EP0290845A2 - Record carrier printing method - Google Patents

Abstract

In a transfer printer, the printed, ribbon-like information carrier is suddenly separated from the printing ink ribbon 1 to 5 mm after the two ribbons have passed the transfer pins. Separation is gently initiated over a brief length before this.

Description

The invention relates to a device for printing a recording medium with a transfer printer writing with fusible printing ink, which has a printhead with a printing plate, the end face of which is a printing surface in which a straight row of electrically selectively heatable transfer pens is arranged, with a printing ink ribbon consisting of a heat-resistant carrier tape coated on one side with fusible, hardened printing ink, with a pressing element which is arranged opposite the printing plate and extends along the row of transfer pins, with drive means for the recording medium and for the printing ink ribbon, with guide means for guiding the Recording medium and the carrier tape separately towards the pressing element, at the same speed and united between the printing surface and the pressing element, namely the carrier tape on the side of the printing surface with the ink coating facing the recording medium and ge separates away from the pressing element, and with a pressure load for the pressing element, by means of which it presses the recording medium against the printing ink ribbon and with it against the transfer pins.

Using a transfer printer of the type in question here, a line of melted printing ink is transferred onto paper passed under a heated transfer pen, which then hardens to form an indelible print job. If a transfer pen is heated for a long time, then it writes a line in the conveying direction of the label tape. If the transfer pen is only heated briefly, it writes a point. With such dots, characters can also be written in the grid. Such a transfer printer is particularly well suited to the usual for labeling goods Record bar code. A transfer pen is then heated for the thin line, two neighboring transfer pens are heated for the medium-thick line and three neighboring transfer pens are heated simultaneously for the very strong line. In this way, even wider lines can be printed. The transfer pins are arranged so close to one another that the lines printed on by adjacent transfer pins adjoin or flow into one another in the finished print.

The object of the invention is to design a device of the type mentioned in the introduction so that it can be operated at the highest possible printing speed.

The invention is characterized in that the outward path of the recording medium, which extends from the end of the row of transfer pens to the completed transfer of the printing ink by separating the recording medium from the printing ink ribbon, 0.2 to 5 mm (millimeters), preferably 1.5 mm , is, and that the sections of the ink ribbon and recording medium involved in the printing are each carried so quickly over the running distance that when the separation is complete, the transferred printing ink is still soft.

The short envisaged, expiring distance also makes it possible to limit the consumption of printing ink ribbon, as will be explained in more detail below. This is important because the ribbon is a costly consumable.

The short running distance and the separation of the recording medium from the printing ink ribbon while the printing ink is still warm makes it possible to operate the device at a very high printing speed.

The desired rapid transfer of ink to the recording medium by the respectively heated transfer pens is favored in that the mutually facing surfaces of the carrier tape and recording medium, the printing ink and the transfer pens and their heating are dimensioned so that the portions of the printing ink softened by the heated transfer pens have a greater affinity for the record carrier than for the carrier tape.

It has been shown that in this way it is not only possible to achieve a high speed with which the recording medium is guided past the transfer pens during printing operation, but also a very precise, sharp-edged printing.

Particularly good results are achieved with a configuration such that after 10 to 70% (percent), preferably 50%, of the running distance from the pressing element, no more pressure is exerted on the printing ink ribbon.

The first section of the expiring path gives the printing ink time to develop the affinity-related adhesion to the recording medium. In the second part of the running distance, the release of the printing ink from the printing ink ribbon is then slowly initiated. Based on this introduction, it is then possible to make the final separation quickly. This has also proven to be useful for a precise, fast and final color transition. A corresponding embodiment, which takes this into account, is characterized in that at the end of the outgoing path on the print head there is an edge around which the printing ink ribbon is inclined at an angle of 3 ° to 42 ° (degrees), preferably 38.5 °, to the recording medium becomes.

The extent to which the separation is initiated in the second section of the outgoing path can be optimized in accordance with the respective operating conditions, and most simply by adjusting the direction in which the recording medium is pulled off the pressing element. A correspondingly preferred embodiment is characterized in that the printing ink ribbon is guided closely along the printing surface in connection with the transfer pens, that the recording medium is pulled off the pressing element in the region of the running distance in such a way that the recording medium with the printing surface forms an acute angle of 0 , 7 ° to 30 °, preferably 1.5 °, which is opened in the conveying direction of the printing ink ribbon, whereby a separation of the printing ink ribbon and recording medium is effected for the rest of the outgoing path, but which continues until the end of the expiring path Stretching the ink layer is bridged.

