KR950007830B1 - Coin handling apparatus - Google Patents

Abstract

A coin handling apparatus having a passageway in which coins travel, and an impact element (10) secured to a part (4) of the apparatus in a position where it will be struck by a travelling coin so as to reduce the kinetic energy of the coin, characterised in that the impact element has a securing portion (38) around which plastics material, of which said part is made, has been moulded to secure the impact element.

Description

Coin handling device

[Brief Description of Drawings]

1 is a perspective view of the device according to the invention with the lid open to inspect the coin for receipt.

2 is a cross-sectional view taken along the line A-A of FIG.

3 is a perspective view of a collision element from the apparatus of FIG.

4 is a front view of the collision element of FIG. 3 taken in the direction of arrow B. FIG.

5 is a cross-sectional view of the collision element taken along line C-C in FIG.

Detailed description of the invention

The present invention relates to a coin handle device, in particular a device installed to inspect coins for storage.

Such a device is well known, and the device has a plurality of sensors arranged to allow a moving coin to pass through, in which there is a passage through which the coin to be inspected moves, and the sensor is a coin for determining the acceptability of the coin or the like. Become part of the inspection means. There are various known types of sensors, in which optical sensors have been used to detect coin characteristics, and capacitive sensors have been proposed, and most commonly used are induction coils with a core. For example, GB-B-2093620 adds a description of how coin sensors operate in response to various different coin characteristics and how their output signals are used in coin inspection means to determine the acceptability of the coin being inspected. The information is described.

In most of the coin inspection devices, the coin passing through the sensor may pass through a predetermined or predetermined path in order to give certain important information to the sensor output to accept or reject the coin, at least with bound or rattling. It is important to move along smoothly. If the above points are not achieved, a number of coins that should not be stored will be stored and a number of coins that must be stored will be rejected.

Various studies have been conducted to minimize the unexpected movement of coins after coins enter the device. Some studies have included the provision of a swinging element, so that the swinging element is placed in the path of the coin entering and the coin is placed so that the kinetic energy can be transferred from the coin to the element to reduce the kinetic energy of the coin. When you hit them you are moved. Another study that has been widely used is to provide a collision element that is fixed to a part of the device in a position that is hit by a coin entering through the inlet, the collision element being generally transverse to the direction in which the coin reaches it. Is extended. GB 1468162 discloses a collision element incorporating a relatively soft material, and GB 1482417 describes a collision element made of a rigid material, ie sintered aluminum oxide.

GB 1482417 is substantially good, so that the material hardness of the collision element is an important factor in maximizing the reduction of the kinetic energy of the coin due to the collision, thus improving the operating reliability of the device and bringing the first sensor closer to the coin collision point. After the coin is initially bound less, the residual bound will disappear as soon as possible to reliably inspect the coin.

The choice of impingement elements of particularly robust material has led to the widespread use of sintered aluminum oxide for this purpose. Mild or hard steels have also been used, although they are not good.

The impingement element is always simply screwed into the plastic part of the device or has a glue sandwiched between a part of the device and the impingement element and screwed it into it. In other cases, to allow a limited amount of free movement of the impact element, for example, by putting a screw through it into the part of the device that has passed through a hole that allows a tolerance without completely tightening the screw, as a result The impingement element is selected to rattle or vibrate against a screw when it is hit by a coin.

By using the prior art, it is very difficult in mass production conditions to prevent undesirable changes to the operation between one device and the other despite the consideration of the selection and fixing of a suitable material of the collision element. And sometimes the change is beyond tolerance limits and as a result the unique complete device needs to be scraped completely or partially. Even if improper operation is confirmed due to improper operation of the collision element, it cannot be determined why it is so.

The object of the present invention is to improve the operational reliability of such an impact element.

A coin handling device having a passageway through which a coin of the present invention moves and a collision element secured to the device portion at a position hit by a moving coin to reduce the kinetic energy of the coin, the collision element being the portion The plastic material to be formed is molded around and has a fixing portion for fixing the collision element.

