EP0890140B1 - Process and circuit for printing a print image - Google Patents

Description

The invention relates to a method for printing a print image on an endless carrier material with respect to a predetermined Position in an electrographic printer.

Electrographic printers in which a motor is known a transport device drives the carrier material a transfer station essentially according to a predetermined Print speed transported past. When printing are print images generated by a print controller in succession at the transfer station at the printing speed the substrate is printed. Transfers the transport device a forward movement by positive locking on the carrier material, as it e.g. when engaging transport spikes in Transport holes one perforated in the edge areas Backing material is the case, so is within certain limits a forced run between the carrier material and the transport device realized.

However, the transport device transmits the forward movement by frictional engagement on the carrier material by a rubberized transport roller or a conveyor belt with the Carrier material are in frictional contact, so it will a forced run between carrier material and transport roller or Conveyor belt prevented by various factors. Among these influencing factors is the micro-slip, which causes occurs that the frictional connection between the drive roller and Backing material is not 100% guaranteed. On another influencing factor lies in the mechanical tolerances in the manufacture of the drive roller and in its storage in the transport device. A forced run between carrier material and drive roller thus does not take place. Since the Transport speed of the carrier material is therefore never completely matches the speed of the drive roller, is a synchronization between carrier material and Printing process excluded. Are e.g. on the carrier material Forms printed by offset printing are available, into the given numbers or letters in the printing process Form fields are to be printed, then a Offset between the letters and the form fields due to the minimal speed difference with every printed form larger. An interruption of the printing process is inevitable to correct the misalignment again.

However, the offset problems mentioned occur also on when the transport device is moving forward transfers positively to the carrier material. In this Case is in the transfer station on a photoconductor drum Clock attached, which has a control loop for the phase (PLL - phase locked loop) the frequency of a stepper motor for driving the transport device and for an exposure line generated for exposing the photoconductor drum. The disadvantage of this solution is that mechanical stiffness, Grid frequency fluctuations etc. are not complete be settled. They are also used to implement phase control complex electronic assemblies necessary that mostly work according to an analog principle, i.e. continuous Process voltage values.

The object of the invention is a simple, digital solution for printing on continuous carrier material, which specify a offset-free printing with respect to a given position allows.

This task is accomplished by a process with the characteristics of Claim 1 solved. The invention is based on knowledge from that with a substantially constant transport speed of the carrier material, the offset cumulatively from Print image is enlarged to print image. To offset Accordingly, only minimal changes in speed are to be corrected the transport speed of the carrier material necessary. The transport speed can therefore despite slight fluctuations as a reference for a measurement of the offset can be used.

In the invention are regular on the substrate Spacing marks for positioning the print images in Direction of transport available. At the start of printing one Print image becomes a print image start signal from the print controller generated. In the case of offset-free printing, the Markings based on the same distance and in the substantially constant transport speed when it occurs of the print image start signal always in the same place regarding the transfer station. An offset manifests itself by the markings with respect to a selected reference point their position in the vicinity of the transfer station slowly change from print image to print image if only snapshots at a time at the reference point at the time of the print image start signal to be viewed as.

In the invention, a signal pickup is fixed with respect to attached to the transfer printing station, which when capturing a marking generates a marker signal. In case of an offset lying in front of the signal sensor in the transport direction To move markings on the signal pickup or from remove this if consecutive snapshots too Times with active print image start signal considered depending on whether the transport speed of the Backing slightly larger or slightly smaller than that Printing speed is.

Because of the larger or smaller distance with respect to the Signal pickup can be the distance in the direction of transport Marking closest to the signal sensor for Measurement of the offset can be used by measuring the time this marker needs to go up to the transducer to get.

Therefore, when the print image start signal occurs, a Counting of clock signals in a counter started. The Counting is started when the next marker signal occurs interrupted at the signal sensor. The counting result is there in a ratio determined by the clock signals Time the next mark to the transducer needs. From this time, multiplication with the Print speed the distance of the marker from the transducer at the time of the print image start signal be calculated. In particular, when there is a change this distance from print image to print image an offset be recognized. In the invention, the counter result is with compared to a setpoint that corresponds to a counter reading with an offset-free Positioning of the printed images in relation to the marking equivalent. If the count result is greater than the setpoint, so the frequency of a current pulse train, the one Controls stepper motor that drives the transport device, elevated. If the count result is less than the setpoint, then the frequency of the current pulse train is reduced so that the mark at the next print image start signal again removed from the signal pickup.

