AU592958B2 - Droplet stream alignment for jet printers - Google Patents

Description

1. 11 11 1 iiiiiiiiiiiiiii1r. COMMONWEALTH OF AUSTRALIA PATENTS ACT 1952-1962 COMPLETE SPECIFICATION

I

I

I

I

I

41 (Ori gi nal FOR OFFICE USE: 4 7.4/03-.

Class Int. Class Application Number: Lodged: 0* *0.

Complete Specification Lodged: Accepted: Published: Priority: T'his docuinient contains the amendmnents made und;kr Section 49 and is cor,,ect for printing.

Related Art:

S.

*5 0 0 *OSO@0

S

S. 0* 0*

S

555 Name of Applicant: Address of Applicant: Actual Inventor(s): Address for Service: AMIP Bu COMMONWEALTH SCIENTIFIC AND INDUSTRIAL RESEARCH ORTGANI ZATION Limestone Avenue Campbell ACT 2601 LESLIE JAMES WILLS DAVIES 9 COLLISON, Patent Attorneys, ilding, Hobart Place, Canberra, ACT 2601 Complete Specification for the invention entitled: DROPLET STREAM ALIGNMENT FOR JET PRINTERS" The following statement is a full dtscription of this invention, including the best mtethod of performing it known to us I 71 -la TECHNICAL FIELD This invention concerns jet printing. M~ore particularly, it concerns mounting arrangements for individual droplet generators which enable a plurality of individual droplet generators to be positioned side by side in jet printing equipment with their droplet jets correctly aligned.

i :1 One example of the sort of jet printing apparatus in which the present invention may be used is described in the specification of Australian Patent No 502,523.

However, it should be appreciated that the present invention may be used in other forms-of jet printer.

BACKGROUND ART Those who have used a jet printer of the type described in Australian patent specification No 502,523 will be aware that if it is desired to produce a pattern on a fabric using dots which are formed by droplets from a number of droplet streams, with each droplet stream issuing fromn a separate orifice, then accurate alignment of the droplet streams and careful positioning of the droplet generators must be achieved and maintained. The achievement of the necessary alignment of the droplet stream has always been a. lengthy, tedious and difficult task and, with the prior art jet printing equipment, the correct alignment has been difficult to maintain. The need for constant re-adjustment of the jet printing equipment has beEtn a significant factor in the labour costs associated with the operation of jet printing equipment, and is one of the reasons why fabric having designs printed on it -2 with such equipment remains expensive, notwithstanding recent technical advances in jet printing.

One method of ensuring the correct relative positioningj of the droplet streams in a jet printer is to mount each jet body so thF-' t. en there is zero charge on the droplets, they fall into a small opening in a collector (also called a trap or a gutter) which has been accurately positioned relative to neighbouring collectors in the jet printer. Since it is difficult to design droplet generating heads which will always produce a stream of droplets that enter their respective collectors in the absence of a charge on the droplets, some form of adjustment mechanism for the generating heads must be provided.

A It is a further requirement, for the most effective jet printing, that the scan amplitude of the droplet streams is either controlled or adjustable, to enable the maximum deflection of one droplet stream to be in exact registration with the minimum deflection of the next droplet stream.

For a single jet, it is possible to design a control mechanism for the jet which enables the jet stream to be precisely aligned to a required specification.

But when a plurality of droplet generators are to be mounted close to each other in an array in a jet printer, the limited space available for the array of droplet generators and the need for all the adjustments to be made independently, make such designs impractical. Simple scaling down of the size of a single jet adjuster is not appropriate because the adjuster must have a certain robustness in order to maintain mechanical stability.

-3- Another point well known to engineers who service jet printing equipment of this type is that although it is a relatively easy matter to place an orifice mount so that the aperture for the stream of droplets is d 5 precisely positioned, the same specifications of accuracy cannot be achieved with the stream axis orientation.

SAn analysis of the problems discussed above has shown that since the aim error of a droplet stream may be in any direction relative to the jet body axis, then two-dimensional planar correction jf the aiming point is necessary. Such adjustments are possible with ball and socket joints or with universal joint arrangements, but sufficient accuracy cnd stability of the joints are difficult to maintain in the small sizes required. A further disadvantage of adjustment systems using such joints is evident when the droplet i generating heads must be closely spaced in a linear i array. In such a case, the spacing of the droplet i 20 generating heads would have to be greater than would be necessary if tilting of the generating heads using such joints were not required. Another disadvantage of such a system is that the jet or stream of droplets from the lenerating head may not be correctly aligned wi th the axis of the charge electrode when the droplet generating head is tilted.

