WO1989008560A1 - Continuous ink jet printing device - Google Patents

Abstract

A continuous ink jet printing device comprises a nozzle plate (1) and a pair of electrode assemblies (EB, LB) which are located relatively to the nozzle plate, at least in its direction perpendicular to the direction of the ink jet, by respective engagement with dowels (6, 7) formed rigidly with the nozzle plate.

Description

DESCRIPTION

CONTINUOUS INK JET PRINTING DEVICE

Downstream of the nozzle(s) of a continuous ink jet printer/ are mounted at least one charge electrode, at least one deflection electrode and a gutter; and there may be other items such as a phase detector and/or position detector. These items, particularly the charge electrode (s) must be very accurately located relatively to the ink stream(ε) in order to provide consistent and reliable operation.

In the past this has been achieved by accurate manufacture and assembly of both the individual components and of the mounting chain between nozzle (s) and electrode (s) , often combined with the provision of multiple fine manual adjustments. This has led to high manufacturing costs and to the need for accurate adjustment both on original setting up and during field service.

In accordance with the present invention, a continuous ink jet printing device comprises a nozzle plate with at least one nozzle from which, in use, a jet of ink drops is ejected, and an electrode assembly with at least a drop-charging electrode, the electrode assembly being located relatively to the nozzle plate, at least in directions perpendicular to the direction of the ink jet(s), by virtue of one of the electrode assembly and nozzle plate being rigid with at least one rigid location member, and by virtue of one or more complementary portion(ε) rigid with the other of the electrode assembly and nozzle plate engaging directly the location member (ε).

This construction facilitates accurate location of the electrode assembly relative to the nozzle (ε) with a minimum of precision manufacture, and requiring little or no adjustments. Thus the nozzle opening(s) may be drilled in the nozzle plate in positions accurately related to the location member(s) or to complementary portion(ε) which engage(s) the location member(ε) by supporting the nozzle plate in a jig which provides a facsimile of the location member(s) or which provides parts to hold the location member (s) if the location member (ε) iε/are already rigid with the nozzle plate. Similarly, the electrode assembly will be assembled, i.e. the charge electrode(ε) and other partε will be mounted on a support body of the electrode assembly, using a jig which provides a facsimile of the location member (s) or which provides partε to hold the location member (s) if the location member(ε) is/are already rigid with support body. When the nozzle plate and electrode aεεembly are then assembled for use, it iε only neceεεary, e.g., to provide or mount the location member(ε) on one of the partε and to bring the other part into engagement with the location member (ε). The location member(s) is/are conveniently one or more rails extending εubεtantially parallel to the direction of the ink jet(ε). Preferably the or each rail iε a cylindrical metal dowel. Thiε may be fixed in a hole in the nozzle plate.

The nozzle plate and electrode aεεembly could both finally be fixed to the location member(ε). However, one of the nozzle plate and electrode aεsembly may have one or more location member-engaging portions in the form of an opening through which the or a respective location member slides, or some meanε of abutment with the location member (ε) which gurantees its position laterally of the ink jet(ε), and its attitude, relative to the location member(s) and hence to the other of the nozzle plate and electrode assembly. For example, when the location member (s) include(ε) at least one rail, a complementary abutment portion may in the form of a groove of V-shaped cross-section receiving and being urged against a longitudinal edge of the rails. Another abutment portion, which may be a flat surface, may be urged against the other rail. This provides very simply positive location of the part relatively to the rail in all directions transversely to the rail, and against twisting about axes both longitudinally and tranεverεely of the rail, i.e. location in all degreeε of freedom except tranεlational movement along the rail parallel to the ink jet(ε). In practice this is the least important degree of freedom in which location iε to be provided, both becauεe it iε leεs critical in operation, and alεo becauεe εome adjuεtment of the deflection electrode (ε) along the ink jet may in any caεe be neceεεary to accommodate different inkε which break up into droplets.

However, if relative tranεlational movement between the nozzle plate and electrode aεεembly in a direction parallel to the ink jet(ε) is alεo to be limited, thiε can alεo be provided by abutment of the complementary portions of the nozzle plate or electrode assembly with the location member (s) for example by providing a three point contact, at least two each consisting, for example, of a projection urged into nesting engagement with a recess.

Alternatively, it could be achieved by a modification of the V groove solution if an additional engagement is provided to limit movement of the rail along the groove.

