KR20080103532A - Apparatus and process for producing document core inlays - Google Patents

Abstract

An apparatus for processing a document core sheet to produce a document core inlay may include a plurality of processing stations, each for executing at least one step in producing the document core inlay, and at least one supporting table for supporting the core sheet and for transporting the core sheet to each processing station for processing. The processing stations may be positioned surrounding a center such that a closed-loop path is defined. The table may travel along the closed-loop path among the processing stations.

Description

Production equipment and process for paper core inlays {APPARATUS AND PROCESS FOR PRODUCING DOCUMENT CORE INLAYS}

The present invention relates to the production technology of filing core inlays.

The documents may include an integrated circuit printed on or printed on each sheet of paper.

In one embodiment, the document may be, for example, a passport, travel document, proof document or other security document. The travel document core inlay production apparatus may be a mixture of a number of processing stations, each performing at least one step of inserting the travel document core sheet into the travel document core inlay.

The machining station includes a loading station for loading (loading) a core sheet, a module placement station for placing a circuit chip integrated in the core sheet, and an electrical connection Wire embedding station for installing wires in the core sheet for installation, spot welding station for welding the wires for electrical connection with the chip module, and unloading for unloading the produced core inlay. An unloading station may be included.

In general, various processing stations can be arranged continuously along a linear rail. The support table may support the core sheet in the process of moving the core sheet from one station to another along the rail.

The apparatus may include a mechanism and / or process to return the support table to the beginning of the rail to produce the next core sheet.

The size of such a machine can be larger than the required size.

Accordingly, it is an object of the present invention to propose a relatively compact document core inlay production apparatus and process.

According to one aspect of the invention, an apparatus for processing a document core sheet into core inlays with each other comprises a plurality of processing stations each carrying out a step of producing at least one travel document core inlay, and the core sheet; And at least one table for transferring the core sheet to each processing station.

The processing stations are arranged so that a closed loop path is defined around the center, and the table moves along the closed loop path between the processing stations.

According to another aspect of the invention, the process of processing a core sheet into a core inlay comprises providing a core sheet, continuously circulating the core sheet to a plurality of processing stations disposed along the closed loop path; Processing the core sheet at each successive processing station, the processing comprising providing a core inlay to the core sheet.

With reference to the drawings illustrative of the spirit of the invention, it is apparent that other features and effects can be obtained from the detailed description presented below. Other techniques deemed to be features of the invention are set forth in the appended claims.

1 is a schematic plan view of an apparatus for producing a travel document core inlay of an embodiment;

2 is a process diagram showing operation of the core inlay production apparatus of one embodiment.

3 shows one embodiment of a loading station.

4A is a plan view schematically showing one embodiment of a turn table of the device of FIG. 1;

4B is a cross-sectional view taken along the line AA ′ of FIG. 4.

5 is a schematic plan view of a paper core inlay production apparatus of another embodiment.

6 is a schematic plan view of a filing core inlay production apparatus of yet another embodiment.

The same reference numerals are applied to the same configurations in the following detailed description and drawings.

1 is a schematic plan view of a travel document core inlay production device 100 of one embodiment.

The core inlay production apparatus 100 includes a plurality of processing stations, for example, a loading station 101, a module placement station 103, a wire embedded station 105. A spot welding station 107 and an unloading station 109 are included.

In one embodiment, the processing stations may be combined with a platform 111 and disposed along the circumference (or periphery) of the annular turntable 113.

In one embodiment, the processing stations may be arranged substantially evenly along the circumference. In one embodiment, the turn table 113 may be rotated about the center or axis 115.

In one embodiment, the turn table may include a plurality of support tables 117a-117e. In one embodiment, the support tables may be evenly arranged along the circumference. In one embodiment, the support tables can be positioned so that they can be fed simultaneously to the individual working areas of the processing stations.

In one embodiment, the path of the support tables 117a-117e may define a closed loop path 317 as the tentable rotates along all of the processing stations 101-109.

