Tyvek® for Packaging - Technical Tips

Topics

Printing

Flexographic Printing
Lithographic Printing
Screen Printing
Gravure Printing
Letterpress Printing
Ink Jet Printing
Laser (Electrostatic) Printing

Cutting and Winding

Slitting, Sheeting, and Cutting
Die Cutting

Seaming and Sealing

Heat Sealing
Dielectric Sealing
Ultrasonic Sealing
Glueing

Laminating and Coating

Laminating
Coating

Recycling

Mechanical Recycling
Chemical Feedstock Recycling

Disclaimer Information

Proper Handling Produces Better Results...

Although Tyvek^® brand material is converted in much the same way as paper or plastic films and on the same equipment, it does require different handling techniques for optimum results. For this reason, we strongly recommend that those who have never worked with Tyvek^® before conduct a pilot run to fully test each conversion operation before beginning full-scale production.

Some things to keep in mind:

Tyvek^® cannot be crush-cut as easily as paper. Its filaments are very strong and each must be completely severed; "hangers" will not break off.
Tyvek^® elongates more than paper and will stretch up to 20-30% before breaking. To minimize distortion or neck-down, keep web tension as low as practical -- 0.75 lb/in. (1.3 N/cm) -- during processing.
Tyvek^® may occasionally curl when sheeted because of its inherent "memory." Conventional decurler (breaker bar) equipment can be used at minimum tension."
Tyvek^® has its own natural lubricity and does not contain abrasive fillers or binders. It therefore requires no additional lubricants for processing. In fact, lubricants should be avoided since some contain low-molecular-weight hydrocarbons which can cause swelling and distortion.
Flying splices can be made with all styles of Tyvek^®. A pressure-sensitive tape is recommended for butt splices.
Tyvek^® is a thermoplastic material and it melts sharply at 275°F (135°C).
When coating or laminating Tyvek^®, the web temperature in the oven should not exceed 175°F (79°C).

Printing

DuPont Tyvek^® is an excellent printing substrate that can be printed in much the same way as paper, using standard commercial printing equipment. However, because of its unique physical properties, and the fact that some styles are neither corona nor antistat treated, special steps must be taken to obtain optimum printing results.

Please contact us for the names of lithographic and/or flexographic printers that have experience with Tyvek^®. Undoubtedly, there are other printers who are capable of producing satisfactory results when printing on Tyvek^®. This list is intended only as a guide and is not a recommendation of any specific company.

Flexographic Printing

Flexography is the recommended technique for printing on "type 10" styles of Tyvek^®. For best results, use the smooth side of the sheet. The difference between the rough ("wire") side and the smooth side is minor, but can usually be felt. Rolls supplied directly from DuPont are wound smooth side out. Rolls supplied from a converter may be wound differently. Be sure to check with your converter or supplier to determine how your rolls are wound. Other important recommendations are listed here.

Press Conditions

Ensuring optimum press conditions will help prevent sheet distortion, registration problems in multi-color work, softening of adhesives and ink pick-off.

Tensions -- Keep tensions below 0.75 lb/lineal in. (1.3 N/cm) of width.
Temperatures -- Maintain web temperatures below 175°F (79°C).
Chilled Rolls -- Use chilled rolls before windup.

Printing Plates

Selecting the appropriate type of printing plate to use will depend on the nature of the job.

For Overall Print Uniformity (even with type as small as 4 points) -- Use DuPont Cyrel^® photopolymer plates with a 50 Durometer hardness (Shore A), mounted with 15 mil to 20 mil (0.38 mm to 0.51 mm) of sticky-back, closed-cell foam.
For Fine-Line Reverses Greater than 13 Mil (0.33 mm) -- Use soft natural rubber plates with a 30 Durometer hardness (Shore A), backed up with 15 mil to 20 mil (0.38 mm to 0.51 mm) of sticky-back, closed-cell foam.

Inks

Using the proper ink is important for achieving high-quality results.

Alcohol-Based Polyamide Inks -- These solvent-based inks typically provide the best adhesion and rub resistance. Adding microcrystalline wax will reduce offsetting.
Water-Based Inks -- These inks help users remain in compliance with state environmental regulations while achieving high-quality results.

Please contact us for the names of some of the companies that supply inks which can be used with Tyvek^® in both the lithographic and flexographic processes. Undoubtedly, there are other suppliers who are capable of producing satisfactory inks for use with Tyvek^®. This list is intended only as a guide and is not a recommendation of any specific company.

