EP2653317A2 - Device for handling a strip - Google Patents

Abstract

The method involves receiving priority information including a list of communication time slots from the root node (102A). The communication time slots are indicated during which a one-hop neighbors (102B-102D) of the root node has communication priority relative to other one-hop neighbors of the root node. The one-hop neighbor of the root node is provided with information to transmit to the root node. The one-hop neighbor is waited for predetermined period of time before transmitting the information to the root node, based on the priority information received from the root node. The one-hop neighbor listening on a control channel of the network for transmissions by other nodes during the predetermined period of time and transmit the information in response to expiration of the predetermined period of time without overhearing transmissions by other nodes during the predetermined period of time. Independent claims are included for the following: (1) network computing device of communication network; and (2) computer-readable medium storing program for implementing hybrid access protocol.

Description

The invention relates to a device for handling a tape serving the optical personalization of data carriers, in particular an ink ribbon, with a first storage module for a first band portion of the band, with a second storage module for a second band portion of the band and with a first drive unit for feeding the tape to the second storage module, the tape being stored in the first storage module prior to use thereof for optical personalization of the storage media and the tape being stored in the second storage module after use thereof for the optical personalization of the storage media.

For optical personalization of data carriers, for example bank cards, credit cards, health cards or the like, a band, in particular an ink ribbon, is usually used today. The tape applies user-related data, such as a card ID number, the user's account number or name to the card. The user-related data that is applied to the card by means of the tape can also be recognized on the ink ribbon - as a kind of image. The tape is therefore the carrier of confidential, user-related data (image data). The tape containing the image data must therefore be protected against access by third parties, against misuse and theft. For this reason, the tape is destroyed after it has been used in the manufacture of the data carriers documented. Destruction is usually done remotely by external service providers. For the purpose of destruction, the tape with the image data is mechanically destroyed, in particular shredded or burned.

In order to extract the tape with the image data during the production of the disk third party access, the device for handling the tape today usually has a first storage module for a first, unused tape portion of the tape and a second storage module for a second tape portion of the tape. In the second storage module, the tape is stored after using it for the optical personalization of the data carrier. In this case, the second storage module is designed as a closed storage module such that at least the second band section of the band with the image data is removed from the access of third parties, in particular also the access of the operating personnel.

The object of the present invention is to develop a device for handling a tape serving the optical personalization of data carriers in such a way that the destruction of the tape after the use thereof for the optical personalization of data carriers is simplified and the costs for the destruction decrease.

To solve the problem, the invention in conjunction with the preamble of claim 1, characterized in that an annihilation module for the destruction of the tape after the use thereof for the optical personalization of the disk and a second drive unit are provided, wherein by means of the second drive unit, the tape Outlet opening of the second storage module from the second storage module can be removed and fed to the destruction module.

The particular advantage of the invention is that the tape is destroyed after use of the same for optical personalization of data carriers on the spot in the destruction module. This can provide maximum protection against abuse and theft. In addition, the costs of destruction are reduced, in particular the logistics costs associated with transporting the tape to service providers carrying out the data destruction. The core idea of the invention is therefore to destroy the tape with the image data on site. Consequently, the destruction process takes place in the already secure area of data carrier production. The area of data carrier production is usually accessible as a security area only to selected persons. In addition, security and identity checks can be implemented when entering and leaving the security area. The misuse or theft of the tape with the image data is therefore prevented.

The destruction module can be designed, for example, in the manner of a shredder and mechanically destroy the strip. Also, the tape can be thermally or otherwise permanently destroyed.

According to a preferred embodiment of the invention, at least one detection unit for detecting the fill level of the second storage module is associated with the second storage module. The detection unit may have suitable sensors for this purpose. Likewise it can be provided that the detection unit is sensorless. By way of example, suitable electrical signals of the first drive unit or of the second drive unit can be evaluated by a control module of the device for sensorless detection of the fill level of the second storage module. For example, a motor current of the same can be evaluated as the electrical signal of the first or second drive unit. Advantageously, by monitoring the fill level of the second storage module, an overflow of the second storage module and, as a result, a standstill of the production facility for the data carriers can be prevented.

