DK151418B - PROCEDURE AND APPARATUS FOR DETERMINING THE AUTHENTICITY AND VALUE OF A MINUTE - Google Patents

Description

151418

The present invention relates to a method for determining the authenticity and value of coins and for rejecting unwanted and counterfeit coins, washers, etc., which is of the kind set forth in the preamble of claim 1.

Coin-operated appliances, such as vending machines, coin-exchange machines and fee collection devices, are universally prevalent, and the extent of their use is constantly growing. Each coin operated apparatus must be capable of determining the authenticity and value of certain coins entering the apparatus and such determination must be made accurately and promptly. There are many coin voters, but the reliability and sensitivity of the voters used is less than desirable. Given that the value of products and * services - A - ·. . > al i I 1 1 2 151418, the accuracy required to avoid significant financial loss is far greater than the accuracy achieved with existing appliances.

Furthermore, existing appliances are extremely complicated in design and operation. They often involve many moving parts and alignment and exact placement of many mechanical elements. These devices require accurate settings of such elements for particular coins and thus necessitate the constant maintenance of professionals including cleaning, repair and replacement of parts in order for the device to function properly. Due to the sensitivity of these devices, they also require careful and accurate installation. Evidently, these factors make the initial cost of the appliance, installation and maintenance very high, since in each case highly trained personnel must be used.

Another major drawback of these appliances is their limited coin approval range, usually up to three coins. Once installed, it is expensive to modify the device to receive other or additional coins. Given that the prices of goods are constantly changing or that the coin shape is sometimes changed, as happened in England in 1968, the existing vending machines have to be significantly changed to take these factors into account. The reliability of mechanical systems for categorizing the coins clearly requires different internal settings for different countries and thus prevents the possibility of them being made internationally flexible in use. Furthermore, a finer determination of value and authenticity is often required, as coin types in many countries can be an excellent imitation when used in coin-operated appliances in other countries.

It is e.g. from the specification to German Patent No. 551.8o9 and U.S.A. Patent No. 2,186,865 is known to sort coins by magnetic influence of the coins in various ways, e.g. by changing the coin's runway. It is further known from the specification of French Patent No. 1,4ol,488 to perform a relatively coarse check of a chord in a coin by means of a number of magnetic or photoelectric detectors located at different distances from a stop against the coin.

In Patent Application No. 3716/68, it is known to be; troll coins by controlling the time between a coin's passage of a sensor before and after a magnetic field, respectively. Furthermore, it is known to control the time of passage of a coin past a sensor following the magnetic field. Thus, in the former case, the coin's velocity in the magnetic field is investigated, and in the second case, a function which is dependent on both a chord dimension of the coin and its velocity is examined.

The object of the present invention is to provide a method for determining the authenticity and value of a coin with an increase in speed and accuracy relative to the above methods, and according to the invention this is achieved by carrying out the method as set forth in claim 1. This gives us a study of two properties of the coin, namely its conductivity and its chord dimension. Conductivity is measured by examining the coin velocity between two points after passing through a magnetic field which causes a coin delay that is directly proportional to the electrical conductivity to density ratio of the coin material. Thus, the velocity examined is essentially the final velocity after the magnetic delay. The chord dimension of the coin, such as its diameter, is determined while the coin is still moving along the channel. The chord dimension signal is made essentially independent of the velocity of the coins, either by modifying the chord dimension signal in dependence on information representing the deviation of the velocity of the coins from a standard velocity, using a time-dependent examination of the chord dimension for a small percentage of the chord dimension, or by using a time-independent chord dimension study. Thus, since the two measurements are independent of each other, greater accuracy can be obtained than the previous methods, and the studies are carried out with great rapidity as they are both made as the coin passes through the channel, the movement of the coin not being stopped when first has been released from a resting position.

In one embodiment of the method according to the invention, which is characterized by that of claim 2, a more accurate coin distinction is obtained, thereby making the coin examination less dependent on the initial rate of the coin. In the embodiment of claim 3, the chord dimension is measured in a speed dependent manner, correcting for variations in the speed using a signal representing the coin speed. In the embodiment of the method according to the invention set out in claim 4, the examination of the chord dimension is only time dependent during a small percentage of the measurement, while claim 5 indicates a time independent examination of the coins. In the embodiment according to claim 6, both the chord dimension and the speed of counting pulses are measured, which gives a digital indication of the values of the coin examined, which can easily be compared with figures for acceptable coins, which numbers are stored in the apparatus register. 7 discloses that an overall value of coins thrown into the apparatus can be achieved. is calculated so that this value can be compared with the values of the goods to be sold.

The invention further relates to an apparatus for carrying out the method, which apparatus is characterized by the one of claim 8. In the embodiment of the device according to the invention as claimed in claim 9, which relates to the resetting of the comparator circuit, the resetting is delayed by a monostable circuit until the last possible time before the coin is measured, to reduce the possibility of different elements of the comparator circuit, such as flip-flops or counters, set or triggered by electrical noise signals, e.g. from nearby industrial equipment. In order to prevent signals from being passed to the accumulator in the event of a coin being blocked in the mechanism, the apparatus of the invention may be designed as set forth in claims 101 and 11. If the coin has not passed said additional coin sensor before the pulse generator stops, the indicator will output a signal indicating that the coin is blocked.

A special arrangement for examining the coin speed is given in claim 12.

Claims 13-19 specify three different arrangements for examining the chord dimension of a coin, and Claims 2o and 21 specify embodiments of the apparatus for compensating for speed variations. In the embodiment of claim 20 in connection with the embodiment of claim 12, an arrangement is provided to compensate for variations in the initial velocity of a coin by examining the velocity of the coin exiting the magnetic field. In connection with the embodiment according to claim 13, the speed compensation has the effect of compensating for variations in the speed when measuring chord dimensions. Claims 14,15 and 16 indicate the arrangements which use a time-dependent study only under a small percentage of the chord dimension measurement. Claims 17, 18 and 19 specify means for examining the chord dimension of the coin independently of its velocity. The chord dimension detector according to claims 14, 15 and 16 has the advantage that fewer sensors are used than in the detector according to claims 17, 18 and 19. It can also be easily adapted to. use with other coin sets. On the other hand, according to claims 17, 18 and 19, the detector performs the chord dimension independently of the coin speed.