Such misalignment errors are known to contribute to charge electrode wetting by satellite drops, and to variability in the sensitivity of deflection.

DISCLOSURE OF THE PRESENT INVENTION It is an objective of the present invention to overcome these shortcomings of the prior art and SL.pri sml bt feiwi provide simple, but effective, which 0

P

0 ii 2

'I

I'

I

-4permits droplet generators to be positioned in a closely-spaced array, with their droplet streams correctly aligned.

This objective is achieved by mounting an assembly which includes the droplet generating head (such an assembly is known as the jet body of the printer) in a cradle which allows rotation of the jet body relative to a mounting body, and providing for the mounting body to be secured at an appropriate location within the jet printer, preferably to a shaft in the jet printer which runs perpendicular to the direction at which the droplets are projected from the jet body.

c 3 According to the present invention, there is provided a support unit for use in supporting the jet body of a jet printer, said support unit comprising a support body having a generally cylindrical cradle formed in the remote end of an arm member extending therefrom, a transverse slot being provided in the upper surface of the arm member to mount the support body in the jet printer -a s part of an array of printing heads, the cradle being adapted to position the jet body in a location such that droplets from the jet body are directed generally in a direction which is perpendicular to a surface to be printed by the jet printer, the jet body being rotatable within the cradle about an axis which is parallel to said direction.

Preferably, a charging electrode (or a pair of charging electrodes), for inducing a charge on droplets from the jet body, is mounted on a second arm member which extends from the support body below the first-mentioned arm member.

The various features of the present invention will be better understood from the following description of the operation of jet printers and of two embodiments of the present invention. In the following description, reference will be made to the accompanying drawings.

Note: In this specification, including the claims, terms which indicate the relative positions of 4tt P components (such as "above" and "below") refer to the ,15 meaning those terms have when the components to which they refer have the orientation shown in the drawings. Users of droplet printing equipment will Z appreciate that when the present invention is incorporated into a printer, the components may be located in a manner that is different from that illustrated (for example, it is not unusual for jets 4 of droplets to be projected substantially *4 horizontally to perform their printing function.

BRIEF DESCRIPTION OF THE DRAWINGS 4 4 25 Figure 1 is a perspective sketch, in partly exploded form, of one type of jet body support.

Figure 2 is a schematic diagram of the droplet generating, collecting and printing features of a jet printer which incorporates the assembly of Figure i.

ri i_ -I ii j~ 5a Figure 3 is a view (partly third angle, partly schematic, and partly exploded) of an array of alignment adjusters in a jet printer, including geometrical constructions that are used to explain the operation of the present invention.

Figure 4 illustrates a preferred embodiment of the present invention.

Figure 5 shows how a double array of droplet generating heads of the type featured in Figure 4 may be created from a single block of insulating material.

DETAILED DESCRIPTION OF THE ILLUSTRATED EMBODIMENTS Referring to Figures 1, 2 and 3, the droplet generating head of a jet printer and its immediately 15 associated components are included in a jet body The orifice mount 11 of the droplet generating head supports an orifice (not shown) having an aperture *i 4 '4 *4 tt *4*4 Ct 4 44 1 4i t 4

I

441 t 4

.I

A t I F -6which produces the stream of droplets. The orif ice mount 11 projects slightly below -the bottom of the jet body The jet body 10 is held against the curved surface or cradle 13A of a mounting body 13 by a strap 12. The strap 12 illustrated in Figures 1, 2 and 3 is formed by a metal strip which has its ends joined by a metal plate or block 12A. Metal block 12A is preferably fitted with a threaded aperture, through which a clamping screw passes, to bear against the flat end face of the mounting body 13 that is adjacent to block 12A.

Alternative strap arrangements may be used, including straps formed of wire, which encircle the mounting body 13 and are attached to pins on the mounting body 13, or are clamped into notches or grooves formed in the mounting body 13. Such alternative strap structures will rely upon a spring bias built V into the wire assembl.y to hold the jet body 10 firmly against the curved cradle 13A of the mounting body 13. Thus they do not require a clamping screw for their effectiveness and avoid one extra adjustment that is necessary with the illustrated embodiment of Figure 1.

