Document acceptor assemblies, such as those used in the vending and gaming industries, typically store accepted banknotes or other documents in a cassette. A stacking mechanism may be incorporated in the assembly to facilitate storage of the documents in the cassette.
In various industries, the cassettes (sometimes referred to as cash boxes) are removed in predefined cycles. In the gaining industry, removal of the cassette is referred to as a “drop.” Removing the cassettes in predefined cycles can be wasteful because many of the cassettes may not be at, or near, capacity at the time of the drop. Another problem may arise as a result of cassettes becoming full in advance of the drop, thus rendering the gaming machine disabled until its scheduled drop.
The disclosure relates to monitoring and reporting the capacity of a currency cassette.
An indicator (e.g., an alarm or warning) is generated to indicate that a currency storage cassette attached to a document handling device (e.g., a currency validator or other currency acceptor) has reached a particular capacity or is approaching its full capacity.
The indicator can include, for example, a visual or audio signal in the vicinity of the document acceptor so as to alert service personnel that the cassette is near full-capacity or that it is expected to reach full-capacity within the near future. Visual or audio indicators that readily can be sensed by service personnel can make it easier to identify when a full (or near-full) cassette needs to be exchanged for an empty one. The indicator of the cassette capacity can be controlled, for example, by the document acceptor's processor instead of the host gaming or vending machine. That can help avoid the need to make expensive changes to software in the host machine.
In some implementations, the physical indicator is provided when the cassette is filled to a predefined capacity (i.e., when the cassette contains at least a specified number of documents). In some implementations, the time at which the indicator occurs is based on a prediction as to when the cassette is expected to become filled to capacity. The predicted time can be based, for example, on the feed rate of documents inserted into the cassette and the actual number of documents stored in the cassette. Thus, in a particular scenario, an indicator or other message is provided if it is determined, based on the current feed rate and capacity, that the cassette is expected to become full within the next fifteen minutes.
Other features may be readily apparent from the following detailed description, the accompanying drawings and the claims.
The acceptor 12 determines whether inserted currency or other documents are acceptable. As used herein, the phrase “currency documents” includes, but is not limited to, banknotes, bills, security documents, paper currency checks, coupons, tickets and the like that may be used as legal tender in exchange for goods or service, and that may be inserted into a document handling device for validation and storage in return for goods or services.
Banknotes may be inserted one at a time into the acceptor 12 at entrance 16. From the entrance 16, the banknote 38 is transported through the acceptor 12 to the acceptor's banknote output by pairs of pulleys or rollers and belts that grip the side edges of the banknote and that may be driven by a motor and drive train according to known techniques.
As the banknote is transported through the acceptor 12, the banknote may be tested by a group of sensors to ascertain its validity and denomination. Output signals from the sensors may be processed by logic circuits in the acceptor 12 to determine whether the banknote is acceptable. Any of various known techniques using optical, magnetic, inductive or other types of sensors may be used to test the banknote. A banknote which is unacceptable may be ejected back out through the entrance 16.
An acceptable banknote is transported into an interconnection region 18 in which the acceptor 12 and stacker 14 are connected together. The interconnection region 18 establishes a smooth uninterrupted path for a banknote to follow when leaving the 15 acceptor 12 and entering the stacker 14. The accepted banknote is transported from the stacker's entrance into a pre-storage channel 20. In a fashion somewhat analogous to the way that a picture frame holds a picture, the channel 20 “frames” the banknote at its side edges and holds it stiff prior to stacking. The piston-type stacker 14, described in greater detail below, pushes the accepted banknote into a cassette 22 where it is stored until removed by service personnel. The cassette is designed to be readily removed or opened by service personnel so that stacked banknotes can be removed.
As shown in
An optical switch 40 is provided for detecting the presence of a flag 42 that indicates when the piston 28 is in the home position (i.e., when the piston is not obstructing the pre-storage document channel 20). The flag 42 may be formed, for example, as a protrusion from the backside of the piston 28.
A sensor is provided to sense electrical signals from the motor during a document stacking operation. In a particular implementation, as shown in
The control system 204 may include a microprocessor 206 to control when the motor 36 is turned on or off in response to signals from the optical sensor 40 and the motor current sensor 200. As discussed below, the microprocessor 206 also can measure the passage of time using, for example, an interrupt software routine driven by a clock signal.
During the initial stage of the stacking state, power is applied to the motor 36, and an eccentric begins to rotate, thereby lifting the piston 28. As illustrated in
A DC motor (such as motor 36) with a substantially fixed input voltage draws a current that is approximately proportional to the mechanical load placed upon it. For example, during the transition from the home position to the initial stacking stage of
When the piston 28 is fully extended as shown in
Next, the piston 28 reverses direction and travels in the opposite direction as illustrated by
Under different circumstances, such as when the cassette 22 is substantially full, the expected values of motor current may vary significantly from the values indicated by curve 50. An example of the motor current profile when the cassette 22 is substantially full is indicated by curve 62 (
The later timing of the peak value 64 when the cassette 2 is full may be attributed to the fact that the stacker mechanism 14 slows down under the higher load. In the illustrated implementation, the full extension state of the piston 28, as shown in
In some situations, the pre-storage document channel 20 may become obstructed by an object other than a genuine, acceptable document. Curve 70 (
In various implementations, one or more values indicative of the motor's actual operation may be compared to one or more reference values to determine whether the motor and, therefore, the stacker, is operating properly. Reference values and expected current profiles may be stored, for example, in memory 208 associated with the control system 204 (see
To predict the time at which the cassette is expected to reach its full capacity, the rate at which documents are being inserted into the cassette is determined. The cassette's actual capacity is determined as well. That information then is used to predict an approximate time when the cassette will reach its full capacity. If it determined that the cassette will reach its full capacity within some predetermined amount of time, then an indicator is provided to alert service personnel to the status of the cassette. The currency acceptor's processor can be used to track the status of the cassette, make any required calculations, and generate appropriate signals to provide the indicator.