Claim 22 indicates the preferred form of sensor which provides a very accurate indication of when the coin passes the sensor.

The invention will now be explained in more detail with reference to the drawing, in which fig. 1 is a schematic electronic block diagram of a coin sensor designed in accordance with a first embodiment of the invention; FIG. 2a and 2b are electronic block diagrams showing the coin sensor circuit of FIG. 1, FIG. 2b is a continuation of FIG. 2a, fig. 3 is a sectional view of the coin sensor of FIG. 1, FIG. 4 is a sectional view taken along line 4-4 of FIG. 3 and showing a magnetic coin ejector; FIG. 5 is an end view of FIG. 3 showing a coin approval control mechanism; FIG. Figure 6 is a schematic electronic block diagram of a coin sensor designed in accordance with another embodiment of the invention; 7 is an electronic block diagram showing the circuit of the coin sensor of FIG. 6, and FIG. 8 is a schematic electronic block diagram of a coin sensor designed in accordance with a third embodiment of the invention.

Throughout the specification and claims, the term "coin" shall mean real coins, counterfeit coins, gaming coins, washers, and any other object which may be used by persons in an attempt to operate coin operated apparatus.

In FIG. 1-3 of the drawings are shown in schematic form a coin selector 100 having a housing 12 with a coin insertion slot 14. The coin insertion column is slightly larger than the diameter of the largest coin to be approved by the coin selector. The coin enters a coin channel 15 and falls onto an inclined surface or groove 16 where it is prevented from further movement by a retractable stop such as a stop pin 18. Stopping the coin at this location serves to ensure that all coins of the same size begin movement through the sensor at the same initial velocity so as to obtain a predictable appearance. A magnetic coin separator 20 in the form of a movable magnet, described in detail below, is positioned near the stop 18. The strength of the magnet is chosen such that some coin 5o has a ratio of magnetic permeability to density that exceeds a predetermined amount. value, will be attracted to the separator 2o and prevented from moving further through the coin selector 1o. To ensure that such coins are attracted to the separator (Fig. 4).

Also adjacent to the stop 18 is a coin sensor 21 which serves to determine the presence of a coin in the selector 1o. After a predetermined interval of time commencing with the sensing of the presence of a coin by means of the coin sensor 21, the stop 18 is removed from the coin path and the coin rolls down the inclined track 16 passing a number of sensing means 22, such as photoelectric means, and rolls through a magnetic field produced by a magnet 23. The sensing means 22 having each of their amplifiers A and the electronic combination circuit in which they are incorporated are described in detail below. Briefly, they sense the velocity of the coin and the length of a chord, and compare these factors with predetermined signals characteristic of coins that can be approved. After passing the sensing means, the coin leaves the inclined track 16 and descends vertically downward on a sloping platform 24. If the coin is acceptable, a coin directional control solenoid 25 (see Fig. 5) is activated, which withdraws the platform 24 from the coin's path and allows the coin to fall into an approval channel 26. If the coin is not genuine or does not have the correct value to be approved, the sensors do not activate the coin directing controls 25 and the coin will hit the platform 24 and bounce back into an eject channel 27.

Since the coin selector 1o uses a magnetic field in the coin's orbit as part of the sensing system to assess whether the coin can be approved, it is necessary to remove a strong magnetic coin, such as an iron disc, from the system before entering the magnetic field. If the magnetic coin is not removed and the ratio of its magnetic permeability to density is greater than a predetermined value, it will attach to the magnetic section of the selector, and means would then be provided to remove the magnetic coin from the selector.

To avoid this problem, a magnetic coin separator 20 is used, which removes magnetic coins at the beginning of the channel 15 before beginning to migrate through the selector 1o. As the coin enters the coin selector, its movement as described above is stopped by the impact member 18 in the vicinity of the magnetic coin separator 20. The separator comprises a solenoid 28 with an anchor 30 attached to a support bracket 32 which is pivotally mounted at one end 34 on the housing 12. The other end of the bracket 32 carries a permanent magnet 36, the pole surfaces of which are covered by a plate. 38 of low-friction plastic material such as polytetrafluoroethylene (Teflon). The plastic sheet forms one wall of the channel at the beginning thereof, the housing 12 forming the other wall. The strength of the magnet 36 and the thickness of the magnetic coin are sufficient to cause substantially horizontal displacement of the coin, but are insufficient to provide sufficient frictional force to counteract the forces acting on the coin. As shown in FIG. 4, the width of the inclined track 16 is minimal, e.g. ca. 4.8 mm. When the solenoid is actuated to remove magnetic coins, the groove 16 supports the coin while the magnet 36 is withdrawn from the channel, causing the coin to shift horizontally (in Fig. 4 to the right) until the coin has moved outside the groove 16. At this moment gravity is exerted on the coin and the combination of the strength of the magnet 36 and the low coefficient of friction of the plastic sheet produces a frictional force which is insufficient to withstand the forces of gravity, allowing the coin to fall directly into a coin return channel 4o leading to the coin ejector 27 .

The coin analysis system can be divided into four parts to facilitate explanation, namely a "start" control system 42, a speed normalization circuit 44, a coin material and diameter sensing circuit 46, and an accumulator 48.