The mounting body 13 is made from an electrically insulating material and is provided with a clamping arrangemenL which enables it to be mounted, as shown in Figures 2 and 3, on a shaft 15 which runs perpendicular to the intended plane of scan of the droplets in the droplet stream from the aperture at the end of orifice mount 11. In the embodiment illustrated in Figures 1, 2 and 3, the clamping mechanism comprises a generally keyhole shaped

ALI

-7arrangement formed by a circular aperture 16 adapted to fit around shaft 15, a set of jaws 14A and 14B, and a bolt 17 passing through a clearance hole in jaw 14A and into a threaded bolt-receiving hole 18 in jaw 14B.

The aperture of a collector, trap or gutter 22 for undeflected droplets in the stream of droplets from the aperture of orifice mount 11 lies directly below the aperture in orifice mount 11 (see Figure 2).

t 10 The jet body 10 is rotatable within the cradle 13A, using a tool adapted to engage the square section extension 10A which extends from the top of the jet body 10. In the illustrated embodiment of Figure 1, when the jet body has been firmly held against the cradle 13A by strap 12, it is necessary to loosen the clamping screw of the strap 12 before the jet body can be rotated, and to re-clamp the strap after the jet body has been correctly positioned.

The mounting body 13 illustrated in Figure 1 also contains an electrically conducting rod 19, which passes through the body 13 to provide an electrical connection to a spade 19A formed at, or mounted on, the end of rod 19. Spade 19A supports a charging electrode 21. When the jet printer is in use, the rod 19 is connected to the electrode charging signal source arrangement of the jet printer.

Referring now to Figures 2 and 3, it will be clear that if the jet body is not properly aligned in the jet printer, rotation of the jet body 10 about a vertical axis (vertical only in relation to the illustrated embodiment; in practice, the j et of droplets may be projected from an ori-fice mount 11 in any required orientation, including horizontally) will cause the undef lected droplet stream to map out a cone P. If the jet body 10 is correctly aligned, however, all undeflected droplets will enter the aperture of the associateC collector, trap or gutter 22 of the droplet generating assembly.

To correctly align the droplets in the stream from the aperture or orifice in orifice mount 11, the jet body 10 is rotated until the droplet trajectory lies in the forwardly projecting plane of the droplets (this plane is shown by triangles ABC and LMN in 4Figure and is best observed by adjusting the stream to the frontal edge of the collector. This 4, plane is necessarily in the same plane as the centre of the collector 22, and orthogonal to the deflection plate 26. This plane also includes the centre or axis of the charge electrodes and ensures centrality of the jet stream in the charge electrode 21. The mounting body 13 is then tilted by unclamping it and moving it around the shaft 15 until the undeflected droplets of the jet enter the centre of the receiving aperture of collector 22. It is then re-clamped. The jet body is now correctly aligned in the jet printer and further rotation of the jet body 10 will result in all the undeflected droplets from the aperture in (±44 orifice 11 entering the collector 22.

Since rotation of the droplet head 10 (using extension 10A) and the unclamping, tilting and4 re-clamping of body 13 can be effected using instruments which are smaller in transverse dimension than the lateral dimension t of the mounting body 13 (see Figure it will be appreciated that the droplet generating heads of the jet printer can be mounted as a closely spaced array of the shaft -9- An alternative arrangement to that illustrated in Figure 1, and included in the equipment of Figures 2 and 3, is shown in Figures 4 and 5. This alternative arrangement, which is the preferred form of the present invention, has a support body 40 which is 1 formed as a single block of a rigid plastics material i (such as the material marketed under the trade mark [i "DELRIN").

An upper arm 50 extends forwardly from the body and has a keyhole shaped slot 42 at its end remote from the main portion of body 40. The slot 42 has an inner surface 42A which is substantially circular in Shorizontal cross-section and which defines a generally cylindrical cradle for the cylindrical jet body 10. The jet body 10 is a press fit into the cradle 42A and, when pressed into position, can be adjusted so that the undeflected droplets in the droplet stream from the aperture of the orifice mount i 11 are projected directly to a collector aperture 43 in a lowermost extension 44 of the body 40. This adjustment is performed by rotating the jet body 6 ~until the undeflected droplet stream is positioned in j the forwardly projecting vertical plane (as described i i for the first shown embodiments in Figures 1, 2 and 3).

Rotation of the jet body 10 within the cradle of the projecting arm 50 can be performed by means of an adjusting tool which engages the upper flat sections 10B formed on the jet body for this purpose.

