EP0713773A2 - Microdroplets generator in particular for ink jet printers - Google Patents

Abstract

The system to generate micro drops, especially for an ink-jet printer, has a housing (1) with a chamber (5) containing a number of piezo electric bending transducers. The chamber (5) has dividing walls (26) between them at least near the second end (16), opposite the first end fixed to the housing (1). The dividing walls (26) are processed to give electroplated deposits of metal, or through anisotropic etching of monocrystalline silicon, or through photographic structuring of photo varnishes or films. The upper transducer surface has a cladding, which is not electrically conductive, such as of organically modified ceramics, an epoxy resin, an acrylate polymer or of polyurethane.

Description

From DE-OS 31 14 192 a drop generator for microdrops is known. A multiplicity of piezoelectric bending transducers are arranged in an ink-filled chamber of a housing, each of which is assigned to a nozzle leading through a housing wall. When a transducer is actuated, an ink droplet is ejected from the nozzle in question. This drop generator is simply constructed. However, the printed image is unsatisfactory, sometimes uneven and washed out. Similar drop generators are described in DE-OS 31 14 224 and DE-OS 31 14 259.

The present invention has for its object to eliminate the above disadvantage. This object is achieved by the combination of features of the claims.

Crosstalk between the adjacent transducers is completely avoided by the partition walls between the individual bending transducers. The partition walls reliably prevent ink from escaping from an adjacent nozzle when one transducer is actuated, because the pressure waves can no longer spread to the adjacent nozzle. In addition, the viscous coupling between adjacent transducers is completely avoided. The partitions also bring a significant increase in efficiency. Because the ink can no longer move sideways under the activated bending transducer, a considerably higher pressure is generated at the nozzle with the same deflection. Therefore, on the one hand, a significantly higher and more constant drop flight speed and, on the other hand, a lower power requirement can be achieved.

Figur 1

einen Längsschnitt durch einen Tropfenerzeuger,

Figuren 2a bis 2d

den Tropfenerzeuger nach Figur 1 in verschiedenen Betriebszuständen,

Figur 3

eine perspektivische Ansicht eines Teils des Tropfenerzeugers,

Figur 4

eine Draufsicht auf eine Düsenplatte, mit Trennwänden und Rahmen,

Figur 5

eine Draufsicht entsprechend Figur 4 mit eingesetzten Wandlereinheiten,

Figuren 6 bis 8

drei Ausführungsformen des Wandlers, und

Figuren 9 bis 11

drei Ausführungsformen mit mehrlagigen Tropfenerzeugern.

Exemplary embodiments of the invention are explained below with reference to the drawings. It shows:

Figure 1

a longitudinal section through a drop generator,

Figures 2a to 2d

1 in various operating states,

Figure 3

a perspective view of part of the drop generator,

Figure 4

a plan view of a nozzle plate, with partitions and frame,

Figure 5

3 shows a top view corresponding to FIG. 4 with converter units inserted,

Figures 6 to 8

three embodiments of the converter, and

Figures 9 to 11

three embodiments with multi-layer drop generators.

1-5 has a housing 1 consisting of a nozzle plate 2, a frame 3 and a cover plate 4, which together form a chamber 5. The nozzle plate 2 has, next to a wall 6 of the frame 3, a straight line of regularly spaced nozzles 7. The cover plate 4 has an inlet opening 8 opening into the chamber 5 for connecting an ink reservoir (not shown). A piezoelectric transducer unit 12 is fastened on a base 9 attached to or molded onto the nozzle plate 2 and arranged opposite the wall 6 and is positioned by means of interacting positioning means, for example by pins 10, which are inserted into bores in the base 9 and engage in bores in the unit 12 .

