DE19507654A1 - Quantitatively checking metal parts in an object esp. document representing value e.g. banknote - Google Patents

Abstract

The checking involves passing an object through an air gap in a magnetic field of a resonance circuit (1) with which the damping is reduced under closed loop control. The manipulated variable of the control loop is used to evaluate the conductivity of the metal parts. A time constant for the control loop can be selected so that at the intersection of metal part and magnetic field the control loop is momentarily unbalanced. The damping can be reduced to a level which produces resonance amplification.

Description

The invention is based on a method for quantitative determination on metal parts in one Subject, especially for testing with a metallic security thread Security such as banknotes, on which the object through an air gap of a magnetic field of a resonance circuit.  

Such methods can be used in many ways. in the The following is an example of the procedure for Securities, in particular banknotes.

The advancement of technology allows from Templates with little effort to make mix-up copies. Today, for example, using a Color copier very quickly the image of a Security like a banknote lifelike be mapped. Corresponding counterfeits are known.

To make a distinction between real and Receiving fake banknotes is some evidence Banknotes on a security strip. Of the Security strip is partially continuous metallized, partially limited, as with the US dollars, the metallization on very small metallic surfaces with a thickness of Metal layer of less than 40 nm. As metallized area is just the value of the Banknote provided in positive writing.

Furthermore, some banknotes are ferromagnetic Areas provided, for example by a Application of magnetizable printing ink or by Introducing a magnetizable Security strip.

The method and the device are used for Evaluation of these security criteria, ultimately  to determine whether a banknote is genuine or fake is.

From the generic EP 0 057 972 A2 is a Method known in which a resonant circuit is provided. The resonant circuit has one Capacitor and two coils and is replaced by one Oscillator excited. Between the two coils a magnetic field is formed. Now becomes one Banknote that has a metallic security strip has passed through this magnetic field, this dampens the resonance circuit. These Attenuation is detected and digitized. This Process brings usable results in a Strip thickness greater than 20 µm. With less The process fails because of the metallization evaluable signal in the range of the noise value of the Resonant circuit. So the process can Authenticity of US dollar bills, the thickness of which Metal layer is smaller than 40 nm, do not recognize.

The present invention therefore has the problem based, starting from the generic Document a method and an apparatus To provide with the metal parts less Reliable detection of thickness in an object will.

According to the invention, the problem is associated with solved the generic features in that the resonance circuit is attenuated that the Damping is carried out in a control loop, and  that the manipulated variable of the control loop as a measure of Conductivity of the metal parts is evaluated.

As is known in the prior art, the Subject, in particular the banknote, by the Air gap of a magnetic circuit, the Coil one together with a capacitor Forms resonance circuit. That to a damping leading power consumption in the air gap parts of the security strip however with small dimensions of the metallic Areas significantly lower than those in Resonance circuit due to the losses in the Power consumed by components. The invention goes therefore from the basic idea that in order to to obtain evaluable measured variable, this Performance ratio can be significantly improved got to. Damping is provided for this. The Damping is integrated in a control loop. Of the The resonant circuit is so far by means of damping dampened until a predetermined resonance increase arises.

A time constant of the control loop can be such be chosen that at a crossing of the metal parts and the magnetic field of the control loop is momentarily out of balance.

The manipulated variable of the control loop, especially its Change is used as a measure of conductivity used.

Through this procedure according to the invention Maintain quality levels in the resonance circuit that the  Quality values of known resonance circuits around a few Exceed powers of ten. This ensures that even in small metallic areas in an object when the object is carried out through the electric field of the resonant circuit easily evaluable signal is generated.

This also creates the possibility that inventive method in counting devices as in Use handheld devices.

Ultimately the metallic area sensing sensor can both in a right Angle to that having the metallic area Security strips, as well as parallel to it will. Even with large positional tolerances of the Security strip, in the example Banknotes is still a reliable detection possible.

A further improvement can be achieved if the attenuation up to a resonance increase he follows.

The resonance circuit is preferably with a high-frequency voltage.

The procedure for examining securities like Banknotes that have a metallic Security strips and magnetizable areas have, is characterized in that in addition to the quantitative determination described above Metal parts continue to have a provision  magnetizable areas. With that both Security criteria checked on a banknote and thus the security of the result further elevated.

The quantitative determination is preferably carried out according to the method and device as described by same applicant in the patent application "Procedure and device for quantitative determination magnetizable areas on an object ", the filed on the same day. This registration is hereby expressly referred to as Declared part of this application.

The device for carrying out the method for the quantitative determination on metal parts in an object is based on a device according to the generic document for the method described above, with an inductance L _res formed by a coil and a capacitance C _res which is excited by an oscillator Form resonance circuit and with an evaluation unit.

The device according to the invention is characterized in that a damping device is provided is that the damping device one Has control loop, and that the evaluation unit with a manipulated variable of the control loop is connected.

The control loop can have a time constant such that when the metal parts cross and a magnetic field of the inductance L _res the control loop is briefly out of equilibrium.