Both the counter and the stepper motor control can digitally executed. There is a microprocessor in the printer is available, the comparison can also be easily carried out digitally become. In the invention need to synchronize the transport speed of the carrier material and the Print speed just a counter and a slightly modified one Pulse control for the stepper motor can be used.

As markings e.g. the transport holes of the carrier material or a cross perforation, if present serve at the beginning and end of a printed page, so that also no additional effort arises from the markings. With no transport holes Carrier material is offset-free printing only required if the carrier material already before Printing e.g. through offset printing with pre-printed forms is printed. The additional effort required to apply the Markings in offset printing is also low because of the Markings are printed at the same time as the forms become.

In one embodiment of the invention, a pulse generator contains a divider and a frequency multiplier, where the divider on the input side with a basic clock of the basic frequency is clocked and outputs an output pulse train that has a frequency determined by the ratio of fundamental frequency and a divisor value determined by the comparison result is defined. The frequency multiplier multiplies the Frequency of the output pulse train by an integer value and outputs the control pulse train. This measure will achieved that the positioning accuracy is increased, because the Reaching e.g. co-determined by the transport device Stepper motor higher operating frequency range Divider values are necessary than without using a frequency multiplier. With higher divisors, the result is the subsequent frequency multiplication per division value step, i.e. an increase or a decrease by one, minor frequency changes in the specified frequency working range. Smaller frequency changes have the consequence that too the carrier material is only moved by small distances, so that even a small offset can be corrected.

The invention further relates to a circuit arrangement the features of claim 9. The circuit arrangement serves to carry out the method according to the invention, so that the above effects also affect the circuitry transfer.

Figur 1

eine Prinzipdarstellung eines elektrografischen Druckers,

Figur 2

drei Lagebeziehungen zwischen einem Sensor und einer Markierung auf dem Trägermaterial,

Figur 3

drei Varianten zum Erzeugen einer Stromimpulsfolge für einen Schrittmotor,

Figur 4

ein Diagramm zum Darstellen des Zusammenhangs zwischen Teilerwert und Frequenz der Stromimpulsfolge,

Figur 5

Zeitverläufe eines Seitenanfangssignals, eines Markierungssignals und eines Zählsignals,

Figur 6

ein Flußdiagramm eines Verfahrens zum versatzfreien Drucken der Druckbilder bezüglich der Markierungen.

The invention is described below using exemplary embodiments. Show:

Figure 1

a schematic diagram of an electrographic printer,

Figure 2

three positional relationships between a sensor and a marking on the carrier material,

Figure 3

three variants for generating a current pulse sequence for a stepper motor,

Figure 4

1 shows a diagram to illustrate the relationship between the divider value and the frequency of the current pulse sequence,

Figure 5

Time profiles of a start signal, a marker signal and a count signal,

Figure 6

a flowchart of a method for offset printing of the printed images with respect to the marks.

Figure 1 shows a schematic diagram of an electrographic Printer 10 and a block diagram of essential electrical Functional units for controlling a stepper motor 12. The Printer 10 has one through stepper motor 12 via a shaft 13 driven transport device 14, which is close to a Transfer station 16 is arranged and endless carrier material 20 at the transfer station 16 essentially according to a predetermined one Printing speed VD transported past. In the Transfer station 16 becomes one on a photoconductor drum 18 applied charge image colored with toner by means of a corona device (not shown) on the endless carrier material 20 transferred. The photoconductor drum 18 rotates itself in the direction of arrow 22. After the transfer Remnants of the toner are removed and the surface of the Photoconductor drum 18 rotates on an exposure line 24 over, which exposes the photoconductor drum 18 again.

After the carrier material 20 is transported past the transfer station 16 it is fed to a fixing station 26 in which the still smearable toner image in the carrier material melted smudge-proof with the help of pressure and temperature becomes. In the indicated by an arrow 28 Transport direction seen in front of the transfer station 12 is one arranged first deflection unit 30, the carrier material 20th to the transfer station 16. A second deflection unit 32 is seen in the transport direction after the fixing station 26 arranged. This second deflection unit 32 stacks the printed one Carrier material 20 on a stack 34. The carrier material 20 gets off a stack at the start of printing 36 removed by the first deflection unit 30. Instead of both stacks 34 and 36 are also used on rolls which the carrier material 20 is rolled up.