The unit 12 consists of a piezoceramic plate 13 which is laminated at the top with a thin metal foil 14 and at the bottom with a thicker metal foil 15. From the free end 16 through the nozzles 7 to the base 9, slots 17 are cut into this composite plate at regular intervals, e.g. ground with a diamond disc, so that the element 12 has a comb-like structure with a connecting web 18 over the base 9 and tines 19. The film 14 is interrupted on the web 18 in the extension of the slots 17, so that a film strip is formed for each tine 19. The film 15, on the other hand, is continuous on the web 18 and projects over the plate 13 on the end face. It is connected to a connecting line 20 for the return conductor. Each strip of film 14 is connected to a connecting line 21 for the outgoing conductor. As can be seen from FIGS. 3 and 4, partitions 26 connected on the end face of the nozzle plate 2 to a chamber wall 6, 25 are fastened, each separating two prongs 19 and being narrower than the slots 17.

The operation of the drop generator described is shown schematically in FIGS. 2a to 2d. FIG. 2a shows a prong 19 in the rest position. A negative pressure prevails in the liquid chamber 5, so that a concave meniscus 28 is formed in the nozzle 7, the capillary pressure of which is in equilibrium with the negative pressure. If a voltage is now applied to the connection 21, the piezoceramic layer 13 of the prong 19 tries to shorten under the influence of the electric field (cross-effect). This shortening is opposed by the thicker metal foil 15 with a greater resistance than the thinner metal foil 14, so that the tine 19 bends away from the nozzle plate 2 (FIG. 2b). The rate of deformation is selected by a suitable choice of the pulse shape at the connection 21 such that the liquid meniscus 28 in the nozzle 7 retracts only very little. When the pulse at connection 21 drops and the previously introduced electrical charge flows away, the tine 19 snaps back into the basic position (FIG. 2 c) and a drop 29 is ejected from the nozzle 7. Figure 3d shows the state shortly after the droplet ejection. The liquid meniscus 28 has withdrawn deeper into the nozzle 7. Liquid flows through the inlet opening 8 until the meniscus 28 has reached its equilibrium position again.

Because this tine movement takes place between two partition walls, pressure impulses can neither propagate to adjacent nozzles 7, nor can adjacent tines be co-excited by viscous friction. This avoids the risk of crosstalk. Since the liquid cannot escape laterally, a much better efficiency is achieved.

• Beschichtung mit flüssigen Reaktionsharzen durch Tauchen oder Aufsprühen mit anschliessendem Abschleudern der überschüssigen Menge und thermischer oder Strahlungshärtung,
• Beschichtung mit verdünnten Reaktionslacken durch Tauchen oder Aufsprühen mit anschliessendem Ablüften und Härten,
• Beschichtung mit pulverförmigen Thermoplasten durch Wirbelsintern, dabei Erwärmen des Piezokamms durch hochfrequente Wechselspannung.

The converter unit 12 preferably has an electrically insulating coating. For example, are suitable for this

• Coating with liquid reactive resins by dipping or spraying with subsequent spinning off of the excess amount and thermal or radiation curing,
• Coating with dilute reaction lacquers by dipping or spraying with subsequent flashing off and hardening,
• Coating with powdered thermoplastics by sintering, thereby heating the piezo comb by high-frequency alternating voltage.

As coating materials e.g. ORMOCERe (organically modified ceramics), epoxies, acrylates, polyurethanes and thermoplastic polymers are used. The selection depends on the working fluid used, since resistance of the coating to the fluid is required. However, the liquid must also wet the coated surfaces well, so that the chamber 5 of the drop generator can be vented properly.

The non-conductive coating means that even electrically conductive inks, e.g. Water-based inks, which are desirable in many cases in printing applications, can be used. In contrast, in the drop generators according to the prior art mentioned at the outset, only electrically non-conductive inks could be used. This restricted the area of application of these devices considerably. In addition, this property can make the ink considerably more expensive.

A bimorph bending transducer element 12 is shown in FIG. It consists of the piezoceramic layer 13, the relatively thick, thus bonded metal foil 15, which at the same time forms the electrode for the return conductor, and the electrode 34, which replaces the thinner metal foil 14 according to FIGS. 1-5. To generate high field strengths, however, as in the embodiment according to FIGS. 1-5, relatively high voltages are required. However, because of the very thin electrode 34, the required ones Tensions lower than in the embodiment according to FIGS. 1-5.

