DE2350989C2 - - Google Patents

Description

The invention relates to a method and a Direction for checking the authenticity of coins according to the waiter Concept of patent claim 1 or that of patent claim 7.

Such a method and such a device device are known from DE-OS 14 74 736. Thereby with a measuring bridge worked in one of their bridges branches a generating an alternating magnetic field Has inductor. The bridge is initially ge Calibrates a valid coin to a predetermined position brought inside the inductor and one in a second Bridge branch provided resistance is set so that the bridge voltage becomes zero. In the later Every coin that does not abort the measuring bridge will perform testing procedures same, displayed as incorrect and sorted out. To this In the end, the coin to be checked becomes the same the valid coin used for initial verification compared. It becomes the degree of interaction once between coin and field and then he sums up when the coin is in the field.

In the known coin validator, there is a risk that the measurement result is falsified by a change that between the original calibration of the bridge circuit based on the reference coin and later testing of the respective unknown coin. Such changes can on the one hand consist in the fact that time constantly assumed values (especially the oszilla idle frequency with which the alternating field is generated) change over time, on the other hand in that spatial Shifts in the measuring arrangement occur by for example, the individual coins in slightly different Roll past the inductor and therefore too under different interactions with the magnetic field. In practice, these latter fluctuations can even then occur when several attempts with the same coin be carried out one after the other.

The invention has for its object a Ver drive and specify a device for coin testing where with both temporal fluctuations in the measurement parameters as also spatial fluctuations within the measuring arrangement are eliminated.

The solution to this problem is in the characteristic part of the Claim 1 or claim 7 specified. After that, at each coin to be tested shows its interaction with the Magnetic field signal not only when the Coin is located in the magnetic field, but also briefly sampled before or after, and both signal values are used to form a third signal; first this third signal is compared with the reference value.

The in claims 1 and 7 in conjunction with the Description of the distance between the acquisition of the first and second signals used relative term "Short" is to say that this period is short in the ver ratio to those changes that eli should be mined.

Advantageous embodiments of the invention are in the Subclaims marked.

Embodiments of the invention are as follows explained in more detail with reference to the drawing. In the drawing shows

Fig. 1 is a schematic front view of part of a coin validator,

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

Fig. 3 is a block diagram of an electrical circuit for the coin testing device of Fig. 1 and 2, and

Fig. 4 is a block diagram for another imple mentation form of the electrical circuit.

The term is used in the present description "Coin" for real coins, tokens, counterfeit coins, Blanks, material disks or other objects, such as they are used  can operate a coin-operated apparatus.

In the apparatus according to Fig. 1 and 2, an inductor 20 runway with one or more pole pieces 22 on one side of a coin 30 is provided. The coin track 30 is defined by two side walls 32 and 34 and by a coin groove 36 which is attached to the side wall 34 . The side wall 32 is attached to the remaining part of the coin validator, while the side wall 34 to which the inductor 20 is attached is connected to the remaining part of the validator via a joint 35 . The side wall 34 is movable to allow cleaning of the inside of the coin track 30 and removal of occasionally jammed coins or objects.

Opposite the inductor 20 (inductance coil), a conductive pole piece 40 , for example a thin copper disk or a disk made of another highly conductive material, is attached in or on the inside of the side wall 32 on the other side of the coin track 30 . If there are no coins or other objects in the vicinity of the inductor 20 in the coin path 30 , the signal at the inductor terminals is influenced by the presence of the pole piece 40 . If the side wall 34 changes its position with respect to the side wall 32 , the signal changes as a function of the relative position of the inductor 20 and the pole piece 40 . Details regarding the selection of suitable inductors 20 and a circuit in which such an inductor can be used can be found in DE-OS 22 25 228.

In Fig. 3, the inductor 320 is connected to a test station circuit 350 , the output signal of which is a function of the material in the field of the inductor 320 . If a pole piece 340 is arranged opposite the inductor 320 in the coin path 330 , then the output of the test station circuit 350 is changed by an amount which is dependent on the relative positions of the side walls 332 and 334 . The pole piece 340 need not be arranged in the device if a dependency on the side wall position is not required.

