NO173475B - PROCEDURE AND APPARATUS FOR SORTING OUT DISCOVERY CIRCUITS, SPECIAL COINS - Google Patents

Abstract

An arriving coin (10') of too large a diameter runs with one edge onto a run-on ramp (44). The raising of the coin (10') also causes the raising of the lower strand (12'') of a conveyor band (12') conveying a stream of coins. The raising brings about a lateral deflection of the lower strand (12'') in the direction of the arrow, the coin (10') to be separated out also being displaced laterally, thereby slipping off from the left-hand supporting edge (22) and tipping into a sorting-out orifice (14). The conversion of the raising movement of the lower strand (12'') into a lateral deflection is brought about by a guide roller (28) which is mounted on an arm (26) pivotable about an axis (50) and which is prestressed against the lower strand (12'') by means of a spring (30). Because the coin (10') to be separated out runs onto the ramp (44), a build-up of coins conveyed thereafter is prevented, thereby guaranteeing a high uniform output of the apparatus. The apparatus makes it possible to separate out coins of too small and of too large a diameter. <IMAGE>

Description

The invention relates to a method according to the preamble of claim 1 and a device according to the preamble of claim 3 for carrying out the method.

In a device of this kind intended exclusively for sorting coins and known from DE-PS No. 3 5 18 2 68, the coins run through a coin recognition device which controls an ejector which attacks the coins to be separated from the side. The ejector pushes the coin aside so that it slides off the installation edge and is tipped into the sorting opening. The movement resulting in this connection across the direction of transport causes the coin in question to slow down and a resulting accumulation of the following coins. The build-up prevents the continuous work process and carries the risk of causing functional disturbances. Furthermore, the impact-like movement of the ejector produces a not inconsiderable noise which is also accompanied by an increased load and a strong utilization.

The purpose of the invention is therefore, in addition to a method, to provide a device which enables the separation of disc-shaped, round objects at a high transport speed and without accumulation.

According to the invention, the stated purpose is solved by the characteristic features in claims 1 and 3.

The solution according to the invention allows, by the same means, the separation of objects with both too small a diameter and too large a thickness. Objects with a diameter that is too small fall through the correspondingly sized sorting opening. For thick objects, a displacement from the transport plane causes the means of transport and thus a lateral deflection of this, so that the objects that are too thick are pulled away from the installation edge until they are tipped into the sorting opening. This does not take place suddenly as with an ejector, but takes place over part of the road along the transport route, so that a "soft" separation is obtained. During a temporary raising of the transport means due to a too thick object which is intended for separation, the transport means are temporarily raised by the adjacent objects which are not to be separated, so that these objects are not torn along in the lateral direction. The continuous transport of the objects is not hindered by the separation of a "false" object, as no sudden braking takes place. Consequently, an accumulation is also ruled out.

With the continuous transport, it is also ensured that during the separation of individual objects there is practically no gap between the objects to be transported further and the conveyor belt. An increased load and noise generation during the separation does not occur. As soon as an object has been tipped down into the sorting opening, it is accelerated downwards by the return force of the deflected means of transport, so that the guide path is again exposed for subsequent objects.

In a preferred embodiment according to claim 2, not only objects that have too small a diameter or are too thick are registered, but also objects that, due to additional criteria, are determined to be separated.

The device according to claim 3 forms the basis of the inventive idea, and makes the separation of non-conforming objects dependent on an elevation of the transport means, which in this connection are deflected laterally in such a way that they convey the object to be separated into the sorting opening.

Although it is also conceivable to use a number of driven rollers as means of transport, an embodiment according to claim 4 is considered particularly preferred.

In an embodiment according to claim 5, a pivotable arm causes the necessary lateral deflection as soon as it is displaced upwards. Although such an arm is also functional due to its gravity, an embodiment according to claim 6 seems advantageous as the spring not only accelerates the return movement, but also accelerates the tilted away object away from the guide path.

In a preferred embodiment according to claim 7, a transformation of the movement into a lateral deflection movement without a pivotable element is possible.

A preferred embodiment according to claim 8 indicates how, due to additional criteria, such objects whose thickness does not exceed the permitted thickness are separated.