On the inlet side, too, you can favor the printing process and thus the possible printing speed. A corresponding preferred solution is characterized in that the recording medium is brought up to the pressing element in such a way that the recording medium forms an acute angle with the printing surface of 2 ° to 30 °, preferably 10.5 °, which is open towards the conveying direction of the printing ink ribbon and that the printing ink ribbon is brought tangentially to the pressing element at an acute angle to the printing surface, which is approximately half the size of the acute angle of the recording medium and is preferably 5 °.

The printing ink ribbon is very expensive for devices of the type mentioned at the outset and it is therefore a further object of the invention to consume the printing ink ribbon restrict as possible.

This object is achieved in that, while the recording medium is being fed, the drive for the printing ink ribbon is operated at the same speed and forwards only during printing operation, in which sections of the recording medium to be printed are guided past the transfer pins and the running distance, that in blank operation - that is the operating time during which the recording medium is moved forward and there is no printing operation - the printing ink ribbon is not moved forward and that the pressing element is pressed against the recording medium and against the printing ink ribbon only during printing operation, whereas it is lifted off the recording medium during blank operation.

While in a known device of the type mentioned the printing ribbon is always running, so that as much length of printing ribbon is used as the length of the recording medium passes the print head, according to the invention only the printing ribbon length is consumed as the total, actually printed sections of the recording medium plus the Length of the expiring route and any tolerance sections provided.

The loss of printing ink ribbon in accordance with the length of the outgoing path is initially unavoidable, because in printing operation the printing ink ribbon must be moved in the same direction with the recording medium until the transferred printing ink has completely transferred to the recording medium, and this is only the case at the end of the expiring path. The shorter the running distance, the lower the resulting ribbon loss.

You can see through the expiring route and any Reduce the loss of tolerances in the ink ribbon loss in that the drive of the ink ribbon immediately after a printing operation and before the start of the next printing operation operates the ink ribbon backwards until the beginning of the ink portion that is unused at the end of the previous printing operation is under the transfer pins and that during the rest of the time Blank operation of the printing ribbon stands still.

In such a transfer printer, the maximum speed at which the paper to be printed in each case, together with the printing ink ribbon, is guided past the print head during the printing process is limited. If this maximum speed is exceeded, the pressure becomes unclean.

In the sense of the task set out at the beginning, the time with which a recording medium is printed can be shortened in that the drive for the recording medium in printing operation at a first slow printing speed is as fast as the printing ink ribbon and in blank operation with a second, many times higher blank speed takes place and that the recording medium is pressed against the printing ink ribbon only during printing operation, but not during blank operation.

Most of the recording media have gaps between the inscription where no ink has to be transferred to the recording media. During these times, the so-called blank times, the recording medium can be conveyed past the print head faster than the printing speed, without the print quality being adversely affected thereby.

So that no ink rubs off the stationary ink ribbon during blank operation of the recording medium, it is selected exposed to the pressure.

It should be ensured that a desired print image is executed properly over the entire area. The upstream and downstream end of the print image is critical. This can be taken into account by a configuration which is characterized in that the printing operation is maintained during a printing period which begins as soon as a first tolerance section reaches the transfer pins immediately before a section of the recording medium to be printed on and ends as soon as a second tolerance section in direct connection to the section to be printed has passed the transfer pins, these tolerance sections, based on the conveying direction of the recording medium, comprising 0.2 to 3.0 mm, preferably 1.0 mm.

The invention can be used in a wide variety of devices in which printing is carried out, for example ticket printers, typewriters, computer printers and the like. It can preferably be used in connection with a label dispenser or label printer for printing the labels of a label tape serving as a recording medium one after the other, which label tape consists of a carrier tape on which uniformly lined-up adhesive labels of the same size are releasably adhered, which are printed and released one after the other.

With such a label tape, no printing is required between the individual labels and the printing field never extends over the entire surface of the label, so that long sections are available for blank operation. It is also generally desired to have a very high printing speed, so that enough Eti printed in the time unit chains are available.

