BoPET explained

BoPET (biaxially oriented polyethylene terephthalate) is a polyester film made from stretched polyethylene terephthalate (PET) and is used for its high tensile strength, chemical stability, dimensional stability, transparency, reflectivity when metallized, gas and moisture barrier properties, and electrical insulation. The film is "biaxially oriented", which means that the polymer chains are oriented parallel to the plane of the film, and therefore oriented in two axes.[1] A variety of companies manufacture boPET and other polyester films under different brand names. In the UK and US, the best-known trade names are Mylar, Melinex, Lumirror and Hostaphan.[2] It was the first biaxially oriented polymer to be manufactured on a mass commercial scale.[3]

History

BoPET film was developed in the mid-1950s,[4] [5] originally by DuPont,[4] Imperial Chemical Industries (ICI), and Hoechst.

In 1953 Buckminster Fuller used Mylar as a skin for a geodesic dome, which he built with students at the University of Oregon.

In 1955 Eastman Kodak used Mylar as a support for photographic film and called it "ESTAR Base".[6] The very thin and tough film allowed 6000feet reels to be exposed on long-range U-2 reconnaissance flights.[7]

In 1964, NASA launched Echo II, a 400NaN0 diameter balloon constructed from a 9μm thick mylar film sandwiched between two layers of 4.5μm thick aluminium foil bonded together.[8]

Manufacture and properties

The manufacturing process begins with a film of molten polyethylene terephthalate (PET) being extruded onto a chill roll, which quenches it into the amorphous state. It is then biaxially oriented by drawing. The most common way of doing this is the sequential process, in which the film is first drawn in the machine direction using heated rollers and subsequently drawn in the transverse direction, i.e., orthogonally to the direction of travel, in a heated oven. It is also possible to draw the film in both directions simultaneously, although the equipment required for this is somewhat more elaborate. Draw ratios are typically around 3 to 4 in each direction.

Once the drawing is completed, the film is "heat set" and crystallized under tension in the oven at temperatures typically above .[9] The heat setting step prevents the film from shrinking back to its original unstretched shape and locks in the molecular orientation in the film plane. The orientation of the polymer chains is responsible for the high strength and stiffness of biaxially oriented PET film, which has a typical Young's modulus of about . Another important consequence of the molecular orientation is that it induces the formation of many crystal nuclei. The crystallites that grow rapidly reach the boundary of the neighboring crystallite and remain smaller than the wavelength of visible light. As a result, biaxially oriented PET film has excellent clarity, despite its semicrystalline structure.

If it were produced without any additives, the surface of the film would be so smooth that layers would adhere strongly to one another when the film is wound up, similar to the sticking of clean glass plates when stacked. To make handling possible, microscopic inert inorganic particles, such as silicon dioxide, are usually embedded in the PET to roughen the surface of the film.[10]

Biaxially oriented PET film can be metallized by vapor deposition of a thin film of evaporated aluminium, gold, or other metal onto it. The result is much less permeable to gases (important in food packaging) and reflects up to 99% of light, including much of the infrared spectrum. For some applications like food packaging, the aluminized boPET film can be laminated with a layer of polyethylene, which provides sealability and improves puncture resistance. The polyethylene side of such a laminate appears dull and the boPET side shiny. Other coatings, such as conductive indium tin oxide (ITO), can be applied to boPET film by sputter deposition.

Applications

Uses for boPET polyester films include, but are not limited to:

Flexible packaging and food contact

Covering over paper

Insulating material

Solar, marine, and aviation

Science

Electronic and acoustic

Printing media

Other

See also

External links

Notes and References

  1. Book: Drobny, Jiri George . Handbook of Thermoplastic Elastomers . 2014-05-30 . Elsevier . 978-0-323-22168-9 . en.
  2. Book: Biaxial Stretching of Film: Principles And Applications . 48 . Mark T. DeMeuse . Elsevier . 2011. 9780857092953 .
  3. Book: Jenkins, Wilmer A. . Plastic Films: echnology and Packaging Applications . Osborn . Kenton R. . 1992-09-25 . CRC Press . 978-0-87762-843-9 . en.
  4. Izard, Emmette Farr, "Production of polyethylene terephthalate", U.S. patent no. 2,534,028 (filed: 1948 May 13; issued: 1950 December 12).
  5. Adams, John Francis Edward; Gerber, Kenneth George; Holmes-Walker, William Anthony, "Process for the production of biaxially oriented polyethylene terephthalate film", U.S. patent no. 3,177,277 (filed: 1957 May 10 ; issued: 1965 April 6).
  6. Web site: Kodak HCF Film/ESTAR Base . www.kodak.com . . 2018-08-24 . April 2015.
  7. Eyes in the Sky, Dino A. Brugioni 2010, Naval Institute Press,, pp. 102, 115.
  8. Staugaitis, C. & Kobren, L. (1966) "Mechanical And Physical Properties of the Echo II Metal-Polymer Laminate (NASA TN D-3409)", NASA Goddard Space Flight Center.
  9. Book: DeMeuse, Mark T. . Biaxial Stretching of Film: Principles and Applications . 2011-07-18 . Elsevier . 978-0-85709-295-3 . en.
  10. Web site: Thiel . Ulrich . Polyester Additives . Dr. Thiele Polyester Technology . 4 January 2019.
  11. Web site: Specifications for Polyester: Poly(ethylene-terephthalate). Preservation. Library of Congress. dead. https://web.archive.org/web/20040623151837/http://lcweb.loc.gov/preserv/supply/specs/500-500.html. June 23, 2004.
  12. Web site: What is Mylar Paper - More Than Just Decoration. Jampaper.com. 23 October 2013. 2015-07-02.
  13. Scott . Randall W. . A Practicing Comic-Book Librarian Surveys His Collection and Craft . Serials Review . 24 . 1 . 1998 . 49 - 56 . 10.1080/00987913.1998.10764429 .
  14. Web site: Albany library's entire collection exposed to smoke. Athens Messenger. Athens County Public Libraries. Kristen Heinichen. June 17, 2008. 2015-07-02. https://web.archive.org/web/20150703083704/http://www.myacpl.org/node/618 . 2015-07-03 . dead.
  15. Web site: How to Convert Mylar Aerospace Drawings to 3D CAD. 31 January 2018. CAD / CAM Services.