An embodiment according to claim 9 serves to separate all objects which have too large a diameter and during transport along the guideway one-sidedly run up the fixed run-up ramp and thus cause the corresponding deflection of the means of transport. With such an embodiment, it is possible to sort out both too small and too large objects without additional control devices, through the same sorting opening, while the objects that are not to be separated are passed over the sorting opening stored on the plant edges.

In an embodiment according to claim 10, the rejection element is movable in the guide path depending on arbitrary criteria, so that e.g. such objects can also be separated if their dimensions do not lie outside the permitted limits.

According to claim 11, the rejection element is a pivotable run-up ramp to achieve a relatively soft rejection movement.

In an embodiment according to claim 12, the sensing and separation takes place in successively spaced stations. Thus, it is e.g. possible to sense the alloy in the individual objects and make the separation dependent on a non-conforming alloy.

According to claim 13, the deflection element has no moving parts.

According to claim 14, the device can be adapted to objects with different diameters.

In connection with the drawing, the following embodiments of the invention will now be explained in more detail. Fig.1 shows a side view of a device for separating thick coins.

Fig. 2 shows the device in fig. 1 view from above.

Fig. 3 shows a section III-III according to fig. 2.

Fig.4 shows the device in fig. 2 when separating a coin that is too thick.

Fig. 5 shows a cross-section V-V according to fig. 4.

Fig. 6 shows a cross-section of a device with a fixed conveyor belt deflector. Fig. 7 shows in cross-section a device with a pivotable conveyor belt deflector. Fig. 8 shows a top view of a device for separating coins that have too large or too small a diameter.

Fig. 9 shows a section IX-IX according to fig. 8.

Fig. 10 shows a section X-X according to fig. 8.

Fig. 11 shows the device in fig. 8 when separating a coin that has too small a diameter.

Fig. 12 shows a section XII-XII according to fig. 11.

Fig. 13 shows the device in fig. 8 when separating a coin

which has too large a diameter.

Fig. 14 shows a section XIV-XIV according to fig. 13.

Fig. 15 shows, seen from the side, an electromagnetically controllable device for separating coins that are detected as counterfeit by means of a sensor.

Fig. 16 shows the device in fig. 15 seen from above.

Fig. 17 shows a detail of fig. 16 in cross-section when a "correct" coin is passed through. Fig. 18 shows the same as in fig. 17, but by the separation of a "false" coin.

Fig. 19 shows a block diagram of the device of fig. 15.

Fig. 1 shows a device seen from the side and which, in the basic design, next to the separation of coins that have too small a diameter, is especially intended for the separation of coins that are too thick. An endless conveyor belt 12' which serves as means of transport 12 winds around two diverting rollers 46 and 46' rotating in the direction of the arrow. The lower belt part 121• of the conveyor belt 12' grips from above by adhesion friction a coin 10 which is transported in a transport plane 20 along a guide path 18. Two pressure rollers 48 standing under spring force ensure that the lower belt part 12'• of the conveyor belt 12<1>is towards the coins 10 which are to be transported over the entire transport route. In order to increase clarity, fig. 1 shown only one coin. However, since it is a high-performance device, during normal operation the coins arrive in a row.

A guide roller 28, which also acts as a deflection element 24 at the lower belt part 12'' of the conveyor belt 12', is stored to an arm 26 which can be swung out on one side about a pivot axis 50. In the bottom 52 of the guide path 18 there is a sorting opening 14.

On the ground plan in fig. 2, it can be seen how the coin IO<1>' which is not to be sorted out, is led away over the sorting opening 14. When the conveyor belt 12' attacks the coin IO'1 offset in relation to the centre, the coin is located during the transport in one-sided contact on a guide rail 16 Between the guide rail 16 and the sorting opening 14 there is a narrow contact edge 22. The shown coin 10'• has such a large diameter that it completely spans the sorting opening 14. From the illustration it can therefore be deduced that a coin with a smaller diameter that is on the guide rail 16 falls into the sorting opening 14. Of the two transfer rollers 46 and 46', the first transfer roller 46 is driven by a motor 54.

