Wetting of CTP offset plate as a function of developing process.
Tomasegovic, Tamara ; Cigula, Tomislav ; Mahovic Poljacek, Sanja 等
Abstract: Offset printing is a complex process where many
parameters, such as fountain solution properties and plate making
process greatly influence quality of the final product. Aim of this
paper was to determine physical-chemical poperties of two fountain
solution types and their wetting properties on printing plates made in
different process conditions. Obtained results show that pH value and
contact angle decreases as volume of added concentrate in fountain
solution increases, while electrical conductivity enhances. Measurments
of the contact angle showed that the increase of developing speed causes
higher values of contact angle. This investigation showed that both of
investigated parameters, fountain solution and developing process,
significantly influence wetting process, consequently printing quality.
Key words: offset printing plate, fountain solution, electrical
conductivity, pH value, contact angle
1. INTRODUCTION
On the offset printing plate geometrical difference between
printing and nonprinting areas is negligible, so selective adsorption of
printing ink is achieved by different physical- chemical properties. The
nonprinting areas are made of hydrophilic [Al.sub.2][O.sub.3] which
enables them to adsorb water-based fountain solution, while printing
areas are built from oleophilic and hydrophobic photoactive layer which
in the printing process adsorbes oil-based printing ink. Different
composition and properties of the fountain solutions may cause poor
wetting resulting with low-quality imprint. Investigations in the field
of fountain solution's composition and properties have been made so
far (S. S. Deshpande).
The aim of this paper is to examine physical and chemical
properties of two fountain solutions made with different concentrates
applied on Computer to Plate (CtP) offset printing plates with
variations in developing time.
2. PLATE WETTING AND FOUNTAIN SOLUTION PROPERTIES
Wetting is a phenomenon which occurs when solid and liquid phase
come in contact. Wetting quality is observed by measuring contact angle.
Contact angle is defined as the angle between the tangent on the liquid
drop and the tangent on the solid surface in the point where all three
phases (gas, liquid and solid) meet. The lower the contact angle, the
better is the wetting.
Fountain solution is a water-based solution in which some
substances (surfactantant, buffer, biocides etc.) are added to improve
its properties. Main purpose of fountain solution is the oleophobization
of the nonprinting areas (Kipphan H., Mahovic Poljacek S et al.).
Applying the fountain solution onto nonprinting areas enhances their
oleophobic character and rejection of the printing ink. Many various
printing plates and fountain solutions are present on the market. Having
in mind ecological and economical approach one should investigate
fountain solution--printing plate combinations to diminish negative
ecological influence, but in the same time keep the desired printing
quality level.
On the other hand, processing of the printing plate has significant
impact on the printing plate quality, consequently on printing process
(Baracic et al., 2009). CtP improved standardization of exposure, but
developing process must be examined and optimized in order to enable
good fountain solution and/or printing ink adsorption (Zitinski et al.,
2009).
3. EXPERIMENTAL
3.1. Sample preparation and measurements
For the investigation two fountain solutions (Solution 1 and
Solution2) from different manufacturers were used. Samples of the
fountain solutions were prepared by adding the concentrate in
demineralized water, starting from 0% to 10% vol successively increasing
the concentration for 2% vol. Thus eleven samples of each fountain
solution were made.
Measurement of the pH value and electrical conductivity were
performed to get insight of fountain solution samples' properties
which are monitored also throughout printing process. In order to
determine influence of the developing process on the wetting of
nonprinting areas, three samples were prepared, first developed at
developing speed of 720 mm/min, second at 900 mm/min and third at 1080
mm/min. Measurements of contact angle were performed by Dataphysics OCA
30 using Sesile drop method.
