FR2569886A1 - Checker for coins of different values - Google Patents

Abstract

Checker for coins of different values, with a first test detector 6 for the alloy, charged successively by voltages of various frequencies delivered by a generator BF 15, a stop on the slide for the coins, a second test detector 8 for the diameter of the coins, mounted downstream from the stop, and a transducer device 22. The transducer device 22 controls the generator BF 15 and inverters 16, 17, 18 for transmission of a checking voltage UQC to a voltage detector 21 and stores its output voltage Um in a memory 26. When put into service, a calibration of the test detectors 6, 8 is carried out before checking a coin, so as to eliminate the influence of temperature variations, external perturbations and of ageing. After calibration and all the checks on a coin, the corresponding values are compared in the memory 26 then an appropriate signal is delivered.

Description

 The present invention relates to a controller of coins of different values, with a first alloy test detector, loaded successively by voltages of different frequency delivered by a LF generator, a stopper disposed on the slide for the coins, a second test detector for the diameter of the parts, mounted downstream of the stop, and a device for translating the two test detectors.

 The subject of Swiss patent application no. 2 904 / 84-0 is a parts controller. In the latter, each piece inserted through the single slot is checked using five signals before triggering a service. The control signals are delivered by a metal detector, a test detector to which two voltages of different frequency are applied, the part being stationary, a test detector for the rolling part and a mass detector, then translated into a device before that the part is collected to authorize the provision of service or, in the case of an imperfect part, direct it to a refusal cup.

 The invention aims, using test detectors for determining the alloy and the diameter of the coin, to allow perfect coin control, not influenced by temperature, aging and external disturbances, by means of an inexpensive control device.

 According to an essential characteristic of the invention, the translator device controls the LF generator via a first control circuit and actuates, through a second and a third control circuit, inverters for transmitting a control voltage to a voltage detector; and the output voltage of the voltage detector is transmitted to a memory of the translator device.

 Other characteristics and advantages of the invention will be better understood with the aid of the detailed description below of an exemplary embodiment and of the appended drawing in which FIG. 1 is the simplified perspective view of a controller. the alloy and diameter of a coin; and Figure 2 shows the block diagram of the controller.

 The controller 1 according to the invention, shown in FIG. 1, comprises a slide 2 for a coin 3 and, perpendicular to said slide, the straight cores 4 and 5 of a first test detector 6 monitoring the alloy. After the first test detector 6, a stop 7 is placed on the slide 2 and controls the passage of the part in the first test detector 6 then in a second test detector 8, sensitive to the diameter of the part 3 introduced. This second test detector 8 is constituted by two magnetic cores 9 and 10 of rectangular section, arranged on either side of the slide 2, symmetrically and on edge relative to the latter. The straight cores 4 and 5 each carry a winding 11 or 12 and the magnetic cores 9 and 10 each a winding 13 or 14. One end of each of the windings 11, 12, 13 and 14 is grounded.

 The block diagram of FIG. 2 represents a BF generator 15, an inverter 16 connected to the windings 11 and 13, a second inverter 17 switching the windings 12 and 14, a phase comparator 18, a peak voltage detector 19, an inverter 20 connected to the outputs of the phase comparator 18 and of the peak voltage detector 19, a voltage comparator represented in the form of a voltage detector 21 and a translator device 22.

 The movable arm of the inverter 16 is connected to an output of the generator BF 15. The latter is also connected to a first input of the phase comparator 18, a second input of which is connected to the movable arm of the inverter 17, which is further connected to an input of the peak voltage detector 19. The movable arm of the inverter 20 is connected to the voltage detector 21.

 The generator BF 15 contains a frequency synthesizer with a quartz oscillator not shown delivering a high frequency alternating voltage, and with a frequency divider with several taps, also not shown. The phase comparator 18 has two inputs, the first of which is connected to the output of the LF generator 15 and the second to the movable arm of the inverter 16.

A voltage Uoc corresponding to the maximum phase difference Ad appears at the output of the phase comparator 18.

 The peak voltage detector 19 comprises at the output a low-pass whose control circuit 24 can vary the time constant. A voltage also designated by U0c appears at the output of the peak voltage detector 19. A low-pass not shown is disposed at the input of the voltage detector 21.

 The translator device notably comprises three control circuits 23, 24, 25 and a memory 26. The first control circuit 23 is connected to the generator BF 15. In addition to the time constants of the peak voltage detector 19, the second circuit 24 controls the two inverters 16 and 17. The inverter 20 is controlled by the circuit 25. The voltage detector 21 is connected to the memory 26 of the translator device 22. The latter is advantageously constituted by a microprocessor.