From the outline in fig. 3, it is particularly clear to what extent the pivot axis 50 is arranged laterally shifted above the transport roller 28. The pivot axis 50 is located on a console 58 arranged to a wall 56. The arm 26 and thus the guide roller 28 stand against a stop 36 under the influence of a tension spring 30, so that the guide roller 28 rests against the lower belt portion 1211 of the conveyor belt 12'.

In fig. 4 it is shown that the guide roller 28 and thus the lower belt part 121' of the conveyor belt 12' is shifted towards the side opposite the guide rail 16 when the lower belt part 12<11> e.g. is raised by a coin that is too thick. During the deflection, the coin 10' is pulled sideways, so that it slides off the contact edge 22 and is tilted into the sorting opening 14.

On the section according to fig. 5, the sequenced lateral displacement of the coin 10' is clearly visible. When raising the lower band part 12'', it is also ensured that the coins 10' which are to be separated, adjacent subsequent and previous coins are not torn laterally, as the lower band part is temporarily lifted up by the thinner coins which are not to be separated out.

By the action of the tension spring 30, the guide roller 28 is forced back into its normal position according to fig. 3. Thus, the tilted away coin 10' is accelerated in the direction of the arrow 60 so that the lower band part 12'<1> again comes to rest on the other coins.

In the above-mentioned type of separation of the coin 10', whose thickness is greater than the thickness of the coins that are passed through, the continuous transport of the coin stream is, however, not hindered in any way, as the separation process by means of the sorting opening 14 extends some distance away over the guideway 18 according to the principle of a track switch. It also follows that the separation takes place without the load of a control device. The deflection element 24 with the guide roller fulfills both functions, namely the registration of a coin that is too thick and the separation of the same.

In fig. 6 shows a conveyor belt deflector 42 in the form of a deflection element 24' with an inclined, fixed deflection surface 42'. Viewed in the longitudinal direction of the guide path, the deflection surface 42' extends arcuately to provide a soft deflection of the lower band portion 12<1>'. In the same way as in the design example according to fig. 4 and 5, the separation of coin 10' which is too thick occurs in that the lower band part 12'' is raised by the coin 10' and deflected by the deflection surface 42'. Thus, the coin 10' to be sorted out is pulled away from the installation edge 22 so that it is tilted into the sorting opening 14.

The embodiment according to fig. 7 has as deflection element 24'' a conical deflection roller 32 stored in the same position. The function of this deflection roller essentially corresponds to the same as for the deflection surface 42'. Both the conveyor belt indicator 42 according to fig. 6 as also a bearing bolt 62 which carries the conical deflection roller 32 is fixed on the vertical wall 56. In comparison with the too thick coin 10" to be separated, in each of the two figures 6 and 7 is shown a normally thick coin 10''. The sorting opening 14 is i

both cases arranged in a bottom plate 64.

The one in fig. 8 device shown in a plan differs from the previously described devices in that a rejection element 3 4 is arranged on the guide path 18 in the form of a run-up ramp 44 which on one side raises the coins to be sorted out and which lie opposite the guide rail 16 on the side in the transport direction in front of or below the sorting opening 14. The run-up ramp 44 is formed by a pusher 66 which, facing the transport rail 16, has another contact edge 68. In the embodiment shown, there is precisely a coin 10<1>' which is not to be separated, over the sorting opening 14, so that it is stored on both sides on the construction edges 22 and 68.

For adaptation to each of the coins IO<1>' to be passed through, the pusher 66 is adjustable after loosening a wing screw 70. For this purpose, the pusher 66 is connected to two guide rods 74 which are guided in a respective pusher guide 72. on the opposite side of the pusher 66, the guide rods 74 are connected by a strip 76 where the wing screw 70 is screwed in and can be displaced in a long hole 78 arranged in the bottom surface 64. Fig. 9 shows a longitudinal section IX-IX according to fig. 8. Fig. 10 shows a cross section X-X according to fig. 8. In fig. 10, it can be seen in particular that the adjustment elements 72,74 and 76 for the pusher 66 are located under the bottom plate 64. Furthermore, it can be clearly seen that the width of the sorting opening 14 can be set with the pusher 66. The arrangement of the guide roller 28 corresponds to those in fig. 1-5 given explanations. Fig. 11-14 show the same device as in fig. 8-10. In fig.11 and 12, it can be seen in this connection how a coin with too small a diameter immediately falls into the sorting opening 14.