2 shows one process 20 for producing a core inlay for a document.

In one embodiment, the process 20 includes loading an unprocessed core sheet 21, placing a module or chip on the core sheet 22, wires for electrical connection with the chip. Inserting (23), welding (eg spot welding) 24 for connecting the module or chip and wires, and unloading the chip 25 from the device. .

In one embodiment, the loading step 21 may be performed first, the placing step 22 may be performed secondly, the wire insertion step 23 may be performed third, The welding step 24 may be performed at the fourth and the unloading step 25 at the end.

In one embodiment, the process may include the step 26 of cycling the core sheet from one processing station to the next. In one embodiment, the core sheet or core sheets may be conveyed from one processing station to the next station by a turn table in which the core sheet or core sheets are rotated at an angle to reach the next processing station.

In one embodiment, by rotating at an angle of 72 degrees of the turn table, circular rotation and five processing stations spaced at regular intervals, the core sheets can be continuously circulated through the processing station.

In one embodiment, as shown in FIGS. 5 and 6, the core seat is centered or by the closed loop rail (313 in FIG. 5) or the support table (315 in FIG. 5) moving on the track. By rotation of the plurality of arms 61a-61e supporting the support tables 117a-117e arranged at a set angle with respect to the axis, it is possible to move from one machining station to the next.

In one embodiment, the process may further comprise feeding the core sheet to a work area of a processing station. For example, when the core sheet is transferred to a new processing station, such as, for example, a module placement station, a wire insertion station and / or a fold welding station, the core sheet may be fed to the working area of the individual processing station.

In one embodiment, the process may include removing the core sheet in the working area of the individual processing station before the individual processing is completed and the core sheet is transferred to the next processing station.

Loading station

3 shows an embodiment of the loading station 101.

In one embodiment, the raw core sheet 31 may be loaded (loaded) from the loading tray 32 of the loading station 101 to the support table 117a. In one embodiment, the loading station 101 raises the core sheets 34 to approximately the same level (height) as the support table 117a determined by the photo sensor 35 installed in the loading station 101. It may include a lift table (33).

In one embodiment, the suction mechanism 36 may suction and lift the upper core sheet by vacuum, and the transfer unit 37 moves the lifted core sheet to the individual support table 117a on the turntable 113. Can supply

In one embodiment, air 38 may be blown into the lift table from the side of the lift table for proper paper separation.

Modular placement station

In one embodiment, when the turn table 113 is rotated or rotated, an unprocessed core sheet may be supplied to the work area of the module placement station 103. In addition, a circuit chip module (not shown) integrated on the core sheet may be mounted at the module placement station 103.

In one embodiment, with five stations, the turn table 113 may be rotated at an angle of 72 degrees.

Wire insertion station

In one embodiment, the core sheet is subjected to a rotation or circulation step 26 of the turntable 113 which is rotated at an angle of 72 degrees, for example, so that wires for electrical connection with the module or chip can be placed on the core sheet. Supply 27 to the wire insertion station 105.

Point welding station

In one embodiment, the core sheet may be removed 28 from the previous station and rotated 26 or rotated into the spot welding station 107. In one embodiment, the wires are welded to allow electrical connection with the chip module by the abutment welding station 107. In one embodiment, in this step, the core sheet may be a completed core inlay.

Unloading station

In one embodiment, the turn table 113 may be rotated 26 degrees or, for example, at an angle of 72 degrees to feed the produced core inlay to the unloading station 109. The produced core inlay is then removed from the support table. In one embodiment, for the new production process 20, the support table from which the core inlay has been removed may be circulated 26 or rotated into the loading station 101.

In one embodiment, tester 29 may be coupled to an unloading station.

According to one embodiment, the core inlay production apparatus can be relatively compact in structure by the arrangement of central peripheral processing stations. According to one embodiment, the core inlay production apparatus may define a closed rook path connecting the processing stations. The closed loop path arrangement may facilitate feeding the support table 117d on the unloading station 109 to the loading station 101 for subsequent subsequent processing.

