The invention relates to coin processing machines for sorting, counting, or verifying coins or like tokens.
Coin processing machine 10 has a rotatable turntable 12 mounted in stationary plate 14. Turntable 12 has an upper coin support surface 16 flush with upper coin support surface 18 of plate 14.
Stationary raking finger 20 and stationary guide finger 22 are mounted on plate 14. Raking finger 20 and guide finger 22 define a first opening 24 that receives a singulated stream of coins from turntable 12. A raised peripheral wall (not shown) mounted to plate 14 partially surrounds the turntable 12 and has an opening aligned with opening 24 to enable coins leaving turntable 14 to move between fingers 20 and 22.
A belt drive 27 has a belt run 29 located above plate 14. The belt run 29 engages coins entering opening 24 and accelerates the coins towards coin through-slot 26 formed in plate 14. The belt drive 27 spaces the coins apart as the coins move towards slot 26 as is described in my U.S. patent application Ser. No. 11/032,718 filed Jan. 11, 2005, which application is incorporated by reference as if fully set forth herein. The belt run 29 urges the coins towards a first, planar guide surface 28 of guide finger 22 (that is, the belt run 29 does not extend parallel with guide surface 28 but extends towards surface 28 as the belt run extends towards slot 26).
Sensors 30 carried in plate 14 are located between opening 24 and slot 26. Sensors 30 are also described in my '718 application and so are not described in detail here. Each sensor 30 is associated with a different diameter coin and is spaced a predetermined distance from guide surface 28. The sensors are arranged to first detect the largest diameter coin (in the illustrated embodiment a US half-dollar piece) and then detect each succeeding smaller-diameter coin as a coin in contact with guide surface 28 passes sensors 30. The sensors 30 are connected to a controller (not shown) that records the denomination of each coin passing the sensors 30 and maintains a running count of the value of the coins discharged from turntable 12.
In operation, a stream of coins is discharged from the turntable 12 and move through opening 24. Opening 24 is sized such that the largest diameter coin of the coin or currency used with the machine is closely received within the opening. The illustrated opening 24 is sized to closely receive a US half-dollar coin. Opening 24 is preferably approximately 0.005 inches to 0.05 inches larger than the diameter of the half-dollar coin.
Larger-diameter coins such as half-dollar coins or quarter-dollar coins contact nose 32 of guide finger 22 as the coin passes through opening 24. The belt rotates or pivots the coin about opening 24 as the coin is driven along guide finger 22 to slot 26. This assures that the edge of the coin maintains contact with guide surface 28 as the coin moves along guide finger 22. The coin is properly aligned against guide surface 28 as the coin passes sensors 30 for accurate discrimination and counting of the coin.
Smaller-diameter coins such as US-currency nickels, dimes, and pennies may pass through opening 24 without contacting raking finger 20 or guide finger 22. The belt urges a smaller-diameter coin towards guide surface 28 as the coin moves towards slot 26. Even before contacting guide surface 28, the coin is sufficiently close to surface 28 that the coin does not pass over the sensors 30 associated with the larger diameter coins. The coin contacts and abuts guide surface 28 before passing over the sensor 30 corresponding to its coin denomination for accurate discrimination and counting of the coin.
It has been observed, however, that sensors 30 may miscount some smaller-diameter coins if the coins are wet or oily. It is believed that the moisture or oil acts as a lubricant that reduces friction between the belt and the coin. The reduced friction is believed to prevent the belt from reliably moving smaller-diameter coins that enter the opening 24 while relatively close to the raking finger 20 against the guide surface 28 before reaching the sensors 30. Such smaller-diameter coins may remain away from guide surface 28 and pass over the upstream sensors intended to sense only larger-diameter coins. As a result, the coin is mistakenly sensed and counted as a larger denomination coin.
Thus there is a need to improve the coin machine 10 and its equivalents for more accurate processing of wet or oily coins.
The invention is an improvement to the coin machine 10 and its equivalents that more accurately processes wet or oily coins. The improvement more reliably aligns the flow of coins with respect to the guide surface.
The improved coin processing machine of the present invention includes a third finger or alignment finger located in the downstream direction along the first guide surface from the first finger. The third finger is spaced from the first guide surface and defines a second opening between itself and the first guide surface downstream from the first opening. The third finger is normally located in a position such that the second opening is smaller than the smallest diameter of the larger coins and larger than the largest diameter of the smaller coins. The third finger is movable away from the first guide surface.
