CH664839A5 - DEVICE FOR CHECKING COINS OF DIFFERENT VALUES. - Google Patents

Description

DESCRIPTION The invention relates to a device for checking coins of different values according to the preamble of patent claim 1.

A coin validation device is the subject of DE-PS 3 506 713. In this, each coin entered through a single existing slot is checked by means of five test signals before a service is triggered by it. The test signals are supplied by a metal detector, a test detector to which two voltages of different frequencies are applied when the coin is at rest, a test detector for the rolling coin and a mass detector and evaluated in an evaluation device before the coin is cashed in order to release the service or one is not perfect coin is passed into a return bowl.

The invention is based on the object, by means of the test detectors for determining the alloy and the diameter of the coin, to enable a flawless coin check, which is not influenced by the effects of temperature, aging and external interference, by means of a less complex control device.

This object is achieved by the features of the characterizing part of patent claim 1.

An embodiment of the invention is explained in more detail with reference to a drawing. It means:

Fig. 1 is a simplified perspective view testing device for the alloy and the diameter of a coin and

Fig. 2 is a block diagram of the test facility.

The testing device 1 according to FIG. 1 according to the invention has a rolling track 2 for a coin 3, to which two rod cores 4 and 5 of a first test detector 6 are arranged in the transverse direction for testing the alloy. Following the first test detector 6, a stopper 7 is attached to the unrolling path 2, which controls the passage of the coin 3 through the first test detector 6 and then through a second test detector 8 which is sensitive to the diameter of the coin 3 entered. This second test detector 8 consists of two magnetic cores 9 and 10 which are arranged on both sides of the unrolling path 2 and mirror images of it, which are rectangular in cross-section and upright with respect to the unrolling path 2. Each winding 11 and 12 is on the rod cores 4 and 5 and on the magnetic cores 9 and 10 each have a winding 13 and 14 attached. The windings 11, 12, 13 and 14 are connected on one side to the ground.

2, a tone generator 15, a switch 16 which can be applied to the windings 11 and 13, a further switch 17 which switches the windings 12 and 14, a phase comparator 18, a peak voltage detector 19 and a switch 20 are connected with the outputs of the phase comparator 18 and the peak voltage detector 19, a voltage comparator shown in the form of a voltage detector 21 and an evaluation device 22.

The switching arm of the switch 16 is connected to an output of the tone generator 15. A further connection from the tone generator 15 is to a first input of the phase comparator 18, from which a second input is connected to the switching arm of the switch 17, which is also connected to an input of the peak voltage detector 19. The switching arm of the switch 20 is applied to the voltage detector 21.

The tone generator 15 contains a frequency synthesizer with a crystal oscillator (not shown) for an alternating voltage of high frequency and with a frequency divider (also not shown) with several taps. The phase comparator 18 has two inputs, the first with the output of the tone generator 15 and the second with the switching arm. of the switch 16 is connected. At the output of the phase comparator 18, a voltage U0c corresponding to the maximum phase difference A <p occurs.

The peak voltage detector 19 contains a low-pass filter in the output, the time constant of which is controlled by a control circuit

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24 can be changed. At the output of the peak voltage detector 19 there is a voltage, also designated U0c. A low-pass filter, not shown, is arranged in the input to the voltage detector 21.

The evaluation device 22 contains, among other things, three control circuits 23, 24 and 25 and a memory 26. The first control circuit 23 is connected to the tone generator 15. In addition to the time constant of the peak voltage detector 19, the second control circuit 24 controls the two changeover switches 16 and 17. The changeover switch 20 is controlled by the control circuit 25. The voltage detector 21 is connected to the memory 26 in the evaluation device 22. The evaluation device 22 preferably consists of a microprocessor.

