EP0197300A1 - Operating method to improve the printing quality of a printer - Google Patents

Abstract

1. A method of controlling and improving the printing quality of a printer, in particular an ink jet printer, wherein at least one ink jet (6) is produced by means of the voltage and frequency applied to an oscillator (5) through at least one nozzle (2) of a perforated plate (1) and, after a certain distance from the perforated plate (1), charged droplets (7) are released from the ink jet (6), the droplet breakaway distance (Sa ) from the perforated plate (1) being optimally adjusted by regulation of the oscillator voltage, and the flight time of a droplet (7) from the droplet break-away point (8) to a charge detector (27) is measured, characterised in that the viscosity of the ink is regulated by observing the oscillator voltage and the droplet break-away distance (Sa ).

Description

The invention relates to a method for controlling and improving the font quality of a printer, in particular an ink color jet printer, wherein at least one color jet is generated by means of voltage and frequency applied to an oscillator through at least one nozzle of a nozzle plate and charged drops after a certain distance from the nozzle plate loosen the ink jet, the tear-off distance of which is set by the nozzle plate by regulating the oscillating voltage.

Ink-color printers as a form of matrix printers are used today as peripheral devices for electronic computing systems for the output of data. Similar to the principle of a dot matrix printer, the print head of the inkjet printer has a series of nozzles arranged vertically below and next to one another, through which jets of liquid ink paint are sprayed onto the material to be labeled under high pressure. Depending on which nozzles are open or closed, the image of the desired letters and numbers is created on the labeling material from dots of color. When writing, nozzles and control devices (for example for closing or for electrostatically or magnetically deflecting the undesired color rays) pass line by line past the labeling material and inject one character after the other.

In addition, so-called permanent color jet printers (continuous jet system) are known, for example from DE-PS 24 46 740. In it, an ink color jet is generated through a nozzle and then equally spaced ink drops of the same size, which have a charging electrode and a constant one generated by deflection plates pass electric field, the drops being deflected in one direction depending on their charge, while the deflection of the drop in the other direction is carried out by another suitable measure, for example moving the object to be labeled.

• -die Umgebungstemperatur des Systems, welche die Viskosität der Tinte verändert (besonders bei alkohol-löslichen Tinten, wie MEK - (Metyläthylketon) und Äthanol) und
• - Tintendruckschwankungen im Hydrauliksystem.

Essentially, two disturbance parameters influence the font quality of such a continuous ink color printer, namely

• -the ambient temperature of the system, which changes the viscosity of the ink (especially with alcohol-soluble inks such as MEK - (methyl ethyl ketone) and ethanol) and
• - Ink pressure fluctuations in the hydraulic system.

The above Disturbance parameters in any case lead to a reduction in the quality of the font. However, they can be compensated for in a certain defined range by setting the optimum drop tear-off distance for the current operating state of the system. So far, this compensation has been done optically and manually. The behavior of the droplet formation is observed with a magnifying glass over a stroboscope diode attached to the write head and readjusted by changing a transducer amplitude using a potentiometer.This method is quite unsafe because it depends on the subjective perception of the observer and requires a high level on the part of the user System knowledge and practice. This effort leads to a restriction in the range of applications and in the marketability of an ink color printer.

The inventor set himself the goal of developing an automatic process and integrating it into existing or new process units, which on the one hand regulates the optimal drop tear-off distance online to ensure the highest possible font quality and on the other hand an increase in the above-mentioned. Display and / or prevent disturbance parameters beyond a certain range. The process is intended to take into account the respective characteristics of the oscillator and nozzle, which are configured in an ink-jet printer, in order not to require very tight manufacturing tolerances.

To solve this task, a printer from the above Type in which the time of flight of a drop is measured from the drop-off point to a charge detector and the drop-off distance is determined via this time of flight.

This eliminates the need for an observer to determine the drop-off point. Furthermore, the change in the drop-off point is no longer dependent on the subjective powers of observation of the observer, but is automatically determined very precisely. Depending on the fine-tuning of the system, a change in the oscillation voltage and thus a shift in the drop break point can take place very quickly, so that suddenly occurring pressure fluctuations in the hydraulic line can be taken into account very quickly. While the distance between the nozzle plate and the drop-off point was previously determined, the distance between the drop-off point and a charge detector is now being determined, this distance always being changed in inverse proportion to the drop-off distance.

An essential element of the present invention is the synchronization between drop separation and drop charging. It is first determined whether a charged drop is even displayed on the charge detector. If this is not the case, a phase jump is made at the charging pulse frequency. This continues until the detector indicates a charge.