To first explain the starting control system 42, the coin presence sensor 21 is positioned near the stop pin 18, The sensor 21 as well as the other sensors 22 in the system to be described below may be any of the usual sensors or detectors such as inductive switches, photoelectric organs, etc. However, photoelectric organs and in particular photocells are preferred, and in the following, special reference is made to such. A light source not shown and the photocell 21 are disposed on opposite sides of the track 16. The light source may be single light bulbs or preferably fluorescent lamps supplied from a single light supply source. An arriving coin shown by dashed lines 5o is brought to rest by the stop pin 18 in such a position that the light is excluded from the sensor 21, which triggers four multivibrators, a stop-tap multivibrator 52 over the signal generated by closing the sensor, a magnetic coin separator multivibrator 54, a reset multivibrator 56, and a coin blocking detector multivibrator 58. The multivibrators are set to change state in sequence as follows and for the following reasons. The first multivibrator to change condition is the stop tap multivibrator 52 which, when changing the mode, activates a solenoid 6o which removes the stop pin 18 from the coin's path and allows the coin to begin wandering down the inclined track 16. The stop tap multivibrator 52 is set to to change state immediately after the coin is brought to rest, on the order of 3oo milliseconds, after the sensor 21 is turned off.

As soon as it can be assumed that a non-magnetic coin has passed the first sensor 21 and the magnetic coin separator 20, the separator multivibrator 54 is caused to change state. If the coin still shuts off the first coin sensor 21, two signals, one from the sensor 21, and an inverse signal from the multivibrator 54, and an AND gate 62 triggering the separator solenoid 28 to remove the magnetic coin that has become attracted by the separator magnet 36 and thereby prevented from moving past the sensor 21.

If the coin does not have sufficient magnetic permeability to cause it to be held by the magnetic coin separator 20, it continues to roll through channel 15 as soon as the pin 18 is removed from its path. along the side of the channel are mounted in the following order a pair of sensors 64.65, the magnet 23 and another pair of sensors 66.67. The first pair of sensors 64.65 senses the velocity of the coin immediately before it enters the magnetic field produced by the magnet 23. The second pair of sensors 66.67 senses the velocity of the coin as it exits the magnetic field.

The magnet 23 which may be a permanent magnet or an electromagnet is disposed on one side of the channel 15. Another magnet or plate (not shown) of ferromagnetic material, such as soft steel, may be placed directly opposite the magnet 23 to provide a constant flux field across channel 15. As the coin passes through the magnetic field, eddy currents are induced in the coin, and the accompanying magnetic fields interact with the permanent magnet to create a braking force. The magnitude of the force exerted on the coin is proportional to the square of the magnetic flux density and is directly proportional to the coin entry rate in the magnetic field, and the coin's "approval ratio" defined as the coin's electrical conductivity divided by its density. such a strength as to reduce the velocity of the coins to pass through the system by between 10 and 5o, the more accurate the system, the greater the reduction in velocity. The change in the coin velocity as it passes through the magnetic field, is used as the one measure in determining the authenticity and value of the coin.

The use of an electromagnet to produce the magnetic field gives the coin selector lo a considerable flexibility as the strength of the magnetic field can be easily changed. With an electromagnet 151418, only a basic magnetic unit is required for all coins from all countries and the strength of the magnetic field can be chosen to take into account the altered metallic content of the large amount of coins as may be desired to approve.

The reset multivibrator 56 is changed to state immediately before the fastest coin to be approved when the first speed sensor 64, and when changed, the entire coin selector combination circuit is reset to prepare it for analysis of a new coin. The reset is delayed until the last possible moment to reduce the chances of the various elements of the combination circuit, such as bistable multivibrators, hereinafter referred to as flip-flops, and the counter being switched or triggered by electrical noise, e.g. from nearby industrial equipment.

The blocking multivibrator 58 is arranged to change state shortly after the slowest coin to be approved is expected to reach the first speed sensor 64. If the coin reaches and blocks the first speed sensor 64 at the expected time or before, the signal from the sensor switches 64 a flip-flop 68 which prevents over a AND gate 69 a signal from being transmitted to an accumulator block 7o. If the coin does not shut off sensor 64 within the expected time, the blocking multivibrator 58 changes state without flip-flop * 68 being switched, and this simultaneous state switches flip-flip * 72 over AND gate 69, indicating that a coin is either too slow or has been blocked in channel 15. Switching the flip-flop * 72 also activates the accumulator latch 7o so that accumulator 48 will not register a partial sum.

A non-magnetic coin, which has not been blocked in channel 15, reaches and interlocks for sensor 64 within the expected time and generates a signal which switches on a flip-flop 74. The coin continues past sensor 64 and interlocks for adjacent sensor 65. resetting the flip-flop 74. In the time interval when the flip-flop * 74 is switched or in other words during the time it takes for the front edge of the coin to pass from the sensor 64 to the sensor 65, a series of pulses are applied. from a system clock 76 to a counter 78 over an AND gate 8o. The pulse frequency from the system clock is a reduced frequency from a main oscillator 81 provided by a conventional divider 82. The main oscillator can e.g. have a frequency of 3.2 MHz, while system clock 108. It can be seen that flip-flop * 74 controls the supply of system clock pulses to counter 78, since an opening state of AND gate 8o will only occur in the interval at which flip-flop * a 74 is switched. The number of input pulses to the counter 78 is directly proportional to the time it takes for the front edge of the coin to move from the sensor 64 to the sensor 65, therefore the number of pulses received by the counter is inversely proportional to the coin speed before being exposed. for the magnetic field. By using an inverter and a conventional modulo N parts 83 which are commercially available, an impulse rate is produced proportional to the velocity of the coin before being subjected to the magnetic field, and this impulse rate serves as a program block designated as an element 84 for the remainder. part of the coin analysis function. The circuit, which includes the system clock 76, the counter 78 and the inverter and the modular divider 83, is the speed normalization circuit 44.

