EP0485709A2 - Device for separating, spacing and transporting coins - Google Patents

Abstract

Moveable ejector elements (25) are arranged in the receiving spaces (21) of a rotary-driven take-up disc (2) moved by a coin-collecting container. To prevent two or more coins lying in the same receiving space (21) from being guided to a sorting rail (30), the ejector elements (25) have a rearwardly descending face (38) in the region confronting the axis of rotation (2') of the take-up disc (2). Furthermore, oblique guide faces (35) are provided for the same purpose in the edge region of the receiving orifices (21). Coins can fall out of the receiving space (21) by way of these guide faces (35) before they arrive at the sorting rail (30). <IMAGE>

Description

The present invention relates to a coin separating device.

In a known device of this type, as is known in particular from DE-A-26 09 788, it can occur in individual currency areas in which the diameter of the largest coin is twice as large or larger than the diameter of smaller coins. that two or more coins are received next to one another in a receiving space of the driving disk, which coins are then simultaneously released to the sorting rail, which leads to faults.

From CH-A-667 158 (or the corresponding GB-A-2,173,027) it is now known to form the edge region of the receiving spaces in a certain way to remedy this disadvantage.

The present invention is based on the object of providing a coin separating device which is capable of reliably ensuring that the coins are separated correctly even when there are two or more coins in a receiving space.

This object is achieved in the manner described in claim 1.

Fig. 1

Einen Vertikalschnitt durch eine Münzenvereinzelungsvorrichtung entlang der Drehachse der Mitnahmescheibe,

Fig. 2

In Draufsicht die Mitnahmescheibe mit Abstreifer und Sortierschiene,

Fig. 3

Eine Draufsicht auf die Mitnahmescheibe mit entfernten Auswerfern,

Fig. 4

Einen Schnitt entlang der Linie IV-IV in Fig. 3

Fig. 5

Einen Schnitt entlang der Line V-V in Fig. 3

Fig. 6

Einen Auswerfer in Seitenansicht,

Fig. 7-12

Die obere Hälfte der Mitnahmescheibe gemäss Fig. 2 in Draufsicht bzw. in einem Schnitt beim Vereinzeln verschiedenartiger Münzen, und

Fig. 13-17

In der Fig. 2 ensprechenden Darstellungen verschiedene mögliche Ausführungsformen.

Exemplary embodiments of the subject matter of the invention are explained in more detail below with reference to the drawing. It shows purely schematically:

Fig. 1

A vertical section through a coin separating device along the axis of rotation of the driving disk,

Fig. 2

Top view of the drive plate with scraper and sorting rail,

Fig. 3

A top view of the drive plate with the ejectors removed,

Fig. 4

A section along the line IV-IV in Fig. 3rd

Fig. 5

A section along the line VV in Fig. 3

Fig. 6

A side view of an ejector,

Fig. 7-12

The top half of the driving disk according to FIG. 2 in a top view or in a section when separating different types of coins, and

Fig. 13-17

In the corresponding representations in FIG. 2 different possible embodiments.

In Fig. 1, the section of the beginning of a coin separating device is shown, which is structurally related to the device according to DE-A-26 09 788, but differs from the latter primarily in the other design of the driving plate, as is shown in FIG 2 to 6 will be explained in more detail.

As can be seen in FIG. 1, the coin separating device has a collecting container 1 for the coins to be sorted as well as a driving disk 2 which, in a manner to be described later, brings the coins out of the collecting container 1 to a sorting rail (not visible in FIG. 1). The inclined drive plate 2 is approximately parallel to an inclined plate 4 held in a frame 3. A shaft 5 is freely rotatable in this plate 4. A pulley 6 and a gear 7 are attached to the end 5a of the shaft 5 which extends on the inside of the plate 4a. At the other end 5b of the shaft 5, the driving plate 20 is fastened, for example by means of screws. A drive belt 8 runs over the pulley 6 and is driven by a motor, not shown. The gear wheel 7 meshes with a pinion 11, which is mounted on a bearing pin 12 fastened to the rear side of the plate 4. With the pinion 11, a sprocket 13 is rotatably connected, which is provided for driving a conveyor chain, not shown, which conveys the coins emitted from the driving plate 2 onto the already mentioned sorting rail to a sorting device, also not shown, by means of conveyor bolts, as has already been done in the mentioned DE-A-26 09 788 is described in more detail.

The driving plate 2 has a plurality of receiving spaces 21 which are arranged along a concentric circle and are open towards the front and closed off at the rear by a base 21a. An ejector 22 is arranged in each receiving space 21. Each ejector 22 has a bolt 23, which extends through the driving plate 2 and is guided in the latter in an axially movable manner and carries a disk-shaped ejection element 25 at one end. A ring 26 is also attached to the bolt 23, on which one end of a compression spring 27 is supported, the other end of which rests on the underside of the driving plate 2. The rear end 28 of the bolt 23 is pressed by the compression spring 27 against a control cam 29, which extends coaxially to the axis of the shaft 5 and has 25 regions of different heights for controlling the movement of the ejection elements, which is still to be described. The control curve 29 extending along an arc is preferably closed.

