DE10256235A1 - Banknote handling device with sensor system for banknote characteristics using pressurized air for pressing banknote against sensor head - Google Patents

Abstract

The banknote handling device has a sensor system (2) for detection of banknote characteristics, with a pressurized air source (7) used for pressing the banknotes (BN) against a sensor head (5) of the sensor system, by providing a pressure force perpendicular to the banknote transport direction of the banknote transport system (1).

Description

The invention relates to a banknote processing device, which for the detection of one or more features of a Banknote has at least one suitable sensor system.

Banknote processing machines are commonly used for counting and / or sorting and / or depositing and / or withdrawing banknotes used. For example, in banknote sorting devices the banknotes contained in the stack are initially separated and attached to one Hand over the transport system, which the banknotes to a sensor system for detecting the banknote features passes. Dependent on The banknotes are fed to individual output compartments from the detection results. For example can a sensor system for checking a or more security elements contained in the banknotes are used. For testing Magnetic properties of the banknotes become magnetic sensors used. Such sensor systems have, for example, a magnetic head on, perpendicular to the direction of transport of the banknotes in the transport system is arranged. The magnetic head usually extends over the entire width of the transport system, so the entire extent of the banknotes to be processed perpendicular to the transport direction of the magnetic head is covered. This makes it particularly possible to find out about the security elements extending across the full width of the banknotes, such as, for example Security threads, Completely to detect when they pass the magnetic head.

Although the banknotes are usually in the transport system between belts or rollers , the banknotes sometimes flutter inside of the transport gap. As a result, the distance between successive banknotes can vary and that the individual Banknotes are not always at the same distance on the sensor systems be transported past. This is particularly problematic with such sensor systems, the measurement result of which varies with the distance of the measurement object changes from the measuring system, for example in optical sensors, but especially also in magnetic sensors. Magnetic sensors with high spatial resolution have a strong dependence on distance. Your adaptation to varying measuring conditions is by no means trivial. Therefore, they are particularly high quality and accordingly expensive Magnetic sensor systems in use.

Instead of such high-quality magnetic sensor systems, simpler systems can also be used if it is ensured that the bank notes are pressed against the magnetic head during transport. In the US 6,119,936 For example, a roller-belt system is proposed, which is constantly coupled to the transport system and is lowered onto the magnetic head in such a way that the banknotes guided in the transport system are pressed against the magnetic head.

This solution is disadvantageous by the constant Contact between pressure system and magnetic head caused by magnetic head wear. The sensor systems are therefore correspondingly maintenance-intensive when they are being processed greater Banknote numbers be used.

In the DE 101 11 117A1 is therefore proposed as an improvement not to let the pressure system run continuously with the transport system, but only to press against the magnetic head when there is actually a banknote for checking in front of the magnetic head. For this purpose, the arrival of a banknote in the transport system is detected by a separate sensor at a distance from the magnetic head and, in the positive case, the pressure system is activated. The one in the DE 10111 117 A1 described banknote processing machine when the separate sensor detects not only the arrival but the exact positioning of the banknotes. Then the activation of the pressure system can be controlled exactly so that it only presses the banknotes against the magnetic head as long as the banknote feature to be detected is in the area of the magnetic head. In the case of a security thread extending transversely to the banknote transport direction, which is usually checked by means of a magnetic head, the contact time is thus reduced to a minimum.

However, the known solutions are constructive complex and therefore prone to repairs.

Object of the present invention It is therefore a less complex, yet low-wear banknote processing device propose.

This task is accomplished by a bank note processing device with the characteristics of the independent Claim resolved. Dependent on it claims are advantageous developments and refinements of the invention specified.

Accordingly, the banknotes are not with mechanical means but with compressed air in the direction of the Sensor system crowded. A such pressure device has fewer components and almost no moving parts apart from valves, which means you extremely wear- and is low maintenance.

To press the banknotes in the direction of the sensor system, either overpressure or underpressure can be used. Thus, it can be provided that the banknote is transported past between a sensor system and a compressed air source and that an impulse is exerted on the banknote in the direction of the sensor system by compressed air. Alternatively or additionally, a suction effect can also be exerted on the banknotes transported past a sensor system. In this case, for example, from the side between Banknote and sensor system Compressed air is blown at high speed, which leads to a negative pressure in this area, whereby the banknote is sucked in the direction of the sensor system in accordance with the Bernoulli effect.

Since the compressed air as such on the Sensor system has no significant wear and tear the compressed air source remain switched on even when there is no banknote in the area of the sensor system. On one separate sensor for detecting the presence of banknotes in the Transport system can therefore also be dispensed with. Still can such a current sensor may be useful, for example, or noise protection reasons Air discharge in Keep limits.

The pressure device according to the invention can Of course also be used if the banknotes are not directly against the sensor head of the sensor system but, for example, against one for the Sensor transparent pad pressed behind which the sensor head is located at a defined distance located. Such a support can be, for example, a grid or be a glass plate. The sensor head is then worn excluded, and the edition is only due to fretting the bypassed ones Banknotes exposed. On the other hand, the banknotes flutter due to of the contact pressure not in the area of the sensor system, so that an adaptation of the measuring system fluttering banknotes is not required.

