EP0352498A1 - Franking machine - Google Patents

Abstract

A franking machine having an ink jet printer, in which the ink jet nozzles are offset both in the direction (7) of movement of the articles (3) for posting and also transversely thereto. Due to the offsetting, the ink drop points on an article (3) for posting can be applied adjoining each other without gaps and in a partially overlapping manner. In a preferred embodiment, the ink jet nozzles (5) are arranged in equidistant columns (..1 to ..4) perpendicular to the direction (7) of movement and in likewise equidistant rows at an inclination to the direction of movement. …<IMAGE>…

Description

The invention relates to a franking machine according to the preamble of patent claim 1.

A franking machine of this type is described in DE-A-2501035. The well-known franking machine has drive rollers for transporting the mail, a drum that carries a cliché that has the same printed image with each franking, and an inkjet printer that is arranged inside the drum and that uses openings in the cliché to print the changing print characters (date, post value) on the mail sprays. The individual nozzles of the inkjet printer are arranged in a row perpendicular to the direction of movement of the mail item.

The inkjet printer has the advantage of high flexibility when applying variable characters. However, as can be seen from the drawing of DE-A, the print produced by him is unattractive, poorly recognizable and legible and therefore unsuitable in particular for advertising purposes. For this reason, in the machine according to DE-A, only the data that changes daily or with each franking is printed with the inkjet printer, but all other data and picture elements are printed with the cliché. If a different print image (e.g. a new advertising slogan, a different company logo, a different reference to new company products depending on the addressee) is to be used or if a damaged cliché has to be replaced, the cliché must be removed each time. This expansion is time-consuming and, due to the color on the cliché, a dirty job that the staff is reluctant to do.

A different type of franking machine is described in DE-A-2701072. It is a small franking machine with a microcomputer without a transport device, which is pushed by hand over the mail to be franked. The entire print is done by an inkjet printer. As can be seen from the drawing of DE-A-2701072, the print is just as difficult to recognize and read as that of the inkjet printer according to DE-A-2501035.

The object of the invention is to provide a franking machine of the type mentioned at the outset, which applies all image and drawing elements to the postal matter or label with the aid of an inkjet printer, in order to enable rapid changes to any image and drawing elements, and yet spares them in an appealing manner, well recognizable and legible print.

The solution according to the invention of these two subtasks which are regarded as incompatible in the prior art is the subject of patent claim 1.

The advantage achieved by the invention is essentially to be seen in the fact that the inkjet printer can achieve complete area coverage and different color intensity of the image and drawing elements on the mail item or label. This results in a quick change of the print as well as an aesthetically appealing, easily recognizable and readable print due to full lines and fully covering areas.

Claims 2 to 11 relate to preferred embodiments of the invention.

The arrangement of the ink jet nozzles offset transversely and longitudinally to the direction of movement can be such that the ink jet nozzles are arranged in at least one row running obliquely to the direction of movement or in a plurality of columns running perpendicular to the direction of movement, the nozzles of each column being related to the nozzles of the adjacent column or columns are mutually offset perpendicular to the direction of movement. The distance between the image points perpendicular to the direction of movement can thus be reduced so that the points connect to one another without gaps or overlap one another. The spacing of the pixels could also be reduced in the case of ink jet nozzles arranged next to one another in a row perpendicular to the direction of movement of the mail item, in that they were arranged relatively far away from the mail item and the axes or exit directions of the outer nozzles were inclined towards the center of the row. With such an arrangement inclined to the vertical, however, the height of the typeface would change with the distance of the mail item from the nozzle opening. Since the surface of the mail to be printed is not exactly flat, a wavy typeface would result.

The ink jet nozzles are preferably arranged in several rows and columns parallel to one another in such a way that the columns are approximately perpendicular to the direction of movement of the mail item, and the rows form an acute angle with the direction of movement. In this way, ink drop points that are contiguous along a straight line perpendicular to the direction of movement can be produced without creating an unsightly step line. With the preferred nozzle arrangement, in addition to the continuously straight lines perpendicular to the direction of movement, steplessly straight lines running at different angles obliquely to the direction of movement can also be produced.