In connection with fig. 13 and 14, it is shown in sequences how a coin 10', which has too large a diameter, runs up the run-up ramp 44 which serves as a rejection element and thus causes an elevation and deflection of the guide roller 28, slides off the contact edge 22 and is tipped into the sorting opening 14, in which connection the guide roller 28 which is under spring load, helps.

Fig. 15-19 shows a device for separating non-conforming coins, regardless of their diameter and thickness. From fig. 15 and 16, it can be seen that a conical deflection roller 32 serves as deflection element 24<1>', as has already been explained in connection with fig. 7. The other elements arranged above the bottom plate 64 mainly correspond to a design according to fig. 1 and 2. Under the bottom plate 64, in the transport direction in front of the sorting opening 14, there is arranged at least one coin recognition device 80 equipped with a sensor 40 and which is connected via signal lines 82 to a control circuit.

A run-up ramp 38 which can be swung into the guideway 18 and operated by means of an electromagnet 84 serves as a rejection element 34•. The electromagnet 84 is maneuvered depending on the previously sensed properties of the transported coins, when the coin 10 just passed is registered as fake and destined for separation. The electromagnet 84 is connected via connection lines 86 to the aforementioned control circuit and, in order to maneuver the run-up ramp 38, has a bumper 88 and a return spring 90. By means of a holder 92, the electromagnet 84 is connected to the bottom plate 64. The run-up ramp 38, which can be maneuvered by the magnet 84, can be swung about a pivot axis 94. To limit the two end positions of the pivot path, a stop 96 formed at the holder 92 is used.

From fig. 17 and 18, the operation of the swing-in ramp 38 can be seen. In the rest position according to fig. 17, the coin can be passed unhindered over the sorting opening 14. When the run-up ramp 38 according to fig. 18, however, is swung into the conveyor path, while the coin 10' is located immediately above it, the coin 10' is then, by the interaction of the deflection roller 32 with the lower belt part 12'1 of the conveyor belt 12<*>picked away from the installation edge 22 and tilted into the sorting opening 14 .

While fig. 17 and 18 show the transport path in cross-section, the circled figures below show the respective position of the run-up ramp 38 seen from the side. In the rest position according to Fig. 17, the upper surface of the run-up ramp 38 is connected to the transport path 18. The arrows below the run-up ramp 38 each show the direction of maneuvering. In fig. 17, the direction of maneuvering against the return force of the spring 90 is indicated. In fig. 18, it concerns the direction of maneuvering by means of the magnet 84.

Since it is a high-performance device for sorting out coins, the coins are transported along the guide path 18 at a relatively high speed. For that reason, it is necessary that the swing-in duration for the run-up ramp 38 according to fig.

18 is in the order of milliseconds.

In fig. 19 shows the already mentioned control circuit 98 which receives the signals to the sensor 40 via the lines 82. The electromagnet 84 is controlled via the line 86. The sensors 40 can e.g. detect the inductance of the transported coins, allowing an inference about their alloy.

The above described embodiment examples should not only be considered as alternatives, but they can be arranged one after the other and complement each other in a meaningful way. Thus, it is e.g. it is possible that separation first occurs due to deviating diameter and thickness, while further criteria for separation are then drawn in, as long as dimensions such as diameter or excessive thickness have not already led to separation.

Although the above description is aimed at coins, it is also possible to sort other round disc-shaped objects, e.g. washers according to the same principle.

With a corresponding setting of the device, it is possible that only a single value of a coin or all coins of a particular currency are allowed through. All coins that have too small or too large a diameter and are too thick can be separated purely mechanically without an electrical or electronic control. The review of a single coin value can e.g. serve to deliver the coins to a subsequent packaging machine. The review of all coins of a particular coin base is particularly desirable when the coins are then to be fed to a counting machine or sorting machine.