The invention can be used in a device which, if necessary, for example at the push of a button, delivers a printed label, a printed ticket or the like, which can then be removed by hand, for example. The invention can preferably be used in connection with a labeling machine in which a label dispenser equipped with a dispensing tongue is arranged downstream of the transfer printer. This label dispenser can be directed to a goods conveyor and is then triggered by clock signals of the goods conveyor for each goods passing by to deliver a label which is peeled off the dispensing tongue and pressed onto the goods with a roller. In such a labeling machine, the dispensing cycle of the labels on the label dispenser is determined by the cycle of the goods being passed. The goods conveying speed may be very high and the dispensing speed with which the label dispenser dispenses a label should be approximately the same. There is a pause between the labels to be dispensed in accordance with the product cycle.

The dispensing speed thus determined by the speed at which the goods are conveyed is generally much higher than the printing speed of a transfer printer. The use of the transfer printer in such a label conveyor is nevertheless made possible in that a label tape store is provided between the transfer printer and the label dispenser, which can accommodate a supply loop of the label tape with some printed labels. So it is possible to operate the transfer printer with a higher clock frequency at a lower printing speed and thus to achieve the label output which is required for the clock with a higher dispensing speed but with a lower clock speed operated label dispenser required. This has a particularly favorable effect on the output capacity of the transfer printer if, according to the further development described at the beginning of the transfer printer, the label tape is only operated at printing speed during printing operation, but otherwise at the higher blank speed.

In general, devices of the type in question are always operated continuously with the same labels, and these labels are always printed in the same way, at least over a longer operating period. This makes it possible from the start to pre-program the switching on and switching of the drives to the different speeds according to the label length and the arrangement of the print image on the respective labels. A corresponding further development is characterized in that a program control device is provided for the drives, that label buttons are provided in the path of the labels and / or goods to be labeled, the key signals of which reach the program control device, and that one or more stepping motors are provided as drive means.

A single drive motor can be provided for all these drives and the different speeds can be derived from this one drive via different clutches and transmission gears. It is easier, however, to provide a separate drive for the various drive problems, and an electrical stepper motor is recommended because of the cyclical operation. This applies in particular to the label dispenser, which is preferably assigned a stepping motor which is independent of the transfer printer drive.

The invention will now na with reference to the accompanying drawings explained here.

• Figur 1 von der Seite gesehen eine Etikettier­maschine im Blankbetrieb,
• Figur 2 den Druckkopf mit der Druckunterlage aus Figur 1, vergrößert herausgezeichnet, je­doch im Druckbetrieb und mit weiteren Details,
• Figur 3 Teile aus Figur 2 perspektivisch,
• Figur 4 von oben gesehen einen Abschnitt des Etikettenbandes mit zwei fertig bedruckten Etiketten, und
• Figur 5 ein Diagramm.

The drawing shows:

• 1 seen from the side a labeling machine in blank operation,
• FIG. 2 shows the print head with the printing pad from FIG. 1, drawn out enlarged, but in printing operation and with further details,
• FIG. 3 shows parts from FIG. 2 in perspective,
• Figure 4 seen from above a portion of the label tape with two finished printed labels, and
• Figure 5 is a diagram.

In the drawing, 1 denotes a housing on which a supply reel 2 for the label tape 3 serving as recording medium, a transfer printer 4, a label dispenser 5, a rewinding reel 6 for the carrier tape freed from the labels, various rollers 7 to 14 and 18 for Guide of the label strip 3 and drive motors 15, 16, 17 which are concealed in the drawing but are drawn out for the sake of clarity.

The label tape 3, also compare FIG. 2, consists of a carrier tape 20, on which labels 21, 22 of equal size, lined up with adhesives and evenly lined up at a distance 80, releasably adhere. The labels consist of paper and are pre-printed on their exposed front side, for example with a colored print 23, which is indicated by crosses in FIG.

The labels are now to be printed in accordance with the goods to be labeled, for example with a goods code corresponding to the bar code 24 and a number 25 from FIG. 4. The printed image is the same for each label and also positioned immediately.

The section of a label to be printed, based on the conveying direction according to arrow 26 of the label tape, is identified by double arrow 27. This area is followed by a first tolerance section 28 in the conveying direction and a second tolerance section 29 in the conveying direction. These two tolerance sections plus the section corresponding to the double arrow 27 result in the printing section according to the double arrow 30. In between, blank sections extend according to the double arrow 31.

