EP3055138A2 - Imprimante à transfert thermique et machine d'étiquetage - Google Patents

Imprimante à transfert thermique et machine d'étiquetage

Info

Publication number
EP3055138A2
EP3055138A2 EP14784365.0A EP14784365A EP3055138A2 EP 3055138 A2 EP3055138 A2 EP 3055138A2 EP 14784365 A EP14784365 A EP 14784365A EP 3055138 A2 EP3055138 A2 EP 3055138A2
Authority
EP
European Patent Office
Prior art keywords
printhead
motor
ribbon
thermal transfer
transfer printer
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Granted
Application number
EP14784365.0A
Other languages
German (de)
English (en)
Other versions
EP3055138B1 (fr
Inventor
Martin Mcnestry
Philip Hart
Gary Pfeffer
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Videojet Technologies Inc
Original Assignee
Videojet Technologies Inc
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Priority claimed from GBGB1318042.7A external-priority patent/GB201318042D0/en
Priority claimed from GB201318176A external-priority patent/GB201318176D0/en
Priority claimed from GB1318581.4A external-priority patent/GB2519371A/en
Application filed by Videojet Technologies Inc filed Critical Videojet Technologies Inc
Priority to EP18214532.6A priority Critical patent/EP3533617B1/fr
Publication of EP3055138A2 publication Critical patent/EP3055138A2/fr
Application granted granted Critical
Publication of EP3055138B1 publication Critical patent/EP3055138B1/fr
Active legal-status Critical Current
Anticipated expiration legal-status Critical

Links

Classifications

    • BPERFORMING OPERATIONS; TRANSPORTING
    • B41PRINTING; LINING MACHINES; TYPEWRITERS; STAMPS
    • B41JTYPEWRITERS; SELECTIVE PRINTING MECHANISMS, i.e. MECHANISMS PRINTING OTHERWISE THAN FROM A FORME; CORRECTION OF TYPOGRAPHICAL ERRORS
    • B41J25/00Actions or mechanisms not otherwise provided for
    • B41J25/304Bodily-movable mechanisms for print heads or carriages movable towards or from paper surface
    • B41J25/312Bodily-movable mechanisms for print heads or carriages movable towards or from paper surface with print pressure adjustment mechanisms, e.g. pressure-on-the paper mechanisms
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B41PRINTING; LINING MACHINES; TYPEWRITERS; STAMPS
    • B41JTYPEWRITERS; SELECTIVE PRINTING MECHANISMS, i.e. MECHANISMS PRINTING OTHERWISE THAN FROM A FORME; CORRECTION OF TYPOGRAPHICAL ERRORS
    • B41J17/00Mechanisms for manipulating page-width impression-transfer material, e.g. carbon paper
    • B41J17/02Feeding mechanisms
    • B41J17/08Feed independent of the record-paper feed
    • B41J17/10Feed independent of the record-paper feed electromagnetically controlled
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B41PRINTING; LINING MACHINES; TYPEWRITERS; STAMPS
    • B41JTYPEWRITERS; SELECTIVE PRINTING MECHANISMS, i.e. MECHANISMS PRINTING OTHERWISE THAN FROM A FORME; CORRECTION OF TYPOGRAPHICAL ERRORS
    • B41J17/00Mechanisms for manipulating page-width impression-transfer material, e.g. carbon paper
    • B41J17/36Alarms, indicators, or feed-disabling devices responsible to material breakage or exhaustion
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B41PRINTING; LINING MACHINES; TYPEWRITERS; STAMPS
    • B41JTYPEWRITERS; SELECTIVE PRINTING MECHANISMS, i.e. MECHANISMS PRINTING OTHERWISE THAN FROM A FORME; CORRECTION OF TYPOGRAPHICAL ERRORS
    • B41J25/00Actions or mechanisms not otherwise provided for
    • B41J25/304Bodily-movable mechanisms for print heads or carriages movable towards or from paper surface
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B41PRINTING; LINING MACHINES; TYPEWRITERS; STAMPS
    • B41JTYPEWRITERS; SELECTIVE PRINTING MECHANISMS, i.e. MECHANISMS PRINTING OTHERWISE THAN FROM A FORME; CORRECTION OF TYPOGRAPHICAL ERRORS
    • B41J35/00Other apparatus or arrangements associated with, or incorporated in, ink-ribbon mechanisms
    • B41J35/36Alarms, indicators, or feed disabling devices responsive to ink ribbon breakage or exhaustion

