The invention relates to a banknote processing machine having power control electronics constructed to supply power delivered by a power source to the parts of the machine.
A banknote processing machine processes banknotes while they are transported through the machine along a transport path of the machine. Basically, the elements of a banknote processing machine can be grouped into mechanical parts, electromechanical parts, sensors, control electronics, software and interface means to an operator.
The transporting of the banknotes is achieved by the electromechanical transport parts, e.g. motors, and mechanical transport parts, e.g. wheels, transport belts and mechanical gates. The mechanical parts are driven by the electromechanical parts, e.g. motors and solenoids. Wheels and belts are used to transport the banknotes. Solenoid driven mechanical gates at branchings of the transport path are used to channel banknotes to one of several possible branches. The processing of a banknote implies, for example, capturing of features of the banknote by different sensors and channeling of banknotes at branchings in the transport path according to captured sensor measurements. Sensors are provided for capturing the number of transported banknotes, serial numbers and quality features of the transported banknotes. The sensors are placed along the transport path, so that the banknotes are transported to pass by the sensors when they are transported along the transport path via the mechanical transport parts.
To process a batch of banknotes, the batch is fed into the banknote processing machine, transported through the machine and processed thereby, and finally all banknotes of the batch are output out of the machine. For the feeding in of banknotes, the machine usually has a singler so as to single out banknotes. For the output of the banknotes, the machine has one or several stackers. The entire process starting at feeding in a batch of banknotes into a banknote processing machine and ending at a regular output of all banknotes out of the banknote processing machine is generally called a deposit cycle.
The software of a banknote processing machine comprises an operating system on which application software runs, so as to control the transport of banknotes along the transport path. The application software further saves deposit data captured during a deposit cycle to a persistent deposit data memory. The deposit data comprise for example the number of deposited banknotes, serial numbers of deposited banknotes and/or quality features of the deposited banknotes.
Generally, operating systems and/or applications running under the operating system generate log files containing the data related to the deposit cycle which are then written in volatile working memory. In case of a power failure, such log files are transferred to a persistent memory if there is enough time to write these log files into this memory. If the power supply is interrupted before the log files are saved to the persistent memory, the data is lost. Log files are also used for application software of banknote processing machines.
As an interface means, a banknote processing machines comprises, for example, a touch sensitive display for output of information to an operator and input of control information by an operator.
The power control electronics of a banknote processing machines is designed to control the powering of the electromechanical parts, sensors, software parts and interface means.
When a power failure occurs at the banknote processing machine during a running deposit cycle, the banknote deposit cycle is interrupted. In particular, it can happen that banknotes are transported along sensors which are already powered off. Thus, the application software can miss number counts and/or quality features of banknotes resulting in generation of inconsistent deposit data (e.g. different number of banknotes for fed-in, counted and output banknotes).
In known banknote processing machines, usually the entire deposit cycle has to be restarted when a power failure occurs during the deposit cycle, either due to a loss of log files containing deposit data, or due to inconsistent deposit data.
Generally, there are known power backup systems for backing up power failures, wherein, in the case of a power failure, backup power is provided through an external so-called uninterruptible power-supply UPS or through a battery.
It is an object of the present invention to provide a banknote processing machine which can get through a power failure occurring during a deposit cycle with reduced disturbing impact of the power failure on the deposit cycle. Preferably, it should be possible to continue a deposit cycle interrupted by the power failure as soon as the power is back.
The object is achieved by a banknote processing machine according to claim 1. Possible and favorable embodiments of the invention are given in dependent claims.
The banknote processing machine according to claim 1 comprises the following elements:
a plurality of electromechanical parts to control a transport of banknotes along a transport path through the banknote processing machine;
a plurality of sensors located along the transport path to capture features of banknotes transported along the transport path while passing by the sensors;
software parts, including application software and a deposit data memory, and configured to transport the banknotes along the transport path, by the electromechanical parts and to generate deposit data according to banknotes having been transported along the transport path, and to store generated deposit data to the deposit data memory;
an interface means to provide an interface between the banknote processing machine and an operator thereof or a network;
power control electronics to supply power delivered by a power source to the electromechanical parts, sensors, software parts and interface means.