Here, it is convenient to explain that the present invention for the most comprehensive aspect includes a coin handling device that does not need to inspect coins in order to be stored. Although the problem in the prior art has been described above in connection with such an inspection apparatus, the problem associated with this also arises in other contexts. For example, window sorters are used to sort coins (which are already housed) according to the diameter of the coins. Each coin rolls on the track past two or more (generally) windows that gradually increase in height, and the coin falls past the first window having a height greater than the coin diameter. In this method, the stored coins are mechanically inspected for the diameter and coins of different diameters are separated. However, such a sorter will only work reliably if the coin rolls past the window without significant bounds, so if the coin falls on the track in front of the window, the coin tracks to allow the coin to pass through the window smoothly. It is desirable to minimize the kinetic energy of the coin as soon as possible after the crash. In general, any coin handling device, whether or not including a device that inspects the coin for other purposes or determines the receipt of the coin, will minimize the unpredictable or uncontrolled movement of the coin as it passes through the device. There is a need, and the various forms of coin handling devices fall within the scope of the present invention when provided with a molded impingement element as described above.

When the impingement element has a fixed portion formed in the elastic material portion of the device, it has been found that the achievement of the degree of acceptance of kinetic energy absorption is less dependent on the very material from which the impingement element is made. For example, a mild steel impingement element fixed in accordance with the present invention will reliably operate as a very preferred embodiment of sintered aluminum oxide fixed using the techniques described above.

The impingement element can be obtained more cheaply, since the actual production cost of the element in a material such as mild steel is lower than that of a ceramic material such as sintered aluminum oxide, or it can supply a collision element made of steel. Because there is a more competitive source.

Ultimately, any metal, such as brass or aluminum alloy, can be used as the impact element, but metals that rapidly wear out due to the impact of coins must be practically avoided.

It is practically unreliable to use the present invention with a collision element of aluminum oxide, which is currently good in mass production, because the method of forming the composite element is so varied in shape and size that it is used to simultaneously form part of a fixed device. It is not fixed during the course of the plastic molding process. However, if the highly consistent dimensions of a number of ceramic impingement elements are selected from a number of prototypes, this may lead them to a standard production machine by assembling the coin inspection device according to the invention with enhanced operation due to the additional hardness of the impingement material. Will enable the principle of use.

It is envisaged that the coin inspection device according to the present invention can be mass produced as it has a substantial component of the finished device or a smaller consumption of the finished device caused by a change in the bound of the coin outside the acceptable limits.

Embodiments of the present invention will be described with reference to the accompanying schematic drawings in order to explain the present invention more clearly.

The coin inspection device shown in FIG. 1 is a KG11 5AQ well known to those skilled in the art, Berkshire, Walking Gum, Winnersh Triangle, Mars Electronics International of Eskdale Road, Winnersh Triangie Wokingham, Berkshire, RG11. Most relevant as the model sold under 5AQ). Therefore this will only be described briefly.

The device has a body 2 in which the lid 4 is fixed by the hinge device 6, which components are injection molded from a plastic material such as NORYL (trade name) filled with glass with 20% glass content. do. The coin track portion 8 is incorporated with the lead 4 and the other portion is formed by the collision element 10. In the qualitative operating state of the device, the lid 4 is close to the body 2 and the coin track is inclined to the rear of the body 2 at the position indicated by the broken line DD 12. Is placed adjacent to.

The coin to be examined falls approximately vertically until it is introduced into the coin inlet 14 and hits the collision element 10. The element 10 is transverse to the passage of the arrival coin (for example between 10 ° and 40 °, preferably between 10 ° and 15 ° with respect to the horizontal plane, the coin falls approximately vertically), and impacts As soon as the coin's kinetic energy decreases, it is sometimes very little bound before it slides or rolls along the coin track to the right as shown in FIG.

As the coin moves along the coin track, the coin will lean in near planar contact with the inclined inner wall 12 and pass through the sensor of the device, which is sensitive to the various characteristics of the coin. For the sake of illustration only, the two-sided coils of the three sensors (16, 16 '; 18, 18'; 20, 20 ') are shown as dashed lines, one coil of each pair being placed behind the inner wall 12 and each pair of The other coil of is placed in the lead 4.

The output signal of the sensor passes through the inspection circuit element, indicated schematically at 22 in the body 2, from which it is determined whether or not the coin will be stored in a known manner. If the inspection circuit element is retracted into the body to actuate the accept / reject gate 24, as a result, coins falling from the end of the coin track portion 8 may fall into the receiving passage indicated by the arrow 26. have. If the coin is not stored, the gate 24 remains in the position shown and the coin is switched over the reject passage indicated by arrow 28.

