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We
have come a long way from the stone
plate. As you can well imagine, it would
be very difficult to mount a piece of
stone on modern high-speed presses.
Senefelder's first press was flat, so
the use of stone was easy. Today's presses
use curved cylinders to hold the offset
plates. The basis of modern lithography
is a combination of photography and
Senefelder's original observation that
"oil and water do not mix". All offset
plates made today employ this offset
principle, they use as an image carrier
such as thin paper, plastic, or a metal
sheet which once exposed and processed
can be wrapped around a cylinder of
a press for printing. This modern offset
plate contains two areas; image areas,
which repel water (remain dry and accept
ink) and non-image areas, which accept
water. This is the basic requirement
of all modern lithography - the ability
to produce a plate which will have image
areas that are "hydrophobic" (meaning
water hating) and non-image areas that
are "hydrophilic" (meaning water loving).
While the basic principle is common,
there are many differences between offset
plates and the method they use to separate
the image from the non-image areas.
Today,
the majority of lithographic plates
are made of aluminum sheets of varying
thickness (usually between .008" and
.0015") with a surface grain or granular
finish. This grain serves to give water-carrying
properties to the plate and to give
anchorage to the image forming material.
Practically all plates are presensitized,
that is they are supplied ready coated
with a light sensitive diazo compound
or photopolymer resin material ready
for light exposure.
This
photopolymer coating, as the term implies,
is a chemical resin or polymer that
will react with ultraviolet light -
much like photographic film. When UV
light strikes the photopolymer on the
plate, it is "hardened". Photopolymer
that is not exposed to the light is
not "hardened" and can be easily removed.
This is the principle of the modern
offset plate.
The
light is reflected away from the dark
portions of the negative and will not
cause a cross linking or hardening of
the polymer. Light, however, will pass
through the clear areas of the negative
and cause a cross linking (hardening)
of the polymer resulting in the image
areas of the plate after processing.
Exposing
an Offset plate to produce a usable
plate for the offset press
There
are seven major types of lithographic
plates used in the printing industry
today:
- Diazo
- Photopolymer
- Silver
Halide
- Electrophotographic
- Bimetal
- Waterless
- Spark
Discharge (digital waterless)
- Laser
(digital waterless)
- Computer-to-plate
- Various types of Plate Material
Film
positives and negatives along with digital
information (computer) are used for
making or exposing most types of offset
plates today. While there are several
types of offset plates, they are all
generally classified as either positive
or negative working plates.
Negative-working
plates are comparatively inexpensive
and commonly used in the United States.
As the name implies, film negatives
are used to image the negative working
plate. These plates are generally coated
with a photopolymer and are known as
negative working presensitised plates.
Exposure and processing of this type
of plate is usually within ten minutes.
To expose the plate, a film negative
is placed over the light sensitive coating
and exposed to UV light. Light that
passes through the clear areas of the
negative causes a reaction with the
"monomers" of the photopolymer which
chemically cross-link with each other
to form polymers. These polymers can
be thought of as complex chains of monomers,
which are linked so strongly, that they
behave as a single, hard, wear-resistant
molecule. The actinic light cannot pass
through the black areas of the negative
so no reaction takes place with the
polymer under the non-clear areas of
the negative. Processing removes unexposed
non-hardened polymer. An application
of a gum solution to the non-image areas
of the plate to make it water-attracting/ink
rejecting. The processing does not wash
off the hardened polymer image areas
of the plate.
Positive
working plates are more expensive
than their negative-working counterparts.
These types of plates are used more
by European printers. As the name implies,
film positives are used to image this
type of plate. The photopolymer used
to produce a positive working plate
is different from the polymer used in
the negative working plate as it is
hardened before exposure. The photopolymer
used here becomes unstable when exposed
to ultraviolet light and remains hard
where no light strikes the polymer.
Plate processing is similar to the negative
plate except that the processor removes
the exposed photopolymer from the plate
and applies a thin layer of gum to protect
the non-image areas from ink.
Plates
are generally made from aluminum. Other
base materials can be used such as paper,
polyester and multi-metal. Multi-metal
plates are used for long extensive press
runs due to their durability. Paper
type plates are used in small offset
presses known as duplicators for very
short runs (1,000 - 10,000 impressions).
Polyester plates may be used in small
press or in larger sheetfed presses.
Like paper plates, these are intended
for short runs. In general, the polyester
and paper plates are much less expensive
than the aluminum or multi-metal plates.
Cost, run length, type of press and
the type of job dictate the type of
plate used by a printer.
Offset
Plate Technology
The
aluminum-based plate contains the light-sensitive
coating applied or coated over the aluminum.
Paper and polyester plates are treated
very similarly. The multi-metal plate,
however, is similar but the structure
of the base plate is slightly different
from that of the aluminum, paper, etc.
