DE2350989A1 - METHOD AND DEVICE FOR USE IN A COIN VALIDATOR WITH INDUCTIVE SENSOR - Google Patents

Description

PATENTANWÄLTE 89 Augsburg 22, October 3, 1973

_,. _- -. ,, Rilkestrasse 10

' Ring. E. LIEBAU

DIPL. ING. G. LIEBAU (please give feedback)

Mars, Incorporated Westgate Park 1651, Old Meadow Road, McLean., Virginia / USA

Method and apparatus for use in a coin validator with inductive sensor.

It has. it has been shown that the distinction between coins, Tokens od. The like. In a coin validator by means of an inductive sensor can be improved in practice that a Function is generated which is both dependent on the present a coin generated by the sensor as well as the information that the sensor slightly before or after the presence of the coin in the probe and by comparing the value of this function with values for acceptable ones Coins.

According to the method of the present invention, the coin or another object to be tested along a known path past one or more poles of an induction coil— led that is on one side of the way .. Bas procedure further comprises the steps of checking the characteristics of the induction coil output signal when there is no coin in the area of the sensor, check the same characteristic if a coin is in the area of the sensor, generate a Signal that is a function of these two tests and

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testify to a signal "regarding the acceptability of the tested Coin. In a further development of the method according to the invention, one can then when the coin coil the inductance runs through on one side of the path, they coil between the inductance and an electrically conductive part on the traverse the other side of the path.

The method according to the invention minimizes errors that result from shifts in the value of the reference standards, on which the coin check is based, for example the oscillator— Torle run frequency, the length of the pulse counting periods and the like. The method in which the coin is passed between the feeler and a pole is particularly useful for reduction of errors caused by changes in the actual position of the sensor relative to the passage ! ■ / earth, for example in devices where the sensor is in a movable Pass-through side wall is attached. The invention also encompasses the combination of elements of a coin validator of the type described below.

In the drawings show:

1 and 2 are schematic front and side views (broken away along line II-II in FIG. 1) of one Part of a coin validator according to the invention; "_

Fig. 3 is a block diagram of an embodiment of the invention;

FIG. 4 is a block diagram of another embodiment of FIG Invention.

The figures are for illustrative purposes only and are not necessarily to scale. '

In this specification the term "coin" is intended to mean real coins, tokens, counterfeit coins, blanks, discs and similar other objects that are used for an experiment

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can operate a coin operated device.

In the device according to FIG. 2, an inductor 20 with one or more pole pieces 22 is provided on one side of a coin passage 30. The passage ahn 30 is defined by two side walls 32 and 3 ^ and by a coin channel 36 which is attached to the side wall 3 ² J-. 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 hinge 35. The side wall 34 is movable to permit cleaning of the interior of the passageway 30 and the removal of occasional jammed coins or objects.

Opposite the inductor 20 (inductance coil) is a conductive pole 40, for example a thin copper washer or washer made of another highly conductive material, in or on the inside of the side wall 32 on the other side of the continuous path 30 attached. If there are no coins or other objects in the vicinity of the inductor 20 in the passage 30, then the signal at the inductor terminals is affected by the presence of pole 40. 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 4-0. details regarding the selection of suitable inductors or sensors 20 and a circuit in which such an inductor is used can be, are from the German patent application P 22 25 228.4 or the German utility model application G 72 19 458.2.

In Figure 3 the inductor or probe 320 is connected to a test station circuit 350 so that the output of test station circuit 350 is a function of the material in the field of inductor 320 is. If a pole 340 is arranged opposite the inductor 320 in the passage 330, then the The output of the test station circuit 350 changed by an amount dependent on the relative positions of the side walls 332 and 334. The pole 340 does not need to be in the device.