The banknote processing machine is characterized in that the power control electronics comprises:
a low voltage monitor to detect a lowering of a voltage of the power delivered by the power source below a minimum voltage; and
a power failure control circuit configured to discontinue supply of power to a first group of said elements and to continue supply of power to a second group of said elements in case of lowering of said voltage below said minimum voltage.
The continued supply of power to the second group of said elements is intended to prevent a loss of data emanating from said elements and save a state of system before power failure. Therefore, preferably those elements are continued to be powered from which valuable data such as deposit data is generated. On the other hand, power is scarce in case of a power failure. To make sure that the elements of the second group get enough power during power failure, supply of power is discontinued to a first group of said elements. Preferably, power is discontinued to those elements that consume much power and/or from which no valuable data such as deposit data is generated. Thus, the scarce remaining power during power failure is saved for elements from which valuable data such as deposit data is generated.
With valuable data such as deposit data being saved throughout the power failure and until power is back, a deposit cycle which is just running at the time when the power failure occurs can be continued as soon as the power is back.
According to a preferred embodiment, the power control electronics comprises a super capacitor, which is assembled in the power control electronics such that, as long as the voltage delivered by the power source is above or not below the minimum voltage, the super capacitor is charged In case the voltage delivered by the power source is lowered below said minimum voltage, the super capacitor is isolated from the power source and therefore super capacitor starts discharging to ensure continuous power supply to the second group of elements during power failure. Super capacitors are known to have a very large capacity. Thus, a long-lasting bypassing or bridging of a power failure can be achieved by means of a super capacitor as a backup power source.
According to another preferred embodiment, the power failure control circuit is configured to continue to supply power to at least some elements from the second group of elements, from the time of receiving the low power signal on, for a duration of a power failure period, which is sufficiently long for the respective element to complete a process running at the time of receiving the low power signal. Thus, indefinite states of elements due to incomplete execution of processing steps at said elements are avoided.
According to another preferred embodiment, the first group of elements comprises one or several of the following: at least some or all of the electromechanical parts; at least some or all of the interface means; at least some of the sensors. These elements have in common that they have high power consumption. Thus, disconnecting these elements saves a high amount of power. On the other hand, mechanical parts and interface means and some sensors are not required in handling valuable data such as deposit data. Therefore switching these elements off is not too critical.
According to another preferred embodiment, the second group of elements comprises software parts having the application software and the deposit data memory. Software parts may further refer to a processing means for executing the application software and storing the log files in the deposit data memory. These elements are particularly critical since they handle valuable data such as deposit data and should therefore preferably be continued to be powered during power failure.
According to another preferred embodiment, the second group of elements comprises at least some or all of the sensors. Also some of the sensors can be implied in handling valuable data such as deposit data and should therefore preferably be continued to be powered during power failure.
According to another preferred embodiment, the power failure control circuit is configured to continue to supply power
to the sensors for a first holdup period, in particular from about 300 to about 1000 milliseconds, more particular for about 500 milliseconds, and
to the deposit data memory for a second holdup period which is larger than the first holdup period, and which is in particular from about 4 to about 10 seconds, more particular from about 5 to about 6 seconds, from the time of the low power signal on.
Preferably, when one or more super capacitor(s) is/are used as a power backup source, the super capacitor(s) is (are) dimensioned adequately so as to achieve desired first and second holding times.
In the following, embodiments of the invention will be described with reference to the drawings, wherein
The application software 33a runs on operating system of the banknote processing machine, so as to control the transport of banknotes along the transport path. The application software further saves deposit data captured during a deposit cycle to a persistent deposit data memory. The deposit data comprise for example the number of deposited banknotes, serial numbers of deposited banknotes and/or quality features of the deposited banknotes. In an embodiment, the application software 33a is stored on local memory of the banknote processing machine and executed by the second CPU 32.