Top of page

Lithographic Printing

Although flexography is the recommended method for printing on "type 10" styles of Tyvek^®, offset lithography can produce acceptable print quality. For best results, use the smooth side of the sheet. Although either side prints well, the smooth side, with a slight downward curl at the edges, is preferred because it makes sheet feeding slightly easier. The difference between the rough ("wire") side and the smooth side is minor, but can usually be felt. Rolls supplied directly from DuPont are wound smooth side out. Rolls supplied from a converter/distributor may be wound differently. Be sure to check with your supplier to determine how your rolls are wound. Other important recommendations are listed here.

Offset Blankets

Selecting the appropriate type of blanket to use will depend on whether or not the Tyvek^® is coated.

For Adhesive-Coated Tyvek^® -- Use conventional offset blankets of medium hardness.
For Uncoated Tyvek^® -- Use compressible offset blankets.

Squeeze

Applying an additional 3 mil to 4 mil (0.08 mm to 0.10 mm) of squeeze between the blanket and back cylinder is required compared to that used for paper of equivalent average thickness. This additional impression, coupled with the compressibility of Tyvek^®, compensates for the thickness variation of Tyvek^®.

Inks

Using the proper ink and following these specific recommendations are important for achieving high-quality results.

Low-Solvent-Content Inks -- Use inks with <3% volatile solvent because hydrocarbon solvents found in many litho inks tend to swell and distort Tyvek^®. Using low-solvent-content inks also benefits the environment because these materials release fewer volatile organic compounds (VOCs) than traditional offset inks.
Extra Strong Colors -- Use extra strong colors to keep ink film thickness to a minimum (<0.3 mil [<0.008 mm]). This will help minimize sheet distortion and dot gain.
Tint Creation -- Use opaque white rather than an extender when creating tints to minimize the appearance of fiber swirl.
Fountain Solution -- Maintain fountain solution at a minimum level. Either conventional water or alcohol/water dampening systems can be used. Alcohol substitutes also work well. If your images appear dull or washed out, reduce the amount of dampening solution in the fountain; do not increase the ink volume.
Drying -- Because litho inks dry more slowly on Tyvek^® than they do on paper, be sure that pile height does not exceed 20 in. (0.5 m). Winding the sheets and maintaining the fountain solution at a pH between 4 and 5 will also accelerate drying.

Special Notes for Adhesive-Coated Tyvek^®

When selecting offset inks, it is important to advise the ink supplier if the Tyvek^® has an adhesive coating because special ink formulations may be required to prevent ink set-off to the coated surface. In some cases, printing is done on the adhesive side. This also should be discussed with the ink supplier to ensure optimum compatibility between the ink and the coating.

Top of page

Other Printing Methods

Although the overwhelming majority of converters of Tyvek^® use flexography and lithography for printing, some prefer to use other methods for certain low-volume and specialty applications.

Screen Printing

Screen process printing has been used successfully to print on Tyvek^® for specific applications, especially short press runs of jobs using large type and simple graphics. Because of the high potential for static and/or ink pick-off, the use of paper slip sheets is sometimes required.

The inks used must be specially formulated for the lower surface tension encountered when printing on untreated styles of Tyvek^®. Lacquer-type inks are preferred because they produce a minimum amount of distortion. Water-based inks work well because they minimize distortion -- even with heavy ink-film thicknesses. Ultraviolet-cured screen inks also have been used successfully. Screen "poster inks" and enamels, which both contain a high percentage of mineral spirits, should be avoided.

Tyvek^® is high-density polyethylene (HDPE), with a melting point of 275°F (135°C). When using conveyor ovens instead of room-temperature drying, the sheet temperature should be kept below 175°F (79°C). When using UV-cured screen inks, cooling is required to prevent sheet distortion or shrinkage.

Gravure Printing

Gravure is a high-quality printing technique that uses costly engraved metal cylinders to print extremely long runs of multiple-color jobs. Since gravure printing uses basically the same ink formulations that are used in flexography, no problems are anticipated; however, we advise careful testing before using this technique on Tyvek^®.

Letterpress Printing

Letterpress is a technique used for short press runs involving a single color, relatively small sheet sizes and simple graphics and line art. Due to the tendency of untreated styles of Tyvek^® to generate static electricity, multiple press passes should be avoided (e.g., a one-color press should not be used for multiple-color printing). As in screen printing, paper slip sheets are sometimes required, particularly when printing on Tyvek^® with an adhesive coating.

To minimize the tendency of Tyvek^® to curl or pucker, the least possible ink film thickness should be applied, with a goal of 0.3 mil (0.0076 mm). Because of the high compressibility of Tyvek^®, more plate packing is required than for an equivalent thickness of paper. To obtain proper ink fill, deep and sharp embossing patterns should be avoided.

