INDUSTRIAL PRINTHEAD

Abstract

An industrial printhead comprising an array of piezoactuated flow channel dispensers enclosed in a chamber with a multi-orifice plate allowing fluid exit.

Claims

1. A tapered dispenser flow channel wherein the cross section at the inlet has a diameter of greater than 10 mm and tapers to an outlet of diameter 5 mm.

2. The tapered dispenser flow channel according to claim 1, wherein the flow channel has a non-round cross section to reduce off-axis vibrations.

3. The tapered dispenser flow channel according to claim 2, wherein the cross sectional shape is oval.

4. The tapered dispenser flow channel according to claim 2, wherein the cross-section is square or rectangular.

5. The tapered dispenser flow channel according to claim 2, wherein the cross-section defines a multi-pointed star.

6. The tapered dispenser flow channel according to claim 1, wherein the flow channel has a circular cross section.

7. The tapered dispenser flow channel according to claim 1, wherein internal ribs are present to reduce resistive forces in shear thinning fluids.

8. The tapered dispenser flow channel according to claim 1, wherein the tapered dispenser flow channel defines a longitudinal axis configured to run parallel to the axis of excitation.

9. The tapered dispenser flow channel according to claim 1, further comprising a locally controlled temperature tip for control of liquid deposition.

10. The tapered dispenser flow channel according to claim 9, wherein the locally controlled temperature flow channel tip comprises a resistive heating element is embedded in the flow channel wall at the tip, in order to apply a localized heating effect.

11. The tapered dispenser flow channel according to claim 9, wherein the locally controlled temperature flow channel tip is configured to provide a flow of cold fluid selectively to the needle outlet to apply a local cooling effect.

12. The tapered dispenser flow channel according to claim 10, wherein the tip temperature is configured to be above the boiling point of the liquid such that gas is formed from the liquid.

Description

FIGURES

[0013] FIG. 1 shows a 3D View of a Printhead design according to aspects of the invention;

[0014] FIG. 2 shows an example of a multi-orifice plate chamber printhead design—saturated solvent vapour in dispenser chamber;

[0015] FIG. 3 shows a plan view of a multiple orifice nozzle plate design;

[0016] FIG. 4 shows a side view of a rotating brush nozzle cleaner;

[0017] FIG. 5 shows a heated nozzle tip to control meniscus and droplet formation;

[0018] FIG. 6 shows of external to focus deposited fluids;

[0019] FIG. 7 shows cross-sections of the flow channel to minimise off-axis movement;

[0020] FIG. 8 shows an ilnterdigitated array of dispenser nozzles to achieve a high resolution printhead configuration. Left—non-overlapped nozzle plate orifices. Right overlapped nozzle plate orifices;

[0021] FIG. 9 shows tapered flow channels to reduce flow resistance to high viscosity fluids;

[0022] FIG. 10 shows piezo re-directed fluids flow.

DESCRIPTION

[0023] The printhead design 1 described includes an array of flow channels 2 entering a gas-filled chamber 3 that encapsulates the flow channel orifices and acts to manage the fluids that exit the flow channel such that they can be deposited onto a substrate more reliably, at higher resolution and using higher viscosity fluids than an array of flow channels 2 alone.

[0024] The chamber design is at the core of this invention and comprises a gas filled headspace, an array of secondary orifices and a means to insert the flow channels into the chamber 3. A key element of the invention is the geometry of the chamber 3 and the position of the flow channels relative to the chamber nozzle plate orifices and internal structures to direct gas flow in the chamber 3.

[0025] In addition, we describe improvements to the flow channels themselves to enhance performance compared to the flow channels described in (previous patent).

[0026] FIGS. 2 and 3 illustrate a first example defining a chamber 3 filled with solvent-saturated vapour: a) the flow channel enclosure is filled with gas to create a solvent saturated environment; b) the flow channel dispense orifice is maintained in an environment of the solvent at saturated vapour pressure, therefore evaporation at the tip in minimised and clogging due to evaporation of the deposition solution solvent is also minimised; c) the saturated gas is introduced into the chamber 3 as a continuous flow; and d) the flow of gas may also direct the dispensed fluid.

[0027] FIG. 4 illustrates a second example defining a nozzle cleaning system comprising a rotating brush assembly within a nozzle enclosure. The brush is designed to be brought into contact with the nozzle tip periodically to remove material build-up.

[0028] FIG. 5 illustrates a third example defining a locally heated nozzle. Heated nozzle tips to minimise material build-up at the nozzle. A resistive heating element is integrated with the flow channel to deliver a locally increased temperature at the nozzle tip. Piezo-actuated liquid deposition is based on breaking the surface tension of a liquid using high shear forces at a needle orifice. Control of the surface tension is therefore, a key element in achieving consistent deposition of liquids.

[0029] Since surface tension is a function of temperature and generally decreases with increasing temperature, the temperature at which the high shear droplet formation process occurs is found to be important. In this invention we describe a design in which the temperature of the tip of the needle is locally controlled in order to provide localised control of the surface tension of the liquid without changing the the liquid bulk temperature.