When a larger-diameter coin moves downstream through the first opening and reaches the second opening, the larger-diameter coin engages the third finger in its normal position. Continued downstream movement of the coin moves the third finger away from the first guide surface towards a retracted position that allows the larger-diameter coin to pass through the second opening and past the third finger. The third finger returns to its normal position after the larger-diameter coin passes by and before any smaller-diameter coin can pass through the second opening.
When a smaller-diameter coin moves downstream through the first opening to the second opening, some of the smaller-diameter coins engage the third finger. The third finger has a second guide surface that faces the first opening and preferably extends in a downstream direction towards the first guide surface. Smaller-diameter coins that engage the second guide surface are directed towards the first guide surface as they move downstream to the second opening. The smaller-diameter coins are thus moved closer to the first guide surface before passing through the second opening so that the belt reliably moves the coins against the first guide surface before the coins reach the sensors.
Other objects and features of the invention will become apparent as the description proceeds, especially when taken in conjunction with the accompanying drawing sheet illustrating an embodiment of the invention.
A pivotable alignment finger 34 is mounted on plate 14 downstream from rake finger 20. Alignment finger 34 has a free end 36 that is spaced away from the first guide surface 28. The alignment finger 34 and the guide surface 28 define a second opening 37 that is downstream from the first opening 24 along the guide surface 28.
Alignment finger 34 pivots about mounting fastener 38. The range of motion of finger 34 is established by dowel pin 40 in circumferentially-elongate finger slot 42 between a normal operating position towards rake finger 20 and a retracted position away from rake finger 20. A spring 44 formed from thin spring steel plate engages finger 34 and urges the free end 36 of finger 34 towards the normal operating position.
Free end 36 of finger 34 extends sufficiently towards the first opening 24 to contact and engage larger-diameter coins passing through the opening as the coins move along guide surface 28. In other words, the width of the second opening 37 is less than the largest diameter of coin to be processed. Free end 36 includes a guide surface 45 that faces the first opening 24. Guide surface 45 extends in a downstream direction towards the first guide surface 28.
When a larger-diameter coin passes through first opening 24, the coin contacts end 36 of finger 34 as it bears against guide surface 28. The lower belt run (represented schematically as arrow 47) forces the coin past alignment finger 34, deflecting spring 44 and moving the alignment finger 34 towards its retracted position. Movement of the alignment finger 34 enables the coin to continue moving through second opening 37 and pass by the finger end 36. Spring 44 urges the alignment finger quickly back to its normal position after the coin passes the alignment finger 34.
When a smaller-diameter coin passes through first opening 24 the alignment finger 34 is in its normal operating position as shown in
The smaller-diameter coin is not compressed between finger 34 and guide surface 28 when it reaches the end of the guide surface 45 and enters the second opening 37, and so the smaller-diameter coin does not force the finger 34 away from its normal operating position. After the smaller-diameter coin passes finger 34, the belt continues the component of coin travel towards guide surface 28 to assure that the coin engages the guide surface 28 before reaching the sensors 30 for accurate discrimination and counting.
When a smaller-diameter coin is away from the raking finger 22 when passing through first opening 24, the coin may not engage finger 34. The coin, however, is sufficiently close to guide surface 28 that the belt will properly align the coin with respect to surface 28 before the coin reaches sensors 30.
If a larger-diameter coin is followed by a smaller-diameter coin, the spring 44 moves alignment finger 34 back to its normal position quickly so that the smaller-diameter coin may engage the guide surface 45 and be directed towards the guide surface 28 before the smaller-diameter coin reaches the second opening 37. Preferably the guide surface 45 extends towards the first guide surface 28 even when the alignment finger 34 has not yet returned to its normal position.
Alignment finger 34 is preferably mounted on plate 14 with a small amount of vertical play 46 (see
The improved coin processing machine reliably counted wet or oily coins when tested.
It should be understood that although the invention is described in relation to US denomination coins, this is not limiting and the invention can be readily adapted for use with coin denominations of other countries.
While I have illustrated and described a preferred embodiment of my invention, it is understood that this is capable of modification, and I therefore do not wish to be limited to the precise details set forth, but desire to avail myself of such changes and alterations as fall within the purview of the following claims.
This application claims priority to my provisional patent application No. 60/912,022 filed Apr. 16, 2007 and titled “Coin Processing Machine with Pivoting Alignment Finger”, which provisional application is incorporated by reference as if fully set forth herein.
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0266021 | Apr 1992 | EP |
Number | Date | Country | |
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20090191801 A1 | Jul 2009 | US |
Number | Date | Country | |
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60912022 | Apr 2007 | US |