According to a development of the invention, a control module is provided which cooperates with the at least one detection unit and the second drive unit in such a way that the second drive unit is activated or deactivated in response to an actuation signal provided by the detection unit. Advantageously, this achieves an automation degree which permits the automatic destruction of the tape section having the image data Depending on the level of the second storage module allowed. The second storage module can therefore have a lower storage volume than the first storage module. On the one hand, this is advantageous in terms of construction space; on the other hand, this ensures that the second strip section with the image data is stored for a short time and destroyed in the destruction module in a timely manner.

Since the production of the data carriers takes place sequentially, the advance of the tape used in the optical personalization of the data carriers is also carried out sequentially. By the destruction module, the second storage module is upstream of storage for the second band section, the annihilation of the tape portion having the image data can be decoupled from the power stroke of the production facility for the disk. This protects in particular the second drive unit, since, for example, initially 100 data carriers can be personalized and then subsequently the second tape section with the image data of this 100 data carriers is destroyed in one work step.

According to a development of the invention, a first detection unit for determining a first critical level of the second storage module and a second detection unit for determining a second critical level of the second storage module are assigned to the second storage module. Here, the first and the second detection unit cooperate with the control module of the device such that the second drive unit is activated by an actuation signal of the first detection unit and is deactivated by an actuation signal of the second detection unit. Advantageously, the degree of automation is thereby further increased. The second drive unit can be operated in dependence on the actuation signals of the first detection unit and the second detection unit. In this case, inexpensive available detection units can be used, which are simple and robust.

According to a development of the invention, an additional detection unit is assigned to the second storage module, the additional detection unit interacting with a further control module responsible for handling the data carrier and providing an actuating signal to this further control module. For example, the actuation signal of the additional detection unit can be designed as an emergency signal such that the further control module interrupts a higher-level process, in particular the production process for the data carriers when the emergency signal is applied. Advantageously, this results in a high process reliability. In the event of a defect of the first or second detection unit and / or in the event of a defect of the second drive unit and / or in the event of a defect of the destruction module, it is prevented that the second storage module overflows and the production system gets into an inadmissible or undefined state. In this respect, the process reliability is further increased by the provision of the additional detection unit.

According to a development of the invention, a sensor is provided as first detection unit or as second detection unit or as additional detection unit, in particular a light barrier sensor or a proximity sensor or a distance sensor. Advantageously, the determination of the fill level of the second storage module can be carried out in a simple manner. The result is a robust and often used in practice embodiment, which is characterized by high reliability and can be realized inexpensively.

According to a development of the invention, the band is concealed in the area between the second storage module and the destruction module. Advantageously, readout of the image data on the second band section can be prevented if the band is stored concealed in the second storage module and / or concealedly supplied to the destruction module. This results in a high level of security and improved protection against abuse.

According to a development of the invention, a housing is assigned to the second storage module and the destruction module. The housing is designed as a closed housing such that the image data present on the second band section can not be viewed. Advantageously, the band can be guided concealed by the provision of a housing as well as protected against mechanical access. This further improves the security against manipulation.

According to a development of the invention, an opening and a closure unit associated with the opening are provided on the housing, wherein the closure unit is designed as a resealable or lockable closure unit and has a closing module. As a closing module, for example, a security lock can be provided. Advantageously, by providing a closable opening the protection of the tape secured against manipulation and at the same time a maintenance access can be realized, which allows inserting the tape in the device or in the case of an unforeseen defect, such as a separation of the tape, the device to repair in a timely manner set and reduce downtime.

According to a development of the invention, the second band section is looped in the second storage module. Advantageously, the loop-shaped guiding of the second band section prevents damage to the band during storage, for example due to buckling or knotting. As a result, the reliability of the process management improves.

According to a development of the invention, the second storage module is designed as a dancer storage with a dancer roller, which has a weight such that the second band section is held in tension in the second storage module by the weight of the dancer roller. As a result, the second storage module can advantageously be made passive. On a further, the second storage module associated drive unit can be waived accordingly. The second storage module is therefore inexpensive and mechanically robust.

