NO148795B - MYNTPROEVER. - Google Patents

Description

The invention relates to a coin sampler for sorting

of bent coins or coins that exceed a predetermined

tuned thickness, comprising a running rail inclined in the direction of movement of the coins on which the coins roll, a coin guide arranged on one side of the running rail which presents a contact surface for the coins, a part arranged on the other side of the running rail which prevents a coin that exceeds the prescribed thickness from continuing its way on the running rail, and a coin return channel for the sorted coins.

Coin control devices in coin-operated machines, especially in coin-operated telephones and vending machines, usually consist of a number of coin testers, each of which tests a certain authenticity criterion, and to which there is practically always a coin thickness tester that ensures that coins that are too thick or bent, which could pass the coin insertion slot , is not accepted, but is sorted out. The control of bent coins has recently increased in importance, as coins are increasingly being used as screwdrivers, especially for setting

ling of ski bindings, and then often get bent. However, even strongly bent coins can be inserted into a coin insertion slot when the coins are tilted accordingly during insertion.

Previously known coin testers of the type indicated at the outset are usually constructed in such a way that coins that are too thick or that are too strongly bent arrive at a blind channel where they remain or are trapped. Only when the channel boundary walls are moved apart correspondingly by pressing the coin return button on the coin machine, can the coins fall via the return channel into the coin machine's return container. With this construction, there is a disadvantage that the user can only get back the coins sorted out by the coin tester and retained in a blind channel when he presses the special coin return button, which is often overlooked or forgotten and then causes annoyance due to the loss of these coins, and that furthermore the necessary, special blind duct entails a greater need for space.

With these well-known coin testers, there is also a danger that they

too thick or too strongly bent coins in one place or another will be jammed. Finally, it is the mechanism that unfolds

the canal walls with a view to releasing the sorted coins, exposed to disturbances.

A coin sampler of the type indicated at the outset

is known from GB patent document no. 1 124 979. This coin sampler has on one side of an obliquely oriented wall a running rail inclined in the direction of movement of the coins. In the area of this running rail, the obliquely oriented wall has a rectangular opening which is dimensioned so large that coins with a diameter that is too small can fall through the opening for the purpose of sorting. The lower edge of this opening is slightly higher than the running rail and forms a coin guide together with the upper edge of this opening. On the other side of the running rail, a strip-shaped part is arranged at such a distance from the coin guide that coins that are too thick are prevented from continuing their way on the running rail because they collide with the leading edge of this part and are thereby stopped. Due to the fact that such a coin hits the leading edge of the mentioned part, this coin must fall down from the running rail and thus arrive at the coin return channel. However, this k-girl arrangement does not ensure reliable, disturbance-free operation, as it is conceivable that coins with a thickness that is only slightly greater than the permitted thickness, or also slightly bent coins, will be jammed due to the strip-shaped part.

The purpose of the invention is to simplify a coin sampler of the type indicated at the outset and to design such a coin sampler in such a way that the sorted coins fall directly immediately into the coin return channel leading to the coin return container, ensuring a virtually maintenance-free and disturbance-free operation, and that the necessary space requirements are only small.

The above-mentioned purpose is achieved according to the invention by the fact that the coin guiding device is a guide line with an upper edge oriented parallel to the running rail which forms the upper limit of the mentioned contact surface and whose distance to the running rail is somewhat greater than the coin radius, and that the said part is a diversion rail that lies several coin thicknesses above the upper edge of the guide ruler and exhibits an inlet chamfer whose distance to the plane passing through the aforementioned contact surface in the coin's rolling direction decreases from an initial value that is greater than the predetermined coin thickness, to a value that corresponds to the predetermined coin thickness, and which transitions into a parallel to said planar running guide raft which is at least approximately as long as the coins' circumferential length, in such a way that a coin which is bent or which exceeds the predetermined thickness, when passing the diversion rail, is tilted so much about one of the guide line needles said upper edge formed a pivot axis that it slides down the running rail and falls into the aforementioned coin return channel.

In this way, it is achieved that the coin sampler is structured

of only a few, practically maintenance-free parts between which the sorted coins cannot be clamped, and that the coins diverting from the running rail by means of the diverting rail, as a separate blind channel is dispensed with, can fall directly into it next to this running rail located at the entrance opening to the coin return channel leading to the coin return container, while the accepted coins roll on the running rail until the end of this and then continue on their intended path, i.e. e.g. until the subsequent coin samples or arrives at the till. The distance of the diversion rail from the plane passing through the contact surface of the guide line needle can preferably be adjustable with a view to both setting the coin thickness limitation and the height of the diversion rail and the guide line needle above the running rail. It is also appropriate that the width of the running rail is smaller than the coin thickness, and the distance of the guide line upper edge from the running rail is advantageously chosen so that it is equal to the coin radius plus 5 - 10% of the coin diameter. This means that this upper edge of the guide line needle for smaller coins is located approx. 2-3 mm and for larger coins approx. 1 mm above the center of the coin. Furthermore, when the plane of the running rail is appropriately inclined in relation to the horizontal and correspondingly the side guide members in relation to the vertical are inclined at a small angle to the side of the guide line, it is achieved that a coin rolling down the running rail under the action of gravity rests easily against the contact surface of the guide line. When the coin does not exceed the predetermined thickness, it can safely roll on the