The pulse width of the detected signal is then compared with the pulse width of a stored signal. If deviations are found here again, there is a further phase shift of the charging pulse frequency.

The flight time of the drop is only measured when there is a synchronization between drop charging and drop formation. This flight time is then to be compared with a stored flight time, for example from the measurement of the previous flight time. If the actual flight time deviates from the stored flight time, the oscillating voltage is changed until the current flight time is equal to or less than the stored value and the range of the optimal tear-off distance is reached.

In practice, it has proven to be advantageous not to compare each individual flight time with the value from the memory, but to add up a multiplicity of flight times and to form an average value therefrom, which is compared with an average value from the memory.

A further improvement of the method according to the invention is preferred, in which after the regulation of the optimal droplet removal, a constant comparison of the vibration voltage values with reference values from a further memory takes place. These reference values are values of an oscillation voltage for an optimal droplet removal depending on the used oscillator and a valid operating viscosity of the paint. If deviations of the vibration voltage values from this reference value are determined, the viscosity of the color can be changed according to the invention. It is known that an increasing color viscosity requires a steady increase in the oscillation voltage, so that the control range of the optimal droplet detachment removal is left with a certain color viscosity. This is avoided by influencing the color viscosity itself.

The procedure is otherwise not tied to any specific form of implementation, i.e. it can be integrated into the system as a hardware solution and / or as a software solution. It is required to measure the controlled variable, i.e. the tear-off removal, only the existing components and measuring devices, which are integrated into the system for the synchronization of the drop charge upon their tear-off. Good font quality is guaranteed over a relatively wide viscosity range of the color. Measurements have shown that systems with a defined operating viscosity of approx. 3.1 mPa x sec with a viscosity increase to over 7 mPa x sec still have a high font quality.

In a device according to the invention for controlling and improving the font quality of a printer, in particular an ink color jet printer, with an oscillator for generating at least one color jet through at least one nozzle of a nozzle plate, charging electrodes being assigned to the color jet and drops dropping out of the nozzle plate after a certain distance from the nozzle plate Loosening the ink jet and this droplet removal from the nozzle plate should be adjustable by regulating the oscillating voltage is a device for determining the flight time of a droplet from. Drop tear-off point is provided to a detector. This device for determining the flight time of a drop preferably consists of the charging electrode for applying a charging voltage to the drop, a charging detector for detecting the charge and a flight time counter. In addition to a pulse generator or pulse converter, both the oscillator and the charging electrode are preceded by a frequency divider, both of which are jointly connected to a system clock feed.

A DAC counter (DAC = digital-to-analog converter) is excited via a start signal, which in turn is connected to a DAC initial value memory. The DAC counter is connected via a digital / analog converter to an amplifier which is connected between the oscillator and its pulse converter. In this way, the vibration voltage can be changed. Here, the digital / analog converter and the DAC counter replace the potentiometer previously used for automatic tracking of the manipulated variable (oscillating voltage). However, other suitable actuators are also conceivable.

Switching elements for synchronizing the charging voltage or a charging pulse with the tear-off are switched on via a second start signal. These switching elements consist of a pulse counter, the above-mentioned frequency divider for the charging electrode and a pulse width comparator. The charge pulse frequency emitted from the frequency divider can be phase shifted via the latter, the pulse width comparator being connected both to the charge detector and to the flight time counter and the latter controls. A pulse width memory is also assigned to the pulse width comparator and contains a value for comparing the current value of the pulse width comparator. This value should preferably be changeable in the pulse width memory, ie it should be possible to adapt current values.

The flight time counter is followed by a time of flight comparator which compares the time of flight values with values from a time of flight memory and controls the DAC counter. These values in the flight time memory can also be changed by entering current values.

However, preferably not every individual flight time should be compared with a value from the flight time memory. To record a plurality of values or their mean value, the flight time counter is assigned a measured value counter and possibly a control device for a specific number of measured values, a flight time adder being interposed between the flight time counter and the flight time comparator to form an average value.

The time-of-flight comparator increments or decrements the DAC counter depending on the existing deviations in the time of flight and the oscillating voltage is changed via the DAC counter or the digital / analog converter and amplifier.