 The operation of the controller 1 is as follows.

the translator device 22 and the generator BF 15 are for commissioning connected to a switch, such as the switch support of a telephone set. During commissioning, a switching of the sequential control in the translator device 22 initiates a calibration of the controller f before checking the part. This operation is carried out in three phases. During the first phase, the circuit 23 of the translator device 22 controls the generator BF 15 so that it successively delivers two alternating voltages U of different frequency, for example 6.25
p kHz and 12.5 kHz. The corresponding socket of the frequency divider is connected in the LF generator 15 to the output of the latter. An alloy of part 3 containing copper or nickel reacts at a frequency of 625 kHz and an alloy containing iron reacts at the second frequency of 12.5 kHz. The control circuit 24 of the translator device 22 establishes, using the inverter 16, a connection between the generator BF 15 and the winding 11 of the right core 4 in the first test detector 6, using the inverter 17, a link between 1 1 winding 12 of the right core 5 of the first test detector 6 and the peak voltage detector 99, and using the inverter 20, a link between the peak voltage detector 19 and the voltage detector 21. The voltage UOC delivered by the peak voltage detector 19 is measured by the voltage detector 21. The amplitude of the alternating voltage delivered by the generator BF 15 is then modified until a predetermined voltage (of 2.5 v for example) is reached in the voltage detector 21. The value for adjusting the alternating voltage of the generator BF 15 is then stored in the memory 26 of the translator device 12, as a function of the frequencies selected .

During the second phase, the generator BF 15 delivers a voltage Up at a frequency of 12.5 kHz. Inverters 16 and 17 occu
p during this phase the same position as during the first phase. The inverter 20 however connects the phase comparator 18 to the voltage detector 21. The phase shift between the voltage U at the output
p from generator BF 15 and a voltage U across the terminals of winding 12
s is converted in the phase comparator 18 into a corresponding output voltage Uoe. The latter produces in the voltage detector 21 an output voltage Um which is stored in the memory 26 of the translator device 22.

 During the third phase, the voltage U of the generator BF 15 p is applied by the inverter 16 to the winding 13 of the magnetic core 9 of the second test detector 8. The inverter 17 connects the winding 14 of the eating core 10 of the second test detector 8 to the peak voltage detector 19, which the inverter 20 connects to the voltage detector 21. The value for adjusting the amplitude of the alternating voltage of the generator BF 15 is determined as described for the first phase, then stored in the memory 26 of the translator device 22.

The three phases of calibration are carried out after commissioning and before the impact of a part 3 inserted. The stop 7 stops the part 3 introduced on the slide 2, between the straight cores 4 and 5. The latter are dimensioned so that their section is completely covered even by the front faces of the smallest part 3 immobilized therebetween. The complete inspection of the 3 parts introduced is carried out in three phases, such as calibration. The generator BF 15 is programmed for each measurement using the corresponding amplitude value, found during the calibration phase. The various voltages U determined at the
m output of the voltage detector 21 are stored in the memory 26 of the translator device 22 until the end of the complete control of the parts 3.

 Only the magnetic properties of the alloy of the part 3 are controlled during the first phase, by the windings 11 and 12 of the straight cores 4 and 5 of the test detector 6, the part 3 being stationary. The introduced part 3 rebounding when it is stopped by the stop 7, the measurements of the first phase are repeated until three successive measurements give the same result.

The measurement program then continues only.

 During this first phase of the part control, and as for the calibration, an alternating voltage is applied successively with a frequency of 6.25 kHz then 12.5 kHz to the winding 11 of the right core 4 of the test detector 6. In the winding 12 of the right core 5, coupled to the winding 11 in the manner of a transformer, the alloy of the part 3 induces weakened voltages Us, which are measured and stored as in the first phase of the calibration.

Immediately after the slide 2 of FIG. 1 has been released by a magnet (not shown) for operating the stop 7, the measurement of the second phase is carried out by the test detector 6 at an even lower speed of the part 3, from that the latter sets in motion on the inclined slide 2. The phase comparator 18 then measures, as for the calibration, the phase shift of the alternating voltage Us at the highest of the frequencies of the first phase, ie 12.5 kHz for example, at the output of the winding 12 relative to at the output voltage U of the generator BF 15. The voltage UOC p as a function of the phase thus determined is applied to an input of the voltage detector 21, at the corresponding position of the inverter 20. The voltage U of the detector output tension 21, corres
m laying down at the maximum voltage UOC as a function of the phase, is stored in the memory 26 of the translator device 22. The corresponding value depends on the nature of the alloy, on the thickness and on the diameter of the part 3.