The test device 1 acts in the following way:

The evaluation device 22 and the tone generator 15 are equipped with a switch for commissioning, e.g. connected to a hook switch of a telephone set. During commissioning, a switchover of the sequence control in the evaluation device 22 starts a calibration of the test device 1 before the coin check. This happens in three phases. In the first phase, the control circuit 23 controls the tone generator 15 in the evaluation device 22 so that it successively generates two alternating voltages Up with different frequencies, e.g. 6.25 kHz and 12.5 kHz. The corresponding tap is connected to the output of the tone generator 15 in the frequency divider of the tone generator 15. An alloy of coin 3 with copper or nickel responds to the first frequency of 6.25 kHz and iron as an alloy component to the second frequency of 12.5 kHz. The control circuit 24 in the evaluation device 22 uses the switch 16 to connect the tone generator 15 to the winding 11 of the rod core 4 in the first test detector 6, and furthermore by means of the switch 17 to connect the winding 12 of the rod core 5 of the first test detector 6 to the peak voltage -Detector 19 and by means of the switch 20 a connection between the peak voltage detector 19 and the voltage detector 21. The voltage Uoc measured by the peak voltage detector 19 is measured in the voltage detector 21. The amplitude of the AC voltage of the tone generator 15 is now changed until a predetermined voltage (e.g. 2.5 V) is reached in the voltage detector 21. The set value of the alternating voltage of the tone generator 15 is now stored in the memory 26 of the evaluation device 22 in accordance with the selected frequencies.

In the second phase, the tone generator 15 is caused to output a voltage Up with a frequency of 12.5 kHz. Switches 16 and 17 remain in the same position in this phase as in the first phase. However, the switch 20 connects the phase comparator 18 to the voltage detector 21. The phase shift between the voltage U ″ at the output of the tone generator 15 and a voltage Us at the winding 12 is converted in the phase comparator 18 into a corresponding output voltage U0c. This generates an output voltage Um in the voltage detector 21, which is written into the memory 26 of the evaluation device 22.

In the third phase, the voltage Up of the tone generator 15 is applied to the winding 13 of the magnetic core 9 of the second test detector 8 by means of the switch 16. The winding 14 of the magnetic core 10 of the second test detector 8 is connected to the peak voltage detector 19 by the switch 17 and the latter is connected to the voltage detector 21 by means of the switch 20. The set value of the amplitude of the AC voltage of the tone generator 15 is derived, as described in the first phase, and stored in the memory 26 of the evaluation device 22.

The three phases of the verification take place after commissioning before the arrival of a inserted coin 3. There is no coin during the verification. Measurement errors are eliminated due to the calibration and measurement procedure. The inserted coin 3 is stopped on the rolling path 2 between the rod cores 4 and 5 by the stopper 7. The rod cores 4 and 5 are dimensioned such that their cross-section is also completely covered by the end faces of the smallest coin 3 which is stationary there. The entire check of the inserted coins 3 takes place in three phases, as in the verification. The tone generator 15 is programmed for each measurement with the corresponding amplitude value found in the calibration phase. The individually determined voltages Um at the output of the voltage detector 21 are stored in the memory 26 of the evaluation device 22 until the entire test of the coins 3 has been completed.

Only the magnetic properties of the alloy of the coin 3 are checked in the first phase by means of the windings 11 and 12 of the rod cores 4 and 5 of the test detector 6 with the coin 3 at a standstill. Since the inserted coin 3 bounces through the stopper 7 when stopped, the measurements of the first phase are repeated until three successive measurements lead to the same result. Only then will the measurement program continue.

In this first phase of the coin check, an AC voltage is applied to the winding 11 of the rod core 4 of the test detector 6 one after the other with the frequencies of 6.25 kHz and 12.5 kHz. In the winding 12 of the rod core 5 coupled with this in the manner of a transformer, weakened voltages Us are induced by the alloy of the coin 3, which are measured and stored as in the first phase.

Immediately after the release of the runway 2 of FIG. 1 by an actuation magnet for the stopper 7, which is not shown, the measurement of the second phase takes place by means of the test detector 6 at a still low speed of the coin 3 as soon as it starts to move on the inclined run-off track 2. The phase comparator 18 measures the shift of the phase of the alternating voltage Us with the higher of the frequencies of the first phase, e.g. 12.5 kHz, at the output of the winding 12 with respect to the output voltage Up of the tone generator 15. The phase-dependent voltage U0c determined is transmitted to an input of the voltage detector 21 when the switch 20 is in the assigned position. The voltage Um corresponding to the largest phase-dependent voltage U0c at the output of the voltage detector 21 is stored in the memory 26 of the evaluation device 22. The corresponding value depends on the type of alloy of the coin 3, its thickness and its diameter.

