DE2346557A1 - INKJET SYNCHRONIZATION DEVICE - Google Patents

Description

Böblingen, September 6, 1973

Applicantin International Business Machines

Corporation, Armonk, N.Y. 10504

Official file number: New registration File number of the applicant: LE 972 006

Ink jet synchronization device

The invention is based on one specified in the preamble of claim 1 Kind of out.

Many of the known inkjet printers have a plurality of Print heads that are arranged in a row next to one another and come into operation simultaneously or one after the other. With these The synchronization problem plays an important role in inkjet printers. This problem can be seen in the fact that the for the required ink droplets are generated at a correct point in time and synchronized with the charging potentials need to be properly distracted for printing.

It is the object of the invention specified in claim 1 to provide a synchronization device for an ink jet printer create, which synchronizes the drop formation and port movement with simple means and consequently functionally reliable, in order to achieve a very to achieve high print quality despite high printing speed.

Further features of the invention can be found in the subclaims .

Details of the invention are described below using an exemplary embodiment illustrated in the figures.

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Show it:

1 shows the block diagram of a synchronization device for an inkjet printer with three printheads,

FIG. 2 shows one which can be used in the circuit according to FIG

Circuit,

3a shows the principle of a detector circuit,

3b shows a preferred embodiment of a detector circuit, which forms the basis for the circuit of FIG. 2, and

Fig. 4 pulse diagrams of various pulses that

occur during a drop time in the inkjet printer of FIG.

The inkjet printer according to Flg. 1 has a plurality of nozzle print heads 1, 2 and 3, each of which has an ink drop against one ejects recording medium not shown. The individual nozzle print heads have crystals 6, 7, 8, charging electrodes IO, 11, 12, Deflection electrodes 14, 15, 16 and sensor ink catchers 18, 19 2O. A charging electrode driver 22 or 23 or 24 is assigned to each nozzle. These charging electrode drivers are used by both the Synchronization pulse generator 26 as well as by the character generator 28 powered. The two generators mentioned are in turn operated by the clock generator 30 and the control logic 31.

The ink droplets are produced in a known manner by the individual nozzle print heads in the form of streams of droplets 33, 34, 35. During synchronization there is a series of drops that are numerical a range from only a few drops to a few hundred drops is detected in associated sensor ink collecting apertures 18, 19

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2O headed. The drops entering the said apertures develop signals that are transmitted via lines 37, 38, 39 to the electronic Circuit 40 are supplied. With the latter is the detector circuit 41 is connected, the output of which is connected to the control logic 31 via the line 42.

The synchronization of the individual streams of ink droplets generated by the nozzle print heads 1 to 3 takes place one after the other. That means that all synchronization processes for a nozzle print head must be completed before the synchronization process for the next printhead begins. However, it is preferable synchronize the nozzle print heads in a semi-parallel manner.

The semi-parallel synchronization mode provides that control signals are fed to the individual nozzle print heads 1 to 3, in such a way that that sequences of drops from the individual nozzle print heads in rotation with during the drop synchronization process of each Nozzle print head developed signals are ejected and the correction is made by all nozzle print heads.

As is known, the synchronization can be achieved by varying the phase of the crystal with respect to the charging potential that the individual charging electrodes 10, 11, 12 is supplied. In the semi-parallel mode of operation, all of the crystals are initially made with the same one Phase signal excited. To begin synchronization, a series of drops 33a, for example three drops, is formed and ejected, charged in nozzle print head number 1, and directed into sensor ink orifice 18. This gives a on the line 37 to the electronic circuit 40 supplied signal. Shortly afterwards, possibly separated by a few drops, the sequence of drops 34a is formed in nozzle print head number 2, ejected, charged, and into the sensor ink catcher 19 where a signal is generated. This signal is fed to the electronic circuit 40 via the line 38. Shortly afterwards, i.e. after a short interval of a few

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Ink drop becomes another series of ink drops 35a through the nozzle print head number 3 is formed, ejected, charged and directed into the sensing ink orifice 20 for over the line 39 to transmit a signal to the electronic circuit 40. In this way there are between the testing of the individual nozzle print heads small intervals during which it is determined by the control logic 31 whether for the synchronization of the assigned printer head correction is required and signals are generated for the other nozzle print heads to at least complete the correction process initiate.