In Fig. 2, which shows a plan view of the driving plate 2 with the collecting container 1 omitted, the sorting rail 30 mentioned earlier is shown. FIG. 2 further shows a wiper 31 formed by a thin sheet metal, which is fixedly attached to the frame 3 in a manner not shown in detail.

The structure of the driving plate 2 will now be explained in more detail below with reference to FIGS. 2 to 6.

As can be seen from FIGS. 3 and 4, which show the driving plate 2 without an ejector 22, a through hole 32 is formed in the bottom 21a of each receiving space 21, that serves to guide the pin 23 of the assigned ejector 2. Furthermore, a further through hole 33 is provided in said bottom 21a, which is offset from the through hole 32 and which serves to receive a guide pin 34 which is provided on the underside of the ejection element 25 (see FIG. 6). A rotation of the ejector 22 in the receiving space 21 is prevented by the pin 34 passing through the through hole 33.

Each receiving space 21 has a substantially cylindrical shape and is provided at the confluence with the flat front surface 2a of the driving plate 2 with a crescent-shaped guiding surface 35 which is chamfered and falls from the front surface 2a of the driving plate 2 towards the interior of the receiving space 21. This bevelled guide surface 35 is provided in the edge region 36 of the receiving space 21, which, viewed in the direction of rotation A of the driving plate 2, is directed toward the axis of rotation 2 'of the driving plate 2. In the area of this bevelled guide surface 35, the height h 'of the edge 21b of the receiving space 21 is correspondingly smaller than the height h of the remaining edge area of the receiving space 21 (see FIG. 4).

Each ejection element 25 has two surfaces 37 and 38 inclined towards one another, as can be seen in particular from FIG. 6. The surface 37 runs approximately at right angles to the longitudinal axis 23a of the bolt 23 and thus approximately parallel to the front surface 2a of the drive plate 2. The other surface 38 then falls obliquely to the surface 37 against the edge 25a of the ejection element 25. The sloping surface 38 is on the axis of rotation 2 'of the drive plate 2 facing side of the ejection element 25 is provided, as can be seen in FIG. 2. In the exemplary embodiment shown, the transition from surface 37 to surface 38 runs approximately along a diameter which is approximately perpendicular to the radial direction of drive plate 2. However, the type and location of the transition from surface 37 to surface 38 can also be designed differently.

Before the operation of the coin separating device is described with reference to FIGS. 8 to 12, the movement sequence of the ejectors 22, which is controlled by the control curve 29, will now be explained with reference to FIG. 2.

As already mentioned, the driving plate 2 is driven in a rotating manner in the direction of arrow A. The ejection elements 25 are in their rear end position, which can be seen from FIG. 2, in the area designated B in which the driving plate 2 dips into the collecting container 1. In this end position of the ejection elements 25, coins can now get into the receiving space 21. When the driving disk 2 continues to rotate, the ejection elements 25 begin at point C, which have reached their front end position at the point denoted by D, in which the surface 37 lies approximately in the plane of the front surface 2a of the driving disk 2. In this front end position, the ejection elements 25 are guided under the scraper 31. At about point E, the ejection elements 25 are moved back relatively quickly by a certain amount in order to prevent the coin from falling out of the receiving space 21 via the guide surface 35. Has a recording room 21 reaches the point F, the ejection element 25 is rapidly moved forward, the surface 37 again coming to lie approximately in the plane of the front surface 2a. The surface 38 and the guide surface 35 are designed such that in this ejection position of the ejection element 25, the surface 38 lies somewhat above the inner edge 35a of the guide surface 35 (FIGS. 2 and 5), so that the coin located in the receiving space 21 now hangs without it to remain on the guide surface 35 slides on the sorting rail 30, via which the coin is then, as already described, carried away. The ejection elements 25 are then quickly moved back to their rear end position.

The separation of coins of different sizes will now be explained with reference to FIGS. 7 to 12.