According to a development of the invention, the dancer roll is linearly guided in the second storage module in a vertical direction. Advantageously, the linear guidance of the dancer roller in the second storage module results in high reliability. At the same time allows the leadership of the dancer roll in the vertical direction, the use of the weight of the dancer roll for tensioning the second band section.

According to a development of the invention, the detection units are arranged distributed along a displacement of the dancer rollers. Advantageously, this can be concluded from the position of the dancer roll on the level of the second storage module.

Embodiments of the invention are explained below with reference to the drawings.

Figur 1

ein Blockschaltbild einer Fertigungsanlage zur Herstellung von Datenträgern mit einer Vorrichtung zur optischen Personalisierung der Datenträger und

Figur 2

eine Prinzipdarstellung der Vorrichtung zur optischen Personalisierung der Datenträger gemäß Figur 1.

Show it:

FIG. 1

a block diagram of a manufacturing plant for the production of data carriers with a device for optical personalization of the disk and

FIG. 2

a schematic diagram of the device for optical personalization of the disk according to FIG. 1 ,

FIG. 1 shows a manufacturing plant for the production of data carriers, in particular bank cards, credit cards, health cards or the like. The production plant comprises by way of example four workstations 1, 2, 3, 4 for the production of the data carrier and a device 5 for optical personalization of the data carrier. The workstations 1, 2, 3, 4 are traversed sequentially during the production of the disk. Around Workstation 3 is the disk by means of the device 5, a tape 6, in particular a ribbon 6, fed. By means of the band 6 user-related data, such as an account number, a credit card number or the name of the cardholder, applied to the disk.

The manufacturing plant has a central control module 7, which cooperates with the workstations 1, 2, 3, 4 and coordinates the processes during the production of the data carrier. The central control module 7 is also data-technologically coupled to the device.

The manufacturing plant is usually operated in a security area of a card company. The user-related data, which are applied by means of the supplied in the device 5 of the workstation 3 tape 6 on the disk, are confidential in nature and must be protected from unauthorized access by third parties. Since, after the optical personalization of the data carriers, image data of the user-related data applied to the data carrier are present on the tape 6, the tape 6 must subsequently be destroyed.

The device 5 has as central components a first storage module 8, a second storage module 9, a destruction module 10, a device control module 11, a feed module 12 arranged between the first storage module 8 and the second storage module 9 and a drive unit 13 cooperating with the feed module 12 on. Furthermore, a total of three detection units 14, 15, 16 are assigned to the second storage module 9. The destruction module 10 is formed in the present embodiment in the manner of a shredder 10. The shredder 10 has a second drive unit 17, a cutting unit 18 actuated by the second drive unit 17, and a storage unit 19 for receiving the cut material 20. Accordingly, a first band section of the band 6 and in the second stocking module 9 a second band section of the band 6 are stored in the first storage module 8, wherein the second band section has the image data of the user-related data applied to the data carriers.

The tape 6 is stored in the first storage module 8 prior to feeding it to the optical personalization performing workstation 3. After using the optical personalization tape 6, image data of the personal data deposited on the media are stored on the tape 6. After using the same for the optical personalization of the data carrier, the tape 6 is fed to the second storage module 9 by means of the feed module 12 driven by the first drive unit 13. The feed takes place sequentially in time with the production line. Consequently, the first drive unit 13 is operated via the work stations 1, 2, 3, 4 associated additional control module 7 in the power stroke. After each personalization of a data carrier, the band 6 is conveyed to some extent in the direction of the second storage module 9, and the second storage module 9 fills in time with the workstations 1, 2, 3, 4.

A level of the second storage module 9 is monitored by means of a total of three detection units 14, 15, 16. The detection units 14, 15, 16 are realized, for example, as sensors. A first sensor 14 delivers a first critical level of the second storage module 9, a second sensor 15 a second critical level and a third sensor 16 a third critical level.