Definitions

  • the present invention relates to a thermal transfer printer and to a labelling machine. More particularly, but not exclusively, the invention relates to techniques for monitoring movement of substrate and/or ribbon past a print roller. The invention also relates to printers and methods for controlling the pressure exerted by a printhead on a printing surface against which printing is to take place.
  • Thermal transfer printers use an ink carrying ribbon.
  • ink carried on the ribbon is transferred to a substrate which is to be printed.
  • the print head is brought into contact with the ribbon, and the ribbon is brought into contact with the substrate.
  • the print head contains printing elements which, when heated, whilst in contact with the ribbon, cause ink to be transferred from the ribbon and onto the substrate. Ink will be transferred from regions of the ribbon which are adjacent to printing elements which are heated.
  • An image can be printed on a substrate by selectively heating printing elements which correspond to regions of the image which require ink to be transferred, and not heating printing elements which correspond to regions of the image which require no ink to be transferred.
  • print quality it is important that the printhead is properly positioned relative to the printing surface and also important that the printhead applies an appropriate pressure to the printing surface and the ribbon and substrate which is sandwiched between the printhead and the printing surface.
  • Movement of the printhead relative to the printing surface is, in some prior art thermal transfer printers, effected pneumatically by an air cylinder which presses the printhead into contact with the printing surface and any substrate and ribbon located between the printhead and the printing surface.
  • an air cylinder which presses the printhead into contact with the printing surface and any substrate and ribbon located between the printhead and the printing surface.
  • a thermal transfer printer comprising: first and second spool supports each being configured to support a spool of ribbon; a ribbon drive configured to cause movement of ribbon from the first spool support to the second spool support; a printhead configured to selectively transfer ink from the ribbon to a substrate, the printhead pressing the print ribbon and substrate together against a print roller; a substrate drive configured to cause movement of a substrate past the printhead; a sensor configured to monitor rotation of the print roller and generate a signal indicative thereof; and a controller configured to determine a measure of movement of the substrate and/or ribbon past the print roller based on the signal output by the sensor.
  • the first aspect of the invention therefore provides a mechanism for monitoring movement of the print roller and using the monitored movement to determine movement of the substrate and/or the ribbon.
  • the use of the print roller for such monitoring is advantageous because the printhead presses the ribbon and substrate against the print roller thereby meaning that movement of the print roller should be a good indicator of movement of the substrate and the print ribbon. That is, there should be relatively little (or no appreciable) slip between the substrate and/or print ribbon and the print roller.
  • the controller may be configured to determine a measure of movement of the substrate and/or ribbon past the print roller based upon the signal output by the sensor and a quantity indicative of a diameter of the printroller.
  • the signal output by the sensor may comprise a plurality of pulses.
  • a known number of pulses may be generated by the sensor for a single rotation of the print roller.
  • Monitoring a number (which need not be an integer number) of rotations of a print roller of known diameter provides a straightforward way of determining linear distance.
  • the quantity indicative of the diameter of the print roller may be a quantity indicative of an effective diameter of the print roller as determined by the controller based upon a quantity indicative of the pressure applied by the printhead to the ribbon and the substrate against the print roller.
  • the applied pressure may affect the diameter of the print roller.
  • the print roller has an outer surface defined by a resilient material (e.g. an elastomeric material such as a silicone rubber)
  • the applied pressure may compress the resilient material in the region of the print roller against which the printhead presses.
  • the resilient material may expand in other regions of the print roller. This may be particularly important where the substrate and/or ribbon passes such parts of the print roller which are caused to expand. This may have the effect of reducing or increasing the effective diameter of the print roller, the extent of change of diameter being determined by the pressure applied for a given resilient material. It is desirable in such a case to determine the effective diameter of the print roller given the applied pressure, particularly where the diameter of the print roller is used in determination of linear displacement of the substrate and/or the print ribbon.
  • the quantity indicative of the pressure may be at least partially based upon the force applied by the printhead to the ribbon and substrate against the print roller.
  • the quantity indicative of the pressure may be at least partially based upon a parameter indicating a size of the print roller. For example, where the printer can be operated with different widths of print roller it is desirable to take print roller width into account in determining the pressure applied and therefore the effective diameter of the print roller.
  • the thermal transfer printer may further comprise a motor configured to cause movement of the printhead towards and away from the print roller.
  • the controller may be configured to provide a control signal to the motor to cause the motor to press the printhead against the print roller.
  • the control signal may be generated or selected to cause a particular desired pressure to be applied to the print ribbon and substrate against the print roller.
  • the controller may be configured to generate the control signal by: obtaining a pressure to be applied to the print roller; and generating a control signal to be applied to the motor to cause the printhead to press against the printing surface with the obtained pressure.
  • the motor which may be a position controlled motor such as a stepper motor, may be coupled to the printhead by an inelastic coupling such as a timing belt.
  • the elasticity provided by internal components of the motor may be greater than the elasticity of the coupling between the printhead and the motor shaft.
  • the elasticity provided by the internal components of the motor may be provided by deviation of a rotor of the motor relative to the magnetic field in the stator of the motor from a position to which the rotor is commanded to move.
  • the quantity indicative of an effective diameter of the print roller may be determined based upon said control signal.
  • the substrate drive may comprise a substrate motor arranged to cause movement of the substrate past the printhead and the print roller.
  • the controller may control the substrate drive at least partially based upon the signal output by the sensor.
  • the substrate drive may comprise a stepper motor and the controller may control the stepper motor.
  • the substrate is a label web comprising a plurality of labels affixed to a backing paper.
  • the substrate drive may comprises a first and second substrate spool supports, the first substrate spool support being arranged to support a spool of label carrying web and the second substrate spool support being arranged to support a spool of web from which at least some labels have been removed.
  • the motor of the substrate drive may drive the second substrate spool supports.
  • the labelling machine may also comprise a labelling station arranged to remove labels from the label carrying web, the labelling station being located on a label path between the first and second substrate spool support.
