analyze several properties of the currency with a single inductive sensor. Similar provisions are known, for example, from document FR 2538934 or document DE 2034426.

However, a circuit layout of this type requires, for an exact determination, that the temperature and other factors do not influence the emission signal or field of emission so that it is altered with respect to the signal of the signal generator Then, the analysis circuit must start provided that the determined damping curves are the which correspond to the emission curves provided previously. If this is not the case, the analysis fails.

Therefore, the invention is based on the task of create an electrical circuit scheme in which the induced voltage in the primary coil it is equal to the input voltage.

This task is solved by characteristics of claim 1.

In the electrical circuit scheme according to the invention is provided a third coil that is coupled by induction to the primary coil, bringing the signal of the third coil acts on the emission signal of the signal generator of such that the signal matches the emission signal.

The induced voltage in the third coil acts as a negative feedback signal and causes the voltage induced in the primary coil is equal to the voltage with which it excites the primary coil (emission signal). Therefore, the receiver coil (secondary coil) in vacuum is crossed by the same magnetic flux as the primary coil, which also in this coil induced voltage has the same curve shape as in the primary coil. Only the amplitude is smaller due to reduced coupling.

According to a configuration of the invention it is provided that the signal generator is connected to the coil primary through an operational amplifier, and that the signal of the third coil is connected to the other amplifier input operational.

An especially simple configuration of the invention provides that the third coil is wound on the core of the primary coil as additional winding. In addition, the coil Primary may present a ferrite core or also be made as air core coil. The broadcast signal is preferably a quadrangular or triangular tension. Without However, it can also be a boost in any way.

The circuit arrangement according to the invention allows a preset curve shape for the emission field which is constant throughout the temperature spectrum. Therefore, it is possible to carry out material analysis with fields that contain harmonic waves, regardless of the effect of disturbances

The invention is explained in more detail by means of of an embodiment example.

The only figure shows an arrangement of circuits according to the invention.

The drawing shows a primary coil 10 which is magnetically coupled to a secondary coil 12. Between the coils 10, 12 is the path of a coin not shown. When the coin crosses the magnetic field it is produced a damping of the magnetic field and, with it, an alteration of the secondary signal in the secondary coil 12. A third coil 14 is wound on the same winding core of the coil 10 Primary and connected without load. The tension induced in it is carried at the negative input of an operational amplifier 16, whose Positive input is connected to a signal generator 18. The signal generator produces, for example, a voltage in form quadrangular.

Therefore, the voltage L_ {14} d \ phi / dt Induced in coil 14 is transmitted as feedback signal negative to differential amplifier 16. With this it is achieved that the output signal of operational amplifier 16 equals the signal input, regardless of variations of temperature or that an attenuation of the coil has taken place 10 primary. Therefore, the form of signal voltage in the secondary coil 12 in idle operation is equal to that of the emission signal of signal generator 18.

Claims (7)

1. Arrangement of circuits for the analysis of coins in a coin apparatus, with a signal generator that feeds a primary coil with a periodic emission signal, a secondary coil coupled by induction to the primary coil, bringing the field Magnetic between the two coils is crossed by the coins, characterized in that a third coil (14) is coupled by induction to the primary coil (10), whereby the signal of the third coil (14) acts on the emission signal of the signal generator (18) such that the signal matches the emission signal. 2. Circuit arrangement according to claim 1, characterized in that the signal generator (18) is connected to the primary coil (10) through an operational amplifier (16) and the signal from the third coil (14) is connected to the other input of the operational amplifier. 3. Circuit arrangement according to claim 1 or 2, characterized in that the primary coil (10) and the third coil (14) are wound on a common winding core. 4. Circuit arrangement according to one of claims 1 to 3, characterized in that the primary coil has a ferrite core. 5. Circuit arrangement according to one of claims 1 to 3, characterized in that the primary coil is an air core coil. 6. Circuit arrangement according to one of claims 1 to 5, characterized in that the emission signal is a quadrangular or triangular voltage. 7. Circuit arrangement according to one of claims 1 to 5, characterized in that the emission signal is an impulse of any form.