The printing process is controlled by a print controller 38. The print controller 38 generates the print images page by page, by adding the image information one line at a time to the exposure line 24 are transmitted via data lines 40. The print images are successively at the transfer printing station 16 printed on the substrate 20 at the printing speed. At the start of printing one side of the Print control 38 a top of page signal SAS on a Generates data line 42 that enables a counter 44 that the pulses of a counting clock sequence on a counting clock line 46 counts. The frequency of the counting clock sequence ZTF is around 100 kHz.

Are on the carrier material 20 in regular Spacing marks 48, which are printed on the Carrier material 20 were printed by offset printing. The markings 48 were made at the same time as the forms 50 printed on the carrier material 20 and are in a predefined position with regard to the form forms 50 arranged.

A light barrier 52 gropes the carrier material 20 according to the Markings 48 onwards. The light barrier 52 contains a light transmitter 54 for emitting a light beam 56 and one Light receiver 58, which the light beam 56 strikes when none of the markings 48 between light transmitter 54 and light receiver 58 is. The light receiver 56 contains a circuit a marker signal when a marker is detected MS generates that on a signal line 60 to the counter 44th is transmitted and interrupts the counting process in counter 44.

The print controller 38 also includes a microprocessor 62, the counting result after completion of the counting process reads the counter 44 via data lines 64 and with a Compare setpoint. The setpoint corresponds to a counter reading with offset-free positioning of the print images with respect to of the marks 48. Free of offset means that in the Letters contained in printed images exactly in the intended Fields of the forms 50 can be printed.

If there is a deviation between the counting result and the setpoint found, the stepper motor 12, the shaft 13 is rotatably connected to the transport device 14, so be controlled so that it varies depending on the direction of the deviation turns faster or slower. The stepper motor 12 is driven by a current pulse sequence SIF, which by a pulse generator 66 is generated. The current pulse sequence SIF is from the pulse generator 66 via a control line 68 to Transfer stepper motor 12.

The pulse generator 66 is on the input side with a basic clock clocked, which has a basic clock frequency of 10 MHz. The Frequency of the current pulse sequence SIF is in one by one integer divisor value TW determined ratio to the fundamental frequency. The divider value TW is determined by the microprocessor 62 transmitted to pulse generator 66 via data lines 72. To At the beginning of the printing process, the divider value TW is determined by the Microprocessor 62 specified so that the speed V of the carrier material 20 in the transport direction of the printing speed VD corresponds. Occur during printing Differences between the speed V and the printing speed VD e.g. by micro-slip of a drive roller the transport device 14 on the carrier material 20, so the counting result will deviate from the target value. The divisor value TW is increased by the microprocessor 62 when the speed V is greater than the printing speed VD. The markings 48 are in the transport direction in this case 28 are offset from the printed image. The divisor value TW is reduced by the microprocessor 62 when the Markings 48 in the transport direction 28 compared to the printed images are set back.

The pressure controller 38 is connected to a via data lines 74 Input / output device 76 connected, e.g. the printing speed VD can be specified by an operator can.

Figure 2 shows three positional relationships between the light barrier 52 and marks 48a, 48b, 48c on the substrate 20 are applied. In this case, each in FIG Shown snapshots of a location of the markings 48a, 48b and 48c each at the start of printing a printed page correspond, exactly at the moment when that Top of page signal signals the start of a new print page.

Part a of Figure 2 shows a marking 48a, which is at the beginning a new print page by distance S1 from the light barrier 52 is removed. The instantaneous speed V des Carrier material 20 corresponds essentially to the printing speed VD. The instantaneous speed practically gives way V only by a maximum of a few thousandths of the printing speed VD, so that the instantaneous speed V at determining the distance between mark 48a and Light barrier 52 at the time of a new top of the page as is considered constant.