  • a labelling machine comprising first and second ribbon spool supports each being configured to support a spool of ribbon; a ribbon drive configured to cause movement of ribbon from the first spool support to the second spool support; first and second iabel spooi supports, the first label spool support being configured to support a spool of Iabel carrying web and the second Iabel spooi support being configured to support a spool of web from which at least some labels have been removed; a printhead configured to selectively transfer ink from the ribbon to labels of the Iabel web, the printhead pressing the print ribbon and label web together against a print roller; a iabel web drive configured to cause movement of the iabel web past the printhead; a sensor configured to monitor rotation of the print roller and generate a signal indicative thereof; and a controller configured to determine a measure of movement of the Iabel web and/or ribbon past the print roller based on the signal output by the sensor.
  • a thermal transfer printer comprising: first and second spool supports each being configured to support a spool of ribbon; a ribbon drive configured to cause movement of ribbon from the first spool support to the second spooi support; a printhead configured to selectively transfer ink from the ribbon to a substrate; a motor configured to cause movement of the printhead towards and away from a printing surface against which printing is carried out, the motor being coupled to the printhead by an inelastic coupling; and a controller configured to provide a predetermined control signal to the motor to cause the motor to press the printhead against the printing surface.
  • the coupling between the printhead and the motor may be a coupling between the output shaft of the motor and the printhead. Given that the coupling between the motor and the printhead is inelastic, the force applied by the printhead to the printing surface is determined by the control signal provided to the motor. The motion of the motor may start when the printhead is spaced apart from the printing surface. The motion of the motor may then cause the printhead to move towards the printing surface. Once initial contact between the printhead and the printing surface is made, commanding the motor to move further in the same direction will cause the pressure exerted by the printhead on the printing surface to increase.
  • the motor may be provided with a positional control signal during this motion.
  • the motor is a stepper motor
  • the rotor of the motor will be unable to move in response to commands to move further towards the printing surface.
  • the rotor of the motor can exhibit a difference in movement compared to the commanded movement of approximately two steps of the motor's native resolution without stalling.
  • Current applied to windings of the stepper motor will determine the ease with which the rotor of the motor can be pushed in the direction opposite to that in which the stepper motor is being commanded to move, with higher current requiring greater pressure for the same movement of the stepper motor.
  • the motor may be a DC motor. In such a case the pressure exerted by the printhead on the printing surface is a function of the current applied to the DC motor, given the well-known torque-current relationship which is inherent in a DC motor.
  • the printing surface may be resilient and in such a case the pressure between the printhead and printing surface is determined by characteristics of the motor and the resilience of the printing surface.
  • the inelastic coupling may provide a synchronous drive between the motor shaft and the printhead. This allows the pressure exerted by the printhead against the printing surface to be quickly and effectively varied based upon the signal applied to the motor.
  • the inelastic nature of the coupling may be such that greatest elasticity in the system is provided by the internal components of the motor. That is to say, the elasticity provided by internal components of the motor is greater than the elasticity of the coupling between the printhead and the motor shaft.
  • the inelastic coupling may comprise a timing belt.
  • the elasticity provided by the internal components of the motor may be provided by deviation of a rotor of the motor, relative to the magnetic field created by the stator of the motor, from a position to which the rotor is commanded to move. That is, where the motor is a stepper motor, the elasticity may be provided by the step position error which the rotor exhibits relative to a step position to which it has been commanded to move. It is known that for a stepper motor, the torque provided at the motor shaft varies in accordance with a torque angle characteristic which determines how the torque provided at the motor shaft varies in dependence upon step position error. An example of a torque angle characteristic is shown in Figure 1 1 and it can be seen to approximate a sine wave.
  • the torque provided at the motor shaft is zero when the step position error is zero.
  • the torque increases until the step position error is a full motor step at which point the torque has a maximum value.
  • the torque decreases until it reaches zero at a step position error of two full motor steps.
  • a timing belt used to couple the motor shaft to the printhead may be formed of two materials a first having a relatively high tensile strength and a second having a relatively low tensile strength.
  • the second material may deformabie and/or have a relatively high coefficient of friction (relative to the coefficient of friction of the first material).
  • the second material may be polyurethane and the first material may be a metal.
  • the timing belt may be a metal-banded timing belt.
  • the metal may be steel.
  • the timing belt passes around first and second pulley wheels, the motor being coupled to the first pulley wheel and the printhead being coupled to the second pulley wheel, such that rotation of the motor causes rotation of the first pulley wheel, movement of the timing belt and movement of the second pulley wheel. In this way movement of the motor may be transmitted to the printhead via the first and second pulley wheels and the timing belt passing fherearound.
  • the printhead may be arranged to rotate together with the second pulley wheel, such that rotation of the motor causes pivoting of the printhead towards or away from the printing surface.
  • the motor may be arranged to cause the printhead to rotate about a pivot, Rotation about the pivot may cause movement of the printhead towards and away from the printing surface.
  • the printhead may be part of a printhead assembly and the printhead assembly may be mounted on the motor shaft.
  • the motor shaft may extend through a mounting provided by the printhead assembly.
  • the motor may take any suitable form.
  • the motor may be a position controlled motor such as a stepper motor.
  • the control signal provided to the motor may be a positional control signal intended to move the motor against the printing surface and increase pressure between the printhead and the printing surface.
  • the controller may be configured to determine the control signal by obtaining a pressure to be applied to the printing surface; and generating a control signal to be applied to the motor to cause the printhead to press against the printing surface with the obtained pressure.
  • the controller may be configured to obtain data indicating a speed at which the ribbon is to pass the printhead during printing and obtain data indicating the pressure which the printhead should apply to the printing surface based upon the obtained speed. This may be useful where the pressure which should be exerted by the printhead on the printing surface varies depending upon a printing speed.
  • the control signal may be a positional control signal.
  • a control signal may be provided to a stepper motor, a DC servo motor or indeed any other form of motor.
  • the control signal may be a control signal comprising a number of steps and a rotational direction of movement.
  • the printer may further comprise a sensor configured to transmit signals indicative of movement of the printhead towards and away from the printing surface, wherein the controller is configured to monitor signals received from the sensor indicating movement of the printhead and to determine a printhead position based upon the provided signal and the monitored signals.
  • the printer may store data indicating a relationship between a provided signal and monitored signals. Such a relationship may indicate monitored signals which should be expected to be received by the controller in response to a particular provided signal.
  • the motor is a stepper motor