The abutment arrangement iε useful for the electrode assembly when the electrode assembly iε to be retractable laterally away from the ink jet(ε), for example to provide access to the nozzle(s), or upon start up or when cleaning iε required. This iε because the electrode aεεembly can be loosely mounted on a carrier and arranged automatically to locate itself in its correct position as the complementary portion comes into abutment with the location member, preferably under the action of a spring acting between the carrier and the electrode asεembly.

The engagement between the electrode aεsembly and carrier, although allowing relative movement in the degrees of freedom which are to be limited by the engagement with the rail(ε) or other location member(s), may provide another solution for limiting the relative tranεlational movement parallel to the rail(s). For example, the carrier may be provided by pivoted arms, which are arranged one on each side of the electrode aεεembly, and provide rotational loεt motion couplingε, εuch as pins and slotε, or εliding ball jointε, with respective ends of a body of the eletrode asεembly. The carrier may be reciprocatable on a slide, but iε preferably pivotally mounted so that it can εwing about an axiε which may be parallel or perpendicular to the jet direction.

In multijet systemε, a deflection electrode iε frequently comb-shaped, one jet paεεing between each adjacent pair of comb teeth. In order to avoid interception of the jetε by the comb teeth, owing to lateral offset of the electrode asεembly aε it iε brought into itε working poεition, and before the rail fully engageε the V groove, lead-in εurfaceε may be provided on one of the electrode aεεembly and nozzle plate to engage the other to centralize the comb relatively to the ink jets as they approach one another.

When the rail and V groove construction iε uεed, there will normally only be one V groove engaging one rail, a flat portion, for example at the bottom of a εlot, εide εurfaceε of which provide the lead-in εurfaceε for lateral centralization with the comb-εhaped eletrode, engaging another rail. The electrode aεεembly may be in the form of two εeparate εub-aεεemblieε having respective carriers which are retractable on opposite sideε of the ink jet(ε) and of the location member (ε) . Each of the εub-aεεemblieε may then be provided with one of the V grooveε for engagement with a respective rail, but usually only that carrying the charge electrode, particularly when thiε is comb-εhaped, will need to be provided with the lead-in εurfaceε for lateral centering aε the sub-assemblies are advanced.

Some examples of printing devices constructed in accordance with the invention are illustrated diagrammatically in the accompanying drawing, in which:-

Figure 1 is an underneath view of a nozzle plate;

Figure 2 iε a εide view of the nozzle plate shown in Figure 1; Figure 3 is a plan of one electrode sub-aεse bly;

Figure 4 is a front elevation of the electrode sub-aεsembly;

Figure 5 iε a plan of another electrode sub-assembly;

Figure 6 is a front elevation of part of a print head;

Figure 7 is a εide elevation of the part of the print head; Figure 8 iε a front elevation of part of another print head;

Figure 9 is a side elevation of the part shown in Figure 8;

Figure 10 is a plan showing the juxtaposition of two electrode εub-aεsemblies of a print head; and

Figure 11 iε a perεpective view of a print head. For eaεe of deεcription the device will be described oriented such that the ink jets are directed vertically downwardly, although the device may be used in a different orientation.

As shown in Figures 1 and 2 a nozzle plate 1 is provided with two accurately positioned and aligned dowel holes 2, 3 set one at each end of a line of nozzle orifices 4. These orifices are formed in the plate accurately positioned relatively to the master dowel hole 2 and to the line between the dowel holes and with their axes aligned relatively to the dowel holes or to the face 5 of the nozzle plate. This can readily be achieved with an appropriately designed jig and forming machine. A multinozzle plate requires accurate pitching and alignment of the orificeε in any event. Dowelε 6 and 7 may be inεerted into the dowel holes 2, 3 prior to forming the orifices 4 and use for location, or may be inserted afterwards in which case the holeε will have been uεed for location. Figureε 3 and 4 illuεtrate one electrode sub-asεembly compriεing a "live" block onto which charge and deflector electrodes 9 and possibly other items are mounted. The block is provided with complementary parts engaging the nozzle plate dowels 6, 7 and comprising a straight V groove 10 which receives the master dowel 6 and a flat 11 which engages the other dowel 7. During assembly the block 8 is mounted in a jig on a facsimile of the nozzle plate dowels and electrodes etc. are accurately located in the jig and secured to the body by means, such aε potting. Thuε when the block iε offered to, and urged against, the nozzle plate dowelε, the electrodes will be accurately positioned relatively to the orifices 4 except in a direction parallel to the dowelε, i.e. to the ink streams. In other words, the sub-assembly will be located against twisting about any of three perpendicular axeε parallel or perpendicular to the ink jets, and against translational movement in any direction perpendicular to the ink jets.