The rows and columns of ink jet nozzles are preferably equidistant, the ink jet nozzles of adjacent columns being offset by approximately the distance between two adjacent ink jet nozzles of a column divided by the number of columns or by an integer divisor of the number of columns. If the distance is divided by an integer divider, depending on the divider used, several nozzles can spray along the same line. The printed image thus receives a more intense color impression or lines highlighted in relation to the rest of the image can be generated.

One part of the ink jet nozzles can be assigned a color and the other part can be assigned at least one other color. For example, the nozzles arranged in adjacent columns can each spray a different color. This makes it possible to produce multi-colored prints that counterfeit the print by e.g. B. Make copies using copiers impossible. With the arrangement of the nozzles in columns and rows mentioned above, multi-color prints with overlaid color separations can be produced.

The distance of the ink drop points parallel to the direction of movement depends on the time interval between the drive pulses to the ink jet nozzles and on the transport speed of the postal items. In order to obtain a perfect imprint, the speed of the mail item is therefore expediently measured using a speed sensor. The sensor sends a signal proportional to the speed to a clock generator of the control device which drives the relevant ink jet nozzles. The sensor can be either a mechanical, magnetic or an optical speed sensor.

The inkjet nozzles are expediently arranged in a stationary manner and the mail item is preferably moved past the inkjet nozzles lying or standing upright by means of the transport device. Here, the postal matter z. B. placed in a charging station and abandoned by a separating mechanism of the transport device.

In order to increase the color intensity, several drops of ink can be sprayed approximately on one and the same location of the postal matter. This can be done either by inkjet nozzles with several outlet openings each or by repeated, immediately successive activation of the same nozzle.

• Fig. 1 ein Beispiel eines Aufdrucks,
• Fig. 2 eine schematische Darstellung einer erfindungsgemäßen Anordnung von Tintenstrahldüsen, und
• Fig. 3 ein Blockdiagramm einer Steuervorrichtung für die Steuerung des Tintentropfenausstosses der Düsen von Fig. 2 mit Eingabetastatur und Waage

The invention is explained in more detail below with reference to the accompanying drawing, which represents only one embodiment. Show it:

• 1 shows an example of an imprint,
• Fig. 2 is a schematic representation of an arrangement of ink jet nozzles according to the invention, and
• Fig. 3 is a block diagram of a control device for controlling the ink drop ejection of the nozzles of Fig. 2 with an input keyboard and a scale

The franking machine has a transport device that moves the mail item 3 to be franked past a stationary inkjet printer and a franking device with a control device 6 for controlling the inkjet printer, as well as a mail accounting device in which the sum of the postage values printed by the franking device is used for a later settlement with the Post is formed and stored, or by which the value of the printed postage is debited from an already prepaid amount. The postal accounting device is protected against manipulation on the part of the user; Settlements can only be carried out by authorized Swiss Post persons with sufficient identification. The transport device and the mail accounting device are designed in the manner customary in the prior art and are therefore not shown.

The mail item 3 is moved past the inkjet printer by the transport device. As shown in FIG. 1, a logo 1 is imprinted as a company advertisement, a date stamp 2 and a postage stamp 4, as well as any further information, such as shipping method, postal categories, franking machine identification, etc.

As shown schematically in FIG. 2, the inkjet printer has a plurality of inkjet nozzles 5 (indicated by crosses) which are offset transversely and longitudinally to the direction of movement 7 of the mail item 3. Ink ejection is controlled by the control device 6, the schematic block diagram of which is shown in FIG. 3. As described in more detail below, the nozzles are arranged and controlled in such a way that ink drop dots that are almost completely adjacent to one another or at least partially overlap one another can be applied to the postal matter 3.

The inkjet nozzles 5 are in the example shown and described in FIG. 2 in thirty-two parallel rows 5.1.1-5.1.4, ..., 5.32.1-5.32.4 and four columns 5.1.1-5.32.1, .. ., 5.1.4 - 5.32.4 arranged, whereby the columns 5.1.1 - 5.32.1, ..., 5.1.4 - 5.32.4 are perpendicular to the direction of movement 7, and the rows 5.1.1 - 5.1.4, ..., 5.32.1 - 5.32.4 include an acute angle α of, for example, approximately 8 ° with the direction of movement 7. In FIG. 2, the mail item 3 lies below the ink jet nozzles 5 shown as crosses. The row of the ink jet nozzles furthest to the left in the direction of movement 7 is designated 5.1.1-5.1.4, and the rightmost row 5.32.1-5.32 .4. As a result of the inclination of the rows of nozzles to the direction of movement 7, the mutual distance of the nozzles 5 perpendicular to the direction of movement 7 is equal to the actual distance b multiplied by the tangent of the angle α. The nozzles 5 of each column are thus offset with respect to the nozzles of the adjacent column or columns 5.1.1 - 5.32.1, ..., 5.1.4 - 5.32.4 by a distance d from one another transversely to the direction of movement 7.