  • the stored data may indicate an expected ratio between pulses provided to the stepper motor and sensor signals which are received.
  • the sensor may be a rotary encoder monitoring rotation of the printhead about the pivot.
  • the controller may be configured to determine a printhead position based upon monitored sensor signals which are not substantially in accordance with the stored relationship.
  • the controller may be configured to determine that the printhead contacts a stop when the monitored sensor signals are not substantially in accordance with the stored relationship.
  • the controller may be configured to position the printhead at a predetermined position relative to the printing surface.
  • the controller may be configured to position the printhead against the printing surface and apply a predetermined movement to the printhead so as to locate the printhead at a predetermined location relative to the surface against which printing is carried out.
  • the controller may be configured to provide a signal to the motor to cause predetermined movement of the printhead such that the printhead bears against the printing surface with predetermined pressure. That is, the movement of the printhead may be determined so as to cause the printhead to apply a desired pressure to the printing surface. For example a look up table may be provided associating particular pressures with particular movement, such that a particular desired pressure may be looked up to determine a movement to be made.
  • the controller may be configured to determine the pressure which is being applied by the printhead to the printing surface by comparing the monitored sensor signals and the stored relationship. Such comparison may then be used to determine a control signal provided to the motor. In this way a closed-loop control system may be provided which is arranged so as to cause the printhead to bear against the printing surface with a predetermined pressure.
  • a thermal transfer printer comprising: first and second spool supports each being configured to support a spool of ribbon; a ribbon drive configured to cause movement of ribbon from the first spool support to the second spool support; a printhead configured to selectively transfer ink from the ribbon to a substrate, the printhead being moveable towards and away from a printing surface against which printing is carried out; a sensor configured to transmit signals indicative of actual movement of the printhead towards and away from the printing surface; a motor arranged to move the printhead relative to the printing surface; and a controller configured to provide a signal to the motor intended to cause movement of the printhead relative to the printing surface; to monitor signals received from the sensor indicating actual movement of the printhead; and to determine a printhead position based upon the provided signal and the monitored signals.
  • the third aspect of the invention generates information indicating printhead position based upon both signals provided to a motor and signals received from a sensor. Where the motor is commanded to move but movement is impeded there will be a discrepancy between the commanded movement and the sensed movement. Such a discrepancy can be used to determine that the printhead is located in a position whereby its movement is impeded.
  • a thermal transfer printer comprising first and second spool supports each being configured to support a spool of ribbon; a ribbon drive configured to cause movement of ribbon from the first spool support to the second spool support; a printhead configured to selectively transfer ink from the ribbon to a substrate, the printhead being moveable towards and away from a printing surface against which printing is carried out; a sensor configured to transmit signals indicative of actual movement of the printhead towards and away from the printing surface; a motor arranged to move the printhead relative to the printing surface; and a controller configured to determine an absolute position of the printhead based upon said signals indicative of actual movement of the printhead.
  • the fourth aspect of the invention may therefore allow information relating to absolute position of the printhead in space to be determined based upon information indicating relative movement of the printhead.
  • Figure 1 is a perspective view of a print and apply labeling machine including a printer in accordance with the present invention
  • Figure 2 is an illustration showing part of the printer of Figure 1 in further detail with the base plate removed for clarity;
  • Figure 3 is a perspective view of a printhead assembly of the printer of Figure 2;
  • Figure 4 is an alternative view of the printhead assembly of Figure 3;
  • Figure 5 is a schematic illustration of a controller arranged to control components of the printer of Figure 2;
  • Figure 6 is a flowchart showing, at a high level, control of the position of the printhead relative to a printing surface;
  • Figures 7 to 9 are flowcharts showing parts of the processing of Figure 6 in further detail;
  • Figure 10 is a schematic illustration of a controller and components connected thereto;
  • Figure 1 1 is an example of a torque vs. angle characteristic for a stepper motor, as has been discussed above.
  • FIG. 1 there is illustrated a print and apply labeling machine in which label web material is provided on a label supply spool 1 and is conveyed through a labeling station 2 to a label take up spool 3.
  • the label web material comprises a plurality of labels which are affixed to a backing paper and the labeling station is arranged to remove labels from the backing paper such that the labels are affixed to packages which are conveyed passed the labeling station 2.
  • the backing paper is then taken up by the label take up spool 3.
  • a motor 4 is coupled to the label take up spool 3 via a belt drive (not shown) thereby causing rotation of the take up spool 3 and consequently movement of the label web from the label supply spool 1 to the label take up spool 3 through the labeling station 2.
  • the labeling station 2 includes a thermal transfer printer which is arranged to print on labels of the label web as they pass through the labeling station 2 and before they are removed from the backing paper.
  • the thermal transfer printer is shown in further detail in Figure 2.
  • ink carrying ribbon is provided on a ribbon supply spool 5, passes a printhead assembly 6 and is taken up by a ribbon take-up spool 7.
  • the ribbon supply spool 5 is driven by a stepper motor 8 while the ribbon fake-up spool is driven by a stepper motor 9.
  • the ribbon supply spool 5 is mounted on an output shaft 8a of its stepper motor 8 while the ribbon take-up spool 7 is mounted on an output shaft 9a of its stepper motor 9.
  • the stepper motors 8, 9 may be arranged so as to operate in push-pull mode whereby the stepper motor 8 rotates the ribbon supply spool 5 to pay out ribbon while the stepper motor 9 rotates the ribbon take-up spool 7 so as to take up tape, in such an arrangement, tension in the ribbon may be determined by control of the motors.
  • tension in the ribbon may be determined by control of the motors.
  • the ribbon may be transported from the ribbon supply spool 5 to the ribbon take up spool 7 past the printhead assembly 6 in other ways.
  • the ribbon take up spool may be driven by a motor while the ribbon supply spool 5 is arranged so as to provide resistance to ribbon motion, thereby causing tension in the ribbon. That is, the motor 8 driving the ribbon supply spool 5 may not be required in some embodiments. Resistance to ribbon movement may be provided by a slipping clutch arrangement on the supply spool.
  • the motors driving the ribbon supply spool 5 and the ribbon take up spool 7 may be motors other than stepper motors.
  • the motors driving the ribbon supply spool 5 and the ribbon take up spool 7 may be direct current (DC) motors, in general the motors driving the ribbon supply spool 5 and/or the ribbon take up spool 7 may be torque controlled motors (e.g. DC motors) or position controlled motors (e.g. stepper motors, or DC servo motors).
  • DC direct current
  • the motors driving the ribbon supply spool 5 and/or the ribbon take up spool 7 may be torque controlled motors (e.g. DC motors) or position controlled motors (e.g. stepper motors, or DC servo motors).
  • Ribbon paid out by the ribbon supply spool 5 passes a guide roller 10 before passing the printhead assembly 6.