Furthermore, a flip-flop with which a DAC comparator is connected can be controlled via the first start signal. This DAC comparator in turn compares the values of the DAC counter with values from a DAC reference memory. The reference value in the DAC reference memory represents the vibrating voltage for an optimal drop tear-off depending on the vibrator used and a valid operating viscosity of the paint. It can also be changed if necessary. If the DAC comparator detects a difference between the reference value from the DAC reference memory and the value of the DAC counter, it controls a device for regulating the viscosity of the paint. Depending on the difference between the two values, either a valve of a tank for paint or a valve of a solvent tank is opened and paint or solvent is let into a main tank.

Overall, the device works fully automatically and is completely independent of the subjective sensations of an observer. The disturbance parameters, e.g. The ambient temperature of the system and color pressure fluctuations in the hydraulic system are automatically compensated. The operability of the system within a reaction time to replenish the viscosity is ensured by the optimal drop tear removal for the current ink viscosity is readjusted. In addition, the reaction time of the replenishment is relatively short even with long hydraulic lines.

• Figur 1 eine vergrößerte schematisierte Darstellung der Arbeitsweise eines Farbstrahldrucker;
• Figur 2 ein vergrößerter Ausschnitt aus Fig. 1;
• Figur 3 eine graphische Darstellung der Abhängigkeit der Tropfenabrißentfernung von der an einen Schwinger angelegten Spannung;
• Figur 4 eine graphische Darstellung der Abhängigkeit eines Schwingerspannungspegels von der Farbviskosität;
• Figur 5 eine graphische Darstellung der Abhängigkeit eines satellitenfreien Bereichs von der Farbviskosität;
• Figur 6 ein Blockschaltbild einer Schaltung zur _Durchführung des erfindungsgemäßen Verfahrens zur Regelung der Tropfenabrißentfernung.

Further advantages, features and details of the invention result from the following description of a preferred exemplary embodiment and from the drawing; this shows in

• Figure 1 is an enlarged schematic representation of the operation of a color jet printer;
• FIG. 2 shows an enlarged detail from FIG. 1;
• FIG. 3 shows a graphical representation of the dependence of the drop tear-off distance on the voltage applied to an oscillator;
• FIG. 4 shows a graphical representation of the dependence of an oscillation voltage level on the color viscosity;
• FIG. 5 shows a graphical representation of the dependence of a satellite-free region on the color viscosity;
• FIG. 6 shows a block diagram of a circuit for carrying out the method according to the invention for regulating the removal of drops.

According to FIG. 1, a nozzle 2 is arranged in a nozzle plate 1, through which ink color is pressed out of a nozzle prechamber 4. 3 with a supply line is indicated with ink. An oscillator 5 is arranged in this nozzle prechamber 4. After the nozzle 2, the ink color forms an ink jet 6 with a diameter d _s - (see FIG. 2) and a flow velocity _Vs. After a certain distance from the nozzle plate 1, drops 7 form out of the ink jet 6, which then tear off from the ink jet 6 at a drop tear-off point 8 and move on at a drop distance h. The drop removal from the tear-off point 8 to the nozzle plate 1 is denoted by s _a .

The drop break-off point lies between two charging electrodes 25, each drop being charged electrostatically differently (according to the shape of the character or matrix). A downstream charge detector 27 checks whether the drops 7 are charged. Then fly through the drop 7 an electric field of two baffles 71 and 72, to which high voltage is applied. Depending on its charge, the drop 7 is deflected in one direction (here vertically). The drop is deflected in the other direction (here horizontally) by the movement of an object 73 to be labeled. If no writing process is triggered, the drop is not deflected by the deflection plates 71, 72, but flies into a collecting tube 74 or the like. and, not shown in detail, is conveyed back into a main tank 64 with a suction pump.

The drop stopping distance s _a is now largely dependent on a voltage U applied to the oscillator 5, as shown in FIG. 3.

If the oscillating voltage U is continuously increased, starting with U _b , the droplet detachment distance s _a gradually decreases. As soon as the oscillating _{voltage has} reached the level U _w , the drop detachment distance s _a begins to rise again. The hatched, so-called satellite-free region 9 of droplet formation occurs between two levels U _o and Um of the oscillating voltage. An optimal font quality of the system is only guaranteed in this area.

The oscillation voltage level U _w lies between the two values U _o and Um and is representative of the shortest drop detachment distance.

An increase in the ink viscosity with unchanged system configuration (oscillator / nozzle) and with constant ink pressure would result in a family of curves with different values for the oscillation voltage levels U _w , U _o and Um in FIG. 2. The dependence of the oscillation voltage level U _w , which is representative of the setting of the shortest droplet _{detachment distance} and thus of the satellite-free region, on the ink _{viscosity ηt is} shown as a representative _{example in FIG} .