The program clock 84, which is part of the material and the chord length determining circuit, has the effect of making the real coin speed immaterial within certain limits. The inverter and modulo divider 83 are set at the expected grouping center of the coin selectable speed of the coin selector lo, and the output of modulo N divider 83 is either above or below this mean. Tests show that the rate of coins starting from the zero rate has a spread of up to approx. plus or minus ceiling for a given slope of the support groove 16. Such a spread may have an effect on the accuracy of the coin selector. However, with the use of the modulo H divider 83, the effect of the spread can be minimized to the point where no severe limitation occurs. If a coin passes past the sensors 64 and 65 at a rate equal to the average rate of a given amount of acceptable coins, the modulo H divides the divider 83 at a rate equal to the velocity of the divider 82. Since the rate of the coin varies for each coin passing through the selector, the sharing speed will also change in the modulo N divider. In this way, the coin's speed is normalized and the system behaves as if all coins move through the magnetic section at the same speed. The use of the program clock 84 also minimizes the effect of variations in the slope of the support groove 16 and also the acceleration of the coin at any point along its path to the sensors 64 and 65, thus helping to make the selector error-prone as tilting the apparatus, that to increase the speed or acceleration of the coin and other known maneuvers to trick such devices will be ineffective.

As the coin passes the sensor 65, it enters the coin material and dimensional sensing system as it enters the magnetic field produced by the magnet 23- A fourth sensor, the sensor 66, is placed immediately after the magnet 23, and a fifth sensor 67 is positioned slightly below sensor 66, The effect of the magnetic field on the coin is determined by observing the velocity of the coin as it leaves the field, and this is accomplished by observing the time of coin passing from sensor 66 to sensor 67. When the coin leaves the magnetic field, it blocks the sensor 66, causing flip-flop * 86 to be switched. Therefore, when the coin locks for the sensor 67, the flip-flop * resets 86, the interval in which the flip-flop * is switched is inversely proportional to the velocity of the coin as it exits the magnetic field. The output of the flip-flop * 86 is applied to an AND gate 88 along with the signal of the program clock 84. During the time when the flip-flop * 86 is switched, the program clock signal is passed to a counter 9o through an OR gate 92.

To facilitate understanding of the other mode of operation of the coin selector, it is assumed that the selector is designed to accept coins with only three values, e.g. a 5 cents, a lo cents and a 25 cents. In determining the rate that real coins will have, after leaving the magnetic field, a first step in coin analysis is ready to be made, as a comparison of the output of the counter 9o with the known corresponding values for acceptable coins can easily be made using usual circuits. The output of counter 9o is passed to an approval ratio decoder 94 over a series of OG ports 96, eight ports being shown, since an eight bit counter is used, each port having an additional input from the flip-flop * an 86. 0G ports 96 ensures that the decoder 94 will only receive the display of the counter 9o during the time the flip-flop * 86 is switched, or in other words during the time the coin passes between the sensors 66 and 67. Three flip-flops 98, loo , lo2, which represents a 5 cent, a lo cent and a 25 cent respectively, receives the output of decoder 94 and responds to a predetermined signal pattern produced by the counter 9o corresponding to signals characteristic of acceptable coins. The flip-flops 98, loo, lo2 are arranged to be reversed by counts representing the lower limits of their particular acceptable coin and to be reset by counts representing the upper limits of their respective acceptable coin. If the coin that has passed through the system is either a 5 cent, a lo cent or a 25 cent 12 coin or a coin with an approval ratio equal to the approval ratio of a 5 cent, a lo cent or 25 cent, one of the flip- the flops 98, loo, lo2 are switched but not reset until the first provision representing the coin material is thus performed. Obviously, if the coin passing through the system does not have an approval ratio equal to the approval ratio of a 5 cents, a lo cents or 25 cents, none of the flip-flops 98, loo, lo2 will be switched, have activation of the coin directing control means 25 for removing the coin approval platform 24 requires switching at least one of these flip-flops, the coin which has passed through the system and has not switched one of the flip-flops 98, loo, lo2, hits the platform 24 and is thrown back into the coin ejection channel 27.

The switching of one of the flip-flops 98, loo, lo2 only indicates that the coin that has passed through the selector lo had an approval ratio equal to the approval ratio of a 5 cents, lo cents or 25 cents. cap is not a guarantee that the coin was a genuine coin of correct value, for this another criterion must be checked. Such a criterion is a dimension or chord length, such as the diameter of the coin, sensed as follows. As the coin passes through the selector lo and begins to block the sensor 67, the counter 9o is erased by an impulse generated by a flip-flop lo4 and a feedback flip-flop lo6. In addition to being fed to flip-flop 86 for authentication ratio detection, the output of sensor 67 is also fed to an AND gate lo8. The signal from the program clock 84 is also fed to the AND gate lo8, and during the time when the sensor 67 is interrupted, the program clock pulses are fed to the counter 9o. The state of the counter when the counter stops, which will happen when the sensor 67 is no longer shut off, is directly proportional to the chord length. The counter output signal is passed to a dimension decoder 11 and prevented from being passed to the approval ratio decoder 94 by the OG gates 96. For the OG gates 96 to be opened, the flip-flop 86 should be in the switched state. However, the flip-flop 86 will have been reset by the shutdown of the sensor 67. A series of AND gates 111 between the counter 9o and the dimension decoder 11a prevent the decoder 11a from receiving the counter output signal during the coin rate measurement.

Three flip-flops 112,114,116 are connected to the dimension decoder 11o and respond to a predetermined signal or count pattern produced by the counter 9o corresponding to signals characteristic of acceptable coins, in this case a 5 cent, a lo cent and a 25 cents. As described above in connection with the approval ratio decoder 94 and its flip-flop 98, loo, lo2, flip-flops 112,114,116 are reversed and reset by the counts representing the lower and upper acceptable limits of their respective coins.

The output of 5 cent approval ratio flip-flop * a 98 and dimensional flip-flop · a 112 is applied to an AND gate 118. The output of the lo cents flip-flops loo, 114 is applied to an AND gate 12o, and the output signals of 25 cents flip The flops lo2 and 116 are passed to an AND gate 122. In order for either of the AND gates 118, 12ο, 122 to open, both flip-flops supplying each gate must obviously be switched, which means , that the coin passing through the coin selector lo had to have an approval ratio in the area of a true coin of correct value and a chord length within the acceptable range for the same coin. The outputs of the three AND gates 118, 12ο, 122 are passed to an OR gate 124, the output of which is fed to the coin direction control solenoid 25. If the coincident states required by any of the ports 118, 12ο, 122 are present. , the coin direction control solenoid is therefore activated and upon movement of the solenoid anchor 126, the approval platform 24 is withdrawn from the coin path and the coin is allowed to fall into the approval channel 26. If the coincident states are not present, resulting in no of the AND gates 118, 12ο, 122 are opened, the solenoid 25 is not actuated and the platform 24 remains in the coin path, causing the coin to be thrown back into the ejector channel 27.

