DE2301995A1 - COIN VALIDATOR - Google Patents

Description

International Cybernetic Machines Limited, Dublin, Ireland.

Coin validator

The invention relates to a coin validator for separating spurious ones Coins of real coins of predetermined denomination with spaced walls that define a coin inlet channel, with a cradle that can be pivoted relative to the hopper is stored and has two mutually spaced coin receiving surfaces that stand in the coin insertion funnel and intercept coins that exceed a certain diameter and prevent dispensing to a coin return funnel and under the weight of such coins to a coin acceptance hopper sway.

With coin validators of this type there is the problem of preventing false coins from being inserted into machines. In the present In the description, the term "false" or "spurious" shall be used to denote any coin that is not the respective one has the required characteristic value that is required to operate the coin release mechanism. The terms are also intended to include washers, metallic punchings or the like. with include that in are occasionally inserted into coin-operated machines with fraudulent intent. This should also be understood to mean characters that be used extensively in slot machines instead of coins. It is a fact that the use of counterfeit coins eo has increased as the number of machines installed.

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Therefore, there is a need to create a coin validator, which ensures an effective distinction between real and fake coins and is also cheap to manufacture.

Numerous coin validators have already been developed that detect such false coins. With many coin validators it is a coin cradle is provided to determine the diameter of the inserted coins and thereby real coins from fake coins to distinguish. These cradles catch real coins and then respond to the weight of the real coin and the real coin is then rotated and passed to a guide or output chutes that feed the real coin to a coin release mechanism to operate this. Too small sized fake coins will not be intercepted by the cradle and will be caught between the coin receiving surfaces the cradle is directed downwards and thus led away from the shaft for real coins (GB-PS 7 37638). Unfortunately However, incorrect coins that are too small can affect the cradles during operation, rotate them and transfer them to the cradles in enter the slot for real coins, so that the coin release mechanism of the machine is operated. There are numerous attempts has been made to solve this problem. For example, the cradle locks have been designed to be too small hold up measured coins so that they cannot turn the cradles of the coin validator, with these coins on the lower coin receiving surface ride the cradle. These cradle locks are very complex (e.g. GB-PS 1 113 323 and 1 113 324). These have extraordinarily ingeniously constructed devices while improving the operation of such a coin validator, they are extremely complex and expensive to manufacture .

The invention is therefore based on the object of providing a coin validator create which has a relatively simple structure and is relatively inexpensive to manufacture.

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According to the invention this object is achieved in that means are provided to move the cradle relative to the coin entry chute so that the coin receiving surfaces of the cradle
be withdrawn from the coin entry chute for a predetermined time interval after a coin has entered the coin entry chute.

According to one embodiment of the invention it is provided that a coin inlet sensor is arranged and in the coin inlet shaft
operationally with the means for moving the cradle relative to the
Coin inlet shaft is connected. According to a further embodiment of the invention, the cradle is pivotably mounted on the core of an electromagnet, which is the device for moving the cradle
forms relative to the coin inlet shaft.

The advantages achieved by the invention are primarily that instead of a relatively complex construction of the
Cradle and the coin validator a relatively simple production is guaranteed. It is also possible to arrange the coin validator so that the owner of the machine can insert a
false coin can determine if the person is actually using the coin validator. The invention also provides a convenient method of stacking coins upon acceptance by the coin validator, thereby avoiding excessive numbers
is not properly layered by coins and clogs the machine.

An exemplary embodiment of the invention is described below with reference to FIG Drawing described. In the drawing show:

Fig. 1 is an exploded perspective view of the

Coin validator,
FIG. 2 is a partial perspective view of the coin validator from FIG

Viewed from the back,
J shows a front view of the mechanism with the cover removed, with a real one passing through the coin slot. Coin,

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FIG. 4 shows a view corresponding to FIG. 3 with a coin slot passing oversized fake coin,

FIG. 5 shows a section along the line V-V according to FIG. 4,

Fig. Β is a view corresponding to Figures 3 and 4 with one of the Undersized coin passing through the coin chute,

7 is a perspective view of the arranged in the coin validator Cradle,

8 is a view of the stamped part from which the cradle is made,

9 is a view corresponding to FIGS. 3, 4 and 6 of the progression. setting coin chute and the coin stacking device.