By providing a plurality of support tables 117a-117e in the core inlay production apparatus, a plurality of core sheets can be easily processed simultaneously. For example, with five support tables 117a-117e, five core sheets can be processed simultaneously.

Each of the separate processing stations may be equipped with an independent security system. By providing independent safety devices for the processing stations, each processing station can be controlled independently.

For example, the turn table 113 illustrated in FIGS. 4A and 4B may have a center 115 rotatably mounted to a pivot or column. The turn table may include a plurality of blocks 201a-201e. The blocks 201a-201e may work together with a laser micrometer 203 coupled to the platform 111 for alignment of the turn table 113.

The support table has a vacuum hole (Fig. 3) for flattening the core sheet and maintaining the core sheet in contact with the support table so that the core sheet can be present on the support table without lifting during processing. 39) can have them.

The vacuum holes function to achieve the required production quality by reducing the possibility of unintentional movement of the core sheet.

5 shows a processing apparatus 300 of another embodiment.

In one embodiment, the apparatus 300 may include a plurality of processing stations 301, 303, 305, 307, 309. The processing stations may perform a function similar to the processing station described in FIGS. 1 to 3.

The processing stations are arranged around the center 311, and the closed loop path 317 connecting the processing stations has an irregular (non-circular) shape.

The processing stations may be connected by rails 313 defining the closed route path 317. The support table (s) 315 are between the machining stations 301-309 by means of gears or gear tracks (not shown), for example, each of which is installed on either the rail or the support table. It may move along the rail 313.

Various embodiments may be further included in addition to the above-described embodiments.

For example, referring to FIG. 3, the loading station 101 may use a positioning unit (not shown) prior to the support table for accurate positioning of the core sheet.

In one example, after the core sheet is loaded onto the platform of the positioning unit by the transfer unit 37, the pair of moving plates (not shown) of the positioning unit is repeated to the support table of the core sheets. In order to enable in-position alignment, the two rear ends of the core sheet are connected to the pair of fixed ends or stoppers on the support table until the two front ends of the core sheet touch the pair of fixed ends on the support table. Not shown).

Air may be blown from the lower side of the positioning unit in order to reduce friction between the core sheet and the positioning unit.

6 is a view showing the document core inlay production apparatus 100 of another embodiment.

The device 100 may include a plurality of bark tables 117a-117e that support the core sheet during processing. The support tables 117a-117e may be mounted or attached to the plurality of arms 61a-61e.

Each of the arms 61a-61e may be mounted to the central structure 62. The central structure 62 may be rotated with respect to the axis 115. The arms 61a-61e may be rotatably provided with respect to the shaft 115.

When the arms 61a-61e rotate about the axis 115, the movement (track) of the support tables 117a-117e defines a closed loop path 317.

One end of the arms 61a-61e is connected to the support table 117a-117e, and the other end is rotatably connected to the center 62, between the machining stations (101-109 in FIG. 1). The support table may be rotated by a rotation motor (not shown) to rotate.

The support tables 117a-117e can be circulated 26 along a continuous machining station as described in FIG. 2.

The terminology used to describe the invention and its various embodiments herein may include, in addition to the general meaning, a meaning that is specifically defined by the structure, operation, etc. of the present invention from the general meaning.

Thus, where a particular element is understood to include one or more meanings, the meaning of the specific element in the claims should be interpreted as a concept including the word itself and all the meanings that may be supported in the specification. something to do.

Accordingly, the concept of the terms described in the claims may be defined by the present specification, not only the literal description but also the concept including equivalent structures, materials that can obtain the same action and effect by substantially the same method. do.