the rail up to the end of the coin tester, but if it does exceed the predetermined thickness, it is safely tipped over the upper edge of the guide ruler with the help of the diverter rail, as the distance between the diverter rail and the upper edge of the guide ruler acting as the coin's swing axis represents an arm's length. The thickness of the coin control path defined by the beginning of the diverter rail's inlet chamfer is suitably naturally made somewhat larger than the thickness of the coin slot of the coin machine.

The invention shall be described in more detail below

in connection with an exemplary embodiment with reference to the drawings, where fig. 1 shows a view of the coin tester according to the invention, partly in section along the line I - I in fig. 3, fig. 2 shows a front view of the coin tester in the direction of the coins' rolling movement, in section along the line II - II in fig.

3, and fig. 3 shows a side view in the direction of arrow III in fig.

1 and 2.

As shown in the drawings, a running rail 2 is attached to a rack wall 1 that is slightly inclined in relation to the vertical. Above the running rail, a guide line 3 parallel to the running rail 2 is attached on one side, and at a distance above this, on the other side of the running rail 2, a diverting rail 7 is attached. The running rail 2 is inclined in the direction of movement of the coins M, i.e. in the direction of the arrow A in fig. 1 and 3, so that the coins M can roll on this, and have a somewhat smaller width than the coins M, as shown in fig. 2.

The guide line needle 3 has a contact surface 3b (fig. 1) for the coins M and an upper edge 3a (fig. 2), and the guide line needle is placed in a recess 16 in the stand wall 1 and grips with its associated bent end sections 4, as shown in fig. 1, behind the areas of the rack wall 1 which limit the recess 16. These end sections 4 of the guide ruler 3 are, according to fig. 3 rectangularly extended and provided with oblong holes 5 for receiving fixing screws 6 which are fixed in the rack wall 1. With the help of the oblong holes 5, the guide line needle 3 can be fixed at an adjustable height above the running rail 2 in such a way that its upper edge 3a is slightly above the midpoint of the coins rolling down on the running rail 2 to be checked.

On the side of the running rail 2 that faces away from the guide line needle 3, the diversion or deflection rail 7 is placed on the rack wall at a distance above the upper edge 3a of the guide line needle 3. The diverter rail is designed as an L-shaped part whose longest leg 7d, oriented parallel to the guide line needle 3, is adjustably attached to the rack wall 1 above the socket 16 by means of two pairs of screws. The short leg 7c, which is oriented perpendicular to it through the guide line needle 3 contact surface 3b walking plane, and which lies a multiple of the coin thickness, in the considered example three to four times the coin thickness, above the upper edge 3a of the guide line needle 3, forms at the edge that cooperates with the coins M to be tested, according to fig. 1 an inlet chamfer 7a whose distance to the plane passing through the contact surface 3b of the guide ruler 3 in the rolling direction of the coins decreases from an initial value that is greater than the width of the coin slot of the coin machine, to a value that corresponds to the predetermined maximum coin thickness d (Fig. 1). This inlet chamfer 7a transitions into a guide surface 7b running parallel to the aforesaid contact surface 3b, which is at least approximately as long as the circumference of the coins and defines the actual coin thickness limitation.

The two screws 8 in the upper pair of screws go through vertically oriented, elongated holes 13 in the stand wall 1 and are screwed into a respective threaded sleeve 9 which exhibits a constriction 9b placed in a hole 14 in the diversion rail 7 and a sleeve head 9a connected to this on the other side of the diverter rail. Each hole 14 expands to a side-directed opening 15 which is so large that the threaded sleeve 9 with its constriction 9b is pushed laterally into the hole 14 which has a smaller diameter than the sleeve head 9a during assembly. In this way, the diversion rail 7 is suspended in the sleeve constrictions so that it can be tilted a small angle. The adjustment to the predetermined maximum coin thickness d takes place with the help of the two screws 10 and the screw springs 11 placed on the screws, located between the rack wall 1 and the diverter rail 7, which keep the diverter rail 7 at the maximum distance from the rack wall 1 given by means of the appropriate screw setting. The screws 10 are placed in oblong holes 12 in the diverter rail 7, so that this can also be adjusted in height by means of the oblong pairs of holes 12 and 13.

To reduce friction with the coins, the height dimension of the guide line 3 is only a fraction of the coin diameter. Immediately next to the running rail 2, under the guide line 3, a lower coin guide edge la protruding above the running rail plane is arranged, which is formed by the rack wall 1 and ensures safe rolling of the coins M on the running rail 2. The room on the other side, immediately next to the runner rail 2 and below the diversion rail 7 form the direct inlet opening for the coin return channel 18 which receives the sorted coins and leads to the coin return container of the coin machine. As indicated in fig. 2, the entire coin sampler is tilted in relation to the vertical at an angle of approx. 10°, so that the coins rolling on the running rail 2 under the influence of gravity rest lightly against the contact surface 3b of the guide line needle 3.