The output signal from the test station circuit 350 is both on the switching element362 as well as switching element364 on which also a sequence of timing in pulse from the clock generator360 issue. During a coin check and at all other times except when at theQ-Output of a monostable multivibrator361 an impulse is generated is the switching element362 through the - Exit the monostable multivibrator361 switched through, which the Output signal from the test station circuit350 for the duration of the timing pulse to a register371 is placed. A Function circuit383 creates a value that is a function of the test value that is in the register371 is saved, and the reference value in a register370 was saved and which is representative of the output signal of the test station circuit350 if there is no coin. This signal from the Function circuit383which, for example, the arithmetic Difference between in the registers370 and371 saved Counts can be sent to a comparison and store circuit390 created. This contains information regarding the values for valid coins and devices for comparison such values with those of the functional circuit383 received values. If the comparison and storage circuit390  determines that a received value is within the range for an acceptable coin, it generates a signal that indicates that the coin under review is the special one Passed the test.

The reference value stored in register 370 is introduced in the same manner as a test value in register 371 . The reference value is entered into the register 370 at three different times under the control of the control circuit 365 , the OR gate 366 , the AND gate 367 and the monostable multivibrator circuit 361 . The control circuit 365 generates signals which are applied via the OR gate 366 and the AND gate 367 to switch over to the monostable multivibrator 361 as follows: when voltage is initially applied to the coin validator; each time a signal is received indicating that the machine connected to the coin validator has received a sell order; and after every second. The AND gate 367, however, receives a signal for the duration of the period, starting from the first detection of a coin (arrival) by the coin validator until the time the coin leaves the coin validator, causing the flow of trigger signals during the period is interrupted. It follows from this that the reference value stored in register 370 cannot contain values which are influenced by the presence of a coin in the area of the sensor.

In a preferred modification of this embodiment, the reference value is stored when the control circuit 365 receives signals either at approximately 300 ms after the initial application of voltage to the coin validator or approximately 300 ms after an acceptable signal relating to any type of coin from part of the coin validator, which is not dependent on the reference value (e.g. a low frequency test signal) followed by the absence of a coin acceptance signal (e.g. a high frequency rejection signal). The delay that may result from the use of a counter within the control circuit 365 for counting the pulses of the clock generator 360 ensures a sharp, relatively trouble-free pulse from the monostable multivibrator 361 and, in the second case, ensures that the coin is the system before the new reference value is entered. From this it follows that the reference value stored in register 370 does not include any values which are influenced by the presence of a coin in the area of the sensor.

If a linear correction as described above is not sufficient, for example for the elimination of variations in the oscillator frequency due to changes in the relative position of the side wall 334 with respect to the side wall 332 or due to other disturbances in the system, the one in the register 371 stored value can be modified by another mathematical function depending on the count stored in register 370 .

In one embodiment of the invention, which is fully digital, the presence of conductive objects in the field of inductor 320 causes a shift in the frequency of an oscillator comprising test station circuit 350 . Such an oscillator circuit is described in DE-OS 22 25 228. The oscillator frequency is measured using timing pulses of precise duration that are output by the clock generator 360 and switch pulses to digital counters that include registers 370 and 371 . AND gates serve as switching gates 362 and 364 . The reference pulse that is stored ge is the difference (ff ₀ ) between the peak frequency with the coin present and that frequency with the coin reading.

In another embodiment, analog circuits are used at least to carry out some of the functions. If, for example, the output signal of the coin test station circuit 350 which gives the coin property of interest is a voltage with variable amplitude, then the registers 370 and 372 from capacitor circuits can be used to store a peak voltage. The information may be converted to digital form at the output of registers 370 and 372 , or may preferably be used as a complex function, while logic circuit 383 may be an analog circuit whose output signal is converted to a digital signal for transmission to a digital storage system 390 can be.

Fig. 4 shows a block diagram of a digital embodiment according to the invention. An inductor or sensor 420 and an oscillator 450 and the details of the coin track (not shown) may correspond to those of the embodiment shown in FIG. 3. A timing pulse generator 460 switches a flip-flop circuit 461 with a pulse of precise duration via an AND gate 463 . In the example shown, flip-flop circuit 461 is gated at the end of each pulse period of precise duration.

In the initial idle frequency mode of operation, flip-flop circuit 461 alternately passes the oscillator output to counter 470 or counter 471 for the duration of an accurate pulse, for example, for 1 ms. AND gates 462 and 464 are used to switch the oscillator output signal between the counters, while AND gates 466 and 468 are used to defi nite the duration of the counting periods.