It can clearly be seen that an increasing ink _{viscosity ηt requires} an increase in the oscillation _{voltage level} U _{w in} order to achieve an optimal droplet _{removal distance} s _a . The droplet detachment distance s _a , based on the nozzle plate 1, decreases.

Typical values for U _{w min.} at _{ηt min} = 2.5 mPa x sec: 35 -60 V.

Typical values f U _{w max} . at q _{t max.} = 5 mPa x sec: 80-120 V.

The spread of the limit values for U _{w min.} and U _{w max.} are due to the different oscillator characteristics.

FIG. 5 shows the satellite-free region as a function of the ink viscosity, limited by the oscillation voltage level U _o and Um. This satellite-free area becomes smaller with increasing ink viscosity. The course of the oscillation voltage level U _w for an optimal droplet removal distance S _a is indicated by _a dashed line. An optical / manual readjustment of this level with increasing ink viscosity is very difficult because the observer can only form his subjective opinion about the satellite state of the ink jet and not about the suitable drop tear-off removal.

According to FIG. 6, a circuit for carrying out the method according to the invention consists of three main blocks: a phase control 20, a drop break control 40 and a viscosity control 60 is excited which have the same frequency.

A drop control 40 applies a first control signal 10 = "start control". It is used to excite a DAC counter 41 (DAC = digital / analog converter) so that it is charged with a DAC initial value 42. This initial value should be such that a sinusoidal voltage of 20 Vpp with a frequency of, for example, 64 kHz is present at the output of an amplifier 45 after an impulse converter 44, generated by the frequency divider oscillator 43. The output of the amplifier 45 supplies the oscillator 5 and is the manipulated variable of the entire drop separation control 40. Desired voltage changes for the oscillator 5 are input to the amplifier 45 via a digital / analog converter 54 via 55, which is connected to the DAC counter 41.

Phase control 20 is initiated with a second control signal 11 = "start synchronization". A pulse counter 21 is started via 11 a and, for 8 clock periods of the 64 kHz of the frequency divider 22, which, like the frequency divider oscillator 43, is connected to the system clock 15, charging voltages alternating between 8 V and 0 V via a charging pulse generator 23 and optionally an amplifier 24 applied to the charging electrode 25 and charged the ink droplets. With the control signal 11 b, a flight time counter 46 is started, which is incremented synchronously with the system clock 15. The flight time counter 46 can be stopped by the output 16 of a pulse width comparator 26, provided the drops 7 are loaded with a load the. Otherwise, the flight time counter 46 reaches a maximum counter reading and causes the charging pulse frequency to experience a phase jump 17 of approximately + ₁ 2 _° with respect to the oscillator frequency. This phase jump is achieved in that the divider factor of the frequency divider 22 is changed before the charge pulse generator 23 for one clock period.

The phase control is repeated until drops with charges are detected by the charge detector 27 and these values are applied as a rectangular pulse via a charge amplifier 28, optionally with pulse processing, at the input of the pulse width comparator 26. The pulse width comparator 26 then compares the current pulse width of the signal with the last maximum pulse width from a pulse width memory 29, which was originally input to the pulse width memory 29 via 30 by the pulse width comparator 26. At the same time, the flight time counter 46 is stopped via the output 16 and a measured value counter 47 is decremented via 16a. If the current pulse width is larger, the old value is overwritten with the new one in the memory 29 via 30 and the phase of the charging pulse generator 23 is shifted in the same direction as the last measurement process by 6 ° with respect to the oscillator frequency. If the current pulse width is smaller, the phase is shifted by + 6 ° and both values are immediately shifted by -6 °. The connections 18, 19 between pulse width comparator 26 and frequency divider 22 are intended for these phase jumps.

This phase control 20 ensures an optimal synchronization between the charging of the drops 7 with a specific charge and their tearing off. Furthermore, the electrical properties of the measuring device (charging electrode 25, charge detector 27 and amplifier 28) are automatically adapted by the adaptive method of pulse width evaluation.