  • the ribbon is guided by a ribbon guide 1 1 of the printhead assembly 6 before passing around a further guide roller 12 and subsequently being taken up by the ribbon take up spool 7.
  • rotation of the guide roller 12 is monitored in a manner similar to that described in earlier European Patent No. EP0814980 so as to determine a diameter of one of the ribbon spools 5, 7.
  • a ratio of rotations can be determined. Given knowledge of the diameter of the guide roller 12 the diameter of the spool of interest can then be determined.
  • the spool of interest is not rotated a predetermined amount. Rather, the spool of interest is rotated so as to cause the guide roller to rotate a predetermined amount. In this way the predetermined rotation of the guide roller can be equated to monitored rotation of the spool of interest to allow the diameter of the spool of interest to be determined given the known diameter of the guide roller.
  • the printhead assembly 6 comprises a printhead 13 which presses the ribbon and label web 14 against a print roller 5 to effect printing.
  • the printhead 13 is a thermal transfer printhead comprising a plurality of printing elements, each arranged to remove a pixel of ink from the ribbon and to deposit the removed pixel of ink on a substrate.
  • the printhead assembly 6 is mounted to a base plate (not shown) for rotation about a pivot 16 thereby allowing the printhead 13 to be moved towards or away from the print roller 15.
  • the printhead assembly comprises a pulley wheel 17 having 30 teeth, A belt 18 passes around the puS!ey wheel 17 and about a drive wheel 19 having 23 teeth,
  • the drive wheel 19 is mounted on an output shaft 20a of a stepper motor 20 such that rotation of the stepper motor 20 causes rotation of the drive wheel 19, causing movement of the belt 18 and consequent rotation of the pulley wheel 17 and movement of the printhead 13 towards or away from the print roller 15.
  • the belt 18 is a Synchroflex® ATS Gen III Timing Beit from the Conti® Synchroflex range of ContiTech AG, the belt having a length of 300mm and a width of 10mm.
  • the stepper motor 20 may be a 86mm frame size hybrid stepper motor such as a that available from Portescap having part number 34H1 18D30B. if is well known that timing belts should be properly tension to ensure correct operation and long life.
  • the stepper motor 20 is mounted to the base plate of the printer via a pair of resilient biasing means 22, 23, and screws 20e are loose.
  • the resilient biasing means 22, 23 each comprise a spring 22a, 23a and brackets 22b, 23b.
  • the brackets 22b, 23b are each connected to their respective spring 22a, 23a by an end of each spring being received by a respective first hole 22c, 23c in the respective bracket 22b, 23b.
  • a second end of each spring 22a, 23a is connected to the base plate via respective screws.
  • Each bracket is also connected to an outer housing 20b of the stepper motor 20 via screws.
  • the resilient biasing means 22 exert a force on the stepper motor 20.
  • the force is a biasing force which acts so as to urge the stepper motor 20 towards second ends of the springs 22a, 23a.
  • the biasing means act so as to urge the stepper motor away from the printhead assembly 6 thereby tensioning the belt 18.
  • the belt 18 can be tensioned to a particular desired tension by the resilient biasing means 22, 23, and the screws 20e can be tightened to maintain the particular desired tension in the belt 18 during operation of the printer.
  • the resilient biasing means has no effect on the position of the motor or the tension in the belt 18.
  • the resilient biasing means include springs 22a, 23a and brackets 22b, 23b
  • any appropriate biasing means may be used to position the stepper motor 20 so as to allow the belt to be properly tensioned before the screws 20e are tightened.
  • the tension in the belt 18 is determined by the force applied by the resilient biasing means to the stepper motor 20. Consequently by the use of the resilient biasing means which are configured to apply different forces to the stepper motor 20 the belt can be differently tensioned.
  • the brackets 22b, 23b of the resilient biasing means 22, 23 include second holes 22d, 23d.
  • connection of the first ends of the springs 22a, 23a to those second holes 22d, 23d will cause a different extension of the springs 22a, 23a and consequently a different force exerted on the stepper motor and thereby a different tension in the belt 18.
  • the springs 22a, 23a are extension springs placing the first end of each of the springs 22a, 23a in the second hole 22d, 23d of each bracket 22b, 23b will result in a greater extension of the springs 22a, 23a compared to their extension when the first ends are received in the first holes 22c, 23c. This will result in the resilient biasing means exerting a greater force on the stepper motor 20 and therefore a greater tension in the belt.
  • the resilient biasing means 22, 23 is configured such that when the screws 20e are tightened to secure the stepper motor 20 to the base plate in a position determined by the resilient biasing means 22, 23, the belt 18 is inelastic in its behaviour.
  • the extent of rotation of the printhead assembly 6 about the pivot 16 is limited by a first point at which the printhead 13 contacts the print roller 15 and a second point at which an opposite side of the print head assembly 8 contacts a stop 21 .
  • Figures 3 and 4 show the printhead assembly 8 in further detail.
  • the printhead 13 is attached to a carrier plate 25. Interposed between the printhead 13 and the carrier plate 25 is the ribbon guide 1 1 which, as best seen in Figure 2 acts to guide the ribbon along its path.
  • the carrier plate 25 comprises an attachment member 26 which in turn magnetically attaches to a shaft 27 via magnetic attachments 28.
  • the attachment member 28 comprises two channels 29 which are each arranged to receive a respective pivot 30.
  • the printhead assembly 6 further comprises a cable guide member 32 providing for convenient routing of cables providing signals to the printhead 13.
  • the shaft 27 is arranged to rotate about the pivot 16.
  • the printhead assembly 6 is provided with a magnetic element 33, rotation of which is monitored by a magnetic encoder (not shown). In this way rotation of the printhead assembly 6 - as caused by movement of the belt 18 - about the pivot 16 can be monitored.
  • the magnetic element may be a magnetic muitipoie ring as supplied by Austria Microsystems with part number AS5000-MR20-44.
  • the encoder may be a rotary magnetic position sensor, also supplied by Austria Microsystems and having part number AS5304.
  • the motor 20 acts to move the printhead 13 towards and away from the print roller 15.
  • the motor 20 also acts to control the pressure which the printhead 13 applies to the print roller 15.
  • the control of the applied pressure is important as it is a factor which affects the quality of printing.
  • FIG 5 is a schematic illustration of components involved in the control of printhead position and pressure.
  • the stepper motor 20 is controlled by a microcontroller 50 which reads instructions from a memory 51 .
  • An encoder 52 transmits signals to the controller indicating rotational movement of the printhead assembly 6 about the pivot 16.
  • the controller provides signals to the motor 20.
  • Control of printhead position and pressure by control of the stepper motor 20 Is now described with reference to Figure 6.
  • Steps SI to S3 represent an initialization process.
  • the motor 20 is controlled so as to rotate the drive wheel 19 to move the belt 18 and pulley wheel 17 and consequently to rotate the printhead assembly about the pivot 16. This movement is continued until the printhead assembly 6 is in a position where it abuts the stop 21 ( Figure 2).
  • step S2 a calibration process is carried out to determine how movement of the stepper motor 20 through one step corresponds to pulses transmitted by the encoder 52 which monitors rotation of the printhead assembly 6 about the pivot 16.
  • step S3 the motor 20 is rotated such that the printhead assembly 6 is moved to a home position which is located close to but spaced apart from the stop 21.
  • steps S1 to S3 The initialisation process of steps S1 to S3 is carried out each time the labeling device of Figure 1 is powered up.