The distance a of the rows 5.1.1 - 5.1.4, ..., 5.32.1 - 5.32.4 perpendicular to the direction of movement 7 is z. B. 0.8 mm and the distance b of the columns 5.1.1 - 5.32.1, ..., 5.1.4 - 5.32.4 is z. B. 6 mm. The offset d of the individual inkjet nozzles 5 of one column compared to the preceding and the following column is equal to the distance a of one inkjet nozzle in one column to the neighboring divided by the number of columns, in the present case four:

This arrangement makes it possible, even with ink jet nozzles 5 spaced relatively far apart, to obtain good area coverage by ink drop points lying close together on the surface of the mail item.

The operation of the franking machine is described below with reference to the block diagram in FIG. 3.

The mail item 3 is transported to the inkjet printer by means of the transport device (not shown). As soon as the front edge 8 of the mail item 3 passes under an edge detector 10, preferably an electro-optical light barrier, an electrical signal from the edge detector 10 switches on a speed sensor 9, which measures the speed of the mail item 3 optically or mechanically. The electrical output signal of the speed sensor 9 controls a clock 12, the z. B. can be designed as a VCO. The clock generator 12 generates electrical pulses, the frequency of which is proportional to the speed. The printing on the postal item 3, as shown in FIG. 1, takes place from right to left, first with the stamp 4, then the date 2 and finally with the company logo 1.

The image information of the stamp 4 without numerical value, the date 2 without date and the logo 1 are stored in a memory 14 for a so-called fixed image. From this memory 14, the image information in another z. B. designed as a FIFO 16 memory corresponding to the four columns of thirty-two inkjet nozzles, from which it can be read again with the clock of the clock 12. The image information is read in such a way that the image parts closest to the edge 8 of the postal matter in FIG. 1 are read in first for the first column 5.1.1-5.32.1. Next is the image information for the second column 5.1.2 - 5.32.2, together with the information for the first column 5.1.1 - 5.32.1, etc. Since the rows 5.1.1 - 5.32.1, ..., 5.1.4 - 5.32.4 run obliquely to the left in the direction of movement 7 and the ink jet nozzles 5 of one column are offset from those of the adjacent columns, the image information is stored in mirror image and nested within one another.

The information for printing z. B. a line perpendicular to the direction of movement 7 over the entire label width, is, as described further below, stored in the FIFO 16 and after applying the relevant readout pulses via an OR gate 46 to a control 47, which simultaneously all the ink jet nozzles 5.1.1 to 5.32.1 of column ..1 controlled by electrical impulses. After a time t 1, in which the mail item 3 has been moved by the distance b, all the ink jet nozzles 5.1.2 to 5.32.2 of the column ..2 receive an electrical pulse, after a further time t 1 the ink jet nozzles 5.1.3 to 5.32.3 the column ..3, and after a further time t₁ the ink jet 5.1.4 to 5.32.4 the column ..4 an electrical pulse. The vertical line is finished.

Wird die Zeit der Pulsabstände t₂ verkürzt, so rücken in Bewe­gungsrichtung 7 die Tintentropfenpunkte näher zusammen, sie überlappen sich teilweise, und das erzeugte Bild erhält eine kräftigere Farbintensität, volle Linien und volldeckende Flä­chen.The information for printing z. B. a line parallel to the direction of movement 7 approximately in the middle of the print is also stored in the FIFO 16 and by means of the control 47, the nozzle 5.16.4 is acted upon with a pulse train. If the distance of the ink drop points in the direction of movement 7 is equal to the distance d of the ink drop points perpendicular to the direction of movement 7, this results in a pulse interval t 2 since the speed v of the mail item 3

If the time of the pulse intervals t₂ is shortened, the ink drop points move closer together in the direction of movement 7, they Partially overlap, and the resulting image is given a stronger color intensity, full lines and fully covering areas.