As mentioned at the beginning, there are systems where the exam in if possible short distance, preferably with contact, takes place, for example in the case of using simple magnetic sensor systems. In these make subject to the sensor heads low wear due to the passed by and banknotes pressed by means of the compressed air. For further Reduction of fretting it makes sense to use a separate position sensor to apply the pressure device to be controlled exactly in such a way that it is only active when this is happening to be checked Banknote feature is located in the area of the sensor system.

According to a preferred embodiment of the banknote processing device according to the invention, the transport system in the area of the sensor system has a gap which extends over the entire width of the banknote transport path and through which the banknotes are forced over their entire width in the direction of the sensor system due to the compressed air. In contrast to that in the DE 10111117 A1 The device described, in which the banknotes are also guided in the area of the sensor system between two conveyor belts, ensures through this preferred embodiment of the banknote processing device according to the invention that the sensor system detects the full width of the banknotes. It also prevents the banknotes from curling transversely to the direction of transport under the influence of the pressing force. Rather, the sensor system is preferably arranged in the gap so that the banknotes are pressed directly against the sensor head or against a support in front of the sensor head by means of the compressed air source. The bank notes are then in contact with the section to be checked for bank note features on the sensor system.

On the one opposite the sensor system On the side of the banknote transport route, the transport system can be a conveyor belt have, which however for the compressed air from the compressed air source must be permeable so that the compressed air can act on the banknotes. The conveyor belt can for example be perforated, consist of meshes or by a plurality of narrow, spaced parallel to each other conveyor belts be educated.

The compressed air source preferably extends over the the entire width of the banknote transport route so that the banknotes themselves do not wave transversely to the direction of transport when crossing the Gap transported in which the sensor system is arranged.

For this purpose, the compressed air source is preferably there out of at least one over the slot nozzle extending the entire width of the banknote transport path. alternative the compressed air source can also be made up of a number of neighboring locally limited compressed air nozzles are formed.

The invention is illustrated below by way of example of the accompanying drawings. In it show:

1 a section of a transport system of a banknote processing device in side view,

2 the section 1 in top view, and

3 an alternative air nozzle shape and arrangement.

In the figures, only those components of the banknote processing device are shown that are important in connection with the present invention, namely a section of the transport system 1 in the area of the sensor system 2 in side view ( 1 ) and top view ( 2 ). The transport system 1 includes an upper conveyor belt 3 and one of two conveyor belts arranged one behind the other 4a . 4b formed lower conveyor belt, between which a bank note BN on the sensor system 2 is led past. The direction of transport is indicated by arrows.

The sensor system 2 lies in a gap between the two lower conveyor belts 4a . 4b , The sensor head 5 of the sensor system 2 is designed so that the BN banknote can easily slide over it during transport. The sensor head forms for this purpose 5 , for example a magnetic head, a flat support surface for the bank note BN parallel to the lower conveyor belts 4a . 4b , The bearing surface can also be convex or, in particular, concave. The front part of the sensor head in the transport direction 5 is slightly chamfered to prevent the BN banknote from entering the gap between the lower conveyor belt 4a and the sensor head 5 threading.

The contact surface of the sensor head 5 lies opposite the transport level of the lower conveyor belts 4a . 4b slightly set back. This measure also serves, on the one hand, to prevent the banknote BN from being threaded into the gap between the lower conveyor belt 4a and the sensor head 5 , On the other hand, this creates a distance from the upper conveyor belt 3 created and wear-prone contact avoided accordingly.

By means of a sensor head 5 opposite pressure device 6 becomes the banknote BN during its transport between the conveyor belts 3 and 4a . 4b against the sensor head 5 pressed so that the banknote BN and the sensor head 5 come into contact with each other. Alternatively, the sensor head 5 be protected from direct contact with the BN banknote by a separate intermediate pad.

The pressure device 6 works on a compressed air basis, using compressed air from a nozzle-like compressed air source 7 acts approximately vertically from above on the banknotes BN transported past.

Due to the action of compressed air, it is ensured in any case that the bank note BN is in the area of the sensor system 2 on the sensor head 5 or lies flat against an intermediate pad so that the detection of a special banknote feature, in particular a security element such as a security thread, is possible without any problems.

In 1 is just an example of a single source of compressed air 7 represented with a point or circular nozzle cross section. Of course, such nozzles are provided over the width of the banknote transport path, ie over the entire banknote width, in order to press the banknote BN over its full width with the most uniform possible pressure against the sensor head 5 to press. In this way, security elements, such as security threads, extending across the entire width of the banknote can be reliably detected.

2 shows the pressure device 6 exemplary in supervision with a number of compressed air sources arranged in a row 7 with point or

circular nozzle cross-sections. It may be useful to use additional compressed air sources in the transport direction of the BN banknote 7 in the area of the sensor head 5 provided. In addition, the cross-sectional shape of the outlet nozzles can have any geometrical shape and can be designed in particular as a slot nozzle. So shows 3 an example of a pressure device 6 with two slit nozzle type compressed air sources 7 which against the in 2 shown pressure device 6 can be exchanged.