The first sensor 14 and the second sensor 15 interact with the control module 11 of the device 5 in such a way that the second drive unit 17 is activated or deactivated depending on the level of the second storage module 9 characterizing actuation signals of the first sensor 14 and the second sensor can. The second drive unit 17 can therefore be operated independently of the power stroke of the manufacturing plant. Only the level of the second storage module 9 decides on the operation of the destruction module 10.

The third sensor 16 cooperates as an additional sensor 16 with the central control module 7 of the manufacturing plant. The actuation signal of the third sensor 16 is formed for example as an emergency signal. When the third critical level of the second storage module 9 is reached and the emergency signal is present at the central control module 7, the sequential manufacturing process of the data carriers in the workstations 1, 2, 3, 4 can be interrupted by the central control module 7.

Optionally, it can be provided that the proper functioning of the second drive unit 17 is monitored by the central control module 7 and / or by the control module 11 of the device 5. To check the function of the second drive unit 17, for example, the motor current can be monitored. A failure of the drive unit 17 can then be detected, for example, if, after signaling the sensors 14, 15, 16, the drive unit 17 would be activated and at the same time the motor current is below a limit, which indicates a non-function of the drive unit 17. In this case, the production of the data carrier from the central control module 7 of the workstations 1, 2, 3, 4 also interrupted or the operating personnel are made aware of the malfunction in particular by optical or acoustic signals.

Optionally, it can further be provided that the second drive unit 17 can only be operated if the storage unit 19 is correctly assigned to the cutting unit 18. For this purpose, for example, an unillustrated position sensor may be provided and cooperate with the control module 11 of the device 5.

The production plant according to FIG. 1 is merely exemplified as a manufacturing plant with four workstations 1, 2, 3, 4 shown. Of course, further workstations can be provided. Likewise, less than the four workstations 1, 2, 3, 4 may be formed. The optical personalization of the data carrier in the workstation 3 is also only exemplary. The optical personalization can be done on any other Workstation done. In this case, the tape 6 is supplied to the corresponding work station by means of the device 5 and destroyed.

The second storage module 9 of the device 5 can according to FIG. 2 For example, be designed in the manner of a dancer memory 9. The dancer memory 9 in this case has a dancer roll 25, which is linearly guided in a vertical groove 26 in the vertical direction 33. The dancer roller 25 cooperates with the second band portion of the band 6 such that when operating the feed module 12, the dancer roll 25 is lowered along an adjustment path 34 defined by the vertical groove 26 and the second storage module 9 is filled. When operating the cutting unit 18, on the other hand, the second band section is conveyed out of the storage module 9. For this purpose, the storage module 9 has an outlet opening 27 assigned to the destruction module 10. The sensors 14, 15, 16 are associated with the adjustment 34 distributed. The first sensor 14 supplies as the first critical level information about a minimum level of the second storage module 9. The second sensor 15 is actuated as soon as the second storage module 9 is filled so far that the second drive unit 17 is to be actuated. If, for example, due to a defect of the second drive unit 17, the second storage module 9 is not emptied after reaching the second critical level, the exceptional operating state can be displayed to the operating personnel, for example, by the audible or visual warning signal. An emergency signal provided by the third sensor 16 may eventually lead to an emergency stop and interrupt the manufacturing process of the data carriers, provided that the third critical level is reached.

A distance of the second sensor 15 from the third sensor 16 can be dimensioned so that the operating personnel after the audible or visual warning signal is a sufficient reaction time available. If, for example, 1000 cards per hour are produced and a reaction time of 90 seconds is to be realized, the volume required for the optical personalization of 40 data carriers must additionally be 6 Storage module 9 are stored before after activation of the second sensor 15, the third sensor 16 is activated.

Due to the design of the storage module 9 as a dancer storage, the second band section in the second storage module 9 is looped or looped. It is thereby realized a sufficient storage volume and at the same time realizes a reliable storage concept, which prevents damage to the tape 6 or a tape salad.

