EP0094032A1 - Device for the ejection of ink droplets - Google Patents

Abstract

The channel (2) filled with liquid has a cross-sectional widening (4) at its end facing away from the outlet opening (3), at which the pressure waves emanating from a transducer (5) provided as a drive element are completely reflected by reversing the sign. Unipolar pulses with the same rising and falling edge are used as control pulses for the converter. The droplet is ejected by the pressure conditions at the outlet opening (3).

Description

The invention relates to an arrangement according to the preamble of patent claim 1.

From DE-AS 25 48 691 an arrangement for an ink mosaic writing device is known, in which an ejection of ink droplets is brought about by the fact that to initiate an ejection process a piezo transducer comprising an ink channel, hereinafter called transducer, by applying one of the directions of polarization of the transducer The voltage is first expanded, and then the voltage causing the expanding state is converted into a narrowed state by changing the polarity. The pulse provided for this is always a bipolar pulse. However, for reasons of a simple circuit structure and a reduced power requirement, it is very desirable to enable safe droplet ejection with simple control impulses that fully meet the requirements of today's printing technology. In this context, it also plays a role that the ejected droplets should be shaped so that they take on a spherical shape very quickly after their ejection, and further that subsequent droplets, even if they are released at close intervals, are influenced as little as possible.

The object of the invention is to provide an arrangement which meets these requirements. In particular, it is an object of the invention to use a unipolar Im pulses and thus simple circuits to enable the ejection of droplets that are ejected at high speed and quickly take on the shape of a sphere.

This object is achieved in accordance with the characterizing features of patent claim 1.

Further advantageous refinements are specified in the subclaims.

The advantages that can be achieved with the invention consist primarily in the fact that droplet ejection takes place with a unipolar pulse with the same edges, as a result of which a reduction in the drive voltage, i.e. a reduction in performance can be achieved that the pressure phases causing droplet ejection and thus also the processes triggering droplet ejection are precisely defined, which leads to a very rapid formation of spherical droplets. Another advantage associated with the invention is that the exact formation of the individual pressure phases in the region of the outlet opening of the channel means that the liquid lost due to the ejected droplet is replenished within a very short time, the processes necessary for this not being influenced by Surface tension is caused. In this way it is avoided that capillary forces have to bring about the refilling, as a result of which the idle state is reached more quickly and the influence of subsequent droplets is considerably reduced.

Another advantage of the invention is that the supply lines and ink supplies are decoupled from the processes in the channel without the need for expensive measures.

• Fig. 1 als Beispiel einen Tintenkanal,
• Fig. 2 in Form einiger Ablaufdiagramme den Zusammenhang zwischen einem Ansteuerungsimpuls und den, den Kanal durchlaufenden Druckwellen.

Details of the invention are explained below with reference to the drawings. Show

• 1 shows an ink channel as an example,
• Fig. 2 in the form of some flow diagrams the relationship between a control pulse and the pressure waves passing through the channel.

The ink channel 2 shown in Fig. 1 has at one end an outlet opening 3, the diameter of which is small compared to the diameter of the ink channel. A cross-sectional widening 4 is provided at its other end. The cross-sectional widening 4 represents a reflection termination of the channel 2, on which pressure waves are reflected with the sign reversed. This reflection takes place almost completely, see losses due to physical effects. In the example, the cross-sectional enlargement 4 is formed by the opening into a so-called ink supply chamber 6. This is what is not shown here, e.g. via a feed channel with an ink reservoir which is slightly lower than the outlet opening 3 of the ink channel. As long as no special influences or actions occur, this ensures that in the idle state, leakage of ink through the outlet opening 3 is reliably avoided. The ink channel 2 can advantageously be formed by a recess in a plastic part 1.

In the vicinity of the cross-sectional expansion 4, the ink channel 2 is surrounded by a transducer 5. It is a _ß polarized piezoceramic, which changes its diameter when actuated with appropriately polarized control pulses U. A voltage applied to the transducer 5 in the direction of polarization leads to a narrowing, while an opposite pulse Polarity causes an expansion of the converter. The converter has connections which connect it to a control circuit 7 via its electrodes. This can be controlled, for example, by the character generator of a printer and provides the correspondingly polarized control pulses U. The transducer 5 comprises the ink channel 2 only over an area b and is arranged at a distance a from the cross-sectional widening 4.