The microcontroller 28 and an output 24 of the 24V low voltage monitor 22 are coupled to a gate input 39 of a MOSFET switch Q138. The super capacitor C112, the CPUs 30, 32 and the microcontroller 28 are connected to a source or drain of said MOSFET switch Q138 via converters U214, U316. A 5V/6.5V buck converter U118 is coupled to the other contact (drain or source of the MOSFET Q138, so as to charge the super capacitor C112 during normal operation at normal operating voltage (24V). A series resistor R134 is connected between the 5V/6.5V buck converterU118 so as to limit the charging current. Instead of one super capacitor C112 as shown in
The normal operating input voltage of the Power supply section supplying power to microcontroller 28 and the CPUs 30, 32 is 24 Volts. The 24V low voltage monitor 22 receives the operating voltage (normally 24 V) at its input. On a power failure, the operating voltage starts falling. As soon as the operation voltage at the input of the 24V low voltage monitor 22 decreases below the specific minimum voltage of 19 Volts (which can have a different value in different embodiments), the output line 24 of the 24V low voltage monitor 22 goes low.
The output 24 of the 24V low voltage monitor 22 is coupled to a gate input 39 of a MOSFET switch Q138 which interrupts the microcontroller 28 so as to switch off the mechanical elements 29-1 and interfaces 29-2. This means that all elements directly controlled by the microcontroller 28 are switched off directly. Further, the super capacitor C112 is disconnected from the power supply via the MOSFET switch Q138.
The CPUs CPU-130 and CPU-232 are coupled to a drain or source contact of the MOSFET switch Q138 via a 5V buck-boost converter U214. The microcontroller 28 is coupled to said same drain or source contact of the MOSFET switch Q138 via a further converter, assembled to follow the 5V buck-boost converter U214, and which is here a 3.3V buck-boost converter U316. Thus, when the output 24 of the 24V low voltage monitor 22 goes low on a power failure, the super capacitor, which is now disconnected from the power source, is discharged. Its charge flows to the 5V buck-boost converter U214 to generate a 5V voltage output to the first and second CPUs CPU-130, CPU232. Further, the charge flows to the 3.3V buck-boost converter U316 to generate a 3.3V voltage output to the microcontroller 28, as a minimum voltage to keep the microcontroller 28 controllable, even though it has been switched off.
The first CPU CPU-130 is provided power at a voltage of 5V along with the sensor driver for a first holding time of about 500 ms (milliseconds) and then switches off the sensors via their sensor drivers 31 as well. By this 500 ms holding time, the sensors can complete capturing processes which are running at the respective sensors at the moment the power failure occurs. Thus, the consistency of deposit date generated from sensor measurements is assured.
The second CPU CPU-232 is provided power at a voltage of 5V along with the application software 33a and to the deposit data memory 33 for a second holding time of about 5 to 6 seconds and then switches off the application software 33a and the deposit data memory 33. The second holding time of 5 to 6 seconds is sufficient for deposit data to be saved to the persistent deposit data memory 33. Optionally, the deposit data are saved by saving log files, which have been generated by the operating system and/or the application software 33a during normal operation.
The super capacitor C112 output is coupled to both the 5V buck-boost converter U214 and the 3.3V buck-boost converter U316 through a blocking diode D136. The MOSFET switch Q138 inserted between the 5V/6.5V buck converter U118 (also) effects blocking of a reverse current flow from the super capacitor C112 through body diodes present in MOSFETs associated with the 5V/6.V buck converter U118.
U420 is a 1.2V buck converter whose input is coupled to 6.5V output of 5V/6.5 V buck converter U118. U420 output (1.2V) is connected to U5 FPGA core supply. When 24V supply fails, FPGA core supply U5 output is turned off and hence 1.2V output of U420 is turned off subsequently. This further saves power during power failure.
Number | Date | Country | Kind |
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3527/DEL/2014 | Dec 2014 | IN | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2015/002416 | 12/2/2015 | WO | 00 |