3.2. Results and discussion
Results of investigations show that prepared fountain solutions
differ by their physical-chemical properties. Solution 1 has higher
values of pH and electrical conductivity in comparison with Solution 2
(Fig. 1). Solutions of lower concentrations have too high pH value,
which might damage the aluminium oxide layer, and low electrical
conductivity that could result with problems in fountain solution
transfer. Fig. 2. shows that increasing the added amount of the
concentrate causes a steady decrease in contact angle's value.
[FIGURE 1 OMITTED]
[FIGURE 2 OMITTED]
With lower concentrations, the decrease is significant, while by
increasing the fountain solution's concentration contact
angle's value streams to a constant value. Sample 2 shows slightly
lower values of contact angle compared to Sample 1, which indicates
better wetting.
[FIGURE 3 OMITTED]
At a developing speed of 900 mm / min (Fig. 3) the behavour of
contact angle values is similar to the developing speed of 720 mm / min.
At lower amount of added concentrate Sample 2 also shows slightly lower
values of the contact angle, while at higher amount of added concentrate
(over 6% vol) both samples have approximately the same value of the
contact angle. Increasing the developing speed to 1080 mm / min (Fig. 4)
the dependence of contact angle on the concentration of fountain
solution is generally higher than with the developing speed of 720 and
900 mm / min. Sample 1 shows a considerably higher values of the contact
angle compared to Sample 2 and thus lower level of adsorption of the
fountain solution onto nonprinting areas.
[FIGURE 4 OMITTED]
[FIGURE 5 OMITTED]
In figure 5 one can see contact angle values of fountain solution
samples at 6% vol at investigated developing speeds. It can be seen that
best wetting results are obtained with Solution 2 on printing plate
developed at developing speed of 720 mm/min. On the other hand, worst
results are noticed by Solution 1 on printing plate developed in the
shortest time (developing speed 1080 mm/min).
4. CONCLUSION
Obtained results showed that used concentrate for fountain solution
has a significant impact on its electrical conductivity and pH value.
Concentrate used for composure of Solution 2 has smaller influence on pH
value and electrical conductivity than concentrate for Solution 1. pH
value of both solutions increases linearly with increasing value
percentage of concentrate. From contact angle measurements one can
conclude that adding concentrate causes decrease of contact angle value.
Printing plate made with developing speed of 720 mm/min shows nealy the
same wetting with both solutions. Results indicate that in investigated
conditions would be best to use developing speed of 720 mm/min and
Solution 2. In addition, this research proved significance of observed
parameters and implies necessity of conducting investigation when
changing working materials in order to sustain needed quality level of
production. For the complete understranding and optimization of the
plate making process one should conduct thorough research which will be
directed in determination of all other process parameters significance.
5. REFERENCES
Baracic M., Cigula T., Tomasegovic T., Zitinski Elias P. Y., Gojo
M. (2009). Influence of Plate Making Process and Developing Solutions on
the Nonprinting Areas of Offset Printing Plates, Proceedings, 20th
International DAAAM Symposium: "Intelligent Manufacturing &
Automation: Theory, Practice & Education", (ed. B. Katalinic),
ISBN 978-3-901509-70-4, Vienna, Austria
Deshpande S.S. (2011.). Fountain solution in lithographic offset
printing, Journal of Engineering Research and Studies, E-ISSN0976-7916,
Beed
Kipphan H. (2001 .). Handbook of print media, Springer-Verlag, ISBN
978-3-540-67326-2, Heidelberg, Germany
Mahovic Poljacek S.; Agie D. & Gojo M. (2006.). Influence of
the Chemical Processing on the CtP Printing Forms, Annals of DAAAM for
2006. and Proceedings of 17th International DAAAM Symposium (ed. B.
Katalinic), ISBN 3-901509-57-7, Vienna, Austria
Zitinski Elias P. Y., Tomasegovic T., Cigula T. (2009.).
Differences in Physical-Chemical Properties of the Nonprinting Areas for
Conventional and CIP Process, Printing Future Days 09 Proceedings, ISBN:
978-3-89700-108-4, Chemnitz, Germany