  • step S4 when the printer is placed on-line, the printhead assembly is moved to a ready to print position which is closer to the print roller 15. in order to carry out a printing operation the printhead is moved from the ready to print position to the print position at step S5. In the print position the printhead bears against the print roller 15 thereby applying pressure to the print roller 15 (or in use to the ribbon and substrate sandwiched between the printhead 13 and the print roller 15).
  • step S5 When a printing operation is complete processing passes from step S5 to step S4 to thereby cause the printhead assembly 6 to return to the ready to print position.
  • step S4 processing passes from step S4 to step S3 such that the printhead assembly 6 returns to its home position.
  • FIG. 7 shows the processing of steps S1 to S3 of Figure 6 in further detail.
  • the stepper motor 20 is commanded to move one or more steps in a direction which corresponds to movement of the printhead assembly 6 towards the stop 21 .
  • the ratio between the steps moved by the motor 20 and the pulses generated by the encoder 52 monitoring rotation of the printhead assembly 6 about the pivot 16 is monitored.
  • step S8 If it is determined that the determined ratio does deviate from the expected ratio a determination is made at step S8 that the printhead assembly abuts the stop 21 , and processing continues at step S9. Otherwise processing returns to step S6 where the motor is turned so as to move the printhead towards the stop 21 .
  • the ratio between motor steps and encoder pulses is 1 :3 ,4, where the motor steps are quarter-steps of the motor's native resolution.
  • This ratio takes into account the gearing provided by the drive wheel 19 and the pulley 17 as well as the number of quarter steps in a revolution of the motor and number of encoder pulses in a revolution of the pulley wheel 17. It is determined that the ratio has deviated from the expected value when the number of encoder pulses is at least twenty-one or more less than would be expected. That is, if 10 steps have been moved, it would be expected that 34 encoder pulses will have been received.
  • step S6 If, however, 14 or less encoder pulses are received it is determined that the printhead 13 is unable to move freely and is instead in contact with the stop 21 .
  • step S9 processing passes to step S9 where the motor is moved a predetermined number of steps in the opposite direction (i.e. to move the printhead assembly 6 away from the stop 21 ).
  • step S10 processing then passes to step S10 where the processing of steps S6 to S9 is repeated one or more times. This is to ensure that the location of the stop is accurately determined.
  • step S10 When the processing of steps S6 to S9 is repeated at step S10, in one embodiment it may be determined that the ratio has deviated from the expected value when the number of encoder pulses is at least twelve or more less than would be expected. This lesser number is used on the basis that in processing as part of step S10 the printhead assembly begins motion from a relatively well known starting position (unlike when the processing of step S8 is carried out for a first time.
  • step S10 When the processing of steps S6 to S9 has been repeated a sufficient number of times, processing passes from step S10 to S1 1 . It should be noted that from the processing of step S9 the printhead assembly 6 is located a predetermined number of motor steps from the stop 21 , This is referred to as the home position for the printhead assembly 8. By accurately finding the location of the stop (through the repeated processing of steps S6 to S9) the home position is accurately defined relative to the location of the stop 21 ,
  • step S1 1 the motor is commanded to rotate a predetermined number of steps (x steps) in a direction which moves the printhead assembly 6 farther away from the stop 21 , then the same number of steps back towards the stop 21 (i.e. to the home position). While this movement is carried out the number of pulses generated by the encoder is counted.
  • the predetermined number of steps is chosen so as to move the printhead assembly 8 towards the print roller 15 but not to cause the printhead to reach the print roller 15, That is, the movement of the printhead assembly 8 is unimpeded as the motor moves through the predetermined number of steps.
  • the predetermined number of steps is 25 in each direction. After the motor stops moving a delay (e.g. 250ms) is applied before taking a reading of encoder pulses to ensure that movement of the pulley wheel 17 has stopped before the number of encoder pulses is obtained.
  • a delay e.g. 250ms
  • the number of encoder pulses generated during movement of the stepper motor 20 through the predetermined number of steps in both directions is used to generate an updated ratio between motor steps and encoder pulses, in some embodiments the determined ratio may be processed together with ratios determined during previous calibration processes to determine an average ratio which is used in the processing described below, in one embodiment three determined ratios are used as a basis for determination of the average.
  • a predetermined range e.g. within 5% or 10%
  • a nominal ratio e.g. the ratio 1 :3,4 discussed above
  • step S14 Processing passes from step S12 to step S14.
  • the nominal ratio (1 :3.4 in the example presented above) may be updated during processing.
  • a rolling overall average of the most recent four determined ratios may be generated, and this roiling average may then take the place of the nominal ratio.
  • This updated nominal ratio is used in all parts of the processing requiring knowledge of a relationship between stepper motor steps and encoder pulses.
  • steps S6 to S10 are repeated so as to ensure that the location of the stop 21 and consequently the home position are accurately known by basing the location of the stop 21 on the accurately determined step: encoder pulse ratio.
  • FIG. 7 corresponds to steps S1 to S3 of Figure 6.
  • Figure 8 shows processing associated with step S4 of Figure 6.
  • step S19 the stepper motor is commanded to move so as to move the printhead to the ready to print position.
  • this position is defined to be a predetermined number of steps (e.g. 91 quarter steps) from the position at which the printhead contacted the stop. Thereafter, the movement is to the previously determined ready to print position.
  • step S20 the stepper motor 20 is commanded to rotate in a direction which moves the printhead assembly 6 towards the print roller 15.
  • the ratio between the steps through which the stepper motor 20 turns and the number of encoder pulses recorded is monitored at step S21 and used at step S22 to determine whether the print roller 15 has been reached by the printhead 13. This determination is based to similar processing to that described above with reference to step S8, specifically that a deviation from the expected ratio of steps to encoder pulses indicates that movement of the printhead assembly 8 is impeded, this time because the printhead assembly has made contact with the print roller 15, It is determined that the printhead assembly 6 has reached the print roller 15 when there is a difference of 12 encoder pulses from the expected ratio. For example, assuming again a ratio of 1 step to 3.4 encoder pulses when the printhead assembly moves freely, if movement of 10 steps equates to less than 22 encoder pulses, it will be determined that contact with the print roller 15 has been made.
  • step S22 While the printhead assembly 6 has not reached the print roller 15, processing returns from step S22 to step S20 and continues as described above.
  • step S23 the stepper motor is moved in a predetermined number of steps in an opposite direction (i.e. to move the printhead assembly 6 away from the print roller 15) at step S23, this position spaced apart from the print roller 15 being referred to as the ready to print position. This position may be defined as that reached by moving the stepper motor 20 through 15 quarter steps.
  • the controller is configured to command the motor 20 to rotate a predetermined number of steps towards the print roller 15, that number of steps being determined by the pressure to be applied.
  • the number of steps corresponding to a particular pressure is determined in advance by experimentation and stored in a look up table such that during operation of the printer, when a particular pressure is desired the controller commands the stepper motor to turn through the corresponding number of steps.
  • the deviation of twelve encoder pulses referred to above has been found in one arrangement to result in a pressure of 3.5kg being applied to the print roller 15 by the print head assembly 6.