A transverse slot 41 is formed at the end of arm which is connected to the body 40. Slot 41 is dimensioned to provide a cantilever hinge 41A which allows a "nodding" adjustment of the jet body 10 in a vertical plane. The nodding adjustment is effected using a set screw 51 which passes through a hole extending vertically through the upper arm 50 to engage a threaded hole formed in the main portion of body 40 immnediately below the hole extending through arm 50. When the set screw 51 is tightened, using an Allen key inserted into a hexagonal recess 51A in the upper surface of set screw 51, it draws arm 50 down towards the main body 40. The centre line of the cradle region 42A should be just forward of the vertical centre line through collector 43, so that there will always be some tension in the set screw 51 when the jet printer is operating.

A second arm 52 extends forward from the body 4 immediately below the upper arm 50. A pair of charge electrodes 46 are positioned on each side of a slot 53 formed vertically in arm 52. The charging electrodes 46 are connected by leads extending through the body 40 to the droplet charging voltage supply (not shown). Since the jet body 10 is mounted with the orifice mount 11 just above, or projecting into, the middle of the space between the charging electrodes 46, the droplets leaving the aperture of orifice mount 11 are charged (if a charged droplet is required) at substantially the instant that the droplets break off from the orifice mount.

11 As an alternative to electrodes 46, the charging electrode may comprise a U-shaped electrode which is a friction fit in slot 53. Such a charging electrode is featured as charging electrode 46 in the droplet i 5 generating heads illustrated in Figure i Beneath arm 52 is a third arm 47, which also extends Sforward of the body 40. Arm 47 has a vertical slot 48 formed in its end which is remote from the body Slot 48 is aligned with slots 42 and 53, and with collector aperture 43, so that an undeflected droplet leaving the aperture of orifice mount 11 and passing through slots 42 and 53 to collector aperture 43 will pass through the central plane of slot 48.

Deflecting electrodes 49 are positioned on the ends of the facing walls of slot 48 which are remote from Sbody 40. Electrodes 49 may be printed on to the surface of the walls of slot 48, with the connection between the electrodes 49 and the voltage source V: which establishes the deflecting field being by wires which pass throxgh the mounting body 40. In the illustrated embodiment of Figure 4, however, a lead 55 to one of the electrodes 49 is shown passing V along the top of arm 47. Lead 55 will be connected to the deflection voltage control unit. The s 25 corresponding lead to the other electrode 49 follows a similar path on the other (lower) side of arm 47.

By connecting the lead 55 of a number of mounting bodies to a single lead from the voltage supply for the deflecting field, it is a relatively straightforward matter to apply the same deflecting field to a plurality of sets of electrodes 49 on respective mounting bodies.

-12- An advantage of the embodiment of the invention that is illustrated in Figure 4 is that the charged droplets can be subjected to a short, intense deflecting field, and then have a long coasting distance before striking the fabric 24 (or other object) that is to be printed. This enables more accurate printing to be achieved since impact of the droplets on the printing substrate with this deflection geometry is close to perpendicular and printing distortion due to changes in printing substrate thickness is minimised with negligible variation in effective scan width.

This embodiment also overcomes one of the problems that has been experienced with the embodiment of Figures 1, 2 and 3, namely, a lack in stability of the droplet path, which was found to be related to the tightening the clamping bolt 17 (see Figure 1).

The accuracy of the mounting of the electrodes in the arrangement of Figures 4 rnd 5 is also improved, compared with the electrode mounting in the embodiment of Figures 1, 2 and 3.

Reverting now to the embodiment of Figures 1, 2 and 3, it will be appreciated by those skilled in this art that, as shown in the specification of Australian Patent No 502,523, jet printing equipment ,,may have arrays of jets which are angled relative to the direction of travel of the material being printed. It will be clear that with such arrangements, good patterns will be printed only if the scan of the droplets is such that the maximum deflection of a droplet from one droplet generating head is immediately alongside the minimum deflection of a droplet from the adjacent droplet generating head.

-13- This feature is shown in Figure 3, where the arrow T indicates the direction of travel of a surface 24 (for example, a length of textile material) and the lines 25 indicate (schematically) the possible scans of droplets falling on the surface 24 from the droplet generating head positioned above collector 22A.