According to Fig.l and 2, the coin validator has a base plate 1 which carries two side walls 2, over which a top wall 3 is arranged. The top wall 3 is fastened to the base plate 1 and the side walls 2 by spring-loaded screws 4a which are screwed into threaded holes 4 in the top wall 3 and protrude through holes 5 in the base plate 1 and the side walls 2. The top wall 3 is rigidly attached to the housing of the machine in which the coin validator is installed. The base plate 1, the side walls 2 and the top wall 3 form a coin inlet chute 6, a Münzabweisschacht J and a Münzannähmeschacht 8. The inlet chute 6, the Abweisschacht 7 and the acceptance chute 8 are dimensioned so that the coin can only run with their edge. A cradle 9 is mounted on the rear side of the base plate 1 by means of a push magnet 10.

will

Referring now to Figures 7 and 8 of the drawings. How from here As can be seen, the cradle 9 consists of a U-shaped stamped sheet metal part with two holes 11 and two protruding outwards Coin arms 12 and I3. The cradle is preferably made of a Mild steel sheet or a bronze plate cut out and bent.

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Pig. 8 shows the blank cut out from which the cradle 9 is bent. First, the blank is folded by bending the te around the fold lines 14,15 upwards by 90 ° and then the plate is bent downwards around the fold lines 16 by 90 ° and then it is bent again around the fold line IJ by 90 ° .

The push magnet 10 fastened to the base plate by means of a bracket 18 carries the cradle 9 by means of a on its core 20 attached rod I9, (shown in dashed lines in Fig.5), and by means of Nuts 21. In the base plate 1 are two arched ones Slots 22 and 23 arranged. Corresponding arcuate slots 24 and 25 are located in the top wall 2. The support arm Ij5 is up through the slots 23 and 25 through. The support arm 12 and the Corner 29 between the coin inlet chute 6 and the coin acceptance chute 8 form a delimiting passage for a coin. In the coin inlet duct 6, an electromagnet 26 is mounted. In addition, there is a coin inlet sensor 27 in the coin inlet shaft 6 and in the coin acceptance shaft 8 a coin outlet sensor 28. For the sake of clarity Details of the electromagnet 26 and the sensors 27 and 28 are not shown. The sensors can be used as photoelectric sensors, as capacitive sensor or as a metal detector / inductive sensor or as a mechanical sensor, for example as a microswitch be. The coin entry sensor 27 is only required to deliver an electronic signal "coin entered" while in the same way the sensor 28 gives a signal "coin leaked". There are a wide variety of structural design options such a feeler.

The inlet sensor 27 and the outlet sensor 28 are on Not shown alarm system connected, which is arranged adjacent to the machine containing the coin validator or also away from the machine. The entry sensor is also electrical with the push magnet 10 and the electromagnet 26 connected.

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In Münzabweisschacht 7 a coin holder 40 is mounted, which of the rod 19 of the push magnet IO is carried. The coin holder 40 has two arms with coin receiving surfaces that support the passage Prevent a wrong coin through the coin deflector slot 7.

Before using the coin validator, the push magnet 10 is activated, which causes the support arms 12 and I3 in the coin inlet shaft 6 protrude.

In operation, several events take place one after the other when a coin is inserted into the coin validator. The following options the insertion of a coin:

1. a real coin,

2. a fake iron coin,

3. a fake coin that is too large,

4. a fake coin that is too small,

5. a fake coin that is too light,

6. a fake coin that is too heavy.

1. Real coin

In the following we refer to Fig.5. A real coin 30 is thrown into the coin inlet slot 6. For clarification The various positions of the coin are identified by letters attached to the reference numeral 30 for the operation of the coin validator. If corresponding positions of the cradle 9 are shown, these are marked with the same appended letter. When the real coin 30 is in position 30a, it has already delivered a coin inlet signal to the push magnet 10 and the alarm system. Then the coin 30 falls on the electromagnet 26 and comes to rest in position 30b on support arms 12 and 13, which are in position 12b and 13b, respectively are. The weight of the coin 30 on the support arms 12 and I3 causes

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that the cradle 9 pivots about the rod 19 so that the coin 30 is tilted downwards and first reaches the position JOc and then into the position JOä, from where it falls into the coin acceptance shaft 3. Then the coin 30 runs into the position 30e in the Münzannähmeschacht 8 and from here it reaches the coin exit sensor 28. This sensor 28 transmits a coin exit signal to the alarm system and prevents this alarm system from being activated.