The upper conveyor belt 3 is in the illustrated embodiment 2 through three narrow, parallel-spaced conveyor belts 3 formed so that the compressed air acts essentially unhindered over the entire width of the banknote BN on the banknote. Other conveyor belts can also be used as long as it is ensured that the bank note BN transported underneath is reached by the compressed air with sufficient pressure intensity. For example, the conveyor belt 3 be designed as a sieve belt, perforated belt, braid or the like. On the other hand, it is also possible to use the upper conveyor belt 3 to form in two parts according to the lower conveyor belt and the compressed air source 7 to place in a gap between the two upper conveyor belt sections, or the upper conveyor belt 3 via the compressed air source 7 away out.

In addition to the elements already described, it can be positioned in front of the sensor system in the direction of transport 2 arranged current sensor 8th the approach of a next bank note BN is detected and a signal to the pressure device 6 are released, possibly via an intermediate data processing device, around the compressed air source 7 to activate. The present sensor 8th can be, for example, a simple light barrier. The present sensor also detects the end of the banknote BN that is passed by 8th detected and a corresponding signal to the pressure device 6 sent which with a predetermined time delay, which depends on the transport speed of the transport system 1 depends, the compressed air discharge interrupts until the arrival of the next banknote is reported. In this way, the compressed air output can be limited to what is necessary.

A further limitation of the compressed air output is possible if the current sensor 8th is designed as a positioning sensor with which the exact position and orientation of the banknote can be detected in the transport system. Such a positioning sensor would be far ahead of the in the transport direction 1 Present sensor shown 8th to be placed so that the banknote BN is completely detected and its position is evaluated before it reaches the sensor head 5 has reached. If the exact position and orientation of the bank note BN is determined by means of such a positioning sensor, it can be concluded from this that the location at which the security element to be checked is located in the bank note. Taking into account the transport speed of the transport system 1 then becomes the compressed air source 6 activated exactly at the point in time at which the security element to be checked is in the area of the sensor head 5 located.

Alternatively or in addition to the previous ones Based on the described exemplary embodiments with overpressure generation, it is also conceivable for the banknotes BN to generate negative pressure in the direction of the sensor head 5 be pushed. or be worked with negative pressure. It can be provided that in one area 10 between the sensor head 5 and a bank note BN transported past it perpendicular to the transport direction from the side, ie in the 1 in a direction perpendicular to the plane of the drawing, by means of a compressed air source, not shown, compressed air at high speed between bank note BN and sensor head 5 can be blown. According to the Bernoulli effect, this creates a negative pressure in the area 10 , causing the banknote BN towards the sensor head 5 is sucked. In principle, the negative pressure can also be generated by a vacuum system which, apart from the transport system 1 is largely sealed to the outside and, for example, by suction of ambient air, the bank notes BN are also drawn towards the sensor head by means of negative pressure 5 sucks.

Claims (9)

1 banknote processing device comprising at least one sensor system ( 2 ) for detecting one or more features of a banknote (BN), a transport system ( 1 ) for transporting the banknote (BN) on the sensor system ( 2 ) over and one perpendicular to the transport direction of the transport system ( 1 ) pressure device acting on the banknotes (BN) ( 6 ) with which the banknotes (BN) towards the sensor system ( 2 ) are pushed around the banknotes (BN) at a given distance to the sensor system ( 2 ) to pass, characterized in that the pressure device ( 6 ) a compressed air source acting on the banknote (BN) ( 7 ) includes. Device according to claim 1, characterized in that the compressed air source ( 7 ) acts with overpressure on the banknote (BN) and / or in an area ( 10 ) between banknote (BN) and sensor system ( 2 ) generates a negative pressure, which the bank note BN to the sensor system ( 2 ) sucks. Device according to claim 1 or 2, characterized in that the compressed air source ( 7 ) extends over the entire width of the banknote transport route. Device according to one of the preceding claims, characterized characterized in that the compressed air source has a number of neighboring, includes locally limited compressed air nozzles. Device according to one of the preceding claims, characterized characterized in that the compressed air source falls over at least one slot nozzle, who are about extends the entire width of the banknote transport route. Device according to one of the preceding claims, characterized in that the transport system ( 1 ) in the area of the sensor system ( 2 ) has a gap that extends over the entire width of the banknote transport path, through which the banknote (BN) extends over its entire width in the direction of the sensor system ( 2 ) be pushed. Device according to one of the preceding claims, characterized in that the sensor system ( 2 ) is arranged in a gap in such a way that the banknote (BN) by means of the compressed air source ( 7 ) to the sensor system ( 2 ) is pressed. Device according to one of the preceding claims, characterized in that the transport system ( 1 ) the sensor system ( 2 ) has opposite conveyor belt through which the compressed air source ( 7 ) acts on the banknote (BN). Device according to one of the preceding claims, characterized in that the sensor system ( 2 ) has a magnetic sensor.