Flexographic Printing (Printing Method)

By Ronald Weidel (azp Chemnitz)

1. Printing method
2. Printing forme production
3. Printing process
4. Print quality

1. Printing method
   When we read the industry news we are warned again and again that the prospects of the printing industry are weak. Offset printing is doomed, and digital printing has a future. This or something along these lines is the message conveyed to us. A printing method which has consistently shown an exciting and eventful development during recent years is flexographic printing. While it was formerly discounted due to coarse screen rulings and the squashed edge effect, flexography could continuously improve its quality and thus significantly expand its position in packing and decorative printing by gaining additional market shares. Noe numerous duels with gravure printing or offset printing are being fought and also won in these fields of application. That's reason enough to explain this printing method in some detail and to have a look at the state-of-the-art.
   Flexography is one of the direct letterpress printing methods. Analogous to conventional letterpress printing, ink is transferred onto the substrate by means of raised printing elements (reliefs). In contrast to the letterpress printing forme, the flexograpic printing forme can adapt itself even to rough or uneven substrates like, e.g., corrugated board or tissue and nevertheless ensure consistently even ink transfer. On the other hand, these properties of the printing forme have adverse effects in the light image areas (highlights). Here, the finely structured relief may quickly be deformed, resulting in strong tonal value increases and unsharp printing behaviour. The printing forme materials used are elastomers or photopolymers. In combination with better printing inks, the latter have opened up the way to fine screen rulings and multicolour flexograpic printing for the very first time near the end of the 1970ies.

The compact design of the flexo printing unit brings about a short ink transfer path similar to that in gravure printing. This becomes obvious above all in the fast response of the inking unit. While in offset printing some, rescpectively, sheets or metres of the web are needed for proper ink settings, changes in the settings in flexograpic printing can be seen on the substrate after just a few revolutions of the printing plate already. This is a very favourable property which also has positive effects on the production run stability as regards inking.

Another advantage of the short inking unit is that cleaning of the pan and anilox rollers is comparatively fast. With a chambered doctor blade system, cleaning of the anilox roller is even possible via the cambered doctor blade. For this purpose, ink transport from the container is interrupted and cleaning agent is pumped through the chambered doctor blades. The cells of the anilox roller are thoroughly rinsed in order to achieve optimum cleaning. Stubborn dirt due to dried ink residues may necessitate additional cleaning. In this case, many different cleaning methods are used. The applications range from chemical wet cleaning to mechanical methods using dry ice and/or plastic particles as well as ultrasonic cleaning. Intensive cleaning of the anilox roller is normally carried out outside the printing press. Treatment in the printing press is only done where extensive assembly operations are involved for the anilox roller. Basically it can be said that cleaning of the anilox roller requires special attention. Dirty cells have a significant effect on ink transfer. Regular maintenance and care are a basic requirement of high-quality flexographic printing.

In combination with the anilox roller, the rather simple principle of letterpress printing enables fast and efficient inking of the printing elements. The anilox roller is a roller with a ceramic coating or a hard chrome-plated roller with an even cell structure on the surface. Together with the frequently used doctor blade system (chambered doctor blade principle) or the simpler pan roller system (squeezing principle), these cells ensure ink metering as required and produce an even in film on the printing forme and later-on the substrate.

The printing inks used are, with the exception of UV printing inks, low-viscous and are water-based or produced with organic solvents. Where conventional inks are used, drying is mainly by evaporation or, where absorbent substrates are used, by absorption of the solvent portion contained therein. Like in other fields of application, the setting of UV printing inks is by cross linking of the monomer and prepolymer structures after radiation with UV light.

Inking in flexographic printing can be described as being very even. The ink quantities applied vary depending on the pick-up volume of the anilox roller used. As a result, there is direct interdependence between the printable screen lining, the selected anilox roller and the substrate. While in a printing unit using the squeeze principle ink application can be adjusted to a small extent by changing the gap between the anilox roller and the pan roller, a printing unit using the chambered doctor blade principle always necessitates an exchange of the anilox roller. This additional set-up operation is, however, worth the trouble because it ensures consistent ink application throughout print production and high reproduction precision in follow-up jobs. Essential requirements are, however, good maintenance of the anilox rollers used, well-planned ink management and well-documented production specifications.

Besiders the construction principle of the inking unit, a distinction between flexo printing presses is also made with regard to the basic design. Depending on the field of application and the print product, basically three types are prevalent now. The cantral cylinder design. Central cylinder printing machines are mainly used for printing on elastic and slightly stretchable printing substrates like plastic films or for preprinting cover sheets for corrugated board. The unit design is used for narrow web label printing machines, stable composite materials (e. g. beverage cartons) and as sheetfed printing machines for printing on corrugated and solid board. The compact design, on the other hand, is, e.g. used for napkin printing machines or in paper sack production. The above-mentioned examples make it quite clear that flexo printing machines are highly specialised production system which are often operated in combination with print finishing aggregates. There simply isn't the one and only flexo printing machine, but each and every machine is tailored to the field of application, is a total techical solution. The large number of substrates that can be used opens up numerous field of application for flexo printing. One domain is, not doubt, packaging printing. The wide spectrum of applications ranges from labels to plastic bags and paper sacks. The consistently improving quality remains a guarantee of the continuation of this course for success.