The loading of the ink drops is usually carried out for synchronization purposes in a similar way to the printing of characters.

This relationship is based on the typical shown in FIG Drop interval. A drop time is with 10 microseconds assumed, with a first part of 2.5 microseconds in length representing a so-called forbidden time in which drops are not should be formed. The synchronization of the drop formation for charging is preferably done in a three microsecond interval, in the further part of the 10 microsecond drop interval. The so-called forbidden time corresponds to the time in which the charging electrode voltage changes, so that during this time no drops should be formed. If a drop during the synchronization time is formed, the formation takes place correctly related to the charging electrode voltage at a fixed point in time.

If there are drops of ink in the sensor ink catcher panels 18, 19, arrive and do not produce an output signal, these drops are formed outside of the synchronization time, which is inexpedient is. The correction process can then be carried out by the control logic 31 caused to change the drop formation, either by shifting the phase of the crystal drive frequency for the crystals 6, 7, 8 or by changing the amplitude of the voltage applied to the crystals 6, 7, 8 or by changing

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the phase of the voltage pulses im fed to the charging electrode Regard to the crystal.

Of course there is a comparable one. Correction process required in the event that relatively low signals are generated by the sensor ink collection orifices 18, 19, 20 and via the electronic Circuit 40 of the detector circuit 41 and the control logic 31 are fed. If a sufficient number of properly loaded Droplets arrive in the sensor ink catcher apertures 18, 19, 20, signal levels are generated of a sufficient size to withstand the correct synchronization of the drop formation for charging the charging electrodes 10, 11, 12. Thus is for these cases no correction process required.

Some in the circuit of Fig. 1 and especially in the electronic one Circuits that can be used in circuit 40 are shown in Figures 2, 3a and 3b.

The basic circuit of FIG. 3a uses the amplifier 45 with a field effect transistor input which draws a negligible current less than 0.5 nanoampere at 55.degree. The resistor 46 (Rl) is a carbon resistor of 50 milliohms + 5%. The resistors 47 and 48 (R2 and R3) serve to increase the apparent feedback resistance through the amplifier A1. The voltage supplied via resistor R1 is determined by the ratio of R2 and R3 (minus input of amplifier 45 to virtual earth). If R2 is 300 ohms and R3 is 2.7 kilo ohms, 10% of the amplifier output voltage is fed back to R1. The effective feedback resistance Rp ₁ results from the equation (D:

(1) R__ - Rl (R2 + R3)

For example, if the ink _{collecting diaphragm current I G} = 4 nanoamps and the resistor Rl is 50 milliohms and Vl is virtual earth, the bias current in amplifier 45 is negligible.

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sigbar and the entire ink collection aperture flow flows through Rl. V2 = 50 milliohms χ 4 nanoamps = 0.2 volts, if R2 «■ is 300 ohms and R3 = 2.7 kiloohms and V3 results as follows:

(2) V3 = 0.2V (R2 + R3)

R2

= 0.2 (300 + 2700) = 2.0 volts 300

The capacitors 50, 51 (C1 and C2) are chosen so that the gain of the amplifier 45 is at a suitable frequency comes to a head.

The circuit of Fig. 3b operates on the same basic principle of Fig. 3a with the exception that a less expensive one Amplifier 53 with a non-field effect transistor input use finds. A balanced pair of junction field effect transistors 55, 56 create a high input impedance buffer for amplifier 53. The balanced pair of transistors is necessary because of the large change in field effect characteristics in current manufacturing processes.

The synchronization method is expanded to synchronize "N" nozzle printheads by using the circuitry of Figure 3b and ^ N "analog switches as shown in Figure 2. Using the principle of the circuits of Figures 3a and 3b, the electronic logic determines whether If this is not the case, the size or phase of the signal supplied to the respective crystals 6, 7, 8 (Fig. 1) is changed in order to bring the drop formation to a desired point The input pulses on lines 37, 38, 39 are derived from Fig. 1 for the circuit of Fig. 2. The circuit of Fig. 2 includes pairs of balanced field effect transistors 60 to 62 denoted by QIl and Q21, Ql2 and Q22 and Q13 and Q23. Each pair of these transistors is connected to a resistor 63 to 65 and a circuit 66 to 68. The