The next example will explain printing a "1" in which the vertical bar is 24 mm long and the slash at forty-five degrees has a "height" of 10 mm. The "1" should be at the top of the label field that can be generated by the inkjet nozzles 5. The following sequence of numbers is to be read in the direction of the arrows and indicates which nozzle or nozzles is or will be activated at the same time and after which the times are in parentheses and the time t 2 determined above is used as the basis. The printing process begins at the moment by driving the nozzles 5.1.1 to 5.30.1 of the first column ..1 when the location of the moving mail item 3 at which the vertical line "1" is to be printed is under the nozzles of the Column ..1 is located. After a time (3 * t₂) with the nozzle 5.1.1 of the first column ..1 the first point is written on the slope of the "1", then after a time (4 * t₂) -> 5.2.1 - -> (4 * t₂) -> 5.3.1 -> (4 * t₂) -> 5.4.1 -> (4 * t₂) -> 5.5.1 -> (4 * t₂) - -> 5.6.1 -> (4 * t₂) -> 5.7.1 until after a time (3 * t₂) from the nozzles 5.1.2 to 5.30.2 of the second column ..2 again points of the vertical line are written will. After the time intervals mentioned below, further points of the slope are written through nozzles of the first ..1 and the second ..2 column (2 * t₂) -> 5.8.1 -> (1 * t₂) -> 5.1.2 -> (3 * t₂) -> 5.9.1 -> (1 * t₂) -> 5.2.2 -> (3 * t₂) -> 5.10.1 -> (1 * t₂) -> 5.3.2 -> (3 * t₂) -> 5.11.1 -> (1 * t₂) -> 5.4.2 -> and after the time (3 * tz) the nozzle 5.12 .1 activated as the last nozzle in column ..1 to write "1" and after a time (1 * ta) the following nozzles in the second column ..2 write on the slope: 5.5.2 -> (4 * t₂ ) -> 5.6.2 -> (4 * t₂) 5.7.2 ->. After a time (4 * t₂) from the nozzles 5.1.3 to 5.30.3 the third Column ..3 points of the vertical line and at the same time written by the nozzle 5.8.2 of the second column ..2 a point on the slope. After a time (1 * t₂) points of the slopes are written from the second and third columns 5.1.3 -> (3 * t₂) -> 5.9.2 -> etc

The procedure is analogous to the changing image information for the postal value and the date, which are stored in a memory 15 for postal values and a memory 17 for the date. The data contents for the postal values in the memory 15 and for the date in the memory 16 are preselected by an input keyboard in an input unit 20 and read into a FIFO 22 or 24 in a sequence not described.

For correct identification and to check the authenticity of the franking, for example, a character consisting of a letter and / or combination of characters is also printed. B. is changed after a fixed key. The image information of these digits is stored in a memory 26 in a manner analogous to that described above. The memory 26 determines its numerical information from the status of a counter 27, which is increased by one by the edge detector 10 with each passage of a postal item 3. This numerical information is transmitted to a FIFO 29.

As described above, the pulses generated by the clock generator 12 are synchronized by the speed sensor 9 with the speed of the mail item 3. The control device has four counters 31, 32, 33 and 34. All four counters 31, 32, 33 and 34 are started by the pulse of the edge detector 10 and count the pulses of the clock generator 12 up to a predetermined one on the relevant counter 31, 32, 33, or 34 adjustable number. The counters 31, 32, 33 and 34 are reset by an electrical signal which the edge detector 10 generates when the mail item 3 of the inkjet printer leaves.

The predetermined number of the payer 31 is a measure of the distance e from the right start of the imprint on the postal item 3, in FIG. 1 the right vertical line of the postage stamp 4. The predetermined number of the counter 32 is a measure of the distance f of the right Beginning of postage printing; in the postmark 4 the right "0". It should be noted that the print begins mirror-inverted and nested from right to left against the reading direction. The predetermined number of the counter 33 is a measure of the distance g from the right start of the date; in the date stamp 2 the right margin of the "8". The printing is also mirror-inverted and nested. Analogous to the above statements, the predetermined number of counter 34 is a measure of the distance h from the right start of the numbering, which in the example is arranged in the postage stamp 4, but can also be located at a different location.