A phase rectifier can be provided which is connected to the oscillator which excites the resonance circuit. Due to the very high quality of the resonance circuit, it is relatively narrow-band. It is therefore possible to continuously readjust the oscillator frequency by means of the phase rectifier. This regulation is carried out in such a way that the oscillator _{output voltage} U _vco and the resonant circuit _voltage U _res processed by means of a linear amplifier remain in a predetermined phase position with respect to one another.

Further advantageous configurations result from the further subclaims.

A device for testing securities such as Banknotes that have a metallic Security strips and magnetizable areas have, is characterized in that in addition to the Device for quantitative determination Metal parts as described above, one Frequency detector circuit is provided.

The detector circuit is designed preferably such as that of the same Applicant and filed on the same day Patent application is described.

The invention is based on exemplary embodiments explained in more detail.  

Show it

Fig. 1 shows a basic circuit of the device and

Fig. 2 shows a basic circuit of a damping device.

In FIG. 1, a resonance circuit 1 is provided which consists of an inductance L and a capacitance C 2 _{res res} 3 is formed. The resonance circuit is excited by means of an oscillator 4 . A further capacitance 5 is arranged between the oscillator 4 and the resonance circuit 1 . Downstream of the resonant circuit 1 is a linear amplifier 6 , the output 7 of which is connected to a rectifier 8 . An operational amplifier 9 is connected with a first input 10 to an output 11 of the rectifier 8 . A reference voltage U _{ref is present} at a second input 12 of the operational amplifier 9 . A controller output 13 of the operational amplifier 9 is connected to an evaluation unit 14 and to a delay element 15 . The delay element 15 is followed by an attenuation device 16 , the output 17 of which is electrically connected to an input 18 of the linear amplifier 6 .

The output 7 of the linear amplifier 6 is followed by a phase rectifier 19 which is coupled to the oscillator 4 via a connection 20 .

A frequency detector circuit 21 is also provided, which is connected downstream of the linear amplifier 6 .

The controllable damping device 16 is shown in more detail in FIG. 2. It is obvious that only a section of the circuit shown in FIG. 1 is shown here.

The capacitance 3 of the resonant circuit 1 is divided into a first capacitance 22 and a second capacitance 23 . Between the capacitors 22 and 23 there is a connection 24 via a feedback resistor 25 to the output 7 of the linear amplifier 6 .

Furthermore, it can be seen from FIG. 2 that the delay element 15 is connected to the inductor 2 via a MOSFET 26 .

The function is explained in more detail below.

A banknote to be examined for authenticity, not shown here, is guided with a security strip to be detected through an air gap of a magnetic circuit, the inductance 2 of which, together with the capacitance 3, forms the resonance circuit 1 . This resonance circuit is excited with a high-frequency voltage and a damping of this resonance circuit 1 is evaluated when the security strip passes through the air gap. The power consumption of the parts of the security strip located in the air gap, however, leads to a damping, given the small dimensions of the metallic areas with an area smaller than 1 mm² and a thickness of approximately 20 nm, which is a few orders of magnitude lower than that absorbed in the resonance circuit due to the losses in the components Power. In order to obtain an evaluable measurand, this performance ratio must be significantly improved. This is achieved in that by means of the damping device 16, the resonance circuit 1 is damped to such an extent that a predetermined resonance increase occurs. The damping device 16 is designed to be controllable with a time constant which is so great that this control circuit is briefly imbalanced when the security strip passes through. The frequency exciting the resonance circuit 1 is always kept in accordance with the resonance frequency.

The frequency detector circuit 21 registers a change in the resonance frequency when magnetizable areas pass through the air gap of the inductor 2 and is used for a quantitative evaluation of the magnetizability.

In particular, an output voltage U _{osz of} the oscillator 4 is fed to the resonance circuit 1 via a voltage divider formed from the capacitance 5 and the capacitance 3 . The voltage generated at the resonant circuit 1 reaches the rectifier 8 via the linear amplifier 6 . The rectified voltage is compared in the operational amplifier 9 with a predetermined target value 27 (U _ref ) and the amplified result of this comparison controls the controllable damping device 16 via the delay element 15 . This regulation is carried out in such a way that the voltage value at the resonant circuit 1 determined by the predetermined setpoint 27 is maintained. The resonance circuit quality Q of the resonance circuit is thus at one value

Q = U _ref / U _osz , C _res / C _k

held.

If the security thread to be detected is now introduced into the air gap of the inductance 2 of the resonance circuit 1 in the equilibrium state of the damping control circuit of the controllable damping device 16 , the resonance voltage drops due to the damping and leads to a temporary change in a manipulated variable at the controller output 13 . This change in the manipulated variable is a measure of the conductivity of the security strip or of the metallic elements of the security strip.

Since the very high quality of the resonant circuit 1 makes it very narrow-band, the frequency of the oscillator 4 must be readjusted permanently. This is effected by the phase rectifier 19 , which controls the oscillator 4 in such a way that the output voltage of the oscillator 4 and the output voltage of the linear amplifier 6 remain in a predetermined phase position with respect to one another.