[0030] The bulk temperature of the fluid can be controlled, however for many materials it is not desirable to use elevated temperatures due to materials stability.

[0031] This invention is also capable of delivering localised heating such that thermal evaporation may occur alongside high shear droplet formation to create an additional process for droplet formation at the orifice.

[0032] A fourth example defines a piezo pulse pattern to remove excess fluid from the nozzle tip.

[0033] A high amplitude pulse (xx Hz, yy V) that causes the material build-up at the nozzle tip to be removed.

[0034] FIG. 6 illustrates a fifth example defining a multi-orifice plate 4 chamber printhead design 1 using external fluid flow 5 to direct deposition. Gas flow is applied to the dispense orifice via the chamber 3 to create an air flow that reduces the spread of the dispensed fluid such that the resolution of the deposited fluid features is increased. The velocity of the air flow can be controlled to achieve the desired resolution, and it is possible to use the air flow to direct the dispensed fluids.

[0035] A sixth example defines flow channels with perpendicular piezoactuators to control deposition width. Flow channels actuated by a multiplicity of piezoactuators attached to the needle, in the preferred embodiment there are two piezoactuators attached perpendicular to the flow channel, enabling control of the flow channel perpendicular to the direction of the substrate onto which fluids are being deposited.

[0036] This enables several elements of resolution control to be achieved: fixed offsets perpendicular to the substrate travel direction of individual nozzles in an array 7; oscillation perpendicular to the substrate travel direction.

[0037] FIG. 7 illustrates a seventh example defining flow channel cross-sections to minimise movement perpendicular to the excitation direction. Known in the art is circular cross section flow channels for piezo-actuated liquid deposition. These cross sections, while suitable for the purpose of liquid transport do not eliminate off axis (the axis defined as the plane parallel to the piezo actuator and nozzle tip) vibrational modes of excitation.

[0038] These off axis vibrations can limit precision of the droplet formation and hence the resolution of the deposited materials.

[0039] This invention refers to non-circular cross sections, which enable mechanical control of the piezo-actuator excitation such that off-axis movement is minimised. We refer in this invention specifically to oval, square, triangular section flow channels and variations therein, which are intrinsically stiffer in off axis directions than a circular cross section of comparable wall thickness. [0040] 1. This invention also refers to external flow channel structures that are mechanically linked to the flow channel such as ribs, which stiffen the flow channel in off-axis directions to minimise unwanted displacement of the orifice. [0041] 2. This invention also refers to butted tubes with variable wall thickness. [0042] 3. Claims: [0043] 4. Flow channel geometries for piezo actuated liquid deposition that reduces off axis vibrations compared to a circular cross section [0044] 5. Flow channel cross sections comprising, oval, square, triangular cross sections [0045] 6. Flow channel cross sections comprising external features that add stiffness in off-axis directions, such as ribs and gussets

[0046] FIG. 8 illustrates an eighth example defining an interdigitated array of dispenser flow channels 2. An array of needles that is interdigitated with an opposing array of needles, where the resolution is doubled by adding the opposing row of needles. The arrays are controlled by the same software signals, enabling a higher resolution image to be created. FIG. 9 illustrates a ninth example defining tapered flow channel cross-sections for high viscosity fluids. Description: A piezo driven needle, wherein the flow channel reduces in cross sectional area from inlet to outlet. The cross sectional area reduction is designed to minimise the flow resistance of the tube such that higher viscosity fluids can be transported using the same outlet orifice dimensions.

[0047] Known in the art is a single piezo-actuated flow channel with constant cross sectional area. However, the fluids that can be transported by this design are limited in viscosity by the overall flow resistance of the channel, which is determined by the cross-sectional geometry required at the outlet for the piezo actuation liquid deposition process to occur.

[0048] It is known that the channel is filled via capillary flow and that the pressure required is inversely proportional to channel diameter to the third power. Hence it is desirable to reduce the channels flow resistance to enable high viscosity liquids to be transported by capillary flow.

[0049] This design is based on the concept that the flow channel is tapered to allow both reduced flow resistance and maintain the required outlet geometry for piezo-actuated liquid deposition to occur. It is known that an outlet geometry with a larger cross sectional area does not enable piezo actuated liquid deposition.

[0050] A further embodiment of this concept utilises a constriction of the orifice cross section itself to minimise area of the meniscus, such that statistical variation of the meniscus geometry is minimised.

[0051] A tenth example defines a rifled flow channel to reduce resistance to flow in the channel. FIG. 10 illustrates an eleventh example defining a continuous flow configuration for high viscosity fluids. The chamber 3 includes an area of the nozzle plate 4 that is connected back to the ink system via a recirculating pump. The dispensed ink flow can be redirected to dispense via one of the following mechanisms: i) air flow; ii) piezo; iii) electrostatic.