Multi-Metal Plates were developed to
extend press run life. In general, multi-metal
plates are presensitized polymer plates
consisting of a metal base with one
or more metals plated to it. Today,
there are two basic types of "bi" or
multi-metal plates:
- Copper
plated onto stainless steel or aluminum
- Chromium
plated on copper
They
are the most durable and the most expensive.
These plates can be coated with either
diazo or photopolymer and can be either
negative or positive working.
They
are designed with a purpose in mind.
In most cases, a major determining factor
is press run length. A long run length,
for example, on a small offset duplicator
might be 10,000 impressions (copies)
with a short run length being in the
neighborhood of 2,000 impressions. When
you talk about larger commercial 4 to
6 color sheetfed presses, short run
lengths would be around 20,000 with
long run lenghts being up to 100,000.
High speed webs differ even more. Long
run lengths generally will be in the
1,000,000 impression range. So it is
difficult to give a generalization of
run length for a particular plate.
Diazo
- is a compound used to coat the offset
plate. Diazo coatings are organic compounds
that are used to make presensitized
plates with a shelf life of about a
year and for wipe-on type plates that
can be in-plant coated with a shelf-life
about one to two weeks. These plates
can be both negative or positive working.
Once exposed, they are treated with
an emulsion developer which consists
of a lacquer and gum in an acid solution.
As the unexposed diazo is dissolved
by the solution, the gum deposits on
the non-printing areas ensuring water
receptivity. The lacquer deposits on
the exposed areas making them ink receptive.
Once developed, the plate is rinsed
with water and coated with a protective
gum arabic solution. Run lengths are
short with these type of plates. Run
lengths of 100,000 to 250,000 impressions
with web and sheetfed presses can be
achieved.
Photopolymer
- coatings used to make photopolymer
plates are organic compounds which are
very inert and abrasion resistant, allowing
longer press runs than diazo coatings
(up to 1,000,000 sheetfed or web impressions).
This type of coating is the most widely
used material in platemaking. Plates
made with photopolymer can be both negative
or positive-working. The photopolymer
coating is different from other sensitizers
as they change in molecular weight during
exposure. This accounts for many of
their unusual properties such as long
runs, resistance to abrasive wear and
increase in wear resistance after baking
(processing technique to extend run
length). Today, new high-speed photopolymer
plates have been developed with a dye
sensitized photopolymer that can be
exposed by laser and used in digital
imaging systems (computer based desktop
systems). The photopolymer plates are
by far the most widely used plates in
the printing industry today.
Silver
Halide - are high speed plates that
use a photosensitive coating similar
to photographic film except that the
silver halide emulsions are slower.
The emulsions are color-blind and very
light sensitive in the blue region of
the visible spectrum so they have to
be handled in yellow filtered light.
This type of coating can be exposed
optically using negatives or by lasers
from digital data. The processing solutions
contain heavy metal (silver) by-products
which must be either carried away to
special treating plants or treated in-plant
with silver recovery chemicals before
being allowed to drain into municipal
sewers. Film-based plates are used to
print single color business forms, reports,
etc. from digital information. These
plates may also be exposed like photographic
film in a large camera then following
exposure, developed and placed on the
press for printing. Silver-halide plates
are used for spot and process color
reproduction using digital data. These
types of plates are popular with short
run, quick turnaround printers.
Electrophotographic
- plates are based on the principles
of the electrostatic copier. There are
two types of plates:
- Inorganic
photoconductor on a drum
- Organic
photoconductor on a substrate
The
photoconductor is sensitized to light
by charging with a corona discharge.
The charge is dissipated in the areas
exposed to light. The charge remaining
on the unexposed areas attracts a dry
or liquid toner with an opposite charge.
The base photoconductor material used
is normally selenium or cadium sulfide
coated onto paper, plastic, etc.
Plates
for laser imaging are coated on electrograined
anodized aluminum. During processing,
the coating must be removed in the non-printing
areas, and the plates are treated with
etch and gum to make them water receptive.
In the chemical removal process the
image elements (dots) become slightly
ragged which can affect their use for
fine screen, high quality process color
printing. Another type of electrophotographic
plate is the Zinc Oxide paper plate
used by quick printers. These plates
are very similar except the Zinc Oxide
is the photoconductor. These types of
plates are normally used for short run
duplicators by quick printers.
Waterless
plates - are similar to the conventional
offset plate except that a layer of
silicone is applied on the surface of
the light sensitive photopolymer. The
thin layer of silicone is bonded to
the photopolymer. Exposure is similar
to that of the conventional offset plate.
Exposure light passes through the clear
areas of the film negative and silicone
layer striking the photopolymer material
beneath. The light activates the photopolymer,
causing a break in the bond between
the photopolymer and the silicone layers.
Areas where light does not pass through
negative, no break in the silicone bond
occurs. Processing removes the un-bonded
silicone leaving only the photopolymer
which is ink receptive. Silicone rubber
has a very low surface energy and is
not wet by the ink.
Systems
have been developed for waterless printing
using special ink temperature control
systems on press to assist in stabilizing
the ink and its viscosity. Waterless
plates can be either negative or positive-working.