In Figures 7 and 8 (which shows a section along the line VIII-VIII in Fig. 7), the separation of a large coin 40 is shown, the diameter of which is slightly smaller than the diameter of the receiving spaces 21. It is obvious that because of the The size of the coin 40 no longer has any space for a second coin in the receiving space 21. However, it would be conceivable for a second coin to lie on the coin 40. However, this second coin would move in the course of the forward movement of the ejection elements 25 before reaching point D. are ejected from the receiving space 21 and fall back into the collecting container 1. If the ejection element 25 has reached the front end position in the area D, in which the surface 37 is flush with the front side 2a of the driving plate 2, the coin 40 is on the one hand on the other surface 38 of the ejection element 25 and on the other hand on the edge 21c of the Recording space 21 on, as can be seen from Fig. 8. FIG. 8 also shows that a small space is formed between the coin 40 and the surface 37 of the ejection element 28, into which the very thin wiper 31 engages when the coin 40 drives past, without acting on the coin 40. In other words, the large coin 40 runs past the stripper 31. 8, the purpose of the obliquely extending surface 38 can now be readily recognized. The ejection element 25 is less high in the region of the edge 25a facing the axis of rotation 2 'of the driving plate 2 than on the opposite side. This means that the coin 40 resting on the surface 38 can still be supported in the edge region 21c of the receiving space 21, although, as already mentioned, the surface 37 of the ejection element 25 is flush with the front surface 2a of the driving plate. The inclination of the surface 38 is chosen such that the height a of the edge 21c on which the coin 40 is supported is less than twice the thickness of the thinnest coins, so that two of the thinnest coins cannot be supported on this edge 21c.

If the receiving space 21 with the coin 40 has now reached the point E, as already mentioned, the ejection element 25 is withdrawn somewhat so that the coin 40 cannot fall out of the receiving space 21 via the beveled guide surface 35 when the driving disk 2 is turned further. At point F, coin 40 is then ejected onto sorting rail 30, as has already been described with reference to FIG. 2.

9 shows the other extreme case, in which three of the smallest coins 41, 42, 43 are located in a receiving space 21. In the case shown, the coins 41 and 43 rest against the inclined surface 38 of an ejection element 25, while the coin 42 rests on the surface 37. At point D, as already mentioned, the ejection element 25 has reached the front end position, in which the surface 37 is aligned with the front surface 2a of the driving plate 2 and the surface 38 lies somewhat above the inner edge 35a of the guide surface 35. When the coins 41 to 43 pass the stripper 31, the coin 42 runs onto the latter, is deflected laterally and falls back into the collecting container 1. Shortly after passing the stripper 31, the coin 43 then falls down over the beveled guide surface 35 from the receiving space 21 into the collecting container 1. Thus, only the coin 41 remains in the receiving opening 21, as described with reference to FIG. 8 , can be supported at the lower edge 21c of the receiving space 21. At point E, the ejection element 25 is moved back a little, as mentioned, so that the coin 41 cannot also slide over the guide surface 35. The coin 41 ejected at point F rolls away over the sorting rail 30.

FIG. 10 shows the separation process with two coins 41 and 42 lying next to one another in a receiving space 21. Both coins 41, 42 lie in such a way that they pass below the stripper 31, which does not extend beyond the surface 37 of the ejection element 25. However, the leading coin 42 slips out of the receiving space in the area of the scraper 31 and before reaching point E via the beveled guide surface 35 21, as has already been described with reference to FIG. 9. The other coin 41 is still supported in the edge region 21c of the receiving space 21 and is thus prevented from falling out. This coin 41 is then conveyed to the ejection point F and transferred there to the sorting rail 30.

A situation is also shown in FIGS. 11 and 12 (which is a sectional illustration comparable to FIG. 8) in which two small coins 41, 42 lie side by side in a receiving space 21. In contrast to the representation according to FIG. 10, however, the mutual position of the two coins 41, 42 is different in that one coin 41 comes to rest on the area 38 in the area of the position D, while the other coin 42 rests on the area 37. The upper coin 42 is, as already described with reference to FIG. 9, gripped by the deflector 31 and thereby stripped by the ejection element 25, with the result that the coin 42 falls back into the collecting container 1. In contrast, as described with reference to FIG. 9, the other coin 41 arrives at point F, where it is ejected onto the sorting rail 30.

As already mentioned with reference to FIG. 8, the course of the surface 38 sloping backwards ensures that in the edge region 21c of the receiving space 21 facing the drive plate 2, a coin is also supported when the ejection element 25 assumes its front end position, in which the other surface 37 is aligned with the front 2a of the drive plate 2. As a result, the coin resting on the surface 37 can be stripped off by the stripper 31 without the coin resting on the surface 38 falling out of the receiving space 21.

As already explained with reference to FIG. 4, the beveled guide surface 35 has the result that the depth h 'of the receiving space 21 is less in its area than in the rest of the area. This means that when the ejection element 25 is in a certain position, a coin can slip out of the receiving space 21 via the guide surface 35, while a coin following in the direction of rotation A of the driving disk 2 can still be supported on the edge region 21c of the receiving space 21, as is shown in FIG Fig. 9 has been explained.

Various modifications of the preferred embodiment explained with reference to FIGS. 1 to 12 are now conceivable. Some of the possible variants are now briefly described with reference to FIGS. 13 to 17.