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Outputs of circuits 66 through 68 are to the detector amplifier circuit 41 connected. The resistors 63 to 65 correspond to the resistor 57 (Rl) of FIG. 3b. The couples more balanced Field effect transistors 60 to 62 serve as high-impedance buffers between the high-impedance sensing inputs 37 to 39 (sensing ink collecting screens) and the low impedance inputs of amplifier 70 on line 72. Switches 66 to 68, The analog switches are used to isolate the field effect transistor pairs 60 to 62 of each other. The switches 66 to 68 are controlled by the control logic 31 via the line 44 in time sequence of inputs 44a, 44b and 44c actuated. Preferably only one switch 66-68 is coupled to amplifier 70 at a given time and the other switches are open minded. By suitably sequencing the switches 66-68 to close, those in the sensing ink catchers 18-20 are generated and signals emitted on lines 37 to 39 are sequentially checked to determine which corrective action to take is necessary for a synchronization of the ink flow of the corresponding nozzle print head.

Although not shown, it is possible to control multiple nozzles by one crystal. When a nozzle in a nozzle group has is provided with a single crystal, the same can be used for synchronization. Then it could be a sufficient one Number of crystals can be used to provide the required number of nozzles. By combining a technique that many nozzles with one crystal used with in-line synchronization, as described above, is a sizable one Reduction in the cost of a synchronization device for a multi-nozzle Inkjet printer possible.

Although the techniques described so far sense the current by means of a direct current measurement, the same result can be achieved by using a non-contacting probe. This would give an AC measurement. The detector senses the sequence of charged drops of ink that electrically isolated a small one

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Sensors near the ink collector. These Method has the advantage that there is no contact with for cooling the ink is required, eliminating the risk of contamination consists.

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Claims (5)

PATENT CLAIMS Device for the synchronization of the drop formation with the charging of the ink drops in an inkjet printer with multiple nozzle printheads, each of which has a nozzle driven by a piezoelectric transducer existing vibration generator for the generation of a stream of ink droplets in mechanical vibrations is, a charging electrode for the electrical generated by charging signals in accordance with the information to be printed Charging of the individual ink droplets, a deflection electrode, through the generated electric field the charged ones Ink droplets are deflected onto the recording medium according to their charge, and an ink collecting diaphragm for receiving the ink drops not required for the printing process, characterized in that that the ink collecting diaphragms (18, 19, 20) generate signals corresponding to the charge of the received ink drops, which are fed to a detector circuit (41) which generates correction signals for said synchronization, and that between this detector circuit (41) and all the ink collecting diaphragms (18, 19, 20) an electronic circuit (40) is interposed, the successive during the successive synchronization intervals only one ink collecting aperture (18 or 19 or 20) is connected to the detector circuit (41). 2. Device according to claim 1, characterized in that one Control logic (31) is provided for the successive connection of the individual charging electrodes 10, 11, 12) associated charging electrode driver (22, 23, 24) to of each nozzle (6, 7, 8) to generate a group of drops, with a time interval between each group of drops, in which no charging takes place, that switching elements for synchronous activation of said electronic circuit (40) are provided for receiving the from h 0 9 8 1 5/1 0.1 5 LE 972 006 Ink collecting panels (18, 19, 20) generated signals during the time intervals in which the charged drops are received and that switching elements (26) to the detector circuit (41) are connected to correct the nozzles (6, 7, 8) associated with the crystal driver or the the charging electrode drivers (22, 23, 24) associated with the charging electrodes (10, 11, 12). 3. Device according to claim 2, characterized in that pairs of field effect transistors (QIl, Q21; Q12, Q22; Q13, Q23) are provided, each pair is followed by a switch (66, 67, 68) and all switches are controlled by the control logic ( 31) can be successively connected to a common amplifier (41). 4. Device according to claim 1, characterized in that the control logic (31) is designed so that the crystal driver and the charging electrode driver (22, 23, 24) are activated so that a synchronization process of a nozzle (6 or 7 or 8 ) is finished before the synchronization process of the next nozzle begins. 5. Device according to claim 1, wherein the individual drops are formed in limited time intervals, characterized in that that the control logic (31) is designed so that within this time interval in a first part the charging electrode drivers (22, 23, 24) and, in a subsequent part, the crystal drivers to achieve synchronization can be activated. 409815/1015 LE 972 OO6 ι * R e r s e ite