2. A fake iron coin

Here again reference is made to Figure 3 of the drawing. if such a fake iron coin is thrown into the coin inlet shaft 6 it runs past the sensor 27, which is a coin inlet signal the push magnet 10 and the alarm system. However, when the fake iron coin reaches the electromagnet 26, it will held by this. After a predetermined time has elapsed, the alarm system is activated. The push magnet 10 is de-energizes and pulls the rod 19 and thus the support arms 12 and I3 from the slots 22,24 and 23,23, respectively. A certain time after arousal of the alarm system, the electromagnet 26 is de-energized and the fake iron coin can pass the support arms 12, 13 into the coin deflector shaft 7, where it is given out to the person who put it in.

3. A fake coin that is too large

In this context, reference is made to FIGS. 4 and 5. If one to large coin is thrown into the coin inlet shaft 6, then it runs past the inlet sensor 27, which sends a coin inlet signal the solenoid fin 10 and the alarm system. The construction of the coin inlet chute 6 is such that coins which are considerably larger than the required coin are prevented from being inserted is simply due to the fact that they are too large to get into the inlet shaft 6 itself can. A fake too

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Large coin 31 also passes the electromagnet 26 and arrives at position 31a. When the coin Jl has the position 31b reached, it rests only on the support arm 12 and is supported in near the corner 29 and the cradle 9 does not pivot. After a predetermined period of time, the push magnet 10 is de-energized and causes the rod 19 to retract and the false, too large coin 31 to fall into the position 31c in the Münzabweisschacht 7 and returned to the person who threw it in. When the cradle 9 is withdrawn, the alarm system is activated.

4. A fake coin that is too small

In the following, reference is made to FIG. If a coin 32 that is too small is inserted into the coin inlet chute 6, it runs past the inlet sensor 27, which transmits the coin insertion signal to the alarm system and the push magnet 10. The fake, too small coin 32 reaches the position 32a, from where it passes the electromagnet 26. The fake, too small coin 32 then reaches the cradle 29 in the position 32b, where it passes through the carrier arms 12 and 13 into the position 32c at the inlet of the deflector shaft 7. Then this coin 32 is held in the deflector shaft 7 by the coin holder kO. After a predetermined period of time the alarm system is activated since no coin exit signal has been supplied by the coin exit sensor 28. After a further period of time, the electromagnet 10 pulls the coin holder 40 back and this releases the fake coin 32 which is too small.

5. Fake too light coin

If a fake too light coin of correct external dimensions is thrown into the coin inlet chute 6, then it runs on Inlet sensor 27 and past the magnet 26, like a real coin. The required coin inlet x-signal is delivered. The too light coin then rests on the support arms 12 and 13 of the cradle. The quality of the counterfeit too light coin, however, is such that the

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Support arms 12 and I3 move more slowly in the direction of the coin acceptance shaft 8 move than the ^ would be the case with a real coin. Accordingly, the push magnet 10 is de-energized before the cradle 9 has inclined so far that the too light Münze.in the acceptance shaft 8 arrives. This makes the support arms 12 and I3 in the arcuate Slots 22 and 24 and 25 and 25, respectively, withdrawn. To this In this way, the fake, too light coin is transferred into the coin rejecting channel 7. The rejection procedure is the same as that of a spurious one too small coin. If, by any circumstance, the fake coin that is too light actually gets into the coin acceptance slot 8 would, then it would still not be able to reach the coin exit sensor 28 sufficiently quickly and the sensor 28 cannot deliver the coin exit signal quickly enough so that the alarm device is switched on. Activation of the alarm system ensures that the machine does not work.

6. A fake coin that is too heavy

If a too heavy coin of correct dimensions is in the coin inlet chute 6 is inserted, then it gets into the coin acceptance slot 8 like a real coin. In practice there are seldom such coins too heavy counterfeit coins. However, the invention ensures that the heavy coin is sent to a second coin validator in the coin acceptance channel 8 is supplied, which is essentially the same as the coin validator described above. This would then have to be trained to be real Coins would be treated in the same way as coins that were too light would be treated by the first coin validator (see no. 5), while fake coins would be treated heavy coins would be rejected in the same way as real coins are accepted in the first coin validator (see No. 1).

If by some circumstance a fake coin that is too small, not directly falls through the support arms 12 and 12, but hits against the support arm 15, the cradle 9 could be inclined. The fake too small However, a coin would be rejected en route in the same way as a too light coin of correct external dimensions.

