Pad printing

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This article is part of the series on the History of printing
Technologies
Phaistos Disc	1850–1400 BC
Woodblock printing		200 AD
Movable type		1040
Intaglio		1430s
Printing press		1439
Lithography		1796
Offset press		by 1800s
Chromolithography		1837
Rotary press		1843
Flexography		1890s
Screen-printing		1907
Dye-sublimation		1957
Photocopier		1960s
Pad printing		1960s
Laser printer		1969
Dot matrix printer		1970
Thermal printer
Inkjet printer		1976
Digital press		1993
3D printing
v • d • e

Pad printing is a printing process that can transfer a 2-D image onto a 3-D object. This is accomplished using an indirect offset (gravure) printing process that involves an image being transferred from the printing plate (cliché) via a silicone pad onto a substrate (surface to be printed). Pad printing is used for printing on otherwise impossible products in many industries including medical, automotive, promotional, apparel, electronics, appliances, sports equipment and toys. It can also be used to deposit functional materials such as conductive inks, adhesives, dyes and lubricants.

Physical changes within the ink film both on the cliché and on the pad allow it leave the etched image area in favor of adhering to the pad, and to subsequently release from the pad in favor of adhering to the substrate (material being printed).

The unique properties of the silicone pad enable it to pick the image up from a flat plane and transfer it to a variety of surface (i.e. flat, cylindrical, spherical, compound angles, textures, concave surfaces, convex surfaces).

Contents 1 History 2 How it works 2.1 Pad Printing Cycle 2.2 Plate and ink interface technologies 2.2.1 Open inkwell system (older technology) 2.2.2 Sealed ink cup system (latest technology) 2.3 Printing pad 2.4 Image plate 2.5 Printing ink 2.6 Substrate 3 Printing plate making 4 Printing application examples 5 See also 6 Further reading

[edit] History

Since the late 1960s, an old printing method, which had been particularly well established in the watch-making industry, has been an unexpected boom. Pad printing was discovered for newer, broader applications and with the help of silicone pads and new machine constructions it truly blossomed. Pad printing machine manufacturers began multiplying and satisfied the real market need for printing and decorating parts in a simple and inexpensive way. Pad printing allows new designing possibilities for engineers and designers as a result, the products are becoming more attractive and functional.

Today, pad printing has reached a technical advanced state and the range is quite diversified.

[edit] How it works

[edit] Pad Printing Cycle

1. From the home position, the sealed ink cup (an inverted cup containing ink) sits over the etched artwork area of the printing plate, covering the image and filling it with ink.
2. The sealed ink cup moves away from the etched artwork area, taking all excess ink and exposing the etched image, which is filled with ink. The top layer of ink becomes tacky as soon as it is exposed to the air, which is how the ink adheres to the transfer pad and later to the substrate.
3. The transfer pad presses down onto the printing plate momentarily. As the pad is compressed, it pushes air outward and causes the ink to lift (transfer) from the etched artwork area onto the pad.
4. As the transfer pad lifts away, the tacky ink film inside the etched artwork area is picked up on the pad. A small amount of ink remains in the printing plate.
5. As the transfer pad moves forward, the ink cup also moves to cover the etched artwork area on the printing plate. The ink cup again fills the etched artwork image on the plate with ink in preparation for the next cycle.
6. The transfer pad compresses down onto the substrate, transferring the ink layer picked up from the printing plate to the substrate surface. Then, it lifts off the substrate, returning to the home position, which completes one print cycle.

[edit] Plate and ink interface technologies

[edit] Open inkwell system (older technology)

Open ink well systems use a trough (ink well) for the ink supply, located behind the printing plate. A flood bar pushes a pool of ink over the plate, and a doctor blade removes the ink from the plate surface, leaving ink on the etched artwork area ready for the pad to pick up.

[edit] Sealed ink cup system (latest technology)

Sealed ink cup systems employ a sealed container (ink cup), which acts as the ink supply, flood bar and doctor blade all in one. A ceramic ring with a highly polished working edge provides the seal against the printing plate.