The embodiment shown in FIG. 13 differs from the exemplary embodiment according to FIGS. 1 to 12 in that there is no scraper, but instead a retaining element 44 in the form of a brush, which is fastened to a carrier 45, which is fixed in place. The retaining element 44 acts on the area of the ejection elements 25 facing the axis of rotation 2 'of the driving plate 2, i.e. onto the area of the inclined surfaces 38. The carrier 45 runs at a distance from the front side 2a of the driving plate 2.

The mode of operation of the retaining element 44 is as follows:
If two coins, as shown in FIG. 10, lie next to one another in a receiving space 21, the coin advancing in the direction of rotation of the driving disk 2 is held back by the retaining element 44, ie prevented from further rotation. The coin retained in this way moves as the driving disk 2 continues to rotate upwards along the edge of the receiving space 21 towards the edge of the driving disk 2. The following coin is also pushed up and, as a rule seen in the direction of rotation A of the driving disk 2, falls backwards out of the receiving space 21. However, it is also possible for this subsequent coin to be moved under the carrier 45 and then over the bevelled guide surface 35 falls out of the receiving space 21 down into the collecting container 1. The coin which is initially leading and retained by the retaining element 44 is finally pushed under the retaining element 44 and, as explained with reference to FIG. 10, conveyed to the discharge point F.

The embodiment according to FIG. 14 differs from the embodiment shown in FIGS. 1 to 12 in that there is no scraper 31. The variant according to FIG. 14 is conceivable for devices in which the driving disk 2 does not rotate at too high a speed.

In the embodiment according to FIG. 15, just as in the variant according to FIG. 14, the scraper 31 is missing. In addition, the ejection elements 25 do not have two surfaces 37 and 38 which are inclined relative to one another. Rather, ejection elements 25 are used with a surface 37 'which is parallel to the front surface 2a of the driving plate 2.

This embodiment is also particularly suitable for devices with a driving disk 2 that does not rotate too quickly.

The embodiment shown in FIG. 16 corresponds to the embodiment according to FIG. 15 with regard to the configuration of the ejection elements 25. However, compared to the latter, there is also an additional retaining element 44, as is also used in the variant according to FIG. 13. With regard to the mode of operation of this retaining element 44, reference is therefore made to the explanations relating to FIG. 13.

The embodiment according to FIG. 17 corresponds to the embodiment according to FIG. 13 with regard to the configuration of the ejection elements 25, but the beveled guide surface 35 is dispensed with. As in the exemplary embodiment according to FIG. 13, there is a retaining element 44 and additionally a scraper 31, as is used in the embodiment according to FIGS. 1-12. However, it is also possible to provide only one retaining element 44 or one scraper 31.

The following variants, not shown, are also conceivable.

In the embodiment according to FIG. 13, the beveled guide surfaces 35 could be omitted.

Finally, it would also be conceivable to provide a wiper 31 in the embodiment according to FIG. 13. However, such a solution is structurally very complex.

Compared to the preferred embodiment according to FIGS. 1-12, all of the variants mentioned above have the disadvantage of greater expenditure or less reliability in certain application purposes.

Claims (5)

Coin sorting device with a rearward inclined, rotatable driving disc (2), which is provided with open receiving spaces (21) for coins (40-43), the bottom of which is formed by displaceable ejection elements (25), the movement of which during the rotation of the driving disc ( 2) is controlled by control means (29), preferably control cams, characterized by at least one of the following features: a) the ejection elements (25) are designed such that in a front end position a first coin support area (37) lies essentially in the plane of the front surface (2a) of the driving plate (2), while a second one, the axis of rotation (2 ') Driving plate (2) facing bearing area (38 ') is set back so that it runs at a distance (a) from said front surface (2a), b) in the area (36) of the receiving spaces (21) leading in the direction of rotation (A) of the driving plate (2), a guide surface (35) is provided that drops towards the interior and thus reduces the height (h) of the receiving spaces (21). Coin sorting device according to claim 1, characterized in that the ejection elements (25) have a first coin support surface (37) which is approximately parallel to the front surface (2a) of the drive plate (2) and a second one which is oblique with respect to the latter Have coin support surface (38). Coin sorting device according to claim 1 or 2, characterized by a fixed stop (31) arranged adjacent to the front surface (2a) of the driving plate (2) and projecting into the movement path of the receiving spaces (21), the certain of the coins resting on the ejection element (25) (42) prevents further movement, so that these coins (42) fall out of the receiving space (21). Coin sorting device according to one of claims 1 to 3, characterized by a stationary retaining element (44) projecting into the path of movement of the receiving spaces (21), which certain coins arranged in a receiving space (21) temporarily prevent further movement in the direction of rotation (A) of the driving disk ( 2) prevents. Coin sorting device according to one of claims 1, 3 or 4, characterized in that the ejection elements (25) have a flat coin support surface (37 ') which runs approximately parallel to the front surface (2a) of the driving plate (2).

Images