FIG. 7 shows a so-called SS-CMB (single sided ceramic multilayer bender). These transducers are described in "Actuator 94 Conference Proceedings", Bremen 1994 by J. Verkerk et al. described in more detail to which reference is made. The element 12 here consists of an active piezoceramic layer 35, a passive piezoceramic layer 36 and a plurality of electrode layers 37 which divide the layer 35 into several layers and are alternately connected to end metallizations 38, 39 and thus to the connecting lines 20, 21. The layers 40 of the layer 35 are alternately polarized in opposite directions. Because the field direction also changes from layer to layer, when a voltage is applied, the layer 35 as a whole becomes shorter or longer compared to the passive layer 36, depending on the polarity of the voltage applied. Due to the parallel connection of many thin piezoceramic layers (20-100 µm per layer) in the SS-CMB, relatively low voltages are sufficient to achieve high field strengths. As a result, the required pulse voltage for droplet ejection - depending on the thickness and number of layers - drops to around 20-40 V. Another advantage is that temperature fluctuations only cause negligible deflection of the tines, since apart from the very thin electrode layers (1 -2 µm per layer) only one material is used.

A symmetrical multi-layer bending transducer element 12 is shown in FIG. It is created by laminating two layers 45, 46 piezoactive materials with the same polarity direction. The outer electrodes 47 which are connected to one another by the end metallization 38 are connected to the return conductor 20 for all tines. The center electrode 48 is severed before the lamination of the second piezoactive layer 45 in the extension of the slots 17. When a voltage is applied between the center and outer electrodes, each layer will change in length transversely to the electric field in accordance with its direction, ie one layer shortens, the other expands. Since the layers are firmly connected to each other, the layer structure bends. With this construction, too, the tension required for deflection can be considerably reduced, because with the same tine thickness and tension, the field strength is doubled and both layers 45, 46 are active in the bending sense, while in the embodiment according to FIG. 6 the film 15 only acts passively .

For printing systems in use today with a printing screen of 300 dots per inch (dpi = dots per inch), the nozzles 7 and thus also the tines 19 must be arranged very closely. If the minimum size of the transducers allows, a one to two row arrangement should be aimed for. In the case of a two-row structure (FIGS. 4 and 5) for 300 dpi, the pitch of the tines 19 of a row is 1/150 ″ or approximately 170 μm. A 100 µm wide tine with a surrounding gap of 20 µm in width therefore requires the structuring of 30 µm thick partitions. In order for the individual tines to be able to transfer enough kinetic energy into the ink, they must be a multiple of this width high, e.g. they can have a height-to-width ratio (aspect ratio) of 5: 1. As a result, the partition walls 26 have to be designed with much larger aspect ratios. Suitable techniques are available today, such as the LIGA process or anisotropic etching of silicon single crystals. These methods are described in W. Menz, P. Bley; Microsystem technology for engineers, Weinheim 1993 described. Other suitable processes for the production of the partition walls are, for example, the electrodeposition of metals onto the nozzle plate 2, the stamping or injection molding, in which case the molds can be produced using the LIGA process. In particular in the case of production by injection molding, the partition walls 26 can be formed in one piece with the nozzle plate 2, the frame 3, the base 9 and, if appropriate, the intermediate wall 25 (FIG. 4). Other suitable methods for producing the partition walls 26 are the photolithographic structuring of photoresist lacquers or foils.

For connecting the lines 21, 22, e.g. the tape automated bonding process.

The embodiments according to FIGS. 9-11 show variants in which the housing 1 contains a plurality of staggered chambers 5, each with a converter element 12 according to FIGS. 1-3 or according to one of FIGS. 6-8. The axes of the nozzles 7 are inclined at least at the outlet end or at right angles to the direction of movement of the tine ends 16. The nozzles 7 are narrowed towards the outlet cross section. The nozzles 7 of the different rows are slightly offset from one another in the longitudinal direction of the rows.