Types and applications of ink cups and doctoring rings

[edit] Printing pad

Pads are three dimensional objects typically molded of silicone rubber. They function as a transfer vehicle, picking up ink from the printing plate, and transferring it to the part (substrate). They vary in shape and durometer depending on the application.

There are three main shape groups: "round pads", long narrow pads called "bar pads", and miscellaneous shapes (square, rectangular, etc.) called "loaf pads". Within each group there are three size categories: small, medium, and large size pads. It is also possible to engineer custom-shaped pads to meet special application requirements.

How to select printing pads

[edit] Image plate

Image plates are used to contain the desired artwork "image" etched in its surface. Their function is to hold ink in this etched cavity, allowing the pad to pick up this ink as a film in the shape of the artwork, which is then transferred to the substrate.

There are two main types of printing plate materials: photopolymer and steel. Photopolymer plates are the most popular, providing a good do-it-yourself option. These are typically used in short to medium production runs. Steel plates come in two choices: thin steel for medium to long runs, and thick steel for very long runs. Both steel plate types are generally processed by the plate supplier as it involves the use of specialized equipment.

[edit] Printing ink

Ink is used to mark or decorate parts. It come in different chemical families to match the type of material to be printed (please consult the substrate compatibility chart for selection).

Pad printing inks are "solvent-based" and require mixing with additives at the time of use. They typically dry to the touch in seconds although complete drying (cure) might take a substantially longer period of time. Please consult with our ink technical sheets for batch makeup information and watch our Ink Mixing instructional video.

Climatic conditions will significantly affect the performance of any pad printing ink, please bear this in mind when planning the location of your pad printer. Always consult Federal, State and local regulations regarding proper handling, storage and disposal of inks.

[edit] Substrate

Substrate is the technical name used to address any parts or materials to be printed, and it is critical to match substrates and ink series as to their chemical compatibility. Please consult the substrate compatibility chart for proper ink selection. Typically you will need a "jig" or "fixture" to hold and support your substrate in order to ensure good quality printing. Note that substrates need to be clean and free from surface contamination to allow proper ink adhesion.

[edit] Printing plate making

There are two main techniques used to create a printing plate. The traditional technique requires a UV exposure unit and involves photo exposure with film positives and chemical etching of a photopolymer plate. [1] A newer technique known as "computer to plate" requires a laser engraver and involves laser etching of a steel or specialized polymer plate. The latter technique provides several advantages over the former; among them:

• Print quality is improved due to minimized loss of resolution. With photo exposure, the image is first transferred on film positive and only them, on the plate. Thus the image on the plate is second generation. With laser etching, the image is transferred on the plate directly from a digital file. Thus the image is first generation and better quality.

• The image on the plate is easily duplicated. Unlike chemical etching that involves several steps with many variables and manual work, laser etching is a simple, easily repeatable procedure with stable results. Plates can be made the same every time.

• Laser etching enables “combination etching” - using halftones for bold areas and open etch for fine graphics.

• With laser etched plate, ink lay down is improved. Laser engraved steel and polymer plates have a straight walled etching and more precise inkwell than photopolymer, thin or thick steel plates.

• Laser etching saves time. Chemical etching usually takes 15-20 minutes for a plate; laser etching takes about 1-5 minutes per plate.

• Laser etching is "greener." Laser etching does not involve chemicals and thus eliminates hazardous waste.

More about computer to plate technology in pad printing

[edit] Printing application examples

• Golf ball logos/graphics
• Decorative designs/graphics appearing on Hot Wheels or matchbox toy cars
• Letters on computer keyboards and calculator keys
• TV and computer monitors
• Identification labels and serial numbers for many applications

[edit] See also

• Kent Pad Printer Canada Inc.
• Gravure printing
• Printing
• Printex
• Inkjet printer
• LED printer
• Thermal printer
• Dye-sublimation printer
• Printer steganography

[edit] Further reading

• Kent Pad Printer Canada Inc. "What is pad printing?"
• Printex "An introduction to Pad Printing"
• Inkcups Now "Comparison of open inkwell system and sealed ink cup system"