The above-mentioned embodiments have the common feature that, with the exception of coins that have too small a diameter, all other coins to be separated cause a lateral deflection of the lower belt part 12•' of the conveyor belt 12', so that the coins in question themselves become sideways displaced in such a way that they slide off the contact edge 2 2 and end up in the sorting opening 14. This kind of sorting takes place without delaying the rest of the coin flow and without the impact of an element striking the coin. Nor does the run-up ramp 38 which can be swung into the guide path 18 according to fig. 15 to 18 give some blow to the coins to be sorted out. Despite these "soft" properties, the mentioned device is suitable as a high-performance sorting device.

Claims (14)

1. Procedure for sorting out disk-shaped, round objects, in particular coins (10), whose characteristics, including dimensions, lie outside the predetermined values for objects that are not to be separated, from a stream of such objects which, with the help of means of transport acting from above (12) is guided along a rising guide rail (16) on the side of a guide path (18) which has at least one sorting opening (14) which is separated from the guide rail (16) by a construction edge (22), characterized in that they at least in the area of the sorting opening (14) across the transport device yieldingly arranged transport means (12) are laterally bent out of the transport plane when one of the transported objects (10') causes displacement, that the object (10') which causes the displacement is thereby pulled away from the guide rail (16) and the construction edge (22) and that the object (10<*>) ends up in the sorting opening (14). 2. Method according to claim 1, characterized in that the objects (10') which are intended for sorting are unilaterally raised in the area of the sorting opening (14). 3. Device for carrying out the method according to claim 1 or 2, where the device is equipped with transport means (12) which grab the objects (10, 10', 101') to be sorted, from above, press them against one side of a guide rail (16) and transports them along a guide path (18) which has a sorting opening (14) which is separated from the guide rail (16) by a narrow contact edge (22), and where the width of the sorting opening (14) is smaller than the diameter of the smallest object (10'') that should not be separated, characterized in that the means of transport (12) in the area of the sorting opening (14) are guided by a deflection element (24), because in the case of one of the transported objects (10') displacement caused it to be deflected from the transport plane (20) in the direction opposite the guide rail ( 16) horizontal page. 4. Device according to claim 3, characterized in that the means of transport (12) have a revolving drivable conveyor belt (12<1>) which by adhesion friction includes the objects (10) to be transported by. 5. Device according to claim 3 or 4, characterized in that the deflection element (24) has one to one swing-out arm (2 6) stored guide roller (28). 6. Device according to claim 5, characterized in that the arm (26) is biased by a spring (30) which causes a return force. 7. Device according to claim 3 or 4, characterized in that the deflection element (24<1>') is formed by a conical deflection roller (32) stored in a fixed position. 8. Device according to one of the claims 3-7, characterized in that a rejection element (34) is arranged on the guide path (18) in the direction of transport in front of or next to the sorting opening (14) for one-sided lifting of the objects (10) that are to sorted out. 9. Device according to claim 8, characterized in that the rejection element (34) is formed as a fixed run-up ramp which lies opposite the guide rail (16) and whose lateral distance from the guide rail (16) is insignificantly greater than the diameter of the largest object (10<11> ) which are not to be separated, and that between the edge of the sorting opening (14) and the run-up ramp, another installation edge is formed which lies opposite the first-mentioned installation edge (22) . 10. Device according to claim 8, characterized in that the rejection element (34) is designed so that it can be moved from below in the guide path (18). 11. Device according to claim 10, characterized in that the rejection element (34) is a run-up ramp (38) which can be swung into the guide path (18). 12. Device according to claim 10 or 11, characterized in that the rejection element (34) can be operated electromagnetically depending on the properties of the objects (10) that are being transported, detected in advance by a sensor (40). 13. Device as stated in claim 3 or 4, characterized in that the rejection element (24') has an inclined, fixed deflection surface (42'). 14. Device according to claim 8, characterized in that the rejection element (34) is formed by a run-up ramp (44) which can be set in the lateral direction from the transport rail (16) and which has another contact edge (68) which lies opposite the aforementioned contact edge (22) ).