The print information is read into the corresponding FIFOs 16, 22, 24, and 29. However, it cannot be read out yet, since the clock pulses required for reading out are blocked by an AND gate 37, 39, 41 and 43, respectively. Each AND gate 37, 39, 41 and 43 has two inputs and one output. One input each of the AND gates 37, 39, 41 and 43 is connected to the output of the clock generator 12, the other input to the output of the counter 31, 32, 33 and 34, respectively, while each output leads to the clock input of the relevant FIFO 16 , 22, 24, or 29 goes. Only when the relevant counter 31, 32, 33 or 34 has exceeded the preset value, the relevant AND gate 37, 39, 41 or 43 allows the clock pulses of the clock generator to pass and the information can be sent to the OR gate 46 as Overlay device are passed.

The OR gate 46 has four inputs, each of which is connected to an output of one of the FIFOs 16, 22, 24, 29. If the information of one of the FIFOs 16, 22, 24 and 29 arrive at the output of the OR gate 46, ie there is an information overlay. The output of the OR gate 46 goes to the control 47, which controls the ink jet nozzles 5.

To simplify the illustration in FIG. 3, data lines for driving the counters 27, 31, 32 and 33, the input unit 20, the memories 14, 15, 16 and 26, the FIFOs 16, 22, 24 and 29, and a scale 49 were used omitted a microprocessor, not shown.

The ink jet nozzles 5 can emit a few thousand drops per second. Since this transmission rate is significantly lower than the processing rates of conventional electronic processing systems, some image processing processes can be carried out in series to save on components and lines.

In order to be able to change the logo as an advertisement quickly and easily, it can be expedient to store the image information for the logo in a further memory, not shown.

Each of the FIFOs drawn can also be divided into four FIFOs according to the number of columns. Although this requires greater electronic effort, it allows all four columns to work simultaneously, which results in a stronger color intensity, since a larger amount of ink can be sprayed on the postal item 3 per location.

Instead of a single speed sensor, two can also be used, one of which then measures the speed component in the direction of the columns of the ink jet nozzles ..1, ..2, ..3, ..4 and the other measures the component perpendicular thereto. The speed sensor measuring in the direction of the columns can be used to shift the image information in the rows of the inkjet nozzles, and hereby to equalize a distorted pressure due to a non-rectilinear mail item 3.

As shown in Fig. 3, the weight of the mail item 3 can be measured with the scale 49. The determined weight is passed on to the input unit 20, which has a data processing unit (not shown) which calculates the postage value for the imprint and transmits this value to the memory 15 for the postage values.

It is only possible to enter the image information of the imprint from an image scanned line by line by means of a calculation process. The data preparation is carried out analogously to the process as described above for generating a "1". The image information of the data to be changed is preferably stored as individual characters in the relevant memories 15, 16 or 26 in mirror image and nested so that they can easily be put together as a postage value, date and identifier.

In order to intensify the color intensity on the surface of the postal matter, several drops of ink can be sent to one location of the postal matter 3. Several drops contain more dye and thus contribute to better coverage. Although the ejection takes place at a high repetition frequency, the surface of the postal matter moves slightly further, which leads to a slight “smearing” in the direction of movement 7, which is perceived by the human eye as a better and more intense color.

If a high resolution of the image is dispensed with, the ink-jet nozzles of some columns can spray a different ink color in order to achieve a multi-colored print. A kind of four-color printing with the colors blue, yellow, red and black can even be achieved. The resolution of the eye with a colored print is not as high as with a monochrome print. For this reason, the colored print also gives satisfactory results.

The ink jet nozzles and the transport device can also be directed so that the mail item 3 is moved past the ink jet nozzles 5 instead of standing upright.

The clock generator 12 could also, if the speed sensor 9 is dispensed with, provide a constant clock frequency if only flat mail items 3 or label strips are to be franked. The acceleration and a non-flat surface of the usual postal items 3, e.g. B. letters with partial filling, but cause the relative speed of the surface to the ink jet nozzles 5 is not constant, which would lead to an uneven pressure at a constant clock frequency. This is avoided with the clock synchronized by the speed sensor 9.

Instead of several rows of ink jet nozzles arranged obliquely to the direction of movement, a single row extending obliquely to the direction of movement can also be used. Since the achievable resolution depends only on the total number of inkjet nozzles, the same resolution can also be achieved with a single row, which however must then be correspondingly longer, if the speed of the postal matter and the clock frequency are successful during spraying Maintaining a straight line movement, to sufficiently synchronize the mail.