In order to ensure unconditional confidentiality of the user-related data and to prevent the access of third parties to the image data of the second band section of the belt 6, the second storage module 9 has a housing 28 of a closed design. The housing 28 has the outlet opening 27 and an additional opening 29, which is designed in its size and position so or so dimensioned that the tape 6 initially inserted into the device 5 and in the event of a defect in the region of the second storage module. 9 a maintenance access to the same is possible. The further opening 29 is covered by a closure unit 30 with a locking module, not shown. The closure unit 30 is held in a closed position by the closure module, which is designed, for example, as a security lock, in which the opening 29 is covered by the closure unit 30 and third-party access to the second belt section of the belt 6 guided in the storage module 9 is not possible.

As a destruction module 10, for example, a substantially commercially available shredder 10 may be associated with the housing 28 so that the band 6 is received directly by the destruction module 10 after passing through the outlet opening 27. A remaining gap 31 between the housing 28 and the destruction module 10 can be closed, for example, by an elastic cover element 32, in particular a brush or a rubber lip.

Claims (10)

Device for handling a tape (6) serving for optical personalization of data carriers, in particular an ink ribbon (6), having a first storage module (8) for a first strip section of the strip (6), with a second storage section (9) for a second strip section of the belt (6) and with a first drive unit (13) for feeding the belt (6) to the second storage module (9), the belt (6) being used for optical personalization of the data carriers in the first storage module (8 ) and wherein the tape (6) is stored in the second storage module (9) after use thereof for optical personalization of the data carriers, characterized in that a destruction module (10) destroys the tape (6) after use thereof for optical personalization of the data carrier and a second drive unit (17) are provided, wherein by means of the second drive unit (17) the strip (6) can be removed from the second storage module (9) through an outlet opening (27) of the second storage module (9) and fed to the destruction module (10). Apparatus according to claim 1, characterized in that the second storage module (9) is associated with at least one detection unit (14, 15, 16) for detecting a level of the second storage module (9). Device according to claim 1 or 2, characterized in that a control module (7, 11) is provided, which interacts with the at least one detection unit (14, 15, 16) and the second drive unit (17) such that the second drive unit (17 ) is activated and / or deactivated in response to an actuation signal provided by the detection unit (14, 15, 16). Device according to one of claims 1 to 3, characterized in that the second storage module (9) has a first detection unit (14) for determining a first critical level of the second storage module (9) and a second detection unit (15) for determining a second critical level the second storage module (9) are assigned, wherein the first detection unit (14) and the second detection unit (15) with the control module (11) cooperate such that the second drive unit (17) by an actuating signal of the first detection unit (14) activated and is deactivated by an actuation signal of the second detection unit (15). Device according to one of claims 1 to 4, characterized in that the second storage module (9) is associated with an additional detection unit (16), wherein the additional detection unit (16) cooperates with a coordinating for handling the data carrier further control module (7) and the further control module (7) provides a further actuation signal available, wherein the further actuation signal of the additional detection unit (16) is designed as an emergency signal such that the further control module interrupts a higher-level process when applying the emergency signal. Device according to one of claims 1 to 5, characterized in that the first detection unit (14) and / or the second detection unit (15) and / or the additional detection unit (16) comprise a sensor. Device according to one of claims 1 to 6, characterized in that the band (6) in the region of the second storage module (9) and / or the destruction module (10) is guided concealed. Device according to one of claims 1 to 7, characterized in that the second storage module (9) and / or the destruction module (10) is associated with a housing (28) and that the housing (28) is formed closed such that on the second Tape section caused by the optical personalization of the disk image data are not visible. Device according to one of claims 1 to 8, characterized in that the housing (28) has an opening (29) and one of the opening (29) associated closure unit (30), wherein the closure unit (30) has a closing module and as a lockable Locking unit (30) is formed. Device according to one of claims 1 to 9, characterized in that the second band portion in the second storage module (9) is guided loop-shaped and / or that the second storage module (9) is designed in the manner of a dancer storage with a dancer roll (25), which a weight such that the band (6) in the second storage module (9) is held in tension by the weight of the dancer roller (25), the dancer roller (25) in the second storage module (9) being linear in the vertical direction (33) is guided and / or that the detection units (14, 15, 16) distributed along a Verstellwegs (34) of the dancer roll (25) are provided.

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