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When a coin is inserted into the coin inlet cha ent 6 and the coin validator is not in operation, i.e. if the push magnet 10 is not working, then the coin simply falls unhindered into the deflector shaft 7

If a coin is either in the coin inlet shaft 6 or in the coin deflector shaft 7 or in the Münzannähmeschacht 8 between the top wall j5 and the base plate 1 clamps, then Schubraagnet 10 and its support arm 18 can be pulled away from the cover wall 5, so that the base plate 1 from the cover plate jj against the spring-loaded Screws 4 is lifted off. It is clear that other devices can also be used to remove the cover wall 5 from the base plate take off.

9 shows a front view of a coin validator acceptance shaft 8 device 50 to be connected downstream. This device 50 has a base plate 51, side walls 52 and a removable cover plate. The base plate 51, the side walls 52 and the cover plate form a port 53 of the coin acceptance shaft, one Coin feed chute 54 and a coin overflow chute 55. A flap 56 can be pivoted at 57 between the inlet of the conveyor shaft 54 and the inlet of the overflow shaft 55 is arranged. The flap 56 can move between the fully extended position shown in the The position indicated by dashed lines can be pivoted. This pivoting the flap 56 can be effected, for example, by an electromagnet (not shown). The coin conveyor shaft opens into a stacking shaft 58 of conventional construction. The overflow chute 55 is more conventional to an overflow vessel 59 Type connected. A coin level sensor 60, for example in the form of a photoelectric sensor, a capacitive or an inductive sensor or in the form of a mechanical sensor (microswitch) is arranged in the coin conveying channel 54 and swiveled the flap 56.

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In operation, real coins are removed from the coin acceptance slot 8 in the coin shaft extension 53 is transferred to the JOf position. If the If the flap 56 is in the fully extended position, a coin 30 runs from the position JOf to the position 30g and then to position 30h and finally to position 30j in the coin stacker 58. When the coin chute fills up, a coin in the conveying chute 54 finally comes to rest, namely in the Position 30h and a level sensor 60 is activated. Through this the flap 56 is switched to the position 56a, which is indicated by dash-dotted lines. The other coins 30 then run out the position 30f in the position 30 1 and 30m in the overflow spearer 59.

Claims

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Claims (6)

Patent claims: Coin validator for the separation of fake coins and real coins of predetermined denomination with two spaced-apart walls that form a coin inlet chute, with a cradle that is pivotable relative to the coin inlet chute and that has two spaced-apart coin receiving surfaces that protrude into the coin inlet channel for coins to separate out that exceed a predetermined diameter, and to prevent a conveyance to a coin deflector shaft and to report a pivoting to the acceptance shaft under the weight of such a coin,
characterized, that means (10) are provided to move the cradle (9) relative to the coin inlet chute (6) and the coin receiving surfaces (12,13) to pull the cradle (9) out of the coin inlet duct (6), after a predetermined time interval has elapsed since the coin entered the inlet duct (6). 2. coin validator according to claim 1, characterized, that a coin inlet sensor (27) is arranged in the coin inlet channel (6) which is operatively connected to the means (10) for moving the cradle (9) relative to the coin inlet chute (6). 3. Coin validator according to claims 1 or 2, characterized in that that the cradle (9) is pivotable on the core (19, 20) of an electromagnet (10) is mounted, which forms the device (10) for moving the cradle (9) relative to the coin inlet shaft (6). 309832/0 4 14 4. Coin validator according to claims 1 to J>, thereby marked chnet, that a coin outlet sensor (28) is provided in the coin acceptance shaft (8) and operationally with the coin inlet sensor (27) and one Alarm system is connected, which means that if the Coin outlet sensor (28) actuated the alarm system before a predetermined time after energization of the coin inlet sensor (27) will. 5. Coin validator according to one of claims 1 to 4, characterized in that it is marked, that an electromagnet (26) in the coin inlet shaft (6) between the Coin inlet sensor (27) and the cradle (9) is arranged and that this electromagnet (26) is de-energized after a predetermined period of time after activation of the coin inlet sensor (27), this predetermined period of time being sufficient for the withdrawal of the coin receiving areas (12,15) of the cradle (9). 6. coin validator according to one of claims 1 to 5, characterized, that a coin separator (50) for receiving real coins is provided and a coin acceptance shaft extension (55), a coin conveyor shaft (54) connected to the shaft extension (55) and an overflow shaft (55) which is also connected to the shaft extension (55) that a flap (56) pivotable about an axis (57) between the coin conveyor shaft (54) and the overflow shaft (55) is pivotable, and that a device is provided to transfer the flap (56) 7 from one position to the other and that a coin level sensor (60) arranged in the conveyor shaft (54) and operational is connected to the means for moving the flap (56) from one position to the other. 309832/04 1