The processes triggered by the arrangement of the converter 5 according to the invention and the processes triggered by its control by means of unipolar control pulses, i.e. that is, the mode of operation of the arrangement according to the invention are also described below with reference to FIG. 2.

It is assumed that a unipolar control pulse U with the same steepness of the rising and falling edge and a polarity opposite to the direction of polarization of the converter 5 is applied to the converter at time t1, and that this pulse is switched off again at time t2 (FIG. 2, line 1). The result of this is that a negative part -pa of the wave w is generated in the ink duct 2 in the area encompassed by the transducer 5 due to its expansion, due to the polarity of the drive pulse U directed in the opposite direction to the polarization of the transducer 8 and 9 of the transducer 5 spreads both in the direction of the outlet opening 3 and in the direction of the cross-sectional widening 4. This propagation takes place at the speed of sound. The switching off of the pulse at time t2 has such a effect that the transducer 5 returns to its rest position and that the positive part + pa of the pressure wave w is generated, which also propagates in the ink channel 2 in both directions at the speed of sound (Fig. 2, line 2). These pressure waves w hit one assumed running time lw at times t4, t5 and t6 at the outlet opening 3 (FIG. 2, line 3).

The pressure wave propagating in the direction of the cross-sectional expansion is reflected on the cross-sectional expansion 4 with reversal of the sign. The resulting reflected pressure waves wr also move at the speed of sound through the ink channel 2 in the direction of the outlet opening 3. There they arrive at the assumed transit time lw + 21wr at times t5, t6 and t7 (FIG. 2, line 4). The pressure curve effective at the outlet opening 3 is determined by the unreflected pressure waves w and by the reflected pressure waves wr. The part of the non-reflected pressure wave w arriving first (FIG. 2, line 5, phase I) causes the ink to be drawn back into the outlet opening 3. The immediately following positive part of the non-reflected pressure wave w is overlaid by the also as a positive part of the incoming reflected pressure wave wr, which leads to a very high pressure rise in the area of the outlet nozzle 3 (FIG. 2, line 5, phase II) . The meniscus of the ink is thereby accelerated very strongly in the direction of the outlet opening 3, so that an ink droplet begins to emerge from the outlet opening at the later flight speed. Immediately afterwards, the negative part of the reflected pressure wave -wr occurs (FIG. 2, line 5, phase III), which has a negative pressure effect in the area of the outlet opening 3. This constricts the amount of ink accelerated to the outside during phase II and the droplet is separated. At the same time, a new meniscus forms, which retracts to the starting position. The rest position (Fig. 2, line 5, phase IV) is reached.

It is advantageous to determine the duration of the drive pulse U, i.e. the time period T between the expansion of the transducer 5 and the resetting of a greater or equal transit time of a pressure wave through the part of the ink-filled area of the ink channel enclosed by the transducer 5 corresponds to and that the time for the expansion and for resetting the transducer 5 itself is short compared to this term is.

Furthermore, it is advantageous to match the length b of the transducer 5, the pulse duration T and the distance a of the transducer from the cross-sectional expansion 4 so that the pressure wave w generated by driving the transducer 5 and the pressure wave reflected on the cross-sectional expansion 4 wr run at such a distance in the ink channel 2 that the pressure reduction in phase I, the pressure increase in phase II, the pressure reduction in phase III and then the idle state in phase IV occur in succession in the region of the outlet opening 3.

The time period for refilling the amount of ink ejected from the ink channel 2 is considerably reduced in the arrangement according to the invention, since the amount of ink required for the ejection was already largely provided during the first phase I. In practice, this means that the so-called spray frequency, ie the frequency with which successive ink droplets can be ejected, is essentially only limited by the ringing processes which usually take place in the ink channel. According to one embodiment of the invention, it is further proposed that the ink channel between the outlet opening and the transducer is delimited by a soft and damping channel wall. The channel can also be somewhat narrowed in the area in which it emerges from the area of the transducer with its hard channel wall, so that Pressure waves can propagate largely without reflection from the transducer into the ink channel, while at the other end of the channel they are reflected by the cross-sectional widening with sign reversal.