A Guide to Handling, Cleaning and Storing Cyrel® Photopolymer Printing Plates

Plate/Solvent Compatibility
Once the plate is properly made, carefully mounted and ready for printing, printing inks, extenders and plate cleaners must be carefully selected to achieve the best results. Inks, additives and cleaners may contain limited concentrations of active solvents, such as acetates, heptane or naphtha. These solvents, and several others, are incompatible with photopolymer printing plates above certain levels. They may cause swelling, or in some cases, shrinking, cracking or softening of the plate. Also, UV inks may contain aggressive monomers which attack the plate, much like aggressive solvents. The Cyrel® Plate/Ink Compatibility Guide is included in this pamphlet for easy reference. A copy can also be found in the Cyrel® Process of Use Manual.

Plate Demounting
The proper demounting procedure is important to ensure the plates are in good condition for future use.
A Cyrel® plate demounting tool, or other blunt instrument (such as a stainless steel spatula/spreader),
can be used to demount the plate. No sharp objects or knives should be used.

• Hold the tool at a 45° angle upward from the horizontal.
• Starting at the edge of the mounted plate, insert the corner of the tool to a 1/8″ to 1/4″ depth between the stickyback and the polyester support of the plate.
• Draw the tool smoothly across. This will give a free flap of the plate to grasp and peel the plate from the stickybacked cylinder.
• If the plate was properly prepared when mounted, by wiping the back with a varnish solution, demounting should not be a problem.

However, if stickyback is still aggressive, a small amount of alcohol applied at the contact point between the stickyback and mounting tape will assist in removal. It is important not to use the tool as a pry bar to
remove the plate from the cylinder. If this happens, the edge of the plate will have a wrinkled wavy appearance and will be impossible to hold down to the cylinder when the plate is remounted.

Plate Cleaning
After printing, Cyrel® plates should be cleaned immediately and thoroughly of ink with a soft, natural
bristle brush and compatible cleaner and allowed to dry before storage. Inks should not be allowed to dry
on the surface of the plate, since they become difficult to remove and may require hard scrubbing. This could
lead to surface damage. The following can be used to properly clean Cyrel® plates.

Solvent Inks
• Undiluted alcohol
• Solvent blends compatible with the plate (see Compatibility Guide).

Water-Based Inks
• Alkaline water with a small amount of mild, liquid detergent/handsoap.
• Cyrel® Flexo Super Cleaner

Ultraviolet Inks
• Undiluted alcohol
• Solvent blends compatible with the plate (see Compatibility Guide).

As mentioned before, make certain that cleanup solvents are compatible with the plate. Test a small
sample of the plate material by immersing it in the solvent for 24 hours and then measure the thickness.
Aggressive solvents, such as acetates, heptane, or naphtha should not be used for cleaning plates. Above
certain levels, these can cause damage to the plate surface and/or swell the plate.
After brushing the plates, blot or blow them dry. Use a lint-free towel or cloth. Do not rub. Plates should
always be thoroughly dried before storage.

Plate Staging and Storage
When plates are mounted and staged for press runs or cleaning, wrap plates in black poly with the edges
sealed to protect against whitelight and ozone. Saran™ wrap can also be used to minimize ozone attack;
however, if whitelight is present, the plates should also be draped with black poly.
The procedures listed below should be followed to properly store the carefully cleaned and dried Cyrel®
processed plates:

• The storage area temperature may range between 40-100°F (4-38°C).
• Humidity does not usually affect plate life, and no special precautions are necessary in the storage area.
• Do not store near heat sources, heating vents, etc.
• Plates must be protected from UV light, whitelight, fluorescent light, window light and sunlight. When storing flat, protect the plates from these lighting sources by storing the plates in black poly bags and sealing them. A UV filter material can be used to protect light from windows or room lighting.
• If plates are stored in stacks, they should be interleaved with paper or foam from raw material packing. Do not stack over 6″ high.
• Plates stored on cylinders should be wrapped with an opaque medium, such as black poly, with the edges sealed.

Naturally occurring ozone is produced by electrical discharge, such as lightning, and by the action of
intense sunlight. Protect plates from ozone by storing them away from power stations, press drives, corona
treating units and other sources of electrical discharge.
Ozone attack is most pronounced when the plate is under stress, such as when mounted and/or inked. The
following steps can minimize ozone damage to Cyrel® plates. All of them may be required when ozone levels
are very high.

1. Use ozone-resistant plate material.
2. Follow platemaking techniques, i.e., proper exposure times, drying procedures.
3. Clean and store plates properly.
4. Use compatible inks/solvents/plate cleaners.
5. Apply protective treatments when conditions are severe.

When ozone conditions are especially severe (in summer months or when known ozone generators are present), finished plates could be treated with spray protectant, such as ArmorAll™, STP Son-of-a-Gun™, etc. These solutions are sprayed on the cleaned and dried plates to form a protective layer before storage.

Care should be taken, however, not to allow this treatment to be transferred to the back of the plate. This may cause plate lifting issues.

Before printing, we recommend that the plate be thoroughly wiped with a compatible cleaning solution. After printing, the plate should be cleaned and then coated with the spray again.

Our Services