1. Field of the Invention
The invention relates to a device for separating coins, comprising a rotatable base disc and a delimiting element, wherein the base disc and the delimiting element delimit a receiving area, open to the top, for receiving a quantity of coins to be separated, and wherein in the delimiting element an opening for the passage of coins and for the feeding to an elastic conveying element is provided in a transfer region, which conveying element feeds separated coins along a circular ring-shaped sorting track to sorting devices.
2. Description of the Related Art
Devices for handling coins usually have an input compartment into which the coins to be handled can be input in the form of an unsorted quantity of coins. This input quantity of coins is fed to a coin storage container in the form of a receiving area which is defined by means of delimiting elements and from which the coins are further processed. So that the input coins can be checked with respect to their authenticity by means of corresponding sensors and a later sorting can be implemented, it is required that the input coins are separated, i.e. that the coins when fed to a sensor unit and/or a sorting unit do not lie on top of each other and are not arranged laterally next to each other on a transport path.
In order to achieve such a separation, often coin centrifuges are used in which the coins of the quantity of coins received in the coin storage container are arranged on a rotating disc. By means of the centrifugal force acting on the coins upon rotation of the disc, the coins are conveyed outward. In the delimiting element for the coin supply, at least one opening is provided which is formed such that only one coin at a time can pass, as a result whereof the separation of the coins is accomplished.
What is problematic with such known coin centrifuges is that the separation is only accomplished unreliably so that it may easily happen that several coins are simultaneously transported through the opening and thus a minimum distance between the coins required for the further processing is not reliably guaranteed. Further, the opening in the delimiting element can easily be blocked by coins getting wedged therein so that a coin jam occurs which can only be removed by way of a manual intervention.
Further, it is problematic that each time the coin centrifuges have to be adapted to the set of coins to be handled, in that the size of the opening is correspondingly matched to the coin set. The opening or the openings have to be designed such that indeed the largest coin to be handled can be conveyed therethrough but no two of the smallest coins to be handled simultaneously fit through the opening. Likewise, it has to be guaranteed that the thickest coin can pass the opening but not two coins lying on top of each other.
A device for separating coins is known from DE 195 43 216 A1. This device comprises a feeder disc which interacts with a coin removal disc and performs a coin separation in connection with a coin gap. The coins to be separated are fed to a circular sorting track on which the coins are moved in a flat-lying and sliding manner by means of an annularly moved brush device along the sorting track. For sorting the coins to be separated, the sorting track contains openings through which the coins fall.
It is the object of the invention to specify a device for separating coins, by means of which in a large range of coins a reliable separation of the coins from an input quantity of coins is made possible.
According to the invention a rotatable base disc and delimiting elements interact such that they delimit an open receiving area for receiving a quantity of the coins to be separated. In the delimiting element an opening for the passage of coins and for the feeding to an elastic conveying element is provided in a transfer region. This conveying element conveys separated coins along a circular ring-shaped sorting track to various sorting devices. The sorting track is arranged eccentrically relative to the base disc. Due to this eccentricity, in which the base disc and the circular ring-shaped sorting track are arranged within a construction that is circular in cross-section, a compact small design is achieved for the entire device.
On the base disc a driver disc is arranged concentrically relative to the base disc, wherein the driver disc and the conveying element interact in the transfer region such that coins of the lowest layer of the quantity of coins conveyed by the driver disc are pushed underneath the conveying element and are clamped thereat. The conveying element moves concentrically relative to the circular ring-shaped sorting track so that due to the eccentricity of the base disc, the driver disc and the circular ring-shaped sorting track or the conveying element running along the sorting track a wedge-shaped geometry results, wherein one side of the wedge is formed by the conveying element and the other side of the wedge is formed by the transport direction of the coins conveyed by the driver disc.
By means of the driver disc and the conveying element a distance A is defined which specifies the distance between the lateral surface of the driver disc and the conveying element. In a preferred embodiment, this distance A is smaller than the diameter of the smallest coin to be separated by the device. Here, A can also take a negative value, i.e. an overlapping between driver disc and conveying element may exist. Even more preferred, this distance A is greater than zero and smaller than the diameter of the smallest coin to be separated by the device. Surprisingly, it has been found out that within these ranges a very efficient separation with little errors is accomplished and that a stationary coin separator—described further below can be dispensed with. By the term “greater than zero” it is meant that the driver disc is arranged just so far from the conveying element that the driver disc no longer contacts the conveying element.