According to a further embodiment, in order to reduce or eliminate the ringing processes, it is also possible to apply compensation pulses to the transducer by twice the running time of a pressure wave from the outlet opening to the cross-sectional expansion after the start of the actuation pulse, which are caused by reflection at the outlet opening and by reflection the cross-sectional expansion largely extinguish such 'disturbing pressure waves that reach the area of the transducer. Such compensation pulses can e.g. the derivation of the control pulse are formed accordingly over time.

The invention has been described using an exemplary embodiment for a single ink channel. However, it is within the scope of the invention to design and control a large number of ink channels in the manner specified, and to arrange them overall in a multiple nozzle head. An ink mosaic scraper designed according to the features of the invention can then be produced in a particularly advantageous manner in the proven injection molding process.

Claims (10)

1. Arrangement for droplet ejection from a liquid-filled channel having an outlet opening, the channel being covered over part of its length by a piezoelectric transducer, the diameter of which changes when actuated by control pulses, and wherein to initiate droplet ejection one of the direction of polarization of the transducer the opposite polarized pulse is applied to the converter,
characterized in that the channel (2) has at its end facing away from its outlet opening (3) a cross-sectional widening (4) at which a pressure wave (pa) generated by actuation of the transducer (5) is completely reflected (pr) with sign reversal, and that the transducer (5) comprises the channel (2) in the vicinity of the cross-sectional extension (4). 2. Arrangement according to claim 1,
characterized in that the length (b) of the transducer (5), the pulse duration (T) and the distance (a) of the transducer (5) from the cross-sectional expansion (4) are coordinated with one another in such a way that the actuation of the transducer (5 ) generated pressure wave (pa) and the pressure wave (pr) reflected on the cross-sectional widening (4) by reversing the sign at such a distance in the channel (2) that in the area of the outlet opening (3) there is initially a pressure reduction (phase I), then a pressure increase (phase II), then a pressure decrease (phase III) and then the idle state (phase IV). 3. Arrangement according to claim 1 and 2,
characterized in that the transducer (5) with unipolar pulses with symmetrical An rising and falling edges is controlled. 4. Arrangement according to claim 1 to 3,
characterized in that the time period (T) between the expansion of the transducer (5) and the resetting is greater than or equal to the transit time of a pressure wave through the part (b) of the channel (2) enclosed by the transducer (5), and that the time for expanding and resetting the converter itself is short compared to this runtime. 5. Arrangement according to one of the preceding claims,
characterized in that after the initiation of droplet ejection (phase I), the ejection of a droplet from the outlet opening (3) takes place by switching off the pulse (U) (phases II and III). 6. Arrangement according to one of claims 1 to 5,
characterized in that the channel (2) is formed from an elastic material with damping properties. 7. Arrangement according to claim 6,
characterized in that the channel (2) has a slightly larger diameter in the area encompassed by the transducer (5). 8. Arrangement according to claim 1 to 7,
characterized in that the transducer (5) can be controlled by compensation pulses delayed with respect to a control pulse (U), in that the time delay is determined by twice the transit time of a pressure wave between the outlet opening (3) and the cross-sectional expansion (4) , and that the compensation pulses have a lower energy than the drive pulses. 9. Arrangement according to claim 8,
characterized in that the shape of the compensation pulses corresponds to the derivation of the drive pulses over time. 10. Arrangement according to one of claims 1 to 9, characterized in that a plurality of in each case an outlet opening (3) having channels (2) are provided, the ends facing away from the outlet openings (3) with a common, preferably as a supply chamber trained and liquid-filled area (6) are connected, these connections being the cross-sectional enlargements (4),
that each channel (2) in the vicinity (distance a) of the cross-sectional widening (4) is encompassed by a transducer (5) over part (b) of its length,
and that each converter (5) is connected to a control circuit that outputs the control pulses and, if necessary, compensation pulses.

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