  • commanding the stepper motor 20 to move the printhead assembly 6 towards the print roller by the number of steps moved away from the print roller 15 to reach the ready to print position will cause application of a pressure of 3.5kg.
  • the application of a further 5 steps has been found to cause application of a pressure of 7.9kg.
  • the pressure to be applied may be specified by a user as a percentage of a pressure to be applied given a particular substrate speed. A pressure of 50% may be considered to be nominal. In such a case the processing of Figure 9 is used.
  • a print speed is obtained.
  • user input indicating a percentage print force to be applied is obtained.
  • a force to be applied is determined and a number of steps through which the stepper motor 20 should be moved to apply that force is obtained,
  • the motor is moved through the determined number of steps to cause the printhead to 13 apply the determined force to the print roller 15.
  • the printer may store data indicating a minimum pressure (associated with user input of 0%) and a maximum pressure (associated with user input of 100%) when particular user input is received the pressure to be applied may be determined by linear interpolation from the stored minimum pressure and stored maximum pressure. Suitable nominal (i.e. 50%) pressures are 8kg where the print speed is 500mms "1 and 4kg where the print speed is 100mms "1 .
  • a stall detection system may be used. At the start of each printing operation a comparison is made between the number of encoder pulses which have been received and the number of steps through which the motor has been commanded to move. This is compared to the expected ratio between steps through which the motor has been commanded to move and encoder pulses.
  • FIG 10 is a schematic illustration of a controller 100 which controls rotation of the motor 4.
  • a sensor 115 associated with the print roller 15 provides a signal indicative of its rotation to the controller 100 and this is used to provide accurate monitoring of the movement of the label web 14 past the printhead 13 and the print roller 15 as is described in further detail below.
  • the controller 100 may control rotation of the motor 4 in any suitable way, but may use the signal received from the sensor 1 15 as a feedback signal to provide for closed-loop control of the motor 4.
  • the print roller 15 comprises a stainless steel shaft of diameter 8mm and is coated with a silicon rubber coating having a Shore A hardness of 50-55 and a thickness of 2.75mm.
  • the primary purpose of the print roller 15 is to provide a backing support against which the printhead 13 presses the ribbon and label web 14 so as to effect thermal transfer printing onto a label. As such the print roller 15 acts as platen roller.
  • the print roller 15 is caused to rotate. Rotation of the print roller 15 is a good indication of movement of the label web 14 past the printhead 13, particularly because of the pressure applied by the printhead 13 which presses the label web 14 against the print roller 15.
  • the coating of the print roller with the aforementioned silicon rubber has the effect of improving the consistency of rotation of the print roller 15 as the label web 14 moves along its path between the label supply spool 1 and the label take-up spool 3. This again contributes to making rotation of the print roller 15 an accurate indicator of movement of the label web past the print head 13.
  • the print roller 15 is provided with a magnet (e.g. part number BMN-35H which is marketed by Bomatec, Hori, Switzerland) which is mounted to the end of the print roller 15 such that it co-rotates with the print roller 15.
  • the sensor 115 then takes the form of an encoder chip (e.g. part number AMS5040, marketed by ams R&D UK Ltd) which measures rotation of the magnet and hence print roller 15, and outputs a signal which is representative thereof to the controller 100.
  • the signal comprises a plurality of pulses, and the controller 100 has knowledge of a predetermined number of pulses which are output by the sensor 1 15 in a single rotation of the print roller 15. Such knowledge can be stored in a memory 101 associated with the controller 100.
  • This signal output by the sensor 1 15 is used by the controller 100 to monitor movement of the label web along the label web path.
  • the diameter of the print roller 15 is known to the controller (and may again be stored in the memory 101 ). In one embodiment the print roller 15 has a diameter of 13.5mm.
  • the controller 100 can determine linear distance of label web which has moved past the print head 13 by determining a linear distance corresponding to the monitored rotation of the print roller 15, It is preferable that the print roller 15 is as rigid as possible so that it does not deflect under print pressure from the printhead 13, as such stainless steel is a suitable material for the shaft of the print roller 15. That said, the pressure exerted by the printhead 13 to press the print ribbon and label web 14 against the print roller 15 will deform the silicon rubber with which the print roller 15 is coated.
  • the silicon rubber may be compressed in a part of the print roller 15 against which the printhead 13 presses but may expand in another part of the print roller 15. This will cause the diameter of the print roller 15 to vary, the extent of deformation of the silicon rubber (and consequently the variation in diameter) being determined by the pressure applied by the printhead 13.
  • the overall effect of the applied pressure may be to increase or decrease the diameter of the print roller 15.
  • the pressure applied by the printhead 13 is determined by a number of steps through which the motor 20 is driven ( Figure 2) which determines the force applied to the print roller 15.
  • the diameter of the print roller 15 may vary in dependence upon the pressure which the motor 20 causes the printhead 13 to apply to the print roller 15.
  • the controller 100 When determining a linear displacement of the label web 14 by monitoring rotation of the print roller 15, the controller 100 first determines a pressure being applied by the print head 8 (which is known given the number of steps through which the motor 20 has been driven, and which may be expressed in terms of a number of steps through which the motor 20 has turned relative to a reference position) and uses the determined pressure to determine a change in diameter of the print roller 15 caused by the applied pressure.
  • the change in diameter for a particular pressure may be determined by a look-up operation.
  • the data being looked up may be generated in advance by experiments in which the diameter of the print roller is measured for each of a plurality of pressures applied by the printhead 13 (which can conveniently be expressed in terms of a number of steps through which the motor 20 has turned relative to a reference position).
  • the uncompressed diameter of the print roller 15 as stored in the memory 101 is modified based upon the data resulting from the look up operation to determine the effective diameter of the print roller 15.
  • the effective diameter of the print roller 15, based upon the applied pressure is then used when determining a linear distance which corresponds to a number of rotations of the print roller 15, that number of rotations being determined based upon the signal provided by the sensor 1 15 and the known number of pulses in a single revolution of the print roller 15. in parts of the foregoing description, references to force and pressure have been used interchangeable.
  • the controller 100 may additionally process information indicating the width of the print roller 15 against which the printhead 13 presses and use this width information to determine the effective diameter of the print roller 15.
  • controllers have been described in the foregoing description (particularly with reference to Figures 5 and 10). It will appreciated that functions attributed to those controllers can be carried out by a single controller or by separate controllers, It will further be appreciated that each described controller can itself be provided by a single controller device or by a plurality of controller devices. Each controller device can take any suitable form, including ASICs, FPGAs, or microcontrollers which read and execute instructions stored in a memory to which the controller is connected.