As shown in Figure 10, there will normally be two of the sub-aεεemblieε εimilar to that εhown in Figureε 3 and 4, and these may be termed a "live" block LB fitted with the charge electrode and live deflection electrode and an "earth" block EB fitted with the earthed deflection electrode. The block LB is shown having a V groove 10 providing the essential location with the master dowel 6 and the block EB having a V groove 10A engaging the dowel 7. This iε the preferred arrangement as it is the live block carrying the charge electrode which requires the more precise location. This is particularly so when, as shown in Figure 5, a charge electrode 12 haε a comb-like shape such that each ink jet 13 passes through a respective slot between adjacent teeth of the comb with a very small lateral clearance. When such an electrode is being moved towards running jets it must be reasonably accurately located laterally even before the V groove 10 engages the master dowel 6. Thiε location may be provided by providing lead-in surfaces at the entrance to a groove 14, the depth of which is such that the lead-in surfaces engage the secondary dowel 7 before the comb engages the jets, and the separation of which limits lateral movement to prevent the jets touching the comb whilst allowing the V groove 10 to take over the lateral location once it engages the master dowels. Alternatively, and preferably, as shown at the top of the sub-aεεembly LB in Figure 10 a groove 14A providing the lead-in surfaces may alternatively be provided at the entrance to the V groove 10. It is acceptable to allow slight lateral movement of the block EB and the groove 10A could be omitted so that both sides of the block EB engage the dowels 6 and 7 in similar faεhion.

Although the electrode εub-aεsemblies LB and EB may be advanced and retracted relatively to one another and to the dowelε 6 and 7 by a linear slide mechanism, a pivotal arrangement iε preferred. Thuε aε shown in Figureε 6 and 7, the "live" block LB iε mounted on a εwinging carrier 15 formed of bent εheet metal and pivotally mounted at itε upper end about a horizontal pin 16. The block LB haε, at each end, projecting pinε 18, which are rotatable in, and εlidable horizontally along, respective elongate slotε 19 adjacent to the bottom of the carrier. The diameter of each pin 18 is insignificantly smaller than the width of each slot 19, whereby the block LB is free to rotate and twist relatively to the carrier 15, but the carrier provides location against translational movement of the block in the vertical direction, i.e. parallel to the dowels 6 and 7 and to the ink jets. The carrier 15 may be latched in itε illustrated operative position by rotating a rod 23 about an axis 24 so that it rides down a cam surface 28 of a cam 26 fixed to the carrier 15, and into a notch 25. Springs 17 acting between the back of the carrier and the block LB then urge the block to abut the dowelε 6, 7 by meanε of the V groove 10 and flat 11, the εub-aεεembly LB automatically accommodating itself into the predetermined poεition relatively to the jetε irrespective of looseneεε between the block and carrier and of any loosenesε or toleranceε in the mounting or conεtruction of the carrier. The εub-aεεembly engageε the dowelε before the rod 23 iε fully home in the notch 25, εo that the final movement of the rod 23 progreεεively co preεεeε the εpring 17 to provide both the engagement and latching forces.

As described with reference to Figure 10, there will normally be two εub-aεsemblieε LB and EB, although only one is shown in Figure 7. This will be clear from Figure 11 which shows a print head in accordance with the invention, although the individual parts, such aε the electrode assemblies and their carriers are shown to have shapeε different from the diagrammatic representations in the other views. Figure 11 shows wiring 30 for conducting electrical control signals to a vibrator for forming the ink jets and to the electrodes, and ducting 31 for the supply and recirculation of ink.

As previously mentioned, the location provided by the carrier 15, i.e. in the vertical direction, iε in the leaεt critical direction. It may in any caεe be neceεεary to provide adjuεtment in thiε direction relatively to the nozzle plate 1 and εuch an adjuεtment iε conveniently provided by moving the pivot pin 16 relatively to the drop generator body 29, which carries the nozzle plate 1.