Claims (11)

1. Franking machine, in which the mail item (3) to be franked or a label to be stuck onto the mail item (3) is moved by means of a transport device in relation to an ink jet printer which has ink jet nozzles (5) which are offset transversely to the direction of movement and whose ink drop ejection is controlled by a control device (6), characterized in that the ink jet nozzles (5) are arranged so as to be offset transversely and longitudinally to the direction of movement (7) and the temporal ink drop sequence can be controlled in such a way that both in the direction of movement (7) and transversely thereto At least approximately seamlessly adjoining or at least partially overlapping ink drop dots can be applied to the mail item (3) or label. 2. Franking machine according to claim 1, characterized in that the ink jet nozzles (5) are arranged in at least one row extending obliquely to the direction of movement (7). 3. Franking machine according to claim 1 or 2, characterized in that the ink jet nozzles (5) are arranged in a plurality of columns extending transversely to the direction of movement (7), and the nozzles (5) of each column (5.1.1 - 5.32.1,. .., 5.1.4 - 5.32.4) with respect to the nozzles of the adjacent column or columns (5.1.1 - 5.32.1, ..., 5.1.4 - 5.32.4) are offset from one another transversely to the direction of movement. 4. Franking machine according to one of claims 1 to 3, characterized in that the ink jet nozzles (5) in several mutually parallel rows (5.1.1 -5.1.4, ..., 5.32.1 - 5.32.4) and columns (5.1 .1 - 5.32.1, ..., 5.1.4 - 5.32.4) are arranged, the columns (5.1.1 - 5.32.1, ..., 5.1.4 - 5.32.4) being at least approximately perpendicular to the direction of movement (7), and the rows (5.1.1 - 5.1.4, ..., 5.32.1 - 5.32.4) enclose an acute angle (α) with the direction of movement (7). 5. franking machine according to claims 3 and 4, characterized by equidistant (a) ink jet nozzle rows (5.1.1 - 5.1.4, ..., 5.32.1 -5.32.4) and equidistant (b) ink jet nozzle columns (5.1.1 - 5.32 .1, ..., 5.1.4 - 5.32.4), the ink jet nozzles (5) adjacent columns (5.1.1 - 5.32.1, ..., 5.1.4 - 5.32.4) approximately by the distance ( a) two adjacent ink jet nozzles of a column (5.1.1 - 5.32.1, ..., 5.1.4 - 5.32.4) divided by the number of columns or by an integer divisor of the number of columns. 6. Franking machine according to one of claims 1 to 5, characterized in that a part of the ink jet nozzles (5) is assigned a color and the other part at least one other color. 7. Franking machine according to one of claims 1 to 6, characterized in that the control device (6) a the speed of the mail item (3) or label with respect to the printer measuring speed sensor (9) and a clock generator (12) for the control the temporal sequence of the ink drop ejection, and the clock frequency of the clock (12) is controlled proportional to the speed, so that the printed image on the mail item (3) or label is independent of the speed. 8. Franking machine according to one of claims 1 to 7, characterized in that the ink jet nozzles (5) are arranged in a stationary manner and the postal matter (3) or label can be moved past the ink jet nozzles (5) preferably lying or upright by means of the transport device. 9. Franking machine according to one of claims 1 to 8, characterized in that the timing of the ink drop sequence can be controlled by the control device (6) in such a way that several ink drops from an ink jet nozzle (5) can be emitted to approximately the same location of the mail item (3) or label are to achieve an increased color intensity at this location. 10. Franking machine according to one of claims 1 to 9, characterized by at least one first memory (14) for storing fixed data for a repetitive print image with each franking, z. B. the unchangeable franking image, an advertising imprint u. Like., a second memory (15, 16, 26) for storing changeable data, for. B. for the date, the amount of the token, a consecutive numbering, a pattern from postage (3) to postage (3) and / or a variable identification, and a superimposition device (46), which reads the data from the second memory in chronological order (15, 16, 26) superimposed on those of the first memory (14). 11. Franking machine according to one of claims 1 to 10, characterized in that the axes of all ink jet nozzles (5) run parallel to one another, so that the exit directions of the ink drops are parallel to one another.

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