In addition to activating the coin directional control solenoid 25, a proper combination of the approval ratio and dimension flip-flop positions will also activate the accumulator circuit 48. Although many different accumulator circuits can be used, the following circuit is considered particularly suitable for the present system. The accumulator circuit 48 is actuated by the system clock 76 and contains an accumulator counter 152 and a control counter 134. Pulses from the system clock 76 are passed through appropriate circuits described below to both the accumulator counter 132 and the control counter 134, the latter controlling the duration of the time at which the system clock pulses is fed to the accumulator counter 132 such that the total number of pulses received by the accumulator counter represents the value of the coin in question which has passed through the coin selector 1o.

Again assuming that a 5 cent, a lo cent and a 25 cent 14 coins are the coins to be accepted, the OG gate 118 is opened when a coin of the lowest value, 5 cents, was passed through the coin selector lo , which causes a pulse to be passed to the accumulator counter 132 through an ELDER port 136 and an 0G ~ port 138. The second signal required to open the AND gate 138 comes from the accumulator block 7o. It can be seen that if the block 7o changes state due to a blocked coin in the channel 15, the AND gate 138 cannot be triggered and consequently no impulses will be able to reach the accumulator counter 132. One coin with the second highest value, lo cents, passes through the counter, the OG gate 12o is opened and the output signal therefrom converts a flip-flop 14o. The output of the flip-flop 14o is coupled with the system clock pulses to the OG gate 142. Mr flip-flop 14o is switched, the system clock pulses are passed through the OG gate 142. and through the ELIER port 136 and AND port 138 to the accumulator counter 132. At the same time, the system clock pulses are passed through an EIDER port 144 to the control counter 134. The output of the control counter is passed to a pair of decoders 146,147, representing a lo cent and a 25 cent, respectively. The lo cents decoder 146 is arranged to reset the flip-flop 14o over an ELDER port 148 after reaching a predetermined number of pulses from the control counter 134. Resetting the flip-flop 14o locks the AND gate 142 and terminates the transmission of system clock pulses to the accumulator counter 132. Since passing a 5 cent through the coin counter lo causes a single pulse to be transmitted to the accumulator counter 132, the decoder allows two pulses to be transmitted to the accumulator counter 132.

A similar coupling is found for the coin with the highest value, 25 cents, opening of the AND gate 122 switches to a flip-flop 149, which in turn opens the AND gate 15o. Opening of the AND gate 15o allows the system clock pulses to be fed to the accumulator counter 132 and simultaneously to the control counter 134. The output of the control counter 134 is passed to 25 cents decoder 147 which, after a suitable time interval, resets flip-flop 149 over the EDDER port 152. 147 is arranged to allow five times the number of pulses for the coin having the lowest value, 5 cents, to pass to accumulator counter 132 before resetting flip-flop * 149 and blocking AND gate 15o so as to terminate the supply of pulses to accumulator counter 132. While the control counter output signal is received by both the lo cents decoder 146 and 25 cents decoder 147, if either a lo cents or 25 cents have passed through the selector, the correct decoder in the given case will have no effect, since only the correct flip-flop, either 14o or 149, which corresponds to the coin of the voter, will be switched and therefore reset.

151418

The output of the accumulator counter 132 is passed through a sales decoder 154 to the coin operated apparatus 156 to indicate the total value of the approved coins passed through the coin selector lo and into the approval channel 26, the accumulator counter 132 retains its accumulated total value until the coin operated apparatus 156 is operated to sell a product or service at which time the accumulator counter 132 is reset. The control counter 134 is reset by throwing each new coin using the pre-described start control system 4o.

The coin selector 20 which constitutes another embodiment of the invention corresponds to the coin selector 1o in the first embodiment described above, the criteria used for the approval and categorization of coins of predetermined value being the same and a corresponding combination circuit used. a magnetic field for retarding the coin's speed, as well as the starting control circuit described above 42.

The coin enters the system, brings it to rest by means of a stop pin 21o, and locks a starting sensor 212 in the same manner as described above. At the same time, blocking of the start sensor 212 starts a stop loss multivibrator 52, a magnetic coin separator multivibrator 54, a coin reset multivibrator 5o, and a blocking multivibrator 58, all operating in the same manner as described above, so the description of their function should not be repeated.

Mr stop pin 21o is removed from the coin path, and assuming that the coin is not sufficiently magnetic to be held by the magnetic coin separator 20, the coin will begin to roll down the guide groove 16 where it enters a magnetic field produced by a magnet 214 The coin's speed will be delayed relative to its approval ratio, the coin exits the magnetic field, blocks it from a sensor 216, which over an inverter 217 switches a flip-flop 218 which opens an AND gate 22o, the coin then blocks the sensor. 222, which resets flip-flop * 218 over an EIDER port 223, The interval at which flip-flop 218 is switched is inversely proportional to the coin speed between sensors 216 and 222. A timing control oscillator 224 which feeds a flip flop 226 in a raid triggering connection is differentiated by a circuit 227 into positive pulses called A clock pulses and 16 negative pulses called B clock pulses, the pulses being out of phase with each other the. The A clock pulses are fed to the open AND gate 22o, from which they are fed to an eight-state counter 228. The output of the counter fed to a decoder matrix 23o is inversely proportional to the speed of the coin. The B-clock pulses are fed to the decoder 23o to trigger it to read counter 228 in the transitions between the A-clock pulses.

