DE2221477C3 - Device for recording information by means of ink drops - Google Patents

Description

The invention relates to a device for recording information by means of a with predetermined frequency and phase vibrating nozzle of ejecting ink, which is through a with video pulses Controlled charging device for the electrical charging of ink drops and then is passed through an electrical deflection field, with one in the direction of the ink flow onto the AIv Steering field following interception device for a phase position outside of the video pulse intervals marked ink drops and a circuit controllable with the collecting device for generating VihratUmssignalen with two possible Phases.

In known recording devices, for example known from U.S. Patent 3,465,350, a conductive liquid is made from a Nozzle opening delivered, which with vorhesiimmier Speed and suitable amplitude vibrates, so that the liquid jet emerging from it in uniform drops with one of the vibration

1.5 speaking frequency is divided. Above the area where the drops separate from the jet, there is usually an arrangement in the form of a charging tunnel, which is an electrostatic Charging of the drops when they are separated from the

aa liquid jet generated. To load the To apply drops, the charging field must be maintained during the process of separating the drops will. In order to apply certain charges to given drops, the moment must

be known as the separation of the respective drop.

. U.S. Patents 3,465,350 and 3,465,351 describe systems for correcting the phase with which the flow of ink onto a target surface must occur before it is passed on to record a line of characters. These systems work satisfactorily, but it would be more beneficial to phase correct the drops during the Recording time, as an incorrect phase condition occurs during this interval and could be retained until the end of a written line. When the phase correction can be carried out at the required moment while the Sthrcibvorgang is running, so time required for phase checking is also avoided, so that the recording is faster is feasible

A device of the type mentioned at the beginning is known from the German Offenlegungsschrift I 960 522, which can meet these requirements, but this is very complicated and expensive to build. the Identification of incorrectly generated and charged ink drops with regard to their phase position takes place by signal pulse trains of a particular frequency, which is evaluated by a particular piezoelectric Transducer arrangement is acted upon by the ink droplets and a voltage with the or a different frequency is generated. There are special signal generators for this and control circuits that already exist Their own tolerances alone mean that there is no constant guarantee in every operating state guarantee.

The task of the invention is to provide a facility to record information by means of ink drops, in which a continuous Checking the phase correction and carrying out such corrections during the recording process is possible and which is characterized by a particularly simple structure with increased operational safety excels.

A device of the type mentioned at the beginning is characterized according to the invention in order to achieve this object by an arrangement for generating a

Tesi pulse immediately before and immediately after d <-Mn interval of each video pulse with one compared to the largest video pulse amplitude, the greater test pulse amplitude, next to the video pulses is supplied to the charging device correspondingly sized to its amplitude charge, and by arranging the catching device on one only by controlling by means of the test pulse charged ink droplets reachable point.

With a device according to the invention, optimum freedom from defects is achieved with the least possible effort the phase position of the ink droplets guaranteed. By the interval of each video pulse The characteristic test pulse is the video waveform relative to the generation of the ink droplets characterized in such a way that a reliable removal of incorrectly generated ink droplets is possible. In addition to the subdivision of the video signal course, the test pulse is used to identify the Incorrectly generated ink droplets used by particularly strong charging. Thus it is possible to arrange the catching device in a place where only those marked by their high charge strength Ink drops may appear.

An embodiment of a device according to the invention is shown below with reference to the figures described. Show it:

Fig. 1 is a block diagram of the function of a Device according to the invention and

2 shows an illustration of the waveform of the test pulses and the video signals.

In Fig. 1 is a block diagram of an ink drop writing system according to the invention is shown, with a determination is possible at any time whether the drops have their correct phase position relative to the Have video signals. A video signal source 10 which supplies information signals to be recorded is connected to a video editing circuit 12. This converts the video signals into video pulses um, the amplitude of which determines the point at which a drop is deposited on a recording medium will. The processing circuit 12 thus converts the video signals fed to it into such signals that can control the charging of an ink droplet flow. In this way they affect Signals a deposition of a drop pattern on the recording medium, for example in the form a letter, number or waveform so that the recording is a reproduction of the Represents video signal. The conditioning circuit 12 is controlled with clock pulses to clock the frequency of their output signals, these clock pulses are derived from the second and third counting step output of a counter 14, which is a factor of 4 is. This counter is a cyclic counter which is controlled by clock signals from a clock signal source 16. The signals at the second and third counting step output of the counter 14 are transmitted via an OR gate 18 the processing circuit 12 is supplied as clock signals. These signals are also an OR gate 20 supplied to which the output pulses of the conditioning circuit 12 are also supplied.

The output of the OR gate 20 is a pulse train with that shown in FIG. 2 course. the The first counting step of the counter 14 is represented by the pulse 22. During the next two counting intervals a video pulse 24 occurs, the amplitude of which is determined by the video signals. This amplitude changes, so that different deflections of the ink drops are generated, for which purpose these are charged proportionally to the amplitude. The last high amplitude pulse 26 corresponds to the last counting step of the counter 14. It should be noted that the first and the last Counting steps of the counter 14 corresponding to the pulses 22 and 26 have a much higher amplitude than that Have video signals 24.

The output signal of the OR gate 20 is fed to a video amplifier 28, the output signal of which is performed on a loading tunnel or loading ring 30.