A coin M, which does not exceed the predetermined maximum thickness d, rolls on the running rail 2 undisturbed past the diversion rail 7 and arrives at the end of the running rail 2 for further processing to the normal coin channel 17 such as e.g. leads to the subsequent coin sampler or to the till. A coin that has a thickness that is greater than the predetermined maximum thickness d, or exhibits a correspondingly strong deformation, when rolling on the running rail 2 is tilted by the diversion rail 7 as much about a pivot axis formed by the upper edge of the guide line needle 3 3a, and in a clockwise direction according to fig. 2, that it slides down from the running rail 2 and falls directly into the coin return channel 18, as indicated in fig. 2 for the dashed coin M'. As the length of the guiding surface 7b of the diverting rail 7 is at least approximately as large as the circumference of the coin to be tested, irregularly bent or deformed coins are also reliably separated with the help of the diverting rail 7. tilting moment must be as small as possible, the height of the upper edge 3a of the guide line needle 3 above the running rail 2 is preferably chosen equal to the coin radius plus 5 - 10% of the coin diameter. In this way, the center point for larger coins is located approx. 1 mm and for smaller coins approx. 2 - 3 mm below the upper edge 3a of the guide line needle 3, which acts as a tilting axis. These dimensions also guarantee that a correct coin cannot safely slide down from the running rail 2 as a result of tilting.

The running rail 2, the contact surface 3b and the edges of the diversion rail 7 which form the inlet chamfer 7a and the guide surface 7b are preferably made of a hard, wear-resistant material which exhibits only a small frictional resistance with the coins.

Claims (8)

1. Coin samples for sorting out bent coins or coins that exceed a predetermined thickness, comprising a running rail inclined in the direction of movement of the coins on which the coins roll, a coin guide arranged on one side of the running rail which presents a contact surface for the coins, a part arranged on the other side of the running rail which prevents a coin that exceeds the prescribed thickness from continuing its path on the running rail, and a coin return channel for the sorted coins, characterized in that the coin guiding device is a guide rail (3) with a parallel to the running rail (2) oriented upper edge (3a) which forms the upper limit of the mentioned contact surface (3b) and whose distance to the running rail (2) is somewhat greater than the coin radius, and that the said part is a diversion rail (7) which lies several coin thicknesses above the guide line the upper edge (3a) of the shaft (3) and exhibits an inlet chamfer (7a) whose distance to the plane passing through the mentioned contact surface (3b) in the rolling direction of the coins (M) decreases from an initial value that is greater than the predetermined coin thickness (d) , to a value corresponding to the predetermined coin thickness, and which transitions into a guide surface (7b) running parallel to the said plane which is at least approximately as long as the coins' circumferential length, on such way that a coin that is bent or that exceeds the predetermined thickness (d), when passing the diversion rail (7) of this, the YipPet becomes so much about one of the aforementioned upper edges (3a) of the guide ruler (3) formed by the axis of rotation that it slides down the running rail (2)„ and falls into the aforementioned coin return channel ( 18). - 2. Coin samples according to claim 1, characterized in that the height of the upper edge (3a) of the guide ruler (3) above the running rail (2) exceeds the size of the coin radius by 5 - 10% of the coin diameter. 3. Coin samples according to claim 1 or 2, characterized in that the width of the running rail (2) is smaller than the coin thickness. 4. Coin samples according to claim 1, characterized in that the distance of the diversion rail (7) from the said plane is adjustable for setting the coin thickness limitation, and that the diversion rail (7) is possibly also height-adjustable. 5. Coin samples according to claim 4, characterized in that the diversion rail (7) is an L-shaped part whose short leg (7c), which is oriented vertically on the plane passing through the contact surface (3b) of the guide ruler (3), forms the inlet chamfer at its edge (7a) and the guide surface (7b), while the long leg (7d) is adjustably attached to a stand wall (1) of the coin tester, which wall lies approximately in the plane of the contact surface (3b) of the guide ruler (3). 6. Coin samples according to claim 5, characterized in that the fastening means for the diversion rail (7) have at least two screws (10) and screw springs (11) arranged around them, which are arranged between the rack wall (1) and the long legs (7d) of the diversion rail (7), and keeps the diverter rail in it by means of the appropriate screw setting given, maximum distance from the rack wall. 7. Coin samples according to claim 1, characterized in that the guide line needle (3) is adjustable with respect to its distance above the running rail (2). 8. Coin samples according to claim 7, characterized in that the height dimension of the guide ruler (3) only corresponds to a fraction of the coin diameter, and that a lower coin guide edge (la) is arranged below the guide ruler (3) immediately next to the running rail (2) which protrudes somewhat above the plane of the running rail.