As in the first embodiment, it is assumed in the following that the coin selector 20 is arranged to approve three coins. In this case, the acceptable coins are merely 1 pence, 3 pence and 6 pence for the sake of illustration. Consequently, the decoder 23o's output is fed to three independent flip-flops, a 1-pence flip-flop 232, a 3-pence flip-flop 234 and a 6-pence flip-flop 236. Each flip-flop is switched by the count representing the lower limit for acceptable speed for that coin, and reset by the count representing the upper limit of the speed of that coin. If a coin having a velocity within the range of an acceptable coin passes through the system, one of the flip-flops 232,234, 236 will be switched for the first determination of an acceptable coin. Since the coin's velocity, after passing through the magnetic field, represents the coin approval ratio, the velocity comparison tests the one coin approval criterion.

It is now necessary to provide means for sensing the coin diameter or other cord length for an examination of the second criterion. This is accomplished by a series of three secondary sensors 216,222,238 coupled to a primary sensor 24o. With the sensor 24o as the primary sensor for the chord measurement, the distances between the secondary sensors 238,222 and 216 from the primary sensor 24o are set to be the minimum acceptable dimensions for each of the three coins that the selector is designed to approve.

Output signal from sensor 24o is applied to each of three OG ports 242,244 and 246 over an inverter 247, while the output of sensors 216,222 and 238 is applied to AND gates 242,244,246, respectively. For any of the AND gates to be triggered, it is necessary that the primary sensor 24o as well as at least one of the other sensors 216,222, 238 be simultaneously blocked by the coin. The AND gates 242 and 244 and 246 also output the flip-flop output signals 232,236,234, respectively, so that each approval ratio flip-flop output signal is fed to an AND gate along with the output signal from the corresponding dimension sensor. P.eks. 1 pence sensor 216 leads to diameter measurement and 1 pence flip-flop 232 to approval ratio measurement to 1 pence AND gate 242. Similarly, the output of 3 pence sensor 238 and flip-flop 234 to the AND gate 246 and the output of the 6 pence sensor 222 and flip-flop 236 to AND gate 244.

Assuming that a 3 pence is passed through the coin selector 2oo, the approval ratio flip-flop * a 234 is partially reset to open the AND gate 246, while the approval prohibition flip-flops 232 and 236 are not reset so that the AND gates 242 and 244 are blocked. For the AND gate 246 to be triggered, it is necessary that the sensors 24o and 238 be locked simultaneously, which will happen with a true 3 pence. When sensors 240,238,222 and 216 are locked, relatively high voltages are applied to wires leading to their respective AND gates 246, 244 and 242. Simultaneous blocking of sensors 24o and 238 together with switching of flip-flop 234 opens AND gate 246 and applies a relatively low voltage to the output line 248 and immediately triggers a multivibrator 25o. The multivibrator 25o shifts state and imposes a relatively high voltage on its output line 251 leading to an AND gate 252. Accordingly, in the period in which the sensors 24o and 238 are blocked, a relatively high voltage is applied to the line 251 which leads to the OG gate 252 and a relatively low voltage applied to a second line 254 connecting the line 248 to the OG gate 252. However, the OG gate 252 is arranged so that it will only be opened upon receipt of two signals. with high voltage. As soon as the coin exposes the sensor 238, the OG gate 246 is blocked and produces a relatively high voltage on the wires 248 and 254. If the multivibrator has not returned to its original state and applies a high voltage to the wire 251, the OG gate 252 is opened and switched. flip-flop * 256. However, if the multivibrator returns to its original state and thus imposes a low voltage on line 251 before the coin exposes sensor 238, and this will happen if the coin is too large, AND gate 252 will not receive two high voltages simultaneously and therefore will not be opened and flip-flop 256 will not be switched and the coin will be ejected. The duration at which the multivibrator provides the relatively high voltage on line 251 is set to cease immediately after a coin having a maximum dimension equal to the maximum corresponding dimension of a true 3 pence has passed and therefore exposes the sensor 238. The other flips flops 257,258 and AND gates 259,26o and multivibrators 261,262 of 6 pence and 1 pence AND gates of 244 and 242 respectively work in the same way.

To briefly summarize the sensing system in the coin selector 2oo, a coin at a rate between the sensors 216 and 222 immediately adjusts the magnetic field thereafter to find a detecting signal for the one of the true acceptable coins, one of the flip-flops. one 232,234,236. If the measured dimension of the coin is large enough to simultaneously block the primary sensor 24o and one of the secondary sensors 238,222 and 216, and if the simultaneous lockout corresponds to the approval ratio flip flop previously switched, the OG port 246,244 or 242 opened and starts the corresponding multivibrator. A coin having a diameter within the approved range will terminate the coincidence between the sensor 24o and. the other sensor 238,226 or 216 previously covered before the multivibrator stops, resulting in switching of the corresponding flip-flop 256,257 or 258. The switching of any of these flip-flops provides a signal over the ELIÉR port 263 to the coin approval solenoid 25, which withdraws the eject platform 24 from the coin path and allows the coin to fall into the approval channel 26. If none of the flip-flops 256,257 or 258 are switched, the coin approval solenoid is not activated and the coin hits the eject platform 24 ejection channel 27.