The counter 44 is started at the beginning of the new print page and interrupted when the mark 48a the light beam 56th interrupts, the counting result corresponds to a time t1, which the marking 48a needs to run through the distance s1. The microprocessor can determine the length of the path s1 calculate by taking the assumed instantaneous speed V multiplied by time t1. In the case of part a of the figure 2, the microprocessor determines that the path s1 is accurate corresponds to a desired distance s0, which ensures that the Print images are aligned with respect to the markings 48. The printed image near the marking 48a also becomes special be aligned with this marker.

Part b of Figure 2 shows the case that at the time of Start of printing a page a stretch S2 between one Mark 48b and the light barrier 52 is present. The The counting result in case b is higher than the counting result in the case a, since the assumed instantaneous speed V is constant is viewed and a larger distance s2 has to be covered. The microprocessor 22 calculates the distance s2 by the Instantaneous speed V with an increased counting result corresponding time t2 multiplied. So the microprocessor 62 find that the distance s2 is greater than that Target distance s0 is. The marking 48b lies in the transport direction or a dashed line 80, which is an end point of the Represents target distance s0. The other end point of the target route s0 is the light barrier 52. The markings 48 hurry up Print images afterwards. The microprocessor is used for correction 62 increase the partial value TW in the pulse generator 66.

Part c of Figure 2 shows the case that a distance s3 between a marker 48c and the light barrier 52 for Time of printing start of a page smaller than the target distance s0 is. The marking 48c lies in the transport direction behind the dashed line 80. The counting result in the counter 44 in case c is below the setpoint. The microprocessor 62 determines the length of the line s3 by in turn the assumed instantaneous speed V with the count result, that corresponds to a time t3, multiplied. The markings 48 are ahead of the printed images in case c. The mark So 48c is near one with respect to one the printed image in the transport direction. to Correction, the microprocessor 62 will decrease the divider value TW.

Figure 3 shows three variants I to III for generating the Current pulse sequence SIF for the stepper motor 12 in the pulse generator 66th

Part a of Figure 3 shows a first embodiment of the Pulse generator 66. The pulse generator 66 contains a divider 90, the input side with the basic clock on the basic clock line 70 is clocked and in the over the data lines 72 of the Divider value TW is saved. The output of the divider 90 is connected directly to the control line 68. So that is Frequency of the current pulse sequence SIF from the ratio Basic frequency and divisor value TW defined.

Part b of Figure 3 shows a second embodiment a pulse generator 66 ', which instead of the pulse generator 66 is used. The pulse generator 66 'contains a divider 90', whose mode of operation is that of part 3 of FIG. 3 explained divider 90 corresponds. An output pulse train AIF of the divider 90 'is on the input side via a data line 92 connected to a frequency doubler 94. The frequency doubler 94 doubles the frequency of the output pulse train AIF and generated on the output side on the control line 68 the current pulse sequence SIF. Using the pulse generator 66 'leads as explained below with reference to FIG. 4 a more precise positioning of the carrier material 20 than when using the pulse generator 66.

Part c of Figure 3 shows a third variant III for production the current pulse sequence SIF, in which the pulse generator 66 ' is used. The time interval is used for fine positioning between two successive comparisons of the Microprocessor 62 divided into two periods. in the in the first period a divisor value TW1 in divisor 90 ' is saved and a divisor value is created in the second time interval TW2 stored in divider 90 '. How the variant works III is also explained below with reference to FIG. 4.

FIG. 4 shows the frequency dependence in a diagram the current pulse sequence SIF the size of the divisor value TW in Pulse generator 66 or 66 '. On the abscissa axis 100 is the Divisor value TW deducted. Numbers refer to curly brackets to a base clock frequency of 1 MHz, Numbers without brackets on a basic clock frequency of 10 MHz and numbers in square brackets to a base clock frequency of 100 MHz. The frequency is on the ordinate axis 102 Current pulse sequence SIF in Hertz. A curve 104 represents the relationship between the divisor value TW and the frequency of the current pulse sequence SIF for variant I. For example, the frequency of the current pulse train is SIF at a base clock frequency of 10 MHz and a divider value TW of 2000 at a point P1 5000 Hz. Since the divisor value TW can only take integer values, there is a curve 104 from a sequence of points. The higher the base clock frequency is, the more points are between two given Points, e.g. P1 and P2 of curve shape 104. In the exemplary embodiment became, as already mentioned, a basic clock frequency selected from 10 MHz. This is a compromise between circuit complexity and the distance between two neighboring ones Points on the curve profile 104.