In the embodiment according to FIG. 9, three identical housing elements 55 corresponding to FIG. 1 but with thicker nozzle plate 56 and an additional nozzle plate 56 are stacked on top of one another. The nozzle channel 57 is bent at a right angle. An additional channel 58 connects the inlet opening 8 to a distribution channel 59 in a cover plate 60.

In the embodiment according to FIG. 10, the axes of the nozzles 7 run at 45 ° to the direction of movement of the tine ends 16.

In the embodiment according to FIG. 11, four rows of nozzles 7 are arranged in a continuous nozzle plate 65 and the tine ends 16 are ground off at 45 °, so that their end faces 66 run parallel to the plate 65. When the tines 19 are deflected, the ends 66 therefore have a movement component perpendicular to the plate 65. The chambers 5 here have lateral connections which can be connected to the storage container via a distributor line. However, the connections can also be connected to a separate container, wherein the containers can contain inks of different colors, so that the drop generator is also suitable for multi-color printing. This variant is also possible in the embodiments according to FIGS. 9 and 10, in that the distributor plate 60 is omitted and the channels 58 are connected to separate containers.

With the embodiments according to FIGS. 9-11, a large number of nozzles 7 can be accommodated in a very small space, so that excellent print quality is made possible.

Claims (13)

Drop generator for microdrops, in particular for ink-jet printers, comprising a housing (1) with a chamber (5), a plurality of piezoelectric bending transducers (19) in the chamber (5), the first end (18) of which on the housing (1 ) and one nozzle (7) each in a chamber wall (2) under the free second end (16) of the transducers (19), characterized in that the chamber (5) is at least adjacent to the second end (16) of the transducers (19) is divided by partitions (26) between these transducers (19). A drop generator according to claim 1, wherein the first ends (18) of the transducers (19) are connected to one another so that the transducers (19) form a comb-like transducer unit (12). A drop generator according to claim 1 or 2, wherein the ratio of the height to the thickness of the partition walls (26) is 10-100. Drop generator according to one of claims 1-3, wherein the partition walls (26) by electrodeposition of metal or by anisotropic etching of monocrystalline silicon or are produced by injection molding or by embossing or by photographic structuring of photoresist lacquers or foils. A droplet generator according to any one of claims 1-4, wherein the partitions (26) are integrally connected to a nozzle plate (2) through which the nozzles (7) extend. A drop generator according to any one of claims 1-5, wherein the end faces of the second ends (16) of the transducers (19) are at a distance from a chamber wall (6) which is at most five times the space between transducers (19) and partition walls (26) . Drop generator according to one of claims 1-6, wherein the nozzles (7) are narrowed against their outlet cross-section. Drop generator according to one of claims 1-7, wherein the surfaces of the transducers (19) are provided with an electrically non-conductive coating, which preferably consists of ORMOCER material or of epoxy resin or of an acrylate polymer or of polyurethane. Drop generator according to one of claims 1-8, wherein the transducer (19) and the housing (1) have interacting positioning elements (10). Drop generator according to one of claims 1-9, wherein the transducer (19) as a multi-layer piezoceramic transducer with a additional passive piezoceramic layer or as a symmetrical multi-layer bending transducer. Drop generator according to one of claims 1-10, wherein the transducers (19) in their basic position in the region of their second ends (16) are at a distance from the nozzle plate (2). Drop generator according to one of claims 1-11, wherein in the housing (1) a plurality of staggered chambers (5) are formed, each containing a series of transducers (19), partitions (26) and nozzles (7), the axes of the Nozzles (7) are inclined at least at the outlet cross section or run at right angles to the deflection direction of the second transducer ends (16). A droplet generator according to any one of claims 1-12, wherein the end faces of the second ends (16) of the transducers (19) are cut at an angle to the longitudinal direction of the transducers (19).

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