Inks for use in letterpress printing on Tyvek^® are similar to offset/litho inks, and are typically formulated from rosin esters and long oil alkyds. These inks can be diluted with drying oils, such as tung (chinawood oil) or linseed oil. High-boiling, "quick-dry" petroleum solvents and aliphatic hydrocarbon resins, which can cause distortion and sheet swelling, should not be used. "Dry pigment grinds" should be used to avoid the residual solvent found in pigments made from flushes.

Ink Jet Printing

Ink jet printing is used primarily for lot and batch marking in automatic form-fill-seal processes in the sterile packaging industry. Tests conducted by DuPont have shown that solvent-based ink systems (ketone/ alcohol) work well with Tyvek^® in the ink jet process. On the other hand, most of the water-based inks that we tested would feather and blur to some extent. In addition, they are slower to dry.

Laser (Electrostatic) Printing

Laser or electrostatic printing is not recommended for Tyvek^® due to the high temperatures used in the fusing section of the printer. Untreated styles of Tyvek^® have a higher propensity to jam in the fuser, where the high temperature will cause it to melt.

Top of page

Cutting and Winding

Slitting, Sheeting and Cutting

"Type 10" styles of Tyvek^® can be slit and cut into sheets on most commercial equipment using conventional paper-cutting techniques. However, the inherent toughness of Tyvek^® requires that all cutting parts be kept clean and sharp, with true, well-supported, nick-free edges. A sharp, slightly rounded edge gives longer service than a pointed edge for crush cutting, but a sharp edge is preferred for other slitting methods.

When it is necessary to convert styles that have no antistat coating, such as styles 1059B and 1073B, the use of conductive "tinsel" or ionized air produced by an electrostatic generator or a radiation bar will usually reduce the buildup of static to an acceptable level. Antistatic agents or aerosol sprays should not be used on Tyvek® that will be used in sterile or food packaging.

Multiple roll sheeting (4-6 rolls) works well with Tyvek® and is preferred for the lightweight styles less than 2.2 oz/yd² (74.6 g/m²).

To minimize cutting problems:

Replace straight-edged blades with blades that have a wavy or serrated edge.
Use blades coated with Teflon® TFE fluorocarbon or lubricated with a nonstaining silicone spray.
Reduce the cutting stroke from 1.5 inches (3.8 cm) down to 1 in. (2.5 cm).
Operate at 1800 rpm instead of 3600 rpm.

Die-Cutting

Sheets of Tyvek® can be die-cut using either steel rule (sharp edge) or male/female dies. Since the inherent toughness of the material requires that male/female dies be manufactured to close tolerances, steel rule dies are usually preferred. Tyvek® fibers must be completely cut; dies must be kept in good condition, with sharp, true, nick-free, well-supported edges. Dull dies cause cut edges to curl. On steel rule or high dies, slight internal relief helps reduce heat buildup. When working with closed dies, the strength of Tyvek® will probably require use of a side cutter or chisel edge to speed up release and prevent die and product damage. Dies should be hardened to Rockwell C 50-60 to extend their life.

Keep lift heights below 3 in. (7.6 cm) when die-cutting to avoid oversizing top blanks by edge compression as the die comes down. Use of a center-die pressure cylinder can help deaerate and compact the lift, and minimize slippage.

Top of page

Seaming and Sealing

Heat Sealing

While it is possible to fuse Tyvek® to itself using only heat, strong seals are difficult to obtain. This is due to the fact that melting Tyvek® destroys the fiber structure, reducing both flexibility and tear strength in the seal area. However, if Tyvek® is heat-sealed to itself, those styles with no antistat coating and no corona treatment (such as styles 1059B and 1073B) should be used. This is because the molecular film of oxide and antistat on the surface of corona-treated/antistated styles causes Tyvek® to melt unevenly, which reduces seal strength.

Trim seal dies, designed with a spring-loaded restraining plate, have been used successfully for heat sealing. However, the preferred method is to apply a coating such as branched polyethylene, which has a lower melting point than Tyvek®. With such a coating, high seal strengths can be achieved using hot-bar or impulse techniques

Dielectric Sealing

Tyvek®, like polyethylene film, cannot be dielectrically sealed by conventional methods. However, commercial proprietary processes have been developed that allow Tyvek® to be dielectrically sealed using conventional radio-frequency equipment.

Ultrasonic Sealing

Recent developments in ultrasonic sealing have also demonstrated fiber tearing seals with most styles of Tyvek®, without the puckering that is often associated with heat seals of Tyvek®. This process also forms strong seals to a variety of plastic films and nonwovens. For more information on sealing, please contact us.