The phase control 20 and drop break control 40 are interlinked via the pulse width comparator 26, among other things. As stated above, this stops the flight time counter 46 and decrements the measured value counter 47 only when the maximum pulse width has been detected by the phase control 20. The counter reading at the output of the flight time counter 46 is directly proportional to the flight time of the drops 7, namely from their demolition 8 to a charge detector 27, ie inversely proportional to the drop stall distance S _a to the nozzle plate 1. The current counter reading then becomes an average value in a time-of-flight adder 48 added. When a number of the required measured values 56 has been reached, an output 33 of the measured value counter 47 activates a time of flight comparator 49, so that the current mean value of the drop flight time is compared with the last mean value from a time of flight memory 50. The last mean value is then overwritten with the current mean value in time-of-flight memory 50 through 34. If the current mean value of the drip flight time is greater than the last mean value, ie the droplet detachment distance S _{a in} relation to the nozzle plate 1 has become smaller, the DAC counter 41 is incremented via the connection 35 and the oscillating voltage is increased by approximately 2 V. This control process is repeated until the current mean value of the drop flight time has become equal to or less than the last mean value and the range of the optimal drop distance has thereby been reached.

If this state is reached, the DAC counter 41 is decremented via the connection 36. A flip-flop 51, which was reset by the signal 10 "start control" via 10b, is set again so that a DAC comparator 52 is activated via 37 and an output 38 of the DAC counter 41 with an output 39 of a DAC reference memory 53 is continuously compared for all further control processes.

When the system is switched on for the first time (commissioning), the value at the output 38 of the DAC counter 41 is loaded when the flip-flop 51 is set in the DAC reference memory 53, as indicated by arrow 12. This value serves as a reference of the vibrating voltage for optimal droplet removal depending on the vibrator 5 used and the valid operating viscosity of the ink.

To control the optimal drop-off distance, the DAC counter 41 is decremented during the next control operations as long as the drop-off distance S _{a is to the} right of the turning point U _w or in the area 9 (see FIG. 3), ie the current measured drop flight time is greater than that of the last measurement or at least the same.

If the currently measured drop flight time becomes shorter than that of the last measurement, the drop-off distance S _{a is} greater and is therefore to the left of the area of the turning point U _w (see FIG. 3). The DAC counter 41 is incremented until the drop stopping distance S _{a is} again to the right of the area of the turning point U _w . This regulation of the tear-off removal can already compensate for ink pressure fluctuations in hydraulic systems alone.

An increasing ink viscosity requires a constant increase in the oscillation voltage U in order to remain in the control range of the optimal drop tear-off distance S _a (see FIG. 4). 6 shows a simple method and an arrangement for viscosity control 60. The DAC comparator 52 continuously compares the output 38 of the DAC counter 41 with the value of the output 39 from the DAC reference memory 53. This reference value is representative of the oscillating voltage U, which is required to achieve the optimum drop-off removal distance S _a . If the value at the output 38 of the DAC counter 41 is less than or equal to that from the reference memory 53, the output 61 from the DAC comparator 52 activates a valve 62 of an ink tank 63, so that a main tank 64 up to a maximum : Level is refilled with ink. If, on the other hand, the value at the output 38 of the DAC counter 41 is greater than the reference value, the output 61 of the DAC comparator 52 activates a solvent valve 65 of a solvent tank 66 and the main tank 64 is refilled with solvent up to the maximum fill level. The ink viscosity in the main tank 64 thus decreases again.

Furthermore, a level monitor 67 is arranged in the main tank 64, the signals of which are sent to a level monitor 68. Level monitoring 68, valves 62 and 65 and output 61 of 52 are connected to one another by corresponding suitable switching elements, such as AND gate 69 and amplifier 70.

Claims (28)

