An apparatus for receiving and sorting disks includes a wheel having at least one well for receiving a disk, a motor coupled to the wheel, a collecting device positioned relative to the wheel, a disk sensor, an ejector, and a controller. The collecting device has at least a first collector and a second collector configured for receiving disks. The disk sensor is configured to detect a value of a parameter of a disk received in the well and generate a parameter value signal. The ejector is coupled to the wheel proximate the well and configured to eject a disk from the well in a plane parallel to a bottom surface of the wheel in response to an eject signal. The controller is operably coupled with the disk sensor and the ejector.

A coin roll crimp includes an indentation along a circumference portion of the crimp, the indentation formed by cutting or tearing the circumference portion of the crimp from the body of a coin roll wrapper proximate the end of the base of the circumference portion of the crimp.

A coin processing apparatus eliminates quickly and surely a coin congestion in the cases where (a) a Tawara state and/or a Keirin phenomenon of coins is/are generated on a conveying surface, (b) additional coins are overlapped or stacked on existing coins having a Tawara state or a Keirin phenomenon, and (c) additional coins are placed on the conveying surface on the upstream side of the existing coins. A conveying belt has a protrusion on its conveying surface. A reversing roller is provided opposite to the conveying surface. Screw-like members with spiral projections on their outer surfaces are respectively provided at two sides of the conveying surface. Coins placed on the conveying surface in their standing state are moved backward due to engagement with the screw-like members to topple down naturally toward the conveying surface during conveyance and then, moved forward due to engagement with the protrusion.

A coin processing apparatus eliminates quickly and surely a coin congestion in the cases where (a) a Tawara state and/or a Keirin phenomenon of coins is/are generated on a conveying surface, (b) additional coins are overlapped or stacked on existing coins having a Tawara state or a Keirin phenomenon, and (c) additional coins are placed on the conveying surface on the upstream side of the existing coins. A conveying belt has a protrusion on its conveying surface. A reversing roller is provided opposite to the conveying surface. Screw-like members with spiral projections on their outer surfaces are respectively provided at two sides of the conveying surface. Coins placed on the conveying surface in their standing state are moved backward due to engagement with the screw-like members to topple down naturally toward the conveying surface during conveyance and then, moved forward due to engagement with the protrusion.

An apparatus for receiving and sorting disks includes a wheel having at least one well for receiving a disk, a motor coupled to the wheel, a collecting device positioned relative to the wheel, a disk sensor, an ejector, and a controller. The collecting device has at least a first collector and a second collector configured for receiving disks. The disk sensor is configured to detect a value of a parameter of a disk received in the well and generate a parameter value signal. The ejector is coupled to the wheel proximate the well and configured to eject a disk from the well in a plane parallel to a bottom surface of the wheel in response to an eject signal. The controller is operably coupled with the disk sensor and the ejector.

An apparatus for receiving and sorting disks includes a wheel having at least one well for receiving a disk, a motor coupled to the wheel, a collecting device positioned relative to the wheel, a disk sensor, an ejector, and a controller. The collecting device has at least a first collector and a second collector configured for receiving disks. The disk sensor is configured to detect a value of a parameter of a disk received in the well and generate a parameter value signal. The ejector is coupled to the wheel proximate the well and configured to eject a disk from the well in a plane parallel to a bottom surface of the wheel in response to an eject signal. The controller is operably coupled with the disk sensor and the ejector.

A method of repurposing coins includes the acts of discharging processed mixed coins into a coin bin, receiving a first request for a number of or value of coins of a first denomination from an authorized person, outputting the mixed coins from the coin bin onto a coin conveyor responsive to the received first request, conveying the mixed coins output from the coin bin, using the coin conveyor, to the coin processing machine for repurposing, and discharging the coins of the first denomination from the coin processing machine to a secure coin cassette and discharging coins of a denomination other than the first denomination back to the coin bin. These acts of outputting, conveying and discharging are continued until the number of or value of coins of the first denomination have been discharged to the secure coin cassette.

A method of repurposing coins includes the acts of discharging processed mixed coins into a coin bin, receiving a first request for a number of or value of coins of a first denomination from an authorized person, outputting the mixed coins from the coin bin onto a coin conveyor responsive to the received first request, conveying the mixed coins output from the coin bin, using the coin conveyor, to the coin processing machine for repurposing, and discharging the coins of the first denomination from the coin processing machine to a secure coin cassette and discharging coins of a denomination other than the first denomination back to the coin bin. These acts of outputting, conveying and discharging are continued until the number of or value of coins of the first denomination have been discharged to the secure coin cassette.

A coin acceptor includes main body having coin dispenser mounted therein, coin tubes mounted in the main body and disposed at the bottom side of the coin dispenser, and sensing device including multiple optical sensor modules respectively aimed at the coin tubes. The distance between each optical sensor module and the coins in the respective coin tube is calculated by: measuring the time taken for the reflected light to travel from the coins in the respective coin tube to the proximity sensor of the respective optical sensor module and then multiplying the time thus measured by the speed of light. The number of coins in each coin tube is calculated by: deducting the distance between the respective optical sensor module and the coins in the respective coin tube from the pre-measured depth of the empty coin tube, and then dividing the reminder thus obtained by the thickness of single coin.

A coin acceptor includes main body having coin dispenser mounted therein, coin tubes mounted in the main body and disposed at the bottom side of the coin dispenser, and sensing device including multiple optical sensor modules respectively aimed at the coin tubes. The distance between each optical sensor module and the coins in the respective coin tube is calculated by: measuring the time taken for the reflected light to travel from the coins in the respective coin tube to the proximity sensor of the respective optical sensor module and then multiplying the time thus measured by the speed of light. The number of coins in each coin tube is calculated by: deducting the distance between the respective optical sensor module and the coins in the respective coin tube from the pre-measured depth of the empty coin tube, and then dividing the reminder thus obtained by the thickness of single coin.