32 with a printing ink ribbon is referred to, which consists of a heat-resistant carrier tape 33, which is coated on its underside facing the label tape 3 with thermoplastic, hardened printing ink 34. The areas of the printing ink 34 which are made warm and soft by heating have a higher affinity for the surface of the labels 21, 22 to be printed than for the carrier tape 33, so that the softened printing ink areas are transferred to the latter when they are pressed against the labels. This is explained in more detail below with reference to FIGS. 4 and 5.

For the printing ink ribbon 32, two deflection rollers 35, 36, a drive roller 18 with associated pressure rollers 56 and 57, a deflection edge 81, a supply bobbin 37 and a take-up bobbin 38 for the used printing ink ribbon are provided on the housing 1. A slip clutch 54 is interposed between the drive motor 15 and the take-up reel 38. The drive motor 15 drives the printing ink ribbon 32 in the direction of the arrow 100. For the supply bobbin 37, a drive motor 59 is provided with an interposed slip clutch 101. The drive motor 59 drives the supply bobbin 37 backwards, that is to say in the direction of the arrow 100. The two types Drive motors 15 and 59 with the associated slip clutches 54 and 101 serve to keep the ink ribbon taut. The forward or backward movement of the printing ink ribbon is determined by the drive 55, which drives the drive roller 18. The drive roller 18 can be driven forwards or backwards or stopped by the drive 55. The ink ribbon 32 wraps around the drive roller 18 due to the two spring-loaded pressure rollers 56, 57, which ensure that the ink ribbon always moves exactly with the circumference of the drive roller 18. A brake 102 that can be applied and removed also acts on the drive roller 18.

With 40 a print head of the transfer printer 4 is designated, which is arranged opposite a printing support device 41.

The label tape 3 is passed with the carrier tape facing the print support device 41 between the print head 40 and the print support device 41. The ink ribbon 32 is guided between the label tape and the print head, with the ink coating 34 facing the label tape. The print head 40 of the transfer printer 4 has a row 44 of electrically selectively heatable transfer pins 45, 46. This row 44 extends across the entire width of the labels 21, 22 and across the conveying direction according to arrow 26. For example, three transfer pins are arranged over a row length of 1 mm (millimeters).

The lower end face of the printhead forms the flat printing surface 47. With 2 to 3. 10⁻² mm protrude the free ends of the transfer pins 45, 46 from the printing surface 47. A pressure roller 48 of the printing pad 41 is arranged opposite the printing surface 47. The press roll is rotatably mounted and extends with its axis 82 parallel to row 44 of the transfer pins. The circumference of the press roll is elastic, the press roll has a diameter of 4 mm. The so-called transfer plane 83, which is defined by the axis 82 and the row 44, extends perpendicular to the printing surface 47. During printing operation, the press roller faces the printing surface 47 in the printing position shown in FIGS. 2 and 3 and presses the label strip 3 and the printing ink ribbon 32 against the printing surface, so that the heat of the heated transfer pens can take effect and melt the portion of the printing ink directly underneath, which is then transferred to the paper of the labels and then hardens to the desired print image after the label tape has been transported further.

The press roller 48 is mounted in the direction of the double arrow 49 so as to be pivotable about an axis 50 parallel to the roller axis on a pair of carriers 51. A tension spring 52 and an electromagnet 53, which is shown inactivated in FIG. 2, act on the pair of carriers, as a result of which the press roller is retracted into its blank position, in which it no longer acts in a pressing manner on the label tape, so that it detaches from the printing ink tape. If the electromagnet 53 is activated, the press roller 48 moves into its printing position shown in FIGS. 2 and 3, in which it presses the label tape against the printing ink tape and the printing surface 47.

As can be seen particularly well from FIG. 2, due to the position of the roller 7, the label strip 3 is brought in the tangential direction to the press roller in the printing operating position in such a way that the label strip with the printing surface 47 forms an acute angle 84 of 10.5 ° which is open against the conveying direction according to arrow 85 of the printing ink ribbon. The printing ink ribbon 32 becomes tangential at an acute angle 86 to the printing surface 47 brought up, which is about half as large as the angle 84, in the exemplary embodiment 5 °.