The next in line is the influence of an accumulator 264. Various conventional accumulators can be used, as is the accumulator described above in connection with the first embodiment. Another accumulator is shown in FIG. 7 and is designed for use with coins having a value ratio of 1: 3: 6, as is the case with 1 pence, 3 pence and 6 pence coins. Activation of the accumulator 264 is initiated by the trailing edge of the coin as it passes the primary sensor 24o. The signal from sensor 24o is reversed by inverter 247, differentiated and then used to trigger two parallel multivibrators 266,267. The active period of the multivibrator 266 is set to terminate a short time after the coin has passed the sensor 24o, while the active period of the multivibrator 267 is set to terminate slightly later than that of the multivibrator 266. The output signals of multivibrators ne 266 and 267 are differentiated and fed. over inverters 268,269 to an EIIER port 27o. Also to the ELIER gate 27o is a pulse received from the primary sensor 24o over a line 272. Accordingly, the EIIiEB transmits the gate 27o three consecutive pulses, the first when the primary sensor 24o is exposed, the second when the multivibrator 266 changes state and the third when the multivibrator 267 changes state. The only pulse from the sensor 24o is also applied to an AND gate 274 along with the output of the 1 pence flip-flop 258. When a 1 pence passes through the selector 2oo, the flip is switched on. the flop 258, and the signal from this flip-flop is passed to AND gate 274 along with the one pulse on line 272 and a single pulse is transmitted over an EILER port 276 to the first stage of a four stage counter 278 which records a count. A 3 pence coin passing through the system switches the flip-flop 256 and generates a signal which is fed to the AND gate 28o. The signal is applied together with the three pulses passing through the OR gate 27o and the three pulses are transmitted by the OR gate 276 to the counter 278. A 6 pence coin passing through the system switches the flip-flop 257 »which opens AND gate 282 to transmit the three pulses from OR gate 27o to the second stage of counter 278. Le three pulses transmitted to second stage of counter 278 are counted as twice the three pulses, or in other words as six counts representing the 6 pence coin. The output of the accumulator counter 278 is passed over a sales decoder 283 to a coin operated apparatus 284 which, when operated to sell the desired product or service, resets the counter 278.

Although two parallel multivibrators are used in connection with accumulator 264, it will be appreciated that a serial arrangement of the multivibrators can also be used.

A modification of the second embodiment is shown in FIG. 8, where three additional sensors are added to determine the possibility of approving a chord dimension, such as the diameter. The three additional sensors replace the multivibrators 25o, 261 and 262 to determine the acceptable maximum dimension of the coin. The other part of the system including the means for detecting the approval ratio is exactly the same as the second embodiment and is therefore not shown in detail in FIG. 8. To determine whether the diameter or a selected chord dimension is within the acceptable range, a pair of sensors corresponding to each acceptable coin is used in combination with the primary sensor 24o, the sensor closest to the primary sensor 24o controlling the minimum dimension and the sensor furthest away from the primary sensor 24o controls the maximum dimension.

Again, it is assumed that the coin selector 3oo shown in FIG. 8 is arranged to approve 1 pence, 3 pence and 6 pence coins, and a pair of sensors 3o2.3o4 corresponding to a 3 pence, a pair of sensors 3o6.3o8 corresponding to a 6 pence and a pair of sensors 31o, 312 corresponding for a 1 pence. The distance between the sensors forming a pair, such as between the sensors ΛΛ O Λ ίΤ ΛΛ / ft Vi * 1 * ί <"« · w ft ^ Λν »ft Ir λλ-λΙλ ^ Ι λ <3 ή« μ λ «* μ _ _ _____ -ΐ _ _ !. -Ο _ Μ J3 - _ Λ ___ "1 151418 tenth coin, and the distance between that sensor in each pair which is / closest to the primary sensor 24o, and this is equal to the minimum acceptable dimension for the coin.The output of each pair of sensors is fed to their corresponding AND gates 314,316,318, which represent a 3 pence, a 6 pence and a 1 pence respectively. To the AND gates concerned are also output signals from the approval ratio flip-flops 234 »222 and 236. A coin passing through selector 3oo and having a speed between sensors 312 and 3o8 corresponding to the speed of a 3 pence» switch flip-flop 234. If the coin is greater than the distance between the secondary sensor 3o2 and the primary sensor 24o and less than the distance between the secondary sensor 3o4 and the primary sensor 24o, the AND gate 314 opens and a flip-flop 32o is switched . Similarly, AND gate 316 is opened and flip-flop 322 is switched as a 6 pence passes through selector 3oo, while a 1 pence passing through selector 3oo opens AND gate 318 and switches flip-flop 324. The switching of one or the other of the flip-flops 32o, 322,324 transmits a signal to a coin approval solenoid 25 which removes the platform 24 from the coin path. Furthermore, the signal is transmitted to an accumulator 328 of the type described above, which in turn enables operation of a coin operated apparatus 33o.

In the description given above, it can be seen that the coin selector of the invention is capable of selecting a large number of coins and also has the ability to be slightly modified to allow approval of other coins. Pen limiting in terms of the number of coins that are acceptable are the comparator circuits and in particular the number of flip-flops which operate depending on the sensors. This number can be increased to almost any practical number. Furthermore, the comparator portion of the circuits can be in the form of plug-in modules that can be easily replaced on site with a minimum of specialist knowledge and work. Due to the large capacity and operating speed of the coin selector according to the invention, a number of single coin operated apparatus can be operated by a single coin selector apparatus, each coin operated apparatus being provided with the sensors and coin channel and the outputs of the sensors being connected to a central combination circuit. which contains the coin material and dimension sensing circuits and an accumulator.

Claims (22)