If there is no coin in the vicinity of inductor 420 , one of counters 470 and 471 stores a value representative of the output frequency of oscillator 450 while the other measures the oscillator output signal. If the coin validator detects the arrival of a coin in the device by a presence detector 455 , the details of which are not part of the invention, an arrival signal is applied to the AND gate 463 , thereby locking this gate and switching between the oscillator output signal counting counters is ended. Instead, one of counters 470 or 471 remains connected to receive and count the oscillator output signal for the period of the precise pulse, while the other stores the last value stored prior to the arrival signal. This stored value is representative of the idle frequency of the oscillator 450 immediately before the next coin check. Alternatively, the idle frequency can also be determined in the manner described for the coin validator according to FIG. 3.

If a coin runs into the field of the inductor, the oscillator frequency increases. During each subsequent period of the exact pulse, a differential element 473 sets a flip-flop 485 as soon as the pulse count of the frequency exceeds the stored pulse count indicating the idle frequency, where the AND gate 489 is switched through. All other pulses from the oscillator 450 during this period are applied to the memory system 490 via OR gate 487 and AND gate 489 for comparison with information stored there about acceptable coins.

After each period of an accurate pulse ends, a reset pulse is generated on line 479 by pulse generator 460 during a short pause before the beginning of the next period of an exact pulse. This resets the flip-flop circuit 485 and corresponding elements in the memory system 490 . The reset pulse is also applied to gates 476 and 478 , one of which is turned on by a signal from flip-flop circuit 461 which determines which counter 470 or 471 should count in the next period, only this counter being reset .

When the coin leaves the coin validator, the arrival signal from the presence detector 455 ends, the AND gate 463 is no longer locked and the device returns to the idle frequency mode.

Claims (9)

1. A method of checking the authenticity of coins, wherein
the coin to be tested is exposed to an alternating magnetic field,
a signal is generated which indicates the degree of interaction between the coin and the alternating field and that is detected when the coin is in the alternating field, and
it is determined whether the degree of interaction corresponds to a reference value valid for an acceptable coin, characterized in that
that a second signal is detected shortly before the coin enters the alternating field or shortly after it has left it,
generating a third signal indicating a function dependent on the first and second signals, and
that the value of the third signal is compared with the reference value. 2. The method according to claim 1, characterized records that the second signal is the same Way like the first signal, but one difference time is generated. 3. The method according to claim 1 or 2, characterized ge indicates that the third signal of the Difference between the first and the second signal corresponds.   4. The method according to any one of claims 1 to 3, characterized characterized in that the first signal and the second signal indicate frequencies of the alternating field. 5. The method according to claim 4, characterized records that the first signal and the second Signal by counting pulses of the alternating field frequency generated and that one of the counts for use is saved when the third signal is generated. 6. The method according to any one of claims 1 to 5, characterized characterized that the first signal is generated throughout the period during which the coin is in the alternating field and that only the maximum value of the first occurring in this period Signal used to generate the third signal becomes. 7. Device for checking the authenticity of coins
an inductor ( 320; 420 ) for generating an alternating magnetic field acting on the coin to be tested,
a circuit ( 350, 360, 362, 364; 450, 460, 461, 462, 464 ) for generating a signal indicating the degree of interaction between the coin and the alternating magnetic field and for detecting this signal when the coin is located in the alternating field, and
a comparator ( 390; 490 ) for determining whether the degree of interaction corresponds to a reference value that applies to an acceptable coin,
characterized,
that the signal generating circuit ( 350, 360, 362, 364; 450, 460, 461, 462, 464 ) the signal at a point in time just before or after the actual measuring process, at which there is no coin in the alternating field, and at another The time at which the coin is in the alternating field is scanned and a sample value is generated in each case,
that a register stage ( 370; 470, 471 ) for storing the earlier of the two samples is connected to the signal generation circuit ( 350, 360, 362, 364; 450, 460, 461, 462, 464 ),
that a function generator ( 383; 473 ) is connected to the register stage ( 370; 470, 471 ) for generating a further signal as a function of the stored and the later of the two samples, and
that the comparator ( 390; 490 ) is connected to the output of the function generator ( 383; 473 ) for comparing the size of the further signal with the reference value. 8. The device according to claim 7, characterized in that the inductor ( 20; 320 ) on one side and an electrically conductive pole piece ( 40; 340 ) opposite the inductor ( 20; 320 ) on the other side of a coin track ( 30; 330 ) is arranged. 9. Apparatus according to claim 7 or 8, characterized in that the function generator ( 330; 430 ) is a differential element.