The coin 3 then rolls further through the space between the magnetic cores 9 and 10 of FIG. 1, the coin diameter being checked. The winding 13 on the magnetic core 9 is connected in this third phase of the coin check by means of the switch 16 to the output of the tone generator 15. Under the influence of the control circuit 23 of the evaluation device 22, this provides an alternating voltage Up with a higher frequency than in the first two phases, for example of 62.5 kHz, in which the type of alloy of the coin 3 has at most a very slight influence on the measurement of the diameter. Depending on the diameter of the coin 3, a more or less large voltage Us arises at the associated winding 14 of the magnetic core 10, which is transmitted to the peak voltage detector 19 by means of the switch 17. This voltage Us passes through a minimum when the center of the coin 3 passes through the space between the magnetic cores 9, 10. This minimum voltage Us represents a criterion for the coin diameter. In this third phase, the time constant of the peak voltage detector 19 is switched off by the control circuit 24.

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Value device 22 lowered. As a result, the peak voltage detector 19 can follow the rapidly changing AC input voltage Us. The output voltage U0c of the peak voltage detector 19 is transmitted by means of the switch 20 to the voltage detector 21 and the voltage Um at its output to the memory 26 of the evaluation device 22.

After all tests for the coin 3 have been carried out by means of the test detectors 6 and 8, an arithmetic unit in the evaluation circuit 22 determines whether the stored measured values are all within the assigned minimum and maximum values stored in the memory 26. If the result of this test by the evaluation circuit 22 is positive, a signal for collecting the checked coins 3 and for releasing the corresponding service appears at its output 27, or else a blocking signal for the service and a signal for redirecting the coins 3 into the return tray .

Of course, 3 or more tests can be carried out before or after the test for the alloy and the diameter of the coin, e.g. for the excretion of plastic discs or the mass of the coin 3, take place. However, these are less influenced by changes in temperature, external interference or aging, against which the device according to the invention provides particularly good protection.

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Claims (8)

664 839 1. A device for testing coins of different values with a first test detector for the alloying of the coins, which can be acted upon in succession with voltages of different frequencies, with a stopper arranged in a rolling path for the coins, a second test detector for the diameter of the coins arranged after this, and one Evaluation device for both test detectors, characterized in that the evaluation device (22) controls the tone generator (15) by means of a first control circuit (23) and changeover switches (16, 17, 20) for transmitting a by means of a second and third control circuit (24, 25) Test voltage (Uoc) actuated in a voltage detector (21) and that the output voltage (Um) of the voltage detector (21) is transmitted to a memory (26) of the evaluation device (22). 2. Device according to claim 1, characterized in that a changeover switch for the sequence control in the evaluation device (22) is designed such that the test detectors (6, 8) are calibrated before each coin (3) is checked. 2nd PATENT CLAIMS 3. Device according to claim 1, characterized in that after the calibration and after all tests of a coin (3) the associated values in the memory (26) are compared by the evaluation device (22) and a corresponding signal at the output (27) of the Evaluation device (22) is output. 4. Device according to claim 1, characterized in that the evaluation device (22) for generating an AC voltage (Up) certain frequency by means of the control circuit (23) in the tone generator (15) a connection between a tap of a controlled by a higher quartz frequency divider with the output of the tone generator (15) and by means of the control circuit (23) the amplitude of the tone generator (15) is changed. 5. Device according to claim 1, characterized in that by the second control circuit (24) controlled switch (16, 17) optionally a connection for the signal of the tone generator (15) via the first test detector (6) to a phase comparator ( 18) or a peak voltage detector (19) or via the second test detector (8) to produce the peak voltage detector (19). 6. Device according to claim 1, characterized in that by the third control circuit (25) controlled switch (20) either a connection of the phase comparator (18) or the peak voltage detector (19) with the voltage detector (21) can be produced. 7. Device according to claim 1, characterized in that the voltage detector (21) is a voltage comparator in which the voltage applied to an input (U0c) is processed and the voltage (Um) at its output to the memory (26) in the evaluation device (22) is transmitted. 8. Device according to claim 6, characterized in that in order to calibrate and to test a coin (3) in a first phase two voltages (Up) of different frequencies from the tone generator (15) via the first test detector (6) to the peak voltage detector ( 19), then in a second phase a voltage (Up) with the higher of the two frequencies via the first test detector (6) on the phase comparator (18) and finally in a third phase a voltage (Up) with a higher frequency than in the first two phases is transmitted to the peak voltage detector (19) via the second test detector (8).