This type of printing has advantages
as it eliminates the gum-water based
fountain solution. Fountain solution,
as it emulsifies with the ink, can dull
printed colors, increase dot gain and
make controlling the press more diffi
cult. Printing with the waterless process
allows the printer to print with finer
line screens (300 lines per inch and
higher) due to the absence of the fountain
solution resulting in higher resolution
pictures. The plates, due to the silicone,
have shorter run lengths (under 100,000)
and scratch easily requiring press shutdown
for plate repair. This type of system
is also more expensive than the conventional
offset plate.
Heidelberg
GTO-DI (Direct Imaging) - plates
are used on the Heidelberg GTO-DI press
system. These plates are very similar
to the above waterless plates except
they are imaged on press by computer.
In a way, the press is the printer for
the computer much like a dot matrix
printer is. The plates are imaged in
this case, however, by lasers. The plates
are made in a three layer composition.
The base material is either polyester
or aluminum. The middle layer is an
infrared-absorbent material. This layer
matches the laser's output wavelength
and its role is simply to vaporize when
struck by the laser light. Over this
layer is a thin layer of silicone. As
the laser strikes the plate, the infrared
vaporizes and loosens the silicone layer
which is wiped away following imaging.
The wiped area is now the image area
as no silicone remains. The non-image
area is the area containing silicone
which was not removed during the imaging
process.
The
same plate and technology is used in
the Heidleberg Quickmaster DI-46-4 press
with the exception that instead of a
single plate a plate roll is used. See
the first section under Printing Processes
for a more detailed description. These
plates are very short run plates (under
25,000 impressions). Once the plate
has been imaged, the waterless process
is near similar to the above waterless
plate. These plates are near similar
to the Toray Waterless plates mentioned
in the Waterless Section in the previous
page.
Heidelberg
Quickmaster D146-4 (Direct Imaging)
- Like it's predecessor the GTO-DI,
the Quickmaster uses a waterless plate.
Unlike the earlier versions of the OTO-DI
(which used the "spark" imaging system)
the Quickmaster waterless plate is imaged
via an laser array. Data (Postscript
level 2) is converted in the RIP (Raster
Image Processor) into screen data, which
is in turn converted into control signals
for 64 infrared laser diodes (16 diodes
per printing unit) in the printing press.
An Ethernet interface is sufficient
to transmit digital documents from the
prepress directly without film exposure,
plate exposure and stripping tot he
Quickmaster DI. The laser beams created
by the laser diodes are led to optics
via fiber-optic cables, and are bundled
into a precise ray of light. On a special,
multi-layer plate very small sharp-edged
depressions are created through high
levels of energy. Analogous to other
dry offset processes these depressions
accept ink, which is repelled by a silicon
layer on all other places on the plate.
The system can image up to 1,270 dpi
or 2,540 dpi. This is sufficient for
printing a 150 Ipi screen in very good
offset quality. Imaging time ranges
from 6 minutes (1,270 dpi) to 12 minutes
(2,640 dpi). Since all four printing
units are imaged at the same time, all
are in registration. The plate itself
is very similar to the waterless plate
used in the GTO-DI with the exception
the plate comes in roll form (see Printing
Methods, Section 2). Like with the OTO-DI
Waterless plate, the Quickmaster plate
is on a mylar or polyester base and
is flexible.
MAN
Dicoweb or the CTPress (Direct Imaging)
- Meaning "Digital Change Over Web"
is the latest digital technology to
hit the printing scene, however, it
is not yet commercially available. The
Dicoweb works by printing digitally
to a "plate" cylinder, printing the
job and then cleaning the "plate" cylinder
for re-imaging. The process works by
using a laser head to directly image
the printing cylinder via a thermal
ribbon. The thermal material transferred
from the ribbon to the plate cylinder
(which is actually a sleeve). The thermal
image laser deposited is ink receptive.
The areas of the cylinder that received
no thermal material are the non-image
areas which accept no ink but fountain
solution instead. After the completion
of a print run, the cylinder surface
is automatically cleaned by a device
similar to a blanket washer. Once washed,
the cylinder is reading for more imaging.
See the Printing Methods Section for
more details.
Continued
on the Next Page Offset Plate Technology
Computer
to Plate (CTP) - Computer to plate
systems today can use a variety of plate
material - depending upon the manufacturer,
system design, etc. CTP systems can
use several systems which include:
- Silver
Halide
- Thermal
- Direct
Thermal - Requires the use of
a special substrate that changes
color when exposed to heat.
- Thermal
Transfer - This approach uses
a thermal array to transfer colorant
from a ribbon to a substrate.
- Photopolymer
- Ink
Jet
- Hybrid
No
matter how what technique is used, the
end result is the same; an offset lithographic
plate with the image areas that will
accept ink and a non-image area which
will accept no ink. Computer to Plate
is a technology whose time has come.
It was only a few short years ago when
only 2 or 3 major vedors were available,
now today there are over 46!
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