A method of determining the authenticity and value of a coin by examining the velocity of a coin passing along a channel and through a magnetic field, and by examining a chord dimension of the coin, characterized in that the chord dimension of the coin is examined while the coin moving along the channel and generating a signal representing the chord dimension of the coin and (essentially independent of the coin's velocity, examining the velocity of the coin between two points located after the magnetic field, and generating a signal representing the speed of the coin and determining whether the signals representing the speed and the chord dimension are characteristic of acceptable coins. Method according to claim 1, characterized in that the signal representing the speed of the coin after the magnetic field is changed depending on the value of a signal representing the speed of the coin before the magnetic field, so as to compensate for a deviation in the speed of the coin, before the magnetic field from a predetermined average velocity before the magnetic field. Method according to claim 1 or 2, characterized in that the chord dimension of the coin is examined in a manner which depends partly on the speed of the coin and that the signal representing the chord dimension is changed depending on the information contained in a signal representing the velocity of the coin. the coin somewhere along the canal. Method according to claim 1 or 2, characterized in that the examination of the chord dimension of the coin comprises the steps that the coin being examined causes to block at least two sensors which produce a signal representing the length of the time in which that is simultaneously locked for the two sensors and that this time is compared to the maximum time for an acceptable coin. Method according to claim 1 or 2, characterized in that the examination of the chord dimension of the coin comprises the steps that the coin to be examined is successively barred for at least three sensors and that a signal is produced indicating the presence of a possible acceptable coin when two sensors are simultaneously blocked while no third sensor is blocked. Method according to any one of the preceding claims, characterized in that the signals representing the velocity and the chord dimensions are each a series of pulses and that un- (ΙρτιηΜίΓΡΐ aPT> no of trnr> ri o ri 4 mon s -ΐ nn no · Vinaf.-in chorl by * mslrifan V-nm-n -ΐηΛονιηΤ Λοη 22 151418 the step of counting the pulses in the respective series of pulses. A method according to any one of the preceding claims, characterized in that a mechanism for causing a coin to be retained or returned to the user is controlled depending on the signals representing speed and chord dimension of the coin and an additional signal is generated which indicates the value of the coin in the case where the coin is retained. Apparatus for determining the authenticity and value of a coin by the method of claim 1, known in the character, by a chord dimension detector (67 * 216,22: 2, .238,24.o; 24o and 3o2-312), a first sensor. (66j2l6; 312) located after the magnetic field and a second sensor (67j222; 308) located even further after the magnetic field, which first and second sensors are connected to a comparative circuit (46 in Fig. 1). Apparatus according to claim 8, characterized in that a reset input on the comparator circuit is connected to a monostable circuit (56) connected to a sensor (21) positioned before the first and second sensors (66 and 67, respectively), wherein the period of the monostable circuit is less than the time taken for the fastest acceptable coin to pass from said sensor (21) to the first sensor (66). Apparatus according to claim 8 or 9, characterized in that the output of the comparator circuit is connected to an accumulator (48) through an AND circuit (138), a blocked coin indicator means (7o) constituting the second input of the AND circuit (138). Apparatus according to claim 1, characterized in that the blocked coin indicator means includes an initial coin sensor (21) before the magnetic field, which is connected to the trigger input of a multi-fiber tor (58) with a predetermined duration pulse, the output of the generator and a further coin sensor (64) after the initial coin sensor is connected to an AND circuit (69). Apparatus according to any one of claims 8-11, characterized in that the comparator circuit contains a port (88) connecting a bistable circuit (86) and a clock transducer (84) to an impulse counter (9o), wherein the first and the second sensor (66 and 67, respectively) is connected to the set and reset inputs of the bistable circuit (86). · Apparatus according to any one of claims 8-11, characterized in that the clock sensor (84) and the chord dimension detector ep are connected over a gate (10o) with an impulse counter (9o), wherein the chord dimension detector comprises a single sensor (67). 23 151418. Apparatus according to any one of claims 8-11, characterized in that the chord dimension detector comprises a primary sensor (24o) and a secondary sensor (238j222; 2l6) spaced apart corresponding to a minimum acceptable chord dimension for a chord dimension. acceptable coin, wherein the primary and secondary sensors are connected over a gate (246; 244 ^ 242) to a comparator circuit containing a multivibrator (25o; 261; 262) of a predetermined duration pulse. Apparatus according to claim 14, characterized in that the gate (246; 244; 242) is connected to the trigger input of the multivibrator (25ο; 2βΐ; 2β2) and the outputs of the multivibrator and the gate (246; 244; 242) are connected to a following port (252; 259; 26o). Apparatus according to claim 14 or 15, characterized by a plurality of secondary sensors (238, * 222 and 216) with associated ports (246; 244 and 242), the secondary sensors being distances from the primary sensor (24o) corresponding to a minimum acceptable chord dimension of acceptable coins with different values and that the primary sensor (24o) is associated with each gate. Apparatus according to any one of claims 8-11, characterized in that the chord dimension detector contains a primary sensor (24ο) and a pair of secondary sensors (3o2 and 3 ° 4; 3o6 and 308; 31o and 312). between the primary sensor (24o) and one of the secondary sensors (3o2; 3o6; 31o) is equal to a minimum acceptable chord dimension of an acceptable coin, and the distance between the primary sensor and the other secondary sensor (3o4; 3o8; 312 ) equals a maximum acceptable chord dimension of an acceptable coin of the same value. Apparatus according to claim 17, characterized in that the primary and secondary sensors are connected to a port (314; 316; 318), wherein one of the secondary sensors is connected to the port over an inverter. Apparatus according to claim 17 or 18, characterized in that there are several pairs of secondary sensors (3o2 and 3o4; 3o6 and 308; and 31o and 312), wherein the distance between the primary sensor and one sensor in each pair is equal to the minimum acceptable chord dimensions of acceptable coins for different values, and the distance between the primary sensor and the other secondary sensors is equal to the maximum acceptable chord dimensions of acceptable coins with the different values mentioned, that one gate (314; 316 and 318) belongs to each a pair of secondary sensors that the primary sensor and a pair of secondary sensors are connected to each port and that a sensor in each pair is connected to its port over an inverter. 24 151418 Apparatus according to any one of claims 8-13, characterized in that the comparator is connected to a speed compensation means (44) and that a third and a fourth spaced sensors (64 and 65) are arranged before the magnetic field and associated with the speed compensation means. Apparatus according to claim 20, characterized in that the third and fourth sensors (64 and 65) are connected to the set and reset inputs of a bistable circuit (74) and the bistable circuit (74) and a first clock sensor (76). ) is connected across a gate (8o) to a pulse counter (78), and the output of the pulse counter is connected to a frequency-changing means (83), the output of which leads to a second clock sensor (84). 21 151418. Claims. Apparatus according to any one of claims 8-21, characterized in that at least one of the sensors (21; 64j.65; 66 $ 67j212j 216; 222; 238; 24o; 3o2 and 3o4; 3q6 and 3o8j31o and 312) is a photosensitive member with an associated light source, which is photosensitive member covered by an elongated aperture mask.