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be arranged, if a dependency of the side wall position is not is required. The output of the test station circuit 350 is applied to both gate 362 and on. the switching element 364 created. which also have a sequence of timing pulses from timing pulse generator 360 are present. Except in the course of a coin check and at all other times if, a pulse is generated at the Q output of a monostable multivibrator 361, the switching element 362 is through the Q output of the monostable multivibrator 361 switched through, whereby the Output of test station circuit 350 for the duration of the timing pulse is applied to a register 371. One ] action circuit 383 generates a value that is a function is the test value stored in register 371 and the reference value stored in register 370 and that representative of the output of the test station circuit 350 "if the coin is missing. This signal from the Function circuit 383, for example the arithmetic Difference between in the registers. 370 and 371 stored Counts are sent to a comparison and storage circuit 390 created. This contains information regarding the values for valid coins as well as means for comparing them such values with those received from the function circuit 383 Values. If the comparison and storage circuit 383 determines that a received value is within the range for. is an acceptable coin, it generates a signal that indicates that the. the coin under test has passed the special test. More details about comparison— and memory circuits suitable for use in the invention can be obtained from the same day pending German patent application which goes back to the priority of British patent application No. 47 161/72.

The reference value stored in register 370 is entered in the same way as a test value in register 371 · the reference value is entered into register 370 at three different times

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under control of the control circuit (house keeping) 565, des OR gate 366, the AND gate 367 and the monostable multivibrator 361 entered. The control circuit 365 generates signals via the OR gate 366 and the AND gate 367 for switching is applied to the one-shot circuit 361 as follows be: When tension is on at the beginning. the coin validator is placed, whenever a signal is received indicating that the machine connected to the coin validator is issuing an up command received and after every second. The AND gate 367, however receives a signal for the duration of the period starting with the first detection of a coin (arrival) by the coin validator until the coin is diverted, thereby interrupting the flow of trigger signals during the period. It follows from this that the reference value stored in register 370 cannot contain values that are determined by the presence of a coin in the Area of the sensor can be influenced. In a preferred modification of this embodiment, the reference value is stored, when the control circuit 365 signals either approximate 300 milliseconds after the initial application of Voltage to the coin validator or approximately 3OO milliseconds after an acceptable signal regarding any coin type is obtained from a coin validator rope which is not dependent is from the reference value (e.g. a low frequency test) followed by the absence of a coin acceptance signal (e.g. a high frequency rejection). The delay caused by the use of a counter within the control circuit 365 for counting the pulses of the timing pulse generator

360 can result in a sharp, relatively interference-free pulse from the monostable multivibrator

361 and in the second case that the coin leaves the system before the new reference value is entered. It follows from this 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 was not sufficient, for example to correct for variations in the oscillator frequency due to changes in the relative position of the side wall 334 with respect to the side

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wall 332 or as a result of other system malfunctions, the stored in register 371 by another mathematical one Function dependent on the count stored in register 370 be modified.

In one embodiment of the invention which is carried out entirely digitally, the presence causes conductive Objects in the field of the inductor or sensor 320 have a displacement at the frequency of one comprising the test station circuit 350 Oscillator. Such an oscillator circuit is described in German patent application P 22 25 228.4. The oscillator frequency is measured by using timing pulses of precise duration obtained from the timing pulse generator. tor 360 and switch impulses through to digital counters, which include registers 370 and 371. AND gates serve as switching elements 362 and 364. The reference pulse that is stored is the difference (f-f) between the peak frequency when the coin is present and that frequency when the coin is being read Coin.

In another embodiment, at least for implementation some of the functions use analog circuits. For example, this is the one indicating the coin property of interest Output of coin checking station circuit 350 is a Voltage with variable amplitude, then registers 370 and 372 can consist of capacitor circuits for storing a peak voltage to serve. The information can be converted into digital form at the output of registers 370 and 372, or they can preferably be used as a complex function, while the logic circuit 383 can be an analog circuit whose output can be converted to a digital signal for transmission to a digital storage system 390.

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 duration (not shown) can match those of the embodiment

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Measure Fig. 3 correspond. A timing pulse generator 460 switches a flip-flop circuit 461 with a pulse of precise duration via an AND gate $ 46. In the example shown, the Fljiflop circuit 461 at the end of each pulse period. Exact duration groped.

In the initial idle frequency mode of operation, the conducts Flip-flop circuit 461 the output signal of the oscillator alternately to the counter 470 or the counter 4? 1 for the duration of an exact pulse, for example for one millisecond. AND gates 462 and 464 are used to switch the 0s " zillatorausgaiigssignals between the counters, while AND gates 466 and 468 are used to define the duration of the counting periods.