Figureε 8 and 9 εhow an alternative method of supporting a sub-assembly LB or EB on a carrier 15. In this case, instead of the pins 18 and slotε 19, εlotε 22 in the εub-asεe bly receive reεpective part-spherical ends 20 on pins 21 fixed to the carrier 15a. The εlotε 22 have dimenεionε greater than the diameter of the sphere in both tranεverse directions, however, vertical location iε again provided.

With the carrier providing the full location in the vertical direction, there iε a degree of overlocation in that both the carrier and the V groove are εetting the paralleliεm of the electrode εub-aεεembly to the nozzle plate. Any problem here can be minimized by keeping the length of the V groove short, and thiε will alεo help with the theorectical overlocation between the length of the V and the length of the flat. An alternative iε to uεe the carrier to locate one end only of the εub-aεεembly block in the vertical direction, and where the V groove can be εufficiently long, this would be practicable. In the Figures 8 and 9 example, it could be implemented by reducing the diameter of one of the part spherical ends 20, εo that it εupportε the diεengaged εub-assembly block, but the V groove takes control once it has been engaged.

If, in Figure 7, the pivot 16 is moved to position 27, then swinging of the carrier after the sub-asεembly LB haε engaged the dowelε will produce axial movement of the sub-asεembly along the dowelε. If the latching position is not accurate then this movement is undesirable, but if the latching position is adjustable, then it could provide the adjustment in the drop break-up length previouεly mentioned.

Claims

C ΔLtlϋ

1. A continuous ink jet printing device comprising a nozzle plate (1) with at least one nozzle (4) from which, in use, a jet of ink drops is ejected, and an electrode assembly (LB) with at least a drop-charging electrode (9), the electrode assembly being located relatively to the nozzle plate, at leaεt in directionε perpendicular to the direction of the ink jet(ε), by virtue of one of the electrode aεεembly and nozzle plate being rigid with at leaεt one rigid location member (6,7), and by virtue of one or more complementary portion (s) (10,11) rigid with the other of the electrode assembly and nozzle plate engaging directly the location member (s).

2. A device according to claim 1, in which the location member(ε) is/are one or more rails (6,7) extending substantially parallel to the direction of the ink jet (s) .

3. A device according to claim 2, in which the or each rail is a cylindrical metal dowel (6,7).

4. A device according to claim 3, in which the dowel (6,7) is fixed in a hole (2,3) in the nozzle plate (1).

5. A device according to any one of claims 2 to 4, in which the complementary portion is in the form of a groove (10) of V-shaped crosε-εection receiving and being urged againεt a longitudinal edge of the rail (6).

6. A device according to claim 5, in which another complementary portion (11) iε urged against another rail (7).

7. A device according to claim 6, in which the another complementary portion (11) is flat.

8. A device according to any one of the preceding claims, in which the electrode assembly is loosely mounted on a carrier (15) and arranged automatically to locate itself in its correct position as the complementary portion(s) come(s) into engagement with the location member(s).

9. A device according to claim 8, in which the electrode assembly locates itself in itε correct poεition under the action of a εpring (17) acting between the carrier and the electrode aεεembly.

10. A device according to claim 8 or claim 9, in which the carrier is provided by pivoted arms (15) , which are arranged one on each side of the electrode assembly, and provide rotational lost motion couplings with respective ends of a body of the eletrode assembly.

11. A device according to claim 10, in which the carrier is pivotally mounted so that it can swing about an axis which is parallel or perpendicular to the jet direction.

12. A device according to any one of claims 8 to 11, in which the electrode asεembly iε in the form of two separate εub-aεsemblies (LB,EB) having respective carriers which are retractable on opposite εideε of the ink jet(ε) and of the location member(s).

13. A multijet device according to any one of the preceding claimε, in which a deflection electrode iε comb-εhaped, one jet paεεing in uεe between each adjacent pair of comb teeth, and there are lead-in εurfaces (14,14A) on one of the electrode assembly and nozzle plate to engage the other to centralize the comb relatively to the ink jets as they approach one another.

14. A device according to claim 13, when dependent at least on claim 6, in which the another complementary portion (11) is at the bottom of a slot (14) , side εurfaces of which provide the lead-in εurfaces for lateral centralization with the comb-εhaped electrode aε the another rail (7) rideε past the lead-in surfaces.