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Twinwall plastic

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6mm Twinwall Polycarbonate Sheet

Twin-wall plastic, specifically twin-wall polycarbonate, is an extruded multi-wall polymer product created for applications where its strength, thermally insulative properties, and moderate cost are ideal.[1] Polycarbonate, which is most commonly formed through the reaction of Bisphenol A and Carbonyl Chloride, is an extremely versatile material.[2]

It is much lighter than glass, yet stronger, more flexible, and impact resistant. Twin-wall polycarbonate is commonly used in greenhouses, offering structural support, limiting UV light due to its translucence, and enduring outdoor conditions. The air trapped between its layers provides insulation, and adding more layers improves insulation but reduces light transmission. Similar sheets of polypropylene, PET, and HDPE are usually called corrugated plastic.

Structure

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Twinwall plastic most commonly refers to two exterior plastic sheets that are connected with a plastic support layer to create parallel channels. This design adds both impact toughness and the ability to support weight. Twinwall plastic may also be used to describe a pipe that has a smooth interior with exterior air filled ridges.[3] The outside ridges add durability to the piping while the smooth interior allows the desired contents to flow efficiently. The hollow ribs also create insulation for the piping.

Twinwall plastic can refer to several different extruded polymers including:

Polycarbonate

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Structure
Polycarbonates received their name because they are polymers containing carbonate groups (–O–(C=O)–O–). Most polycarbonates of commercial interest are derived from rigid monomers. A balance of useful features including temperature resistance, impact resistance and optical properties position polycarbonates between commodity plastics and engineering plastics.

Although polycarbonate does not stand up to ultraviolet radiation for extended periods of time, products such as Makroclear coextrude a layer of UV-resistant polycarbonate on top of the standalone polycarbonate product. This layer significantly reduces UV light damage, increasing the service life of the material by prolonging its translucence and toughness.

Polypropylene

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Structure
Most commercial polypropylene is isotactic and has an intermediate level of crystallinity between that of low-density polyethylene (LDPE) and high-density polyethylene (HDPE).[4] Polypropylene is normally tough and flexible, especially when copolymerized with ethylene. This allows polypropylene to be used as an engineering plastic, competing with materials such as acrylonitrile butadiene styrene (ABS). Polypropylene is reasonably economical, and can be made translucent when uncolored but is not as readily made transparent as polystyrene, acrylic, or certain other plastics. It is often opaque or colored using pigments. Polypropylene has good resistance to fatigue.

Polypropylene is liable to chain degradation from exposure to heat and UV radiation such as that present in sunlight. Oxidation usually occurs at the tertiary carbon atom present in every repeat unit. A free radical is formed here, and then reacts further with oxygen, followed by chain scission to yield aldehydes and carboxylic acids. In external applications, it shows up as a network of fine cracks and crazes that become deeper and more severe with time of exposure. For external applications, UV-absorbing additives must be used. Carbon black also provides some protection from UV attack. The polymer can also be oxidized at high temperatures, a common problem during molding operations. Anti-oxidants are normally added to prevent polymer degradation.

Polyethylene Terephthalate (PET)

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Structure
PET in its natural state is a colorless, semi-crystalline resin.[5] Based on how it is processed, PET can be semi-rigid to rigid, and it is very lightweight. It makes a good gas and fair moisture barrier, as well as a good barrier to alcohol (requires additional "barrier" treatment) and solvents. It is strong and impact-resistant. PET becomes white when exposed to chloroform and also certain other chemicals such as toluene.

About 60% crystallization is the upper limit for commercial products, with the exception of polyester fibers. Clear products can be produced by rapidly cooling molten polymer below Tg glass transition temperature to form an amorphous solid. Like glass, amorphous PET forms when its molecules are not given enough time to arrange themselves in an orderly, crystalline fashion as the melt is cooled. At room temperature the molecules are frozen in place, but, if enough heat energy is put back into them by heating above Tg, they begin to move again, allowing crystals to nucleate and grow. This procedure is known as solid-state crystallization.

High-Density-Polyethylene (HDPE)

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Structure
Polyethylene is a thermoplastic polymer consisting of long hydrocarbon chains.[6] Depending on the crystallinity and molecular weight, a melting point and glass transition may or may not be observable. The temperature at which these occur varies strongly with the type of polyethylene. For common commercial grades of medium- and high-density polyethylene the melting point is typically in the range 120 to 180 °C (248 to 356 °F). The melting point for average, commercial, low-density polyethylene is typically 105 to 115 °C (221 to 239 °F).

Most LDPE, MDPE and HDPE grades have excellent chemical resistance, meaning that it is not attacked by strong acids or strong bases. It is also resistant to gentle oxidants and reducing agents. Polyethylene burns slowly with a blue flame having a yellow tip and gives off an odour of paraffin. The material continues burning on removal of the flame source and produces a drip.[7] Crystalline samples do not dissolve at room temperature. Polyethylene (other than cross-linked polyethylene) usually can be dissolved at elevated temperatures in aromatic hydrocarbons such as toluene or xylene, or in chlorinated solvents such as trichloroethane or trichlorobenzene.[8]

Properties

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Comparison of various physical properties of single and multi-wall materials [1]

Twinwall Polycarbonate exhibits high degree of durability and toughness. Although single layer polycarbonate sheeting is more flexible than polycarbonate in twinwall configuration, it still retains significant advantages over alternative materials, including glass. A typical 6mm sheet has a density of 0.72 g/cm^2[9] and a thermal insulation R value of 0.3 m^2°C/W, while allowing 80% of visible light pass through.[10] These attributes, coupled with a service temperature range in excess of 120 °C (-51 °C to 71 °C), makes polycarbonate the ideal material for twinwall application.