1. A method for controlling and improving the font quality of a printer, in particular an ink color jet printer, wherein at least one color jet is generated by means of voltage and frequency applied to an oscillator through at least one nozzle of a nozzle plate and charged drops after a certain distance from the nozzle plate from the color jet solve, whose tear-off removal is set by the nozzle plate by regulating the oscillating voltage,
characterized,
that the flight time of a drop is measured from the drop-off point to a charge detector and the drop-off distance is determined via this time of flight. 2. The method according to claim 1, characterized in that the tear drop and the drop charging are synchronized. 3. The method according to claim 1 or 2, characterized in that the charging is carried out by regular charging pulses. 4. The method according to claim 3, characterized in that upon detection of the non-charging of the drops on the charge detector, the charge pulse frequency undergoes a phase jump until a charge is detected by the charge detector. 5. The method according to claim 4, characterized in that the pulse width of the detected signal is compared with the pulse width of a stored signal. 6. The method according to claim 5, characterized in that in the event of a deviation of the current pulse width from the stored, the charge phases. Of the charge pulse are shifted with respect to the oscillator frequency. 7. The method according to claim 6, characterized in that the new pulse width is stored as the current pulse width after the phase shift. 8. The method according to any one of claims 2-7, characterized in that the determination of the flight time of the drop is made only after the synchronization between drop tear-off and drop charging. 9. The method according to at least one of claims 1-8, characterized in that the current flight time is compared with a stored flight time and then, if necessary, the new flight time is stored. 10. The method according to claim 9, characterized in that when the current flight time deviates from the stored flight time, the oscillating voltage is changed until the current flight time is equal to or less than the stored value and thereby the range of the optimal tear-off distance is reached. 11. The method according to claim 9 or 10, characterized in that a plurality of flight times are measured and added to form an average. 12. The method according to at least one of the An Proverbs 1-11, characterized in that after the regulation of the optimum drop tear-off distance, a constant comparison of the vibration voltage values with reference values from a further memory takes place, which serve as a reference of the vibration voltage for an optimal drop tear-off distance depending on the vibrator used and a valid operating viscosity of the paint. 13. The method according to claim 12, characterized in that the viscosity of the color is changed when the vibration voltage values deviate from the reference value. 14. Device for controlling and improving the quality of the fonts of a printer, in particular an ink color jet printer, with an oscillator for generating at least one color jet through at least one nozzle of a nozzle plate, charging electrodes being assigned to the color jet and drops from the color jet after a certain distance from the nozzle plate solve and this drop tear-off distance from the nozzle plate can be adjusted by regulating the oscillating voltage, characterized in that a device for determining the flight time of a drop (7) from the drop tear-off point (8) to a detector (27) is provided. 15. The apparatus according to claim 14, characterized in that the device for determining the flight time of a drop (7) from the charging electrode (25) for applying a charging voltage to the drop (7), a charging detector (27) for detecting the charge and one Flight time counter - (46) exists. 16. The apparatus of claim 14 or 15, characterized in that via a start signal - (10) a DAC counter (41) can be excited, which is connected to a DAC initial value memory (42) and via the output of an amplifier - (45) a certain sinusoidal voltage with a certain frequency, generated by a frequency divider (43) to which the oscillator (5) is applied. 17. The apparatus according to claim 16, characterized in that switching elements for synchronizing the charging voltage or a charging pulse with the tear-off can be switched on via a second start signal (11). 18. The apparatus according to claim 17, characterized in that the switching elements consist of a pulse counter (21), a frequency divider (22) and a pulse width comparator (26), via which the frequency divider (22) via a charge pulse generator (23) to the Charging electrode (25) emitted charging pulse frequencies are phase shiftable, the pulse width comparator (26) also being connected to the charge detector (27) and controlling the flight time counter (46). 19. The apparatus according to claim 18, characterized in that the pulse width comparator (26) is assigned a pulse width memory (29) which contains changeable values for comparing the current values of the pulse width comparator (26). 20. The apparatus according to claim 18 or 19, characterized in that the frequency divider - (22) via a system clock (15) with the frequency divider (43) of the oscillator (5) and the flight time counter (46) is connected. 21. The device according to at least one of claims 16 to 20, characterized in that the flight time counter (46) is followed by a time of flight comparator (49) which compares the time of flight values with possibly variable values from a time of flight memory (50) and the DAC counter (41 ) controls. 22. The apparatus according to claim 21, characterized in that the flight time counter (46) is connected to a measured value counter (47) and optionally to a control device (56) for a number of the measured values, wherein between the flight time counter (46) and time of flight comparator (49) Flight time adder (48) is arranged to form an average. 23. The device according to claim 22, characterized in that the time-of-flight comparator (49) is also connected via a flip-flop (51) controlled by the start signal (10) to a DAC comparator (52) in which the values of the DAC counter (41 ) with values from a DAC reference memory - (53). 24. The apparatus according to claim 23, characterized in that this reference value is the oscillation voltage for an optimal drop tear-off distance (S _a ) depending on the oscillator used and a valid operating viscosity of the paint. 25. The apparatus of claim 22 or 23, characterized in that the DAC comparator (52) with a device (60) for controlling the Viscosity of the paint is associated. 26. The apparatus according to claim 25, characterized in that the device consists of a main tank (64) for the paint, which is in communication with a paint tank (63) and a solvent tank (66). 27. Device. according to claim 26, characterized in that the level in the main tank - (64) is monitored. 28. The apparatus according to claim 26 or 27, characterized in that on the paint tank (63) and on the solvent tank (66) valves (62, 65) are arranged for controlling the addition.

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