A good pattern production is required, droplets from the droplet generating head positioned above the collector 22A must be controlled so that the droplet which is deflected when maximum charge is applied to the relevant deflecting electrode 21 falls upon surface 24 immediately adjacent to the region of printing of surface 24 by droplets from the other droplet generating head. This scan control can be effected by adjustment of the potentiometer that conventionally controls the slope of the ramp voltage that is applied to the droplet charging electrode 21.

If the embodiment of Figure 4 is used, an array of droplet generating heads may be established by mounting a plurality of generating heads alongside each other, on a rectangular rod that extends perpendicular to the direction of movement of the fabric underneath the droplet generating heads. If space for adjustment of the jet body 10 is required, the droplet generating heads may be mounted on two transverse rods, with the individual heads separated from each other by a distance which is approximately d of Figure 4.

As an alternative to mounting a plurality of droplet generating heads of the type illustrated in Figure 4 on one or more rods, a plurality of the droplet generating heads may be formed from a single block of 14 insulating material, to be adjacent to each other.

Another alternative is to create two linear arrays of droplet generating heads, back to back, from a single block of insulating material, as shown in Figure In the embodiment of Figure 5, the droplet generating heads of one array are positioned to be mid-way between the droplet generating heads of the other array.

Advantages to be gained by adopting the embodiment of Figure 5 include a reduced packing density of the jet arrangements (giving better access for maintenance) and a reduced droplet scan (resulting in more accurate printing).

Other modifications to the jet printing apparatus incorporating the present invention, or constructed in accordance with the present invention, may be made without departing from the present inventive concept.

INDUSTRIAL APPLICABILITY The present invention is particularly suited for use in jet printers for printing detailed patterns on fabrics and the like, where accurate placement of the printing droplet on the fabric is of paramount importance. However, the invention can also be used, with benefit, in jet printers where the accuracy of the drop placement is less critical in the printing process.

Itjt i

Claims (9)

1. A support unit for use in supporting the jet body of a jet printer, said support unit comprising a support body having a generally cylindrical cradle formed in the remote end of an arm member extending therefrom; and being characterised in that a) a transverse slot is provided in the upper surface of the arm member to mount the support body in the jet printer as part of an array of printing heads; b) the cradle is adapted to position the jet body in a location such that droplets from the jet body are directed generally in a direction which is perpendicular to a surface to be printed by the jet printer; and c) the jet body is rotatable within the cradle about an axis which is parallel to said direction.

2. A support unit as defined in claim 1, including adjustment means to adjust the orientation of said arm member relative to said support body.

3. A support unit as defined in claim 2, in which said adjustment means is a set screw.

4. A support unit as defined in claim 1, claim 2 or claim 3, in which a) a second arm member extends from said support body below said first-mentioned arm member; b) a second slot is formed in the end of said second arm member which is remote from said support body; t r cli cl r A I i 'It t i4 v 4t t I 4 4tt 1 4 m~ 7; Z( r? .h m I-F, -16- c) a charging electrode or a pair of charging electrodes is or are mounted on or supported by the opposed faces of said second slot; and d) said second arm member is positioned adjacent to the first-mentioned arm member, whereby the aperture in the orifice mount of said jet body from which said droplets are projected is positioned within the second slot, and thus within the region of influence of said charging electrode or electrodes.

A support unit as defined in claim 4, in which there is a single charging electrode in the form of a generally U-shaped electrode having a friction fit within said second slot.

6. A support unit as defined in either claim 4 or claim 5, further characterised in that a) a third arm member extends from said support body below said second arm member; b) a third slot is formed in the end of said third arm member which is remote from said support body; c) a pair of planar deflecting electrodes are mounted on the opposed faces of said third t slot; d) said third slot is positioned so that said 3droplets enter the region between said deflecting electrodes after said droplets have passed through the region of influence of said charging electrode or electrodes. -17-

7. A support unit as defined in claim 6, including a collector for uncharged. droplets which pass between said deflecting electrodes, said collector being formed integrally with said support body.

8. A plurality of support units as defined in any preceding claim, formed as a single structure.

9. An array of support units as def ined in any f preceding claim, said array of units being mounted on a common shaft. A support unit for use in supporting the jet body of a jet printer, substantially as hereinbefore Aft, t II I tdescribed with reference to Figures 4 and 5 of the accompanying drawings. it, 4 1 COMMONWEALTH SCIENTIFIC AND INDUSTRIAL RESEARCH ORGANISATION ~by its Patent Attorneys DAVIES COLLISON