Following the transfer pins 45, 46, the printing ink ribbon 32 is guided closely along the printing surface 47, namely up to the edge 81 at the downstream end of the printing surface, which extends transversely to the conveying direction arrow 85 parallel to the row 44. This edge has a small radius of curvature of approximately 0.1 mm and is designed as a sliding edge. The printing ink ribbon is drawn off obliquely upwards to the roller 18 around this edge, so that it is continued with the printing surface 47 at an angle 87 of 38.5 ° to the label tape 3. The angle 87 is open in the conveying direction.

After it has passed the transfer pins 45, 46, the label band 3 wraps around the press roller 48 a little way according to arrow 89 and leaves it tangentially in a direction in which it forms an acute angle 88 of 1.5 ° with the printing surface 47 . The distance measured in the conveying direction according to double arrow 90 between the end of the transfer pins 45, 46 and the edge 81 is 1.5 mm. The path of the label tape that corresponds to this distance is called the expiring path 90. The transfer of the printing ink ends at the end of the expiring path, that is to say at the edge 81. In other words, the transfer of the printing ink from the printing ink ribbon to the label intended for the desired printing has been carried out there.

The sections of the ink ribbon and recording medium involved in the printing are each guided so quickly over the running path that when the separation has been completed, the transferred printing ink is still soft. The mutually facing surfaces of the carrier tape and recording medium, the printing ink and the transfer pens and their heating are dimensioned so that the be by the be heated transfer pens softened portions of the printing ink have a greater affinity for the recording medium than for the carrier tape. In this way it is ensured that the required ink transition is completed when passing the edge 81.

The radius, the pressure load during printing operation and the elasticity of the press roller 48 are dimensioned such that after 30 to 70%, in the exemplary embodiment 50%, the running distance - this is the point S3 in FIG. 5 - no more pressure on the Printing ink ribbon 32 is exerted by the press roller 48. Since you do not have to wait with the separation of label and printing ink ribbon as in known devices until the transferred ink has hardened, you can drive the two tapes during printing operation at a higher speed than in the known device.

The pressure and temperature curve shown in FIG. 5 results during printing operation.

In FIG. 5, the pressure P is applied to the vertical axis, with which the press roller 48 acts on the label strip 3 from below and presses it with the printing ink ribbon 32 against the printing surface 47 or the transfer pins 45, 46. In addition, the temperature t is plotted on the vertical axis, which is assumed by those areas of the printing ink which are transferred to the labels in the course of the printing carried out. Above temperature t1, the printing ink is soft and the affinity of the printing ink for the surface of the labels to be printed is significantly greater than for the carrier tape.

The path S of the label strip 3 is plotted on the vertical axis. The point S1 corresponds to the center of the transfer pins, the point S2 corresponds to the edge 81. From S1 The outgoing path extends to S2 and S3 marks the center of the outgoing path 90. S4 is a point that is just as far away from S1 as S3, however, on the inlet side. The transfer pins 45, 46 extend from the point T1 to T2.

The temperature rises steeply when passing heated transfer pins, i.e. at T1, and then drops slowly after leaving the transfer pins at T2. At the end of the expiring path, i.e. at point S2, the temperature of the ink regions to be transferred is still above t1.

During printing operation, the pressure effect of the press roller 48 begins at S4 and increases. The transfer pins take effect at T1. When heated, the ink is heated. The affinity of the printing ink for the carrier tape 33 decreases in the heated state and the affinity of the printing ink for the label surface increases. As a result, the printing ink adheres to the label surface and loses its adhesion to the carrier tape. At the same time, the pressure rises to the maximum at S1, which favors this transition. At T2, the pressure has dropped slightly and heating has ended. The pressure drops further and the ink has time to develop its affinity-related adhesion to the label surface. At S3, the pressure exerted by the press roller is "0". In the further course of the movement of the label tape, since the label tape is still lying against the circumference of the press roller 48, it increasingly lifts downward from the printing ink tape 32 due to the angle 88 or 89. As a result, the transferred printing ink, which still has greater affinity on the label surface than on the carrier tape, pulls on the carrier tape and increasingly dissolves there. The resulting train leads to a slight, increasing negative pressure.

At S2, the printing ink ribbon comes into the region of the deflection edge 81 and suddenly moves away from the label ribbon. The transferred printing ink now tears off on the carrier tape of the printing ink ribbon, which leads to the short vacuum peak at S2. The recording medium is then depressurized.

