Inkjet printing

Optimization of the ink, the printing process and the substrate with surface science methods

While inkjet technology is declining in the home and office sectors, industrial applications are recording strong growth. Thanks to the multitude of possible combinations of ink types and substrates, as well as low set-up costs, inkjet printing is a very adaptable process. The quality depends very much on the control of the print heads, on the flight behavior of the droplets and on the droplet distribution on the substrate as well as on its wettability. The method of Drop Watching and the investigation of the static and dynamic surface tension of the ink as well as the surface properties of the substrate are typical applications for our measuring instruments.

 

 

Common applications of inkjet printing
  • Packaging printing and individual branding
  • Printing on ceramics, decor and glass
  • Floor coverings
  • Textile printing
  • Printable circuits
  • 3D printing

 

 

Optimization of the printing process and the ink by means of Drop Watching

Drop Watching is the examination of ink drops immediately after leaving the print head. Ideally, the piezo nozzles of the print head are controlled directly by the measuring instrument, so that the drop behavior can be observed as a direct effect of the defined waveform. The novel two-color double strobe method allows accurate measurements of volume, velocity, ligament length and the formation of satellite droplets. The results help to match print parameters and ink formulation in a targeted manner to achieve high-quality print results.

 

 

Controlling the ink’s wetting behavior with static and dynamic surface tension

Drop formation and spreading is largely controlled by the surface tension of the ink, which is commonly lowered with surfactants. Our tensiometers help to adjust the surfactant concentration by measuring the static surface tension. The critical micelle formation concentration (CMC) as an indicator for the surfactant’s efficiency is measured automatically using a wide concentration range.

 

To optimize ink in terms of wetting means to regulate the speed with which the surfactant lowers the surface tension. During ink ejection, the surface tension needs to be large enough to ensure meniscus recovery inside the nozzle, and thereby, guarantee a proper drop formation. However, after a very short flight time, the surface tension needs to be low enough to assure proper wetting of the substrate. Our bubble pressure tensiometers monitor the dynamic behavior of the surface tension in a wide range of speed.

 

 

Evaluating the wettability of the print carrier and the effect of surface treatment

The surface energy of the substrate defines the wettability and partly controls the adhesion between ink and substrates such as paper or plastics. Our Drop Shape Analyzers determine the surface free energy and its division into polar and disperse parts. This energy profile serves to optimize surface preparation steps like plasma or corona treatment.

 

As ink-jet printing drops of approximately 100 pL are ejected onto a substrate, our picoliter dosing unit, microscope optics, and high speed camera characterize this wetting process very closely to true environmental conditions.

 

 

Avoiding foam with the help of foam analysis measurements

Wherever there are surfactants involved in dynamic processes, foam formation can become a challenge to solve. Our Dynamic Foam Analyzer – DFA100 offers highly reproducible methods for measuring foam formation in the short-term range of unstable foams. This makes it a powerful tool for optimizing antifoam agents added to the ink.

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Our application experts are curious about your individual task in interfacial analysis. Contact us for a conversation and benefit from their experience.

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