In variant II of FIG. 3 there is a curve 106 the relationship between the divider value TW and the basic clock frequency ago. In variant II, the divisor value must be used to set the same frequency of the current pulse train SIF twice as high be as in variant I. A point P1 'is a divisor TW of 4000 and a frequency of the current pulse train SIF assigned from 5000 Hz. A point P2 'is a divisor value TW of 6000 and a frequency of the current pulse train of 3333 Hz assigned. There are double between points P1 'and P2' as many points on the curve profile 106 as between the Points P1 and P2 on the curve 104. As a result the resolution of the curve profile 106 compared to that of the Curve course doubled 104. That means that with the Variant II minor position deviations can be corrected can be used as variant II, e.g. an increase in Divider value TW by the value 1 only a small change in Frequency of the current pulse train SIF results, and the associated change in the transport speed of the Backing material 20 only at a small offset of the backing material 20 leads.

Variant III of FIG. 3 is based on curve shape 106 off, however, the resolution compared to variant II increased again by the integer divisor value TW thus predetermined frequency jump of the current pulse sequence SIF is weakened that only an absolutely necessary Part of the frequency hopping for the correction of the position of the Markings 48 takes effect against the printed image. The Principle of variant III can of course also in a variant IV can be used in the pulse generator 66.

FIG. 5 shows a time profile 110 of the start of page signal SAS, a time course 112 of the marker signal MS and a time course 114 of a count signal ZS. Furthermore, in Figure 5 shows part of a time line 116, which as Reference variable for the time profiles 110 to 114 is used. To a Time ZP1 is determined by a voltage pulse I1 of the start of page signal SAS the voltage value of the count signal ZS increased, whereby the counting process in the counter 44 is started. At a point in time ZP2 at which a marking 48 detects the light barrier 52 happens, is by a voltage pulse I2 of Marking signal MS the count signal ZS to a lower Voltage value switched, causing the counting process in the counter 44 is stopped.

The microprocessor 62 determines from the count result in the counter 44 depending on variant I, II, III or IV a new divisor value TW1 and stores it in divider 90 or 90 'if it is from Divider value TW0 deviates. In variants III and IV after a predetermined time t4, a divisor value TW2 in the Divider 90 'stored. At a time ZP3 is through the Pressure control 38 a voltage pulse I3 of the top of the page signal SAS creates a new one as described above Initiates counting. After completing this counting process a divisor value TW3 is stored in the counter 90 or 90 '.

FIG. 6 shows a flow diagram of the method for non-offset Printing the printed images with respect to the marks 48. The method begins in a step 200 with an initialization phase from steps 202 and 204. In step 202 the divider 90 or 90 'is initialized with a divisor value TW, at a speed V of the carrier material 20 leads, which corresponds approximately to the printing speed VD. To At the beginning of the printing process, the carrier material 20 becomes in the transport direction 28 aligned so that the markings 48 on a ruler so that the first Print images have no offset with respect to the marks 48 to have. In step 204, the microprocessor 62 waits until on first counting in counter 44 is completed.

In step 206, the microprocessor 62 reads the count result from the counter 44 and determines in one step 208 a new divisor in the case of variants I and II or two new divisor values TW in the case of variants III and IV. In step 210, the divider value TW1 is over the data lines 72 transferred to the divider 90 or 90 '.

In a step 212, the microprocessor 62 checks whether the Variants III or IV are active. If this is not the case, then the method is continued in a step 218. Is the Variant III or IV is active, the microprocessor 62 is waiting in a step 214 until a time calculated in step 208 is over, then in a step 216 the second Divider value TW2 to divider 90 or 90 'to be transmitted. Subsequently the method continues in step 218, in which the microprocessor 62 is waiting for a new count result. If there is a new counting result, the microprocessor checks 62 in a method step 220 whether the printing has ended shall be. If this is not the case, the procedure continued in a loop from steps 206 to 220. In step 220, the microprocessor 62 determines that the print is to be ended, he ends the process in a step 222.