Glueing

A number of adhesives can be used to glue Tyvek®, either to itself or to other substrates. In general, water-based adhesives that provide quick tack and fast drying are preferred. However, the first step in choosing an adhesive is to determine how it will react with Tyvek®. Laboratory testing is the best way to make this determination. Please contact us for a list of solvents that are preferred for use with Tyvek® (ask for the "Product Properties & End-uses Handbook").

Natural-product adhesives based on starch, dextrin, casein or animal by-products are preferred to synthetic-based adhesives. Synthetic adhesives often contain low-molecular-weight materials that can act as solvents at elevated temperatures and cause swelling and wrinkling. Hot animal glue is an excellent adhesive for adhering Tyvek® to paperboard. Water-based synthetic lattices also bond Tyvek® to itself and a variety of substrates. Ethylene/vinyl acetate adhesives are especially useful, as are the acrylic pressure-sensitive adhesives. Solvent-based single-component polyurethane adhesives provide optimum adhesion (lap and shear), flexibility and water-resistance for adhering Tyvek® to itself and a variety of substrates.

Hot-melt adhesive technology has been amply demonstrated in a number of applications involving Tyvek®, including the construction of desiccants, envelopes, and medical packaging. Care must be exercised in adhesive selection and consultation with the adhesive manufacturer is recommended. Please contact us for a list of some of the companies that have formulated satisfactory adhesives for Tyvek®. Undoubtedly, there are other suppliers who are capable of producing satisfactory adhesives for use with Tyvek®. This list is intended only as a guide and is not a recommendation of any specific company."

Top of page

Laminating/Coating

Tyvek® material can be laminated or coated with a wide range of films, foils and papers for a variety of end uses. When coating or laminating Tyvek®, the web temperature in the oven should not exceed 175°F (79°C)."

Laminating

Tyvek® can be extrusion-, adhesive-, and calender-laminated. Examples of end uses include Tyvek® laminated to foil in military and electronics packaging, and Tyvek® laminated to polyethylene film as a ply in bag construction. When additional liquid holdout or hazardous chemical protection is required, Tyvek® can be extrusion-coated with polyethylene or laminated to a polyvinylidene chloride film.

Coating

Tyvek® can be coated with a wide range of solvent and water-based solutions using conventional equipment. In general, air-knife coating is preferred for aqueous coating systems, as it gives uniform thickness of coating. It also produces a very smooth surface, which is ideal for offset lithographic printing. Gravure coating has been used successfully for solvent-based coating systems and is recommended if deep coloration is required. Pyroxylin coating formulations containing a high concentration of isopropyl alcohol (25%) are preferred for obtaining deep coloration.

Top of page

Recycling

Mechanical recycling

Tyvek® is made from 100% high-density polyethylene (HDPE). For this reason, Tyvek® or products made from Tyvek® can be mechanically recycled into products such as underground cable protection piping, automotive parts, blown film, packaging cores and trays. Products made from Tyvek® which are printed, glued, welded or sewn can also be recycled as can Tyvek® which has been extrusion coated or laminated with an item from the same polymer family. Polyethylene can normally be recycled 4 to 5 times before physical properties are substantially affected.

At the end of their useful life, products made from Tyvek® can be recycled via your local recycler for polyethylene waste. Additionally DuPont has set up a network of recyclers who have agreed to take back items made from Tyvek® for mechanical recycling into other products. (The items sent for recycling must not have been in contact with any hazardous substance.)

Chemical feedstock recycling

Tyvek®, together with other synthetic waste, can be processed through chemical feedstock recycling. The chemical components are separated and these basic raw materials are recovered for reuse, thus reducing consumption of new oil resources.

A custom program can be set up for you that works with local recyclers in your region. For more information, contact:

Terry Fife - Tyvek® Recycling Specialist
1-800-222-5676 or 1-800-44-TYVEK®

Disclaimer Information

We believe that this information is the best currently available on the subject, it is offered as a possibly helpful suggestion in experimentation you may care to undertake along these lines. It is subject to revision as additional knowledge and experience are gained. DuPont makes no guarantee of results and assumes no obligation or liability whatsoever in connection with this information. Anyone intending to use recommendations contained in this web site concerning equipment, processing techniques, or chemical products should first satisfy himself that the recommendations are suitable for his use and meet all appropriate safety and health standards. This web site is not a license to operate under, or intended to suggest infringement of, any existing patents.

Rapidly advancing knowledge of new, long-term toxic effects of many chemicals has emphasized the need to reduce human exposure to many chemicals to the lowest practicable limits. We strongly recommend that processors seek and adhere to manufacturer's or supplier's current instructions for handling each chemical they use.

Top of page

If you are interested in medical packaging applications with Tyvek®,
please click here to go to the Medical Packaging home page.