Various techniques can be used to track the number of documents stored in the 20 cassette. For example, the processor associated with the currency acceptor can keep track of the number of stack cycles that occur. The completion of each cycle would indicate that another document has been stored in the cassette. As described above, a stack cycle begins with the piston in the “home” position (
In some implementations, the capacity of the cassette is determined based on the motor current. As the cassette nears its full capacity, the force required to stack a document increases and the current in the motor increases. Thus, the increase in force can be detected by measuring the current draw of the stacker motor. The increase is predictable, and thresholds can be determined dynamically or can be predefined. The thresholds indicate the capacity status. For example, with reference to
According to some implementations, once the number of documents stored in the cassette has been determined, the physical indicator is provided if the number of documents in the cassette has reached a pre-defined threshold.
Such techniques, however, do not account for the rate at which the documents are being received and stacked in the cassette. Thus, for example, if documents are being stacked at a relatively slow rate (e.g., if customers are not using the gaming machine very often), the cassette might not become full for a relatively long time. On the other hand, if the current document feed-rate is relatively high, the cassette may reach its full capacity sooner.
To obtain a better sense of when the cassette is likely to reach full-capacity, the rate at which the documents are being stacked during a specified period (e.g., the previous half-hour) can be monitored and used together with the actual number of documents currently stored in the cassette to predict the amount of time until the cassette will become full or substantially full. Such an approach can provide an adjustable amount of warning time and compensate for different play (i.e., document insertion) rates. Thus, a currency acceptor associated with a busy gaming machine will issue its alarm sooner than the currency acceptor associated with a more slowly played machine. The warning can also be issued in degrees as the cassette's maximum capacity is approached (i.e., 10%, 20%, etc.).
A particular implementation uses the following comparison to determine whether the cassette is at, or will be at, substantially full capacity in the near future:
Is ((CC+(CR*WT))>MAX)?
where,
MAX=maximum capacity (i.e., number of documents) of the cassette
CC=current document count in the cassette
CR=current document feed rate (e.g., documents per hour)
WT=warning time (in hours) 20
The value for “CR” may be recalculated on a periodic basis, for example, every thirty minutes. The value for “WT” may be set dynamically by the host or through a pre-configuration setting.
If the value (CC+(CR*WT)) is greater than the value MAX, then the cassette is either already at full capacity or likely to reach its full capacity soon, and an indicator is provided. Preferably, the indicator is controlled directly by the currency acceptor and can be sensed by service personnel. For example, the indicator can be a visual warning such as a light emitting diode (LED) or other light source, located on the top of the gaming machine, being turned on. Such an LED or other physical indicator can be located elsewhere such as on the bezel of the currency acceptor. In some implementations, turning on the LED serves as the indicator. In other implementations, the blinking rate of the LED indicates the anticipated time until the cassette reached full capacity. For example, in particular scenario, a faster blink rate would indicate that the cassette is expected to become full sooner than if the blink rate were slow. Audio warnings (e.g., a beeping or other sound) also can be used in addition to, or instead of, visual warnings. Alternatively, or in addition to the physical indicator, a message may be sent to a remote location (i.e., remote from the currency acceptor and host machine) to alert service personnel.
The currency acceptor can be configured to clear the indicator (e.g., turn off the LED) automatically once the cassette is changed.
Various aspects of the system may be implemented in hardware, software or a combination of hardware and software. Circuitry, including dedicated or general purpose machines, such as computer systems and processors, may be adapted to execute machine-readable instructions to implement the techniques described above. Computer-executable instructions for implementing the techniques can be stored, for example, as encoded information on a computer-readable medium such as a magnetic floppy disk, magnetic tape, or compact disc read only memory (CD-ROM). In one particular implementation, the computer-readable medium includes non-volatile electronic memory such a PROM, EPROM or FLASH. Algorithms also may be implemented, for example, through use of a programmable gate array.
The foregoing implementations, including the motor current profiles, are intended as examples only and are not intended to limit the scope of the invention.
The techniques may be employed in connection with stackers other than piston-type stackers, including, for example, stackers in which banknotes are wrapped around a drum or in which banknotes are rolled onto a stack. The techniques also may used with stackers using actuators other than DC motors, including, for example, actuators for stepper motors, AC motors and brushless motors. In some cases, signals other than current, including, for example, the phase lag may be used to measure the actuator load.
Other implementations are within the scope of the claims.
This application is a continuation application of U.S. Ser. No. 11/751,444 filed May 21, 2007 which claims the benefit of priority from U.S. Provisional Patent Application No. 60/802,375, filed on May 22, 2006.
Number | Date | Country | |
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60802375 | May 2006 | US |
Number | Date | Country | |
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Parent | 11751444 | May 2007 | US |
Child | 13481460 | US |