Claims (9)

1. Method for printing a print image on a continuous carrier material (20) relative to a predetermined position in an electrographic printer (10),
   wherein a stepper motor (12) controlled by a current pulse sequence (SIF) drives a transport apparatus (14) that drives the carrier material (20) by friction or positively locked engagement, said transport apparatus transports the carrier material (20) past a transfer printing station (16) substantially according to a predetermined printing speed (VD),
   during printing operation, print images generated by a print control unit (62) are printed successively on the carrier material (20) at the transfer printing station (16) at the printing speed (VD),
   at the beginning of the printing of a print image a print image start signal (SAS) is generated by the print control unit (62), which signal starts a counting process for counting clock signals (ZTF) in a counter (64),
   a signal pick-up (58) scans the carrier material (20) for markings that are present at regular intervals for positioning the print images in transport direction (28), the signal pick-up (58) generating a marking signal (115) when detecting a marking (48),
   the counting process is interrupted upon occurrence of the marking signal (115) or upon occurrence of a fixed number of marking signals (115),
   the count result is compared to a desired value (step 208) that corresponds to a counter reading given offset-free positioning of the print images with respect to the markings (48),
   and wherein dependent on the result of the comparison, the frequency of the current pulse sequence (SIF) is set (steps 210, 216).
2. Method according to claim 1, characterized in that the transport apparatus (14) transmits at at least one location in positively locking fashion a forward movement in the direction of transport (28) to the carrier material (20).
3. Method according to claim 1 or 2, characterized in that the frequency for the current pulse sequence (SIF) is generated by a pulse generator (66) that is clocked with a basic frequency, which pulse generator outputs the current pulse sequence (SIF) at the output side with a frequency related to the basic frequency by a whole number divider value (TW).
4. Method according to claim 3, characterized in that the divider value (TW) is defined dependent on the result of the comparison.
5. Method according to claim 3 or 4, characterized in that the pulse generator (66, 66') contains a divider (90), which is clocked at an input side with a basic clock of the basic frequency (GTF), and in that the divider outputs the current pulse sequence (SIF) with a frequency that is defined by the ratio of basic frequency and the divider value (TW).
6. Method according to claim 3 or 4, characterized in that the pulse generator (66') contains a divider (90') and a frequency multiplier (94), the divider (90') being clocked at the input side with a basic clock of the basic frequency (GTF) and outputs an output pulse sequence (AIF) that has a frequency that is defined by the ratio of the basic frequency (GTF) and the divider value (TW), wherein the frequency multiplier (90') multiplies the frequency of the output pulse sequence (AIF) by a whole-number value, preferably the value two, and wherein the frequency multiplier (90') outputs the current pulse sequence (SIF).
7. Method according to one of the claims 4 to 6, characterized in that for a fine positioning a time interval (ZP2 to ZP4) located between two successive comparisons is divided into at least two time segments, and in that a determined divider value (TW1, TW2) is allocated to each of the time segments.
8. Method according to one of the preceding claims, characterized in that the markings (48) had been printed on the carrier material (20) before the beginning of the printing process.
9. Circuit arrangement for printing a print image on a continuous carrier material (20) relative to a predetermined position in an electrographic printer (10),
   comprising a pulse generator (66, 66') for generating a pulse sequence (SIF) of a predetermined frequency according to a predetermined value,
   a stepper motor (12) controlled by the pulse sequence (SIF) of a predetermined frequency for driving a transport apparatus (14) which transports the carrier material (20) past a transfer printing station (16) substantially according to a predetermined printing speed (V),
   a control unit (62) for generating the print images that are printed successively on the carrier material (20) at the transfer printing station (16) at the printing speed (V),
   a signal pick-up (58) for scanning the carrier material (20) for markings (48) which are present at regular intervals on the carrier material (20) for the positioning of the print images in the direction of transport (28),
   the signal pick-up (58) being designed such that it generates a marking signal (115) upon detection of a marking (48),
   a counter (44) which is designed such that it starts a counting process for counting clock signals (ZTF) by a print image start signal (SAS) that is generated by the control unit (62) at the beginning of the printing of a print image, and that it interrupts the counting process upon occurrence of the marking signal (48) or upon occurrence of a fixed number of marking signals (48),
   wherein the control unit (62) is designed such that it compares the count result with a desired value (step 208) which corresponds to a counter reading given offset-free positioning of the print images relative to the markings (48), and that it sets a predetermined value in the pulse generator dependent on the result of the comparison (steps 210, 216).

Images