The part 3 then rolls in the gap between the magnetic cores 9 and 10 of FIG. 1, where the diameter is checked. The winding 13 of the magnetic core 9 is, during this third phase of the control of the part, connected by the inverter 16 to the output of the generator BF 15. The latter then delivers, under the influence of the control circuit 23 of the device translator 22, an AC voltage U at a frequency higher than that of the first two p phases, of 62.5 kHz for example, at which the nature of the alloy of part 3 exerts at most a very small influence on the measurement of the diameter. Depending on the diameter of the part 3, a greater or lesser voltage Us appears at the terminals of the corresponding winding 14 of the magnetic core 10, then is applied by the inverter 17 to the peak voltage detector 19.
U goes through a minimum when the center of part 3 crosses the es
s space between the magnetic cores 9 and 10. This minimum voltage U constitutes a criterion for the diameter of the part. during
s this third phase, the control circuit 24 of the translator device 22 decreases the time constant of the peak voltage detector 19. The latter can thus follow the rapid variations of the alternating input voltage Us. The output voltage UOC of the peak voltage detector 19 is applied by the inverter 20 to the voltage detector 21, the output voltage U of which is transmitted
m to the memory 26 of the translator device 22.

 After all the checks of part 3 by the test detectors 6 and 8, an calculator housed in the translator circuit 22 determines whether the stored measured values are all between the corresponding minimum and maximum values stored in memory 26. In the event of positive result of this check by the translator circuit 22, the output 27 of the latter delivers a signal for the collection of the pieces 3 checked and the authorization of the corresponding service provision; otherwise, this output delivers a signal blocking the provision of service and a signal returning the parts 3 in the refusal cup.

 The control of the alloy and of the diameter of the part 3 can obviously be preceded or followed by other controls, for example for the elimination of plastic washers or of the mass of the part 3. These controls are however even less influenced by temperature variations, external disturbances or aging, against which the controller according to the invention is particularly well protected.

 Of course, various modifications can be made by those skilled in the art to the principle and to the devices which have just been described only by way of nonlimiting examples, without departing from the scope of the invention.

Claims (8)

Claims 1. Controller of coins of different values, with a first alloy test detector, successively charged by voltages of different frequency delivered by a generator BF, a stopper arranged on the slide for the pieces, a second test detector for the diameter of the pieces, mounted downstream of the stopper, and a translator device of the two test detectors, said controller being characterized in that the translator device ( 22) controls the LF generator (15) via a first control circuit (23) and actuates, through a second and a third control circuit (24, 25), inverters (16, 17, 20) for the transmission of a control voltage to a voltage detector (21); and the output voltage (Um) of the voltage detector (21) is transmitted to a memory (26) of the translator device (22). 2. Controller according to claim 1, characterized in that an inverter for the sequential control in the translator device (22) is carried out so that a calibration of the test detectors (6, 8) precedes the control of each part (3 ). 3. Controller according to claim 1, characterized in that after the calibration and then the sequence of all the checks of a part (3), the corresponding values are compared in the memory (26) by the translator device (22) - , which then delivers an appropriate signal at its output (27). 4. Controller according to claim 1, characterized in that for the production of an alternating voltage (U) of determined frequency, p the translator device (22), using the control circuit (23) established in the generator BF (15) a connection between a tap of a divider attacked by the frequency of a quartz and the output of the LF generator (15) and varies the amplitude of the latter. 5. Controller according to claim 1., characterized in that the inverters (16, 17) controlled by the second control circuit (24) optionally establish a connection between the LF generator (and, by the first test detector (6) , a phase comparator (18) or a peak voltage detector (19), or, by the second test detector (8), the peak voltage detector (19). 6. Controller according to claim 1, characterized in that the inverter (20) controlled by the third control circuit (25) optionally establishes a connection between the phase comparator (18) or the peak voltage detector (19) and the voltage detector (21). 7. Controller according to claim 1, characterized in that the voltage detector (21) is a voltage comparator which processes the voltage (UOC) applied to an input, then delivers its output voltage (Um) to the memory (26) of the translator device (22). 8. Controller according to claim 6, characterized in that for the calibration and control of a part (3), the LF generator (15) delivers, during a first phase, successively two voltages (Up) of different frequency to the detector peak voltage (19), by the first test detector (6); during a second phase, a voltage (Up) at the higher of the two frequencies at the phase comparator (18), by the first test detector (6); and during a third phase, a voltage (Up) at a frequency greater than  p those of the first two phases at the peak voltage detector (19), by the second test detector (8).