In section 91 the printing ink is pressed and in section 92 the detachment of the transferred printing ink from the carrier tape is gently prepared so that the decay at the edge 81 takes place suddenly and precisely.

The roller 10 is mounted on a lever 61 which is loaded by a compression spring 60 and is pivotably mounted about the axis of the roller 39. The label tape 3 is guided over the rollers 9, 10 and 11 in the form of a supply loop 62 which is always tight due to the spring loading of the compression spring 60 of the roller 10 and can store five to nine label lengths. Following this label tape store 19, the label tape arrives at a dispensing tongue 63 of the label dispenser 5, at which it is returned with a small radius in a U-shape, so that the individual labels, such as the label 64, are pushed off the carrier tape 20 due to their rigidity . This donor tongue is directed onto the surface of goods 66 of a goods conveyor 67. By means of a pressure roller 71, such a label which has been pushed off is pressed down onto the goods 66 presented and pulled off at the conveying speed of the goods and stapled onto the goods.

The label tape 3 is driven by the roller 8, which, as indicated, is coupled to the stepping motor 16. A spring-loaded pressure roller 68 bears on the circumferential section that wraps around the roller 8 in order to increase the friction. The empty carrier belt 20 is driven by the roller 13, which, as indicated, touches the crotch switch motor 17 is coupled, which also drives the take-up reel 6 with the interposition of a slip clutch 70.

The printing ink ribbon 32 is driven via the take-up reel 38, which in turn, as indicated, is coupled to the stepping motor 15 for driving.

73 denotes a program control device which has a control panel 74 which can be operated by hand and, as indicated by arrows, controls, among other things, the drive motors 55, 16, 17 and is controlled by three contactless buttons 75 to 77 and the print head 40. The button 75 feels in the path of the goods 6 to be labeled, the button 76 is directed at the printed labels and the button 77 at the unprinted labels in front of the transfer printer 4.

The device is operated as follows:
Label tape 3 is pulled off the filled supply reel 2, at the speed specified by the roller 8. The roller 8 conveys the label tape while a blank section according to double arrow 31 is guided past row 44 at the blank speed and, while a printing section according to double arrow 30 is passed past row 44, at printing speed. The printing speed is, for example, 12 m / min (meters per minute), while the blank speed is 18 m / min. Only as many labels are printed until the supply loop 62 is filled.

On the label dispenser 5, the label tape 3 moves at the dispensing speed which is caused by the drive of the roller 13 and is predetermined by the conveying speed of the goods 66. The label tape is advanced step by step on the label dispenser 5, specifically with released a label for each cut. The dispensing speed is higher than the blank speed and, for example, 30 m / min.

During the printing operation, that is the period of time during which its printing section is moved past the row 44 according to the double arrow 30 up to the edge 81, the press roller 48 is in its printing position shown in FIG. 3.

During the blanking operation, that is the period of time during which a blank section according to double arrow 31 is guided past row 44 or faces row 44 with the label strip stationary, the press roller 48 is in its functionless blank position shown in FIG.

The printing operation can extend over individual lines and between them can be blank operation. However, it can also extend over paragraphs and between the paragraphs is then blank operation. At the end of a printing operation, printing ink ribbon is used unused, in accordance with the tolerance section 28 from FIG. 4 and the subsequent expiring distance according to double arrow 90, compare FIG. 4. In order to avoid this loss, the printing ink ribbon is driven immediately after a printing operation and before Beginning of the next printing operation, the printing ink ribbon is conveyed backwards until the beginning of the printing ink section which is not used at the end of the previous printing operation stands and stands under the transfer pens and the printing ink ribbon stands still during the blank operation.

In order to guide the printing ink ribbon 32 backwards, the drive roller 18 is rotated backwards by a corresponding distance and the drive motor 15 pulls the printing ink ribbon 32 accordingly back. This backward step 93 corresponds to the tolerance section 28 plus the expiring path 90.

During the printing operation, the printing ink ribbon 32 is moved at the printing speed of the label ribbon 3 in the same direction as this, due to the drive of the take-up reel 38. In contrast, during the blanking operation, the printing ink ribbon 32 stands still. So there is no ink ribbon consumption during blank operation.