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  • Physics & Mathematics (AREA)
  • Electromagnetism (AREA)
  • Electronic Switches (AREA)
  • Impression-Transfer Materials And Handling Thereof (AREA)

Abstract

Imprimante à transfert thermique comprenant : des premier et second supports de bobine, chacun étant configuré pour supporter une bobine de ruban; un organe d'entraînement de ruban configuré pour provoquer le déplacement du ruban depuis le premier support de bobine vers le second support de bobine; une tête d'impression configurée pour transférer sélectivement l'encre du ruban sur un substrat, la tête d'impression appuyant le ruban d'impression et le substrat ensemble contre un rouleau d'impression; un organe d'entraînement de substrat configuré pour provoquer le déplacement d'un substrat au-delà de la tête d'impression; un capteur configuré pour surveiller la rotation du rouleau d'impression et pour produire un signal indicatif de celle-ci; et un dispositif de commande configuré pour déterminer une mesure de déplacement du substrat et/ou du ruban au-delà du rouleau d'impression sur la base du signal sorti par le capteur.
EP14784365.0A 2013-10-11 2014-10-10 Imprimante à transfert thermique et machine d'étiquetage Active EP3055138B1 (fr)

Priority Applications (1)

Application Number Priority Date Filing Date Title
EP18214532.6A EP3533617B1 (fr) 2013-10-11 2014-10-10 Imprimante à transfert thermique et machine d'étiquetag

Applications Claiming Priority (4)

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GBGB1318042.7A GB201318042D0 (en) 2013-10-11 2013-10-11 Thermal transfer printer
GB201318176A GB201318176D0 (en) 2013-10-14 2013-10-14 Thermal transfer printer
GB1318581.4A GB2519371A (en) 2013-10-21 2013-10-21 Thermal transfer printer
PCT/GB2014/053050 WO2015052531A2 (fr) 2013-10-11 2014-10-10 Imprimante à transfert thermique et machine d'étiquetage

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Cited By (2)

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EP3650232A1 (fr) * 2018-10-31 2020-05-13 Brother Kogyo Kabushiki Kaisha Système d'impression
US10815360B2 (en) 2016-11-30 2020-10-27 Landa Labs (2012) Ltd. Thermal conduction transfer printing

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EP3825132B1 (fr) 2016-06-17 2024-05-29 Videojet Technologies Inc. Imprimante
GB2558224A (en) * 2016-12-22 2018-07-11 Videojet Technologies Inc Printer
EP3645295B1 (fr) * 2017-06-28 2024-05-22 Videojet Technologies Inc. Imprimante à transfert et procédé associé
CN109367245A (zh) * 2018-10-26 2019-02-22 湖南鼎致远科技发展有限公司 一种走纸精度控制装置及其热转印打印机
GB201904440D0 (en) * 2019-03-29 2019-05-15 Videojet Technologies Inc Printer
DE102019127153A1 (de) * 2019-10-09 2021-04-15 Phoenix Contact Gmbh & Co. Kg Technik zur Kennzeichnung eines Objekts
CN111660678B (zh) * 2020-06-30 2023-11-21 厦门汉印电子技术有限公司 打印辊的回转量检测装置、回转量检测方法及打印机
CN113844181B (zh) * 2021-10-14 2024-05-28 北京中馨智信科技有限公司 具有旋转组件的打印机装置

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GB9702098D0 (en) * 1997-01-31 1997-03-19 Neopost Ltd Thermal transfer printing apparatus
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US10815360B2 (en) 2016-11-30 2020-10-27 Landa Labs (2012) Ltd. Thermal conduction transfer printing
EP3650232A1 (fr) * 2018-10-31 2020-05-13 Brother Kogyo Kabushiki Kaisha Système d'impression

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Publication number Publication date
WO2015052531A3 (fr) 2015-06-11
CN105408121A (zh) 2016-03-16
EP3533617A1 (fr) 2019-09-04
EP3055138B1 (fr) 2018-12-26
CN105408121B (zh) 2017-10-13
EP3533617B1 (fr) 2020-12-23
WO2015052531A2 (fr) 2015-04-16

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