Claims (28)

A plurality of processing stations each performing at least one step of producing a document core inlay; And At least one support table for supporting the core sheet and transferring the core sheet to each processing station for processing; And the processing stations are arranged such that a closed loop path is defined around the center, wherein the table moves along the closed loop path between the processing stations. The method of claim 1, And the processing stations are arranged substantially uniformly along the circumference of the circle having the center, the core of the document core sheet into each other core inlay. The method of claim 2, And an arm, one end of which is connected to the table and the other end of which is pivotally connected to the center. The method of claim 3, wherein And a motor for rotating the arm further comprising: a document core sheet into a core inlay to each other. The method of claim 2, Further comprising a turntable having said at least one support table and rotatable in said center. The method of claim 5, wherein And the turn table has at least one position locator. The method of claim 1, And a rail defining the closed route paths, connecting the processing stations, and moving the table along the rails, wherein the document core sheets are core inlay to each other. The method of claim 7, wherein And a gear track mounted to either the table or the rail to move the table along the rail. The method of claim 7, wherein And a belt disposed along the rail for movement of the table, wherein the document core sheets are core inlayed to each other. The method of claim 1, The processing stations include a loading station for loading a core sheet, a module placement station for placing an integrated circuit chip module on the core seek, a wire insertion station for placing wires on the core sheet for electrical connection, And a welding station for welding the wires for electrical connection with the chip module and an unloading station for unloading the produced core inlays. The method of claim 10, And said unloading station acts as an inspection station. The method of claim 10, Said processing stations are arranged in series, said unloading station being located adjacent said loading station. The method of claim 10, And the loading station includes a lift table for raising the core sheet not processed to the same level (height) as the support table. The method of claim 10, And said processing stations are integrally formed with a single platform. The method of claim 14, A turn table is formed integrally with the platform and is rotatable about the center, wherein the at least one support table is configured to allow the support table to be moved to the machining stations by rotation of the turn table. Apparatus for processing document core sheets into core inlays with each other, located on a turn table. The method of claim 10, At least one processing station comprises an independent safety checking mechanism, wherein the documents core sheets are core inlayed to each other. The method of claim 10, The loading station includes a positioning unit that receives the core sheet before the core sheet is loaded onto the support table, And the position alignment unit includes a pair of moving plates that push the rear end of the core sheet towards the support table located in the contact area of the loading station. The method of claim 17, And the positioning unit comprises air holes through which air flows to reduce friction between the positioning unit and the supplied core sheet. The method of claim 1, And the support table includes a stopper for aligning the position of the core sheet supplied to the support table. The method of claim 1, And said table includes vacuum holes for allowing said core sheet to lie flat. Providing a core sheet; Continuously circulating the core sheet to a plurality of processing stations disposed along the closed loop path; And Processing the core sheet in successive processing stations, And said processing step includes providing a core inlay to said core sheet. The method of claim 21, Continuously circulating the core sheet, Transferring the core sheet to a module placement station; Transferring the core sheet to a wire insertion station; And Transferring the core sheet to a contact welding station, wherein the core sheet is processed into a core inlay. The method of claim 21, Processing the core sheet includes placing a module in the core sheet, inserting wires into the core sheet, and welding the wires for electrical connection with the module. To a core inlay. The method of claim 21, Further comprising loading the core sheet into a support structure, Processing the core sheet into a core inlay, wherein the support structure is conveyed to a plurality of processing stations disposed along the closed loop path. The method of claim 24, Wherein said support structure comprises vacuum holes for securing the position of a core sheet overlying said support structure. The method of claim 21, The closed loop includes a turntable rotatably mounted to the shaft, Circulating the core sheet to the plurality of processing stations includes rotating the turn table about the axis. The method of claim 21, The closed loop includes a plurality of arms rotatably attached to a central structure, Circulating the core sheet to the plurality of processing stations includes rotating the arm about the central structure. The method of claim 21, The closed loop path includes a closed rail system, Circulating the core sheet to the plurality of processing stations includes fixing the position of the core sheet to the support structure; Continuously moving the support structure along the rail system to the plurality of processing stations.

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