Years of real-world testing reveal that the key to aluminum foil inkjet printing boils down to two issues
In traditional printing processes, roll-type aluminum foil materials are often printed using flexographic printing, while single-sheet aluminum foil is printed by offset printing. A relatively mature process system has now been formed to accommodate the special printing suitability of aluminum foil materials. For example, to enhance color vibrancy and improve the adhesion between ink and aluminum foil materials, specialized inks made mainly from polyphthalamine or vinyl chloride vinyl acetate copolymerized resins are commonly used in the industry.
With the growing demand for personalized market and the rapidly changing market environment, the proportion of orders for small-batch, multi-variety aluminum foil printing orders continues to rise. With its core advantages of small batch sizes and personalization, inkjet printing has become an important direction for meeting this demand. However, how to ensure high-quality printing in aluminum foil printing and empower enterprises has become an urgent problem for the industry.
The needs and pain points of inkjet printing in aluminum foil material applications
Aluminum foil differs significantly from traditional printing materials such as paper, PVC, PET, BOPP, and others. In inkjet printing processes without dedicated inks, two core issues are usually encountered:
First, aluminum foil has high tensile strength, is almost non-stretchable, has low tear strength, and has a smooth surface. During roll-to-roll printing, issues such as slipping and misalignment can easily occur, potentially scratching the printhead.
Second, the surface energy of aluminum foil materials is relatively low, resulting in poor adhesion after the ink layer dries on the printed surface, making ink dropping more likely.
Based on the above issues, industrial-grade inkjet printing equipment on the market currently rarely attempts aluminum foil printing. The author has been engaged in research on digital inkjet printing solutions for many years and now shares relevant practical experience with industry peers to provide references for industry applications.
Pain Points Solution for Aluminum Foil Inkjet Printing
01
Solves issues such as paper slippage, misalignment, and nozzle scratches
Given the smooth surface and low tensile properties of aluminum foil, we need to set the tension during production to a certain extent without wrinkling or damage, thereby preventing material slippage on the guide roller and preventing deviation caused by unstable material transmission. At the same time, appropriately increasing the tension can also improve material warpage to some extent and reduce the chance of the nozzle being scratched.
It should be noted that there is no unified standard for tension settings-different equipment manufacturers use different servo drive systems and tension optimization methods. It is recommended to increase tension as much as possible in actual production, while ensuring the material does not slip.
02
Solves issues of poor ink adhesion and ink dropping
To solve the ink adhesion problem, it is first necessary to clarify the core effect of surface tension: Currently, the surface tension of inkjet printing inks on the market is generally around 38 dyn/cm. Only when the surface tension of the printing material exceeds the ink surface tension can good wetting be achieved and ink dropping avoided. However, untreated aluminum foil rarely achieves surface tension above 38 dyn/cm; Additionally, the aluminum foil surface lacks pores, preventing ink from penetrating inside, creating an "anchoring effect." Even after ink transfers and drying, ink dropping is still common.
To address this issue, we often use corona treatment or pre-coating processes to solve it. The specific practice is as follows.
(1) Corona treatment process
The principle of corona treatment is to apply a high-frequency voltage between the insulating electrode and the grounded dielectric drum, breaking down the air between the two electrodes and plasmaizing it; When these plasma particles interact with the aluminum foil surface, they can open chemical bonds on the material surface, forming free radicals that accelerate surface activation, thereby improving the surface energy and wettability of the aluminum foil, ultimately enhancing the adhesion strength between the ink and the aluminum foil surface.
In actual production, a corona device can be installed on inkjet printing equipment to achieve online corona processing, but the corona power must be determined through testing. Taking a corona device with a power of 2kW as an example, the conventional test parameters are 30%~50% of the power ratio; If about 50% power is used for corona treatment and ink buildup and ink loss still occurs, it indicates that the aluminum foil material cannot improve printing results through corona treatment. There is no need to further test other power ratios, and the process can be optimized for pre-coating.
Tests have shown that aluminum foil, as a conductive material, can significantly increase its surface energy through corona treatment, but there is still room for optimization (see Figure 1 for comparison of results).
Figure 1 Comparison of Corona Effects
(2) Pre-Coating Process
Through long-term systematic testing, the author found that the pre-coating process can significantly improve ink adhesion, but it is necessary to focus on three core issues: the selection of anilox roll line count (to control the pre-coating amount), the pre-coating method (inline/offline), and the compatibility between the pre-coating solution and the ink. These must all be determined through practical testing.
The selection of anilox rolls can follow the standards below: for conventional materials, a line count of 600–1000 lines with an ink carrying capacity of about 3.95 bcm³ is commonly used; for special materials like aluminum foil, tests suggest using an anilox roll with around 800 lines, with no need for excessive coating thickness to meet ink adhesion requirements.
Pre-coating methods are divided into offline and inline pre-coating: offline pre-coating refers to first performing pre-coating on aluminum foil using flexographic equipment, and then feeding the pre-coated aluminum foil back for inkjet printing; inline pre-coating is carried out on an inkjet printing machine equipped with a flexo unit, achieving simultaneous pre-coating and inkjet printing with greater flexibility. The author recommends using inline pre-coating for aluminum foil inkjet printing.
Choosing a pre-coating solution must consider two dimensions: first, the compatibility of the pre-coating solution with the aluminum foil material, for which a suitable traditional flexo pre-coating solution can be selected based on the type of aluminum foil; second, the compatibility of the pre-coating solution with digital ink, which must be verified through machine testing based on the digital ink brand used while ensuring compatibility with the aluminum foil.
The thickness of the pre-coating significantly affects ink adhesion. As shown in the left image of Figure 2, when the pre-coating is too thick, ink loss still occurs during scratching; the right image shows the effect of an appropriate pre-coating thickness, where even with obvious scratches, no ink loss occurs.
Figure 2 Effect of pre-coating thickness on ink adhesion
Aluminum foil materials, with their unique performance advantages, will see increasingly widespread application in the field of printing and packaging. Small batch production, personalization, and short delivery times have become the core demand trends in the upstream printing market, which requires practitioners in the digital printing field to further optimize the printability of aluminum foil materials and improve related solutions. The author will continue to explore the aluminum foil inkjet printing process in depth and will continue to exchange and share experiences with peers to help the industry improve together.