In addition to the preferential thermal properties of polycarbonate, its ability to be recycled at the end of its service life is also highly beneficial. Polycarbonate is thermoplastic, meaning that it can be melted after polymerization. This is what allows it to be extruded, which decreases twinwall production cost.

The warm, stagnant air present within the twinwall cells can present problems. Algae and bacterial growth can be incubated inside these cells, resulting in a decrease in optical clarity, reducing the efficiency of the greenhouse.[11] Cleaning can be tricky since many solvents damage polymer glazing, like polycarbonate. Solvents break down the plastic’s structure, causing cloudiness and reducing light transmission.

Processing

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There are two main methods for making twin-wall plastic: extrusion and ultrasonic welding, though the latter is less common. Extrusion pushes melted resin through a die to form continuous sheets, usually cut into 4x8 ft panels. This method is versatile, allowing for curved panels used in awnings and other applications.[12][13]

Applications

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Twin-wall polycarbonate sheeting is used primarily as an alternative to glass.[14] Weight, flexibility, and impact strength are all benefits of using polycarbonate as a glass substitute.[15] Applications include those in which thermal insulation is necessary while still allowing light transmittance. Green houses, window replacements, shower enclosures, partitions, light covers, patio covers, carports, and windbreaks are all modern applications for twin-wall.[16] In greenhouse construction, twin-wall polycarbonate's flexibility, transparency, and insulation support horticultural success. It adapts to tough conditions and maintains stable temperatures year-round. [17]

Twinwall plastics, primarily polypropylene and HDPE, are also being increasingly utilized for waste water drainage piping. Their high strength allows them to endure the repeat stresses associated with vehicle travel over roadways, as well as the initial stress of being buried.[3]

See also

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References

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  1. ^ a b Nising, W (1986). "Twin-Wall Sheet in Polycarbonate". Kunststoffe--German Plastics. 76: 1095–1097.
  2. ^ "Polycarbonates". The Essential Chemical Industry. 2017-04-27.
  3. ^ a b "Wavin Twinwall". europipes.co.uk. 2001-04-15. Archived from the original on 2013-07-02.
  4. ^ Engineers, NPCS Board of Consultants & (2014-01-01). Disposable Products Manufacturing Handbook: Disposable Products Manufacturing, Disposable Thermocol Paper cup manufacturing business, disposable thermocol plates manufacturing process, Disposable Wet Wipes for Babies, facial tissue manufacturing process, How are plastic cups manufactured. Niir Project Consultancy Services. p. 71. ISBN 978-93-81039-32-8.
  5. ^ Resources, Management Association, Information (2017-01-11). Materials Science and Engineering: Concepts, Methodologies, Tools, and Applications: Concepts, Methodologies, Tools, and Applications. IGI Global. p. 263. ISBN 978-1-5225-1799-3.{{cite book}}: CS1 maint: multiple names: authors list (link)
  6. ^ Takada, Hideshige; Karapanagioti, Hrissi K. (2018-10-13). Hazardous Chemicals Associated with Plastics in the Marine Environment. Springer. p. 74. ISBN 978-3-319-95568-1.
  7. ^ "How to Identify Plastic Materials Using The Burn Test". Boedeker Plastics. Retrieved 8 May 2012.
  8. ^ Whiteley, Kenneth S.; Heggs, T. Geoffrey; Koch, Hartmut; Mawer, Ralph L.; Immel, Wolfgang (2000-06-15). "Polyolefins". Ullmann's Encyclopedia of Industrial Chemistry. Weinheim, Germany: Wiley-VCH Verlag GmbH & Co. KGaA. doi:10.1002/14356007.a21_487. ISBN 3-527-30673-0.
  9. ^ "Solid Polycarbonate Sheet with the Highest Impact Strength".
  10. ^ "Twin wall Polycarbonate Products". co-excorp.com. 2011-02-03.
  11. ^ "Greenhouse maintenance (pics)". Houzz. 2006-11-07. Archived from the original on 2006-11-07.
  12. ^ US Patent 4986950, "Method of Forming Polycarbonate Sheeting" 
  13. ^ "Plastic wall panels". Retrieved 2024-09-16.
  14. ^ Knippers, Jan; Cremers, Jan; Gabler, Markus; Lienhard, Julian (2012-12-17). Construction Manual for Polymers + Membranes: Materials, Semi-finished Products, Form Finding, Design. Walter de Gruyter. p. 86. ISBN 978-3-0346-1470-2.
  15. ^ "Polycarbonate TwinWall Plastic Panels & Sheets". tapplastics.com.
  16. ^ "8mm Twin-Wall Polycarbonate Sheets". farmtek.com. Archived from the original on 2013-01-23.{{cite web}}: CS1 maint: unfit URL (link)
  17. ^ "Guide to Polycarbonate Sheet Thickness for Greenhouses". ERoofing. 2022-04-27. Retrieved 2022-08-24.
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