Claims (10)

1. Device for printing on a recording medium
with a transfer printer writing with fusible printing ink, which has a print head with a printing plate whose end face is a printing area in which a straight row of electrically selectively heatable transfer pens is arranged,
with an ink ribbon consisting of a heat-resistant carrier tape coated on one side with meltable, hardened ink,
with a pressing element which is arranged opposite the pressure plate and extends along the row of transfer pins,
with drive means for the recording medium and for the printing ink ribbon,
with guide means for guiding the recording medium and the carrier tape separately towards the pressing element, at the same speed and united between the printing surface and the pressing element, namely the carrier tape on the side of the printing surface with the printing ink coating facing the recording medium and away from the pressing element, and
with a pressure load for the pressing element, by means of which it presses the recording medium against the printing ink ribbon and with it against the transfer pins, characterized in that
that the outward path of the recording medium (90), which extends from the end of the row of transfer pins (45, 46) to the completed transfer of the printing ink by separating the recording medium from the printing ink ribbon (32), 0.2 to 5 mm (millimeters), preferably 1.5 mm, and
that the sections of the ribbon and the recording medium involved in the printing are each carried so quickly over the expiring path that when the separation is complete transferred ink is still soft. 2. Device according to claim 1, characterized in
that the mutually facing surfaces of the carrier tape and recording medium, the printing ink and the transfer pens and their heating are dimensioned so that the portions of the printing ink softened by the heated transfer pens have a greater affinity for the recording medium than for the carrier tape. 3. Device according to claim 1 or 2, characterized in that
that after 10 to 70% (percent), preferably 50%, of the running distance (90, 91) of the pressing element (48), no more pressure is exerted on the printing ink ribbon (32). 4. Device according to one of the preceding claims, characterized in
that at the end of the running distance on the print head (40) there is an edge (81) around which the printing ink ribbon (32) is inclined at an angle (87) of 3 ° to 42 ° (degrees), preferably 38.5 °, to the recording medium ( 20) is continued. 5. The device according to claim 3, characterized in
that the printing ink ribbon (32) is guided close to the printing surface (47) following the transfer pins (45, 46),
that the record carrier (20) is pulled off the pressing element (48) in the region of the outward path (90), such that
that the recording medium with the printing surface (47) includes an acute angle (88) of 0.7 ° to 30 °, preferably 1.5 °, in the conveying direction of the printing ink ribbon (32) is opened, which causes a separation of the printing ink ribbon and the recording medium for the rest of the expiring path, but which is bridged by stretching the ink layer until the end of the expiring path. 6. Device according to one of the preceding claims, characterized in
that the record carrier (20) is brought up to the pressing element (48) in such a way that
that the recording medium with the printing surface (47) forms an acute angle (84) of 2 ° to 30 °, preferably 10.5 °, which is open towards the conveying direction (85) of the printing ink ribbon (32). 7. Device according to one of the preceding claims, characterized in that
that the printing ink ribbon (32) is brought tangentially to the pressing element (48) at an acute angle (86) to the printing surface (47), which is approximately half as large as the acute angle (84) of the recording medium (20) and preferably 5 ° is. 8. Device according to one of the preceding claims, characterized in that
that during the advance of the record carrier (20 the drive (55) for the printing ink ribbon (32) equally fast and forward only during the printing operation, in which the sections (31) of the record carrier (20) to be printed on the transfer pins (45, 46) and the outgoing route (90) is passed, operated,
that with blank operation - that is the operating time during which the recording medium is moved forward and there is no printing operation - the printing ink ribbon is not moved forward and
that the pressing element (48) is pressed against the recording medium and against the printing ink ribbon only during printing operation, whereas it is lifted off the recording medium during blank operation. 9. Device according to one of the preceding claims, characterized in that
that the drive (55) of the ink ribbon (32) immediately after a printing operation and before the start of the next printing operation operates the ink ribbon backwards until the beginning of the unused ink section at the end of the previous printing operation is under the transfer pins (45, 46) and
that the printing ink ribbon stands still during blank operation. 10. The device according to claim 8 or 9, characterized in that
that the drive (55) for the recording medium (20) takes place at the same speed as the printing ink ribbon (32) during printing operation at a first slow printing speed and at a second, higher blank speed during blank operation and
that the recording medium is pressed against the printing ink ribbon only during printing operation, but not during blank operation.

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