The ink is supplied from a pressure vessel 32 to a nozzle 34. The nozzle is using clock frequencies vibrated by a tuned amplifier and driver circuit 36. Through this For example, the ink is dispensed in the form of a flow 38 from the nozzle 34, within the flow Drops 40 formed in the charging tunnel 30. The sir flow is fed into the pressure vessel by c! .. Pressure emerge from the tunnel and then passes between two plates 42 and 44 the recording medium 48. The disks carry a voltage which is generated by a high-voltage source 46 is produced. The charged drops are created by an electric field between the two plates guided and according to the amplitude of the charge that is applied to them within the ring 30 was distracted. Then they fall onto a recording medium 48 at a point which is marked by the Deflection of the drops during their passage through the field between the two plates 42 and 44 is determined. Those drops that are not used for recording end up in one Collection container 50.

From Fig. 2 it can be seen that the respective drop for correct charging in the tunnel 30 during of the interval in which the video pulse is applied to the tunnel 30. This is in Fi £. 2 represented by the video period. the Time at which the drop is formed, or more precisely the interval of the drop separation within the Tunnels, is not necessarily specified, but can lie within an interval which is shown in FIG. 2 as Drop period is designated. Any drop that formed within the interval of the test pulse 26 does not receive a video pulse charge and is lost for writing.

The interval of drop formation is a function of the frequency and phase at which the nozzle 34 vibrates. These quantities are in turn determined by the frequency and the phase of a signal that the driver circuit 36 controls. It should also be noted that if drops are formed with defective phase, the droplets formed thereafter are out of control until the driver circuit is restored Provides signals that are in phase with the video signals.

The arrangement for phase correction according to the invention consists of two electrodes 52 and 54 placed between the recording medium 48 and the deflector plates 42 and 44 are arranged and are aligned with the deflection area of such drops which were charged by one of the test pulses 22 and 26. These drops are very strongly charged and stronger than through the video impulses with the highest possible amplitude. The electrodes 52 and

54 are so close together that they .through such charged drops are bridged wcr-lines. The electrode 52 is grounded, the electrode 54 is connected to a transistor switch 56. Becomes a charged drops of conductive ink are brought between the two electrodes 52 and 54, the Base of the transistor switch 56 momentarily grounded, so that a pulse signal a pulse shaper and Amplifier 58 is supplied. The output signal of this circuit controls a flip-flop circuit 60.

The exit C? the flip-flop circuit 60 is connected to a NAND gate 62. The output ~ Q of the flip-flop circuit 60 is connected to a NAND gate 64. This is turned on and forwards the clock pulses of the output signal of the OR gate 18 when an input signal ~ Q is present. These clock pulses are also fed to a NAND gate 66 which operates as an inverter. If an output signal Q is present at the flip-flop 60, the NAND element 62 is opened and forwards the output signal of the NAND element 68 when a signal corresponding to the fourth counting step of the counter 14 occurs.

The output signals of the NAND gates 62 and 64 are fed to a NAND gate 66. Its output signal consists either of pulses from the NAND gate 62 or from pulses from the NAND gate 64. So it either delivers clock pulses in phase with those generated by counting steps 2 and 3 of the Counter 14 generated clock pulses or clock pulses out of phase with the through the counting steps 2 and 3 of the counter 14 generated clock pulses. The output of the NAND gate 66 controls the tuned Amplifier 36 with which the nozzle 34 is in turn driven.

From the above description it can be seen that that in the event of a drop formation during the video signal interval, the nozzle 34 is in the correct phase and frequency vibrates and no change in the signal controlling the driver amplifier 36 is generated. If a drop is generated in an interval outside the video pulse interval, it will receive one ίο Charging with high amplitude by a test pulse and thus activates the switching system described. creating a phase shift of half a drop period of 180 ° and the driver amplifier 36 controlled accordingly. This means that the drops generated thereafter are in phase with the Video loading signals brought.

If desired, a drop can be removed from electrodes 52 and 54 by removing the electrode 52 is somewhat porous and a vacuum pump 53 ao is connected to its rear side, which has a bridging Sucks out ink droplets.

The system described above corrects the phase at which ink drops are generated any time during the recording interval, there is no special time to phase check Drops generated with defective phase required. The system can be used with stationary and movable print heads are used, as a continuous phase check takes place. Therewith the overall result is a more uniform, sharper and more faithful recording quality, combined with a more economical mode of operation compared to known arrangements.

1 sheet of drawings

Claims (4)

Patent claims: 1. Device for recording information by means of a nozzle that vibrates at a predetermined frequency and phase Ink fed by a charging device controlled by video pulses for electrical charging is guided by ink droplets and then through an electric deflection field, with an in Direction of the ink flow on the deflection field following interception device for a phase position outside of the video pulse intervals marked ink drops and a circuit controllable with the collecting device for the generation of Vihrationssignalen with two possible phases, marked by an arrangement (14, 16) for generating a Tesi pulse (22, 26) immediately before and immediately avenge the interval of each video pulse (24) with a test pulse amplitude greater than the largest video pulse amplitude, the charge measured in addition to the video pulses for its amplitude the loading device (30), and by the arrangement of the collecting device (52, 54) on an ink droplets charged only by control by means of the test pulse reachable place. 2. Einricr'ung according to claim 1, characterized in that that the collecting device (52, 54) is formed from two conductive electrodes. whose distance can be bridged by a captured ink drop. 3. Device according to claim I, characterized in that the circuit (56, 60, 62, 64) for generating the vibration signals comprises a flip-flop circuit (60), the two outputs of which are connected to one input of two NAND gates (62, 64), whose other inputs can be controlled by clock signals or clock signals carried by an inverter (68) are that the outputs of the NAND gates (62. 64) to the control inputs of a further NAND gate (66) which supplies the vibration signals and that the flip-flop circuit (60) is controlled by the collecting device (52, 54). 4. Device according to claim 3, characterized in that that the clock signals are also fed to a video processing circuit (12) supplied by a video signal source (10) and video signals to be recorded in video pulses for controlling the charging device (30) converts.