The quantity of coins is conveyed by the rotating base disc in the direction of the transfer region, wherein the coins can lie on top of each other in several layers. At its lateral surface, the driver disc only conveys coins of the lowest layer in the direction of the transfer region in which, due to the mentioned wedge-shaped geometry, coin and conveying element approach each other such that the coin conveyed by the driver disc is pushed underneath the conveying element and is clamped thereat. By means of this clamping effect the conveying element then conveys the separated coin further along the circular sorting track. Due to the elasticity of the conveying element both thin and thick coins in a broad thickness range can be clamped and conveyed further. Coins of a higher layer than the lowest layer are not necessarily conveyed in the direction of the transfer region or conveying element by the driver disc but continue to rotate with the rotatable base disc within the delimiting element until they reach the lowest layer on the base disc and are then conveyed by the lateral surface of the driver disc up to the conveying element and clamped thereat. In this way, a reliable separation of the coins given a broad universal applicability for a broad range of coins is accomplished.
The driver disc is in particular rigidly connected to the base disc so that it has the same speed of rotation as the base disc. As a result, a simple structure of the device is achieved. It is, however, likewise conceivable that the driver disc is driven separately and has a higher speed of rotation than the base disc, as a result whereof further technical advantages are achieved, such as a more efficient separation given a relatively slowly rotating base disc.
The driver disc in particular has a height smaller than the smallest thickness of the coins to be processed. In this way, it is guaranteed that only the lowest layer of the quantity of coins is moved in the direction of the conveying element and individual coins are clamped thereat. Thus, a double transport of coins lying on top of each other is prevented.
In a preferred embodiment, the driver disc has at its lateral surface a friction coating, in particular a rubber coating or a sand grain coating. Alternatively, the lateral surface can have a roughened structure or a toothing. By increasing the friction coefficient, coins of the lowest layer are reliably conveyed and there will be no “back-up” of coins in the lowest layer in the transfer region.
An option which is not absolutely necessary but advantageous is to arrange a stationary coin separator in the transfer region. Preferably, the stationary coin separator is used when the distance A between the lateral surface of the driver disc and the conveying element is greater than the diameter of the smallest coin to be separated by the device. If, as described above, the distance A is, however, smaller than the diameter of the smallest coin to be separated by the device, then advantageously a stationary coin separator can be dispensed with. Thus, a preferred embodiment of the present invention relates to a device for separating coins without a stationary coin separator. An even more preferred embodiment of the present invention relates to a device for separating coins without a stationary coin separator, wherein the distance A is smaller than the diameter of the smallest coin to be separated by the device, even more preferred wherein the distance A is greater than zero and smaller than the diameter of the smallest coin to be separated by the device. If a stationary coin separator is used, then it is preferably arranged at the end of the transfer region, as viewed in the direction of rotation of the driver disc. For example, as a coin separator a deflecting element can be provided which feeds coins of the lowest layer reliably to the conveying element. The height of the deflecting element should be slightly lower than the smallest thickness of the coins to be processed. Such a stationary coin separator improves the efficiency of the separation.
The device is in particular designed such that the transport speed of the conveying element is higher than the transport speed of the coins which are transported by the lateral surface of the driver disc. In this way, the elastic conveying element conveys the separated and clamped coins faster away from the transfer region than they are fed by means of the driver disc. As a result, the separation becomes reliable and on the sorting track there result sufficient distances between the separated coins.
In one embodiment, the conveying element comprises a ring-shaped elastic clamping ring and a holding ring made of a rigid material, such as plastic or metal, connected to this clamping ring. For example, the clamping ring is made of rubber or thermoplastic polyurethane (TPU) or of polyurethane (PU). These materials are well suited to apply sufficient clamping force on the separated coins to convey these away from the base disc and to transport them along the sorting track.
Further features and advantages of the invention result from the following description which explains the invention in more detail on the basis of embodiments in connection with the enclosed Figures.
Along the sorting track 12 and concentrically relative thereto, an elastic conveying element 14 is arranged which serves to convey separated coins and transports these along the sorting track 12. The elastic conveying element 14 comprises at its underside a ring-shaped elastic clamping ring (not illustrated in
An arrangement for feeding separated coins to the conveying element 14 comprises a rotatable base disc 32, a delimiting element 34 and a driver disc 36, wherein the base disc 32 and the delimiting element 34 delimit a receiving area, open to the top, for receiving a quantity of coins to be separated. In the delimiting element 34, an opening for the passage of coins and for the feeding to the elastic conveying element 14 is provided in a transfer region 38. Typically, the delimiting element 34 can be designed as a funnel which has a larger opening at the top as compared to the lower boundary. The delimiting element 34 can be oval or have any other shape.
