There are two
main technologies in use in contemporary inkjet printers: continuous (CIJ) and
Drop-on-demand (DOD).
Another
emerging printing technology is EHD. Liquids can be printed at nanoscale by
pyro-EHD.
Drop-on-demand
Most consumer
inkjet printers, including those from Canon, Hewlett-Packard, and Lexmark, use the thermal inkjet process. The idea of using thermal
excitation to move tiny drop of ink was developed independently by two groups
at roughly the same time: John Vaught and a team at Hewlett-Packard's Corvallis
Division, and Canon engineer IchiroEndo. Initially, in 1977, Endo's team was
trying to use the piezoelectric effect to move ink out of the nozzle but noticed that ink shot
out of a syringe when it was accidentally heated with a soldering iron.
Vaught's work started in late 1978 with a project to develop fast, low-cost
printing. The team at HP found that thin-film resistors could produce enough
heat to fire an ink droplet. Two years later the HP and Canon teams found out
about each other's work. In the thermal inkjet process, the print cartridges consist
of a series of tiny chambers, each containing a heater, all of which are
constructed by photo lithography. To eject a droplet from each chamber, a pulse of current
is passed through the heating element causing a rapid vaporization of the ink
in the chamber and forming a bubble, which causes a large pressure increase,
propelling a droplet of ink onto the paper (hence Canon's trade name of Bubble Jet).
The ink's surface
tension, as well as the condensation and
resultant contraction of the vapor bubble, pulls a further charge of ink into
the chamber through a narrow channel attached to an ink reservoir. The inks
involved are usually water-based and use either pigments or dyes as the colorant. The inks must have a volatile component to
form the vapor bubble; otherwise droplet ejection cannot occur. As no special
materials are required, the print head is generally cheaper to produce than in
other inkjet technologies.
Most commercial
and industrial inkjet printers and some consumer printers (those produced by Epson and Brother
Industries) use a piezoelectric material in an ink-filled chamber behind each nozzle instead of a
heating element. When a voltage is applied, the piezoelectric material changes
shape, generating a pressure pulse in the fluid, which forces a droplet of ink
from the nozzle. Piezoelectric (also called Piezo) inkjet allows a wider
variety of inks than thermal inkjet as there is no requirement for a volatile
component, and no issue with kogation (buildup of ink residue), but the print
heads are more expensive to manufacture due to the use of piezoelectric
material (usually PZT, lead
zirconium titanate). A DOD process uses software that
directs the heads to apply between zero to eight droplets of ink per dot, only
where needed. Piezo inkjet technology is often used on production lines to mark
products. For instance, the "use-before" date is often applied to
products with this technique; in this application the head is stationary and
the product moves past. Requirements of this application are high speed, a long
service life, a relatively large gap between the print head and the substrate,
and low operating
cost.
Ink formulations
The basic
problem with inkjet inks is the conflicting requirements for a coloring agent
that will stay on the surface vs. rapid dispersement of the carrier fluid.
Desktop inkjet
printers, as used in offices or at home, tend to use aqueous inks based on a mixture of water, glycol and dyes or pigments. These inks are inexpensive to manufacture, but are
difficult to control on the surface of media, often requiring specially coated
media. HP inks contain sulfonated polyazo black dye (commonly used for dying leather), nitrates and other compounds. Aqueous inks are mainly
used in printers with thermal inkjet heads, as these heads require water to
perform.
While aqueous
inks often provide the broadest color
gamut and most vivid color, most are not
waterproof without specialized coating or lamination after
printing. Most Dye-based inks, while usually the least expensive, are subject
to rapid fading when exposed to light. Pigment-based
aqueous inks are typically more costly but provide much better long-term
durability and ultraviolet resistance. Inks marketed as "Archival Quality" are usually pigment-based.
Some
professional wide format printers use aqueous inks, but the majority in
professional use today employ a much wider range of inks, most of which require
piezo inkjet heads and extensive maintenance:
Solvent inks
the main
ingredient of these inks are volatile
organic compounds (VOCs), organic chemical compounds that
have high vapor
pressures. Color is achieved with pigments
rather than dyes for excellent fade-resistance. The chief advantage of solvent
inks is that they are comparatively inexpensive and enable printing on
flexible, uncoated vinyl substrates, which are used to produce vehicle graphics,
billboards, banners and adhesive decals. Disadvantages include the vapour
produced by the solvent and the need to dispose of used solvent. Unlike most
aqueous inks, prints made using solvent-based inks are generally waterproof and
ultraviolet-resistant (for
outdoor use) without special over-coatings. The
high print speed of many solvent printers demands special drying equipment,
usually a combination of heaters and blowers. The substrate is usually heated
immediately before and after the print heads apply ink. Solvent inks are
divided into two sub-categories: hard solvent ink
offers the greatest durability without specialized over-coatings but requires
specialized ventilation of the printing area to avoid exposure to hazardous
fumes, while Mild or "Eco" solvent inks,
while still not as safe as aqueous inks, are intended for use in enclosed
spaces without specialized ventilation of the printing area. Mild solvent inks
have rapidly gained popularity in recent years as their color quality and
durability have increased while ink cost has dropped significantly.
UV-curable
inks
these inks
consist mainly of acrylic monomers with an initiator package. After printing, the ink is cured
by exposure to strong UV-light. Ink is exposed to UV radiation where a chemical
reaction takes place where the photo-initiators cause the ink components to
cross-link into a solid. Typically a shuttered mercury-vapor lamp is on either
side of the print head, and produces a great amount of heat to complete the
curing process (this lamp is used for free radical UV ink, which is what the
majority of flatbed inkjet systems use). UV inks do not evaporate, but rather
cure or set as a result from this chemical reaction. No material is evaporated
or removed, which means about 100% of the delivered volume is used to provide
coloration. This reaction happens very quickly, which leads to instant drying
that results in a completely cured graphic in a matter of seconds. This also
allows for a very fast print process. As a result of this instant chemical
reaction no solvents penetrate the substrate once it comes off the printer,
which allows for high quality prints. The advantage of UV-curable inks is
that they "dry" as soon as they are cured, they can be applied to a
wide range of uncoated substrates, and they produce a very robust image.
Disadvantages are that they are expensive, require expensive curing modules in
the printer, and the cured ink has a significant volume and so gives a slight
relief on the surface. Though improvements are being made in the technology,
UV-curable inks, because of their volume, are somewhat susceptible to cracking
if applied to a flexible substrate. As such, they are often used in large
"flatbed" printers, which print directly to rigid substrates such as
plastic, wood or aluminium where flexibility is not a concern.
Dye
sublimation inks
these inks
contain special sublimation
dyes and are used to print directly or
indirectly on to fabrics which consist of a high percentage of polyester fibres. A heating step causes the dyes to sublimate into the
fibers and create an image with strong color and good durability.
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