No coin is in the vicinity of the inductor 420, one of the counters stores 470 and 471 a value which is representative of the output frequency of the oscillator 450, while the other measures the oscillator output signal _o If the coin validator the arrival of a coin in the device by Arrival / Sequence fixed setting device en 455, the details of which are not rope of the invention, then an arrival signal is applied to the AND _{gate 463 9} whereby this gate is blocked and the switching back and forth between the counters counting the oscillator output signal is ended " Instead, one of the counters 470 or 471 remains connected to receive and count the oscillator output signal for the period of the exact pulse, while the other stores the last value stored before the arrival signal. This stored value is representative of the idle frequency of the oscillator 450 immediately before the next coin check. Alternatively, the idling 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, it grows Oscillator frequency. During each subsequent period of the exact pulse, comparators 473 turn on a flip

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flop 485, as soon as the pulse count of the frequency that the idle— exceeds the frequency indicating, stored pulse count, the AND gate 489 being switched through. All other impulses from the oscillator 450 during this period are via OR gate 487 and AND gate 489 to the memory system 490 for comparison with information about acceptable coins stored there.

Subject termination of each period of a precise pulse while a short pause before the start of the next period of an exact pulse becomes a reverse pulse on a line 479 generated by the pulse generator 460. This provides the plip-flop circuit 485 and corresponding elements in the memory system 490 back. The reset pulse is also applied to gates 476 and 478, one of which is a signal from the Flip-flop circuit 461 is switched through, which determines which of the counters 470 or 471 is to count in the next period, only this counter is reset.

If the coin leaves the coin validator, the arrival signal ends of the arrival / evacuation devices 455, the ÜHD gate 465 will no longer lock out and the device will revert to the idle frequency mode of operation.

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Claims (11)

Ij method for checking coins for their authenticity, characterized by generating an alternating magnetic field, exposing a coin to this field, generating a first signal with a property that is decisive for the degree of interaction between coin and field, generating a second signal with a Value that corresponds to a function that is dependent on both a first value of the property when there is no coin in the field and a second value of the property when the coin is in the field, and comparing the value for the coin corresponding to the function with a value of the function for an acceptable coin. 2. The method according to claim 1, characterized in that that the value corresponding to the function is the arithmetic difference between the first and second value. 3. The method according to claim 1 or 2, characterized in that the degree of cooperation the decisive property is the frequency of the magnetic field. 4. The method according to claim 5 * characterized eh. Net, that the first and second values of the property are generated by counting the pulses of the field frequency and that one of the values for generating the second signal is stored. 5. The method according to any one of claims 1 to 4, characterized in that the function of the coin corresponding values are generated throughout the period during which the coin is subject to the field and that a coin is only found to be acceptable if the greatest of the values is within a predetermined value - 10 - A09816 / 0426 7350989 Limits for acceptable coins of a given coin type. 6. Device for checking coins with regard to their authenticity, characterized by inductor · or sensor « devices through which a coin is exposed to an alternating magnetic field, devices for generating a first Signal with a property that is representative of the degree of interaction between the coin and the magnetic field is, means for storing a first value of the property of the first signal detected when there is no coin in the IPeId, function generator devices, which receive the first value of the first signal as well as the second value which is determined when the Coin is present in the field, and a function of the first and second values produce ^ and by means of lending devices, which receive the output of the function generator devices and one corresponding to the function of the coin Compare value with a value corresponding to the function of an acceptable coin. 7. Device according to .Anspruch 6, characterized in that a coin passage is provided is through which the coins to be tested along a a predetermined path, as well as a conductive pole, with the inductor on one side of the path and the pole on the other side of the same is arranged opposite the inductor. 8. Device according to claim 6, characterized in that a coin path is provided, along which coins to be checked are guided through the field, as well as a first side wall on one side of the track, to which side wall the inductor is attached, and a second side wall on the other side of the track to which Side wall, a conductive pole is attached opposite the inductor, the side walls being movable relative to one another are. - 11 '- 409816/0425 ~ 11 - 7350989 9. Device according to one of claims 6 to 8, characterized characterized in that the means for generating the first signal are an oscillator which the Contains inductor as a frequency-determining element. 10. Device according to one of the claims 6 to 9 _S, characterized in that the property of the degree of interaction of the coin with the field is the frequency of the first Sgials. 11. Device according to one of claims 6 to 10 _s, characterized in that the function generator devices generate the arithmetic difference between the first and second values. .4 09816/0425 Empty soap