The output voltage of the linear amplifier 6 is also fed to the frequency detector circuit 21 for evaluating the frequency change caused by magnetizable areas.

The controllable damping device 16 must meet very high linearity requirements. This is achieved in that the capacitance 3 of the resonant circuit 1 is formed by the first and second capacitors 22 , 23 . The feedback resistor 25 supplies the resonance circuit 1 with more energy than is consumed in the lossy components. By an additional series resistance of the inductor 2 , which is realized here by the controllable resistance of the Mosfet's 26 , the balance between damping and damping is regulated accordingly.

The circuit of FIG. 2 can be operated as an oscillator itself. The feedback branch, essentially formed from the rectifier 8 , the operational amplifier 9 and the delay element 15 , regulates the on-resistance of the Mosfet's 26 , that is, the resistance in the switched-on state of the Mosfet's, such that the one from the first and second capacitance 22 , 23 and the inductance 2 and the linear amplifier 6 formed oscillator is kept at the limit of the use of vibrations. A passage of the security strip through the air gap of the inductor 2 causes the oscillation to subside temporarily until the oscillatable state is restored by the controllable damping device 16 . The decay time constant depends on the conductance of the security thread and causes corresponding output voltages at the output of the operational amplifier 9 .

Reference list

1 resonance circuit
2 inductance
3 capacity
4 oscillator
5 capacity
6 linear amplifiers
7 exit
8 rectifiers
9 operational amplifiers
10 first entrance
11 exit
12 second entrance
13 controller output
14 evaluation unit
15 delay element
16 damping device
17 exit
18 entrance
19 phase rectifier
20 connection
21 frequency detector circuit
22 first capacity
23 second capacity
24 connection
25 feedback resistor
26 Mosfet
27 specified setpoint

Claims (14)

1. A method for quantitative determination of metal parts in an object, in particular for testing securities equipped with a metallic security thread, such as banknotes, in which the object is guided through an air gap of a magnetic field of a resonance circuit, characterized in that the resonance circuit ( 1 ) is damped is that the damping is carried out in a control loop, and that the manipulated variable of the control loop is evaluated as a measure of the conductivity of the metal parts. 2. The method according to claim 1, characterized in that a time constant of the control loop ( 1 ) is selected such that when the metal parts and the magnetic field cross the control loop ( 1 ) is briefly out of balance. 3. The method according to claim 1 or 2, characterized characterized that the damping up to there is an increase in resonance. 4. The method according to one or more of claims 1 to 3, characterized in that the resonant circuit ( 1 ) is excited with a high-frequency voltage. 5. Procedure for examining securities such as Banknotes that have a metallic Security strips and magnetizable Have areas, characterized in that a quantitative determination on metal parts according to one or more of claims 1 to 4 and a quantitative determination magnetizable areas. 6. Device for performing the method according to one or more of claims 1 to 4, with an inductance formed by a coil L _res ( 2 ) and a capacitance C _res ( 3 ), which is excited by an oscillator ( 4 ) resonant circuit ( 1 ) and with an evaluation unit ( 14 ), characterized in that a damping device ( 16 ) is provided, that the damping device ( 16 ) has a control loop, and that the evaluation unit ( 14 ) is connected to a manipulated variable of the control loop. 7. The device according to claim 6, characterized in that the control loop has a time constant such that at a crossing of the metal parts and a magnetic field of inductance L _res ( 2 ) the control loop is briefly out of equilibrium. 8. Apparatus according to claim 6 or 7, characterized in that the damping device ( 16 ) has a linear amplifier ( 6 ), that the linear amplifier ( 6 ) is applied to the resonant circuit ( 1 ) applied resonant circuit voltage, and that an output ( 7 ) the linear amplifier ( 6 ) is connected to a rectifier ( 8 ). 9. The device according to claim 8, characterized in that the rectifier ( 8 ) is followed by an operational amplifier ( 9 ), and that the operational amplifier ( 9 ) is supplied with a setpoint U _ref ( 27 ). 10. The device according to claim 9, characterized in that a controller output ( 13 ) of the operational amplifier ( 9 ) with the evaluation unit ( 14 ) is electrically connected. 11. The device according to claim 9 or 10, characterized in that the operational amplifier ( 9 ) is followed by a delay element ( 15 ), and that an output of the delay element ( 15 ) is connected to an input of the damping device ( 16 ). 12. The device according to one or more of claims 6 to 11, characterized in that a phase rectifier ( 19 ) is provided, and that the phase rectifier ( 19 ) is connected to the oscillator ( 4 ). 13. The device according to one or more of claims 6 to 12, characterized in that a feedback resistor R _f ( 25 ) is provided, and that the feedback resistor ( 25 ) is dimensioned such that the resonant circuit ( 1 ) is supplied with more energy than is consumed in the lossy components. 14. A device for checking securities such as banknotes which have a metallic security strip and magnetizable areas, characterized in that the device for quantitative determination on metal parts is designed according to one or more of claims 6 to 13 and that a frequency detector circuit ( 21 ) is provided .