On the base disc 32, the driver disc 36 is arranged concentrically relative to the base disc 32. The driver disc 36 is rigidly connected to the base disc 32 and, with respect to the level of the base disc 32, has a height smaller than the smallest thickness of the coins to be processed. The driver disc 36 and the conveying element 14 interact in the transfer region 38 such that, given a clockwise rotation of the driver disc 36 and thus coins conveyed in same direction as the conveying element 14, coins of the lowest layer are pushed underneath the conveying element 14 and are clamped thereat.
The sorting track 12 and thus the conveying element 14 rotating on a circular ring are arranged eccentrically relative to the base disc 32 and thus eccentrically relative to the driver disc 36. Due to this eccentric geometry, a wedge shape results in the transfer region 38, which wedge shape causes that coins of the lowest layer of the quantity of coins conveyed by the lateral surface of the driver disc 36 and given a clockwise rotation are inevitably moved outward in the direction of the conveying element and are thus pushed underneath the conveying element and are clamped thereat. By setting the eccentricity, the wedge shape can be varied and thus be adapted to the size range of the diameter of the coin range.
The coins separated and clamped in this way, are further conveyed clockwise by the elastic conveying element 14 and reach an orientation device 40 which orients the separated coins such that they are conveyed along the outer track boundary 16 by the conveying element 14. On their conveying path, the coins reach a coin checking device 42, known per se, where they are checked for physical properties. Incorrect coins are fed by means of a deflecting device 44, such as a controllable deflector or an extendible pin, to a rejecting ejector 46, where the incorrect coins are sorted out. Correct coins are further conveyed on the sorting track 12 and successively reach the various sorting ejectors 18 to 30, where they are sorted in ascending order dependent on the coin diameter.
Preferably, the driver disc 36 has a friction coating, such as a rubber coating, on its lateral surface. As a result, the transport of the coins of the lowest layer of the quantity of coins by means of the driver disc 36 becomes more efficient and a coin jam is prevented. Due to the rotation of the base disc 32, coins lying over the lowest layer run in a circulating manner within the receiving area into the circle.
The transport speed of the conveying element 12 is higher than the transport speed of the coins which are fed in the transfer region and which are transported by means of the lateral surface of the driver disc 36. In this way, the separated coins are quickly transported out of the transfer region 38 so that along the sorting track 12 the coins are sufficiently spaced apart. Preferably, the speed relations are set such that the speed v1 at which the coins are moved due to the rotation of the base disc 32 is lower than the speed v2 at which the coins of the lowest layer are transported by means of the lateral surface of the driver disc 36 which in turn is lower than the transport speed v3 of the conveying element 14. Accordingly, the following applies to the speeds: v1<v2<v3.
Optionally, in the transfer region 38 a stationary coin separator (see
In a detail,
The described device can be further developed in various ways. The driver disc 36 can be arranged such that it is rotatable independently of the base disc 32. The base disc and the driver disc can also be formed in one piece, the driver disc projecting above the level of the base disc by the described height.
The eccentric arrangement of the base disc 32 and the driver disc 36 with respect to the circular arrangement of the conveying element 14 can be adjustable, as a result whereof the wedge geometry can be varied to be adapted to different sizes of the coins to be processed. By means of the shown device all international coins in the diameter range between 14.5 mm to 33 mm can be separated reliably. The speed of rotation for the base disc can be substantially lower than the one of conventional coin centrifuges which usually use rotation discs. The coins output by the sorting ejectors can directly be supplied to a cash register or a coin storage.
Number | Date | Country | Kind |
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12188583 | Oct 2012 | EP | regional |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/EP2013/069366 | 9/18/2013 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2014/060172 | 4/24/2014 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
5295899 | Adams | Mar 1994 | A |
6772870 | Sugai | Aug 2004 | B2 |
6945864 | Hino | Sep 2005 | B2 |
7704133 | Adams | Apr 2010 | B2 |
Number | Date | Country |
---|---|---|
39 11 727 | Oct 1990 | DE |
39 11 727 | Oct 1990 | DE |
195 43 216 | May 1997 | DE |
9318488 | Sep 1993 | WO |
Entry |
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English Translations of International Preliminary Report on Patentability and Written Opinion—Apr. 30, 2015, PCT/EP2013/069366 (9 pages). |
International Search Report of Oct. 10, 2013, PCT/EP2013/069366 (9 pages). |
European Search Report of Mar. 20, 2013, 12188583.4 (6 pages). |
Number | Date | Country | |
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20150269803 A1 | Sep 2015 | US |