3 to 5 show the collision element 10 shown in detail, which is composed of blocks formed from sintered steel, which is countered by coins and at an angle of approximately 15 ° with respect to the circumferential surfaces 32 and 34 thereof. Impingement surface 30 is provided. The block has an extended upper portion 36 under the narrow fixing portion 38 via three circular holes 40 arranged in rows.

Because of the metal, the impingement element 10 is easily formed with precise enough tolerances to enable a precise fit to the cavity portion of any suitable type of injection molding machine, which are well known and already commercially available. It is used in the injection molding lead 4 from a plastic material. The forming cavity is designed such that the plastic material for forming the lid 4 in the forming operation is all molded around the fixing part 38 through the circular hole 40, which can be most clearly shown in FIG. 2. As it is, they are in direct contact with the circumferential surfaces 32 and 34 at both ends of these holes. The material also extends to the right around the edge over the edge of the impact surface 30 or relative to the top of the circumferential surface 34.

The side of the expanded upper part 36 is the left gap of the plastic material as the two lower corners 42 of the fixing part 38 as shown in FIG. 1. The impingement element is stopped by two corners and surfaces on the inner surface of the molding cavity when an injection molding process takes place.

Because of the circular holes 40 (although differently shaped holes or other mechanical forms can be used to achieve the same purpose), they are held completely firmly in place, even if there is no bound between the plastic material and the metal of the impact element. The impingement element is physically interconnected with the enclosed plastic material so that it can be. Substantially the bound occurs, and as shown in FIGS. 1 and 2, the particularly strong and fixed mounting of the impact element of plastic material forms the shape of a protrusion, and the lead 4 to which the impact element 10 is set. It is integrated with the inner wall of

When the lid 4 is closed, the inner wall thereof is horizontal to the inner wall 12 of the body 2, and the upper surfaces of the collision element 10 and the coin track portion 8 are coplanar with the two walls. It is placed at approximately 15 ° incline. As soon as the coin starts to move down the coin track, its lower edge moves towards the inner wall 12, so that the face of the coin is relatively evenly in contact with it when required by the sensor to apply any inspection on the coin. It will slide along the wall.

As shown from FIG. 1, the pair of coils 20, 20 'are at a relatively high level to correspond to the position of the upper edge of the coin relative to the coin track portion when the coin is centered between the coils. have. The coin then depends on its diameter, and since it blocks from the bottom of the coil to the top of the coin, the ratio of the blocked coil depends on the diameter of the coin. This in particular corresponds to the position associated with the coin track portion of the member of the coin, in combination with the sensor of the above type, the above method of fixing the collision element being that the output is most affected by any bound of the coin as the coin passes. It works best because it's a sensor that works the most.

Claims (10)

A coin handling device comprising a passageway through which coins move and a collision element (10) fixed to the lid (4) of the device at a position to be collided by the movement coin to reduce the kinetic energy of the coin. 10 is a coin handling device, characterized in that the plastic material is formed around the fixing portion (38) for fixing the collision element (10). The coin handling device of claim 1, wherein the collision element is made of metal. The coin handling device according to claim 2, wherein the collision element (10) is made of sintered metal. The coin handling device of claim 2 or 3, wherein the metal is steel. 2. The fixing part (38) of claim 1, wherein the fixing part (38) has one or more circular holes (40) therein, wherein the plastic material extends through the hole and has a portion of the fixing part (38) around both ends of the hole. Coin handling device, characterized in that in close contact with the surface. The coin handling device according to claim 5, wherein the circular hole (40) is plural. 7. Coin handling device according to claim 6, characterized in that the circular holes (40) are arranged in a row. The coin handling device according to claim 1, wherein the collision element (10) has a collision surface (30) which is opposed by a coin and protrudes stepwise from the wall of the collision surface. 9. A coin handling device according to claim 8, wherein the fixing portion (38) lies below the impact surface (30) and the plastic material molded around the fixing portion is integral with the wall to form the protrusions. . 2. Coin handling apparatus according to claim 1, characterized in that means for inspecting at least one coin characteristic is located downstream from the collision element (10).