Lamination
This article has multiple issues. Please help improve it or discuss these issues on the talk page. (Learn how and when to remove these messages)
|
Lamination is the technique/process of manufacturing a material in multiple layers, so that the composite material achieves improved strength, stability, sound insulation, appearance, or other properties from the use of the differing materials, such as plastic. A laminate is a layered object or material assembled using heat, pressure, welding, or adhesives.[1] Various coating machines, machine presses and calendering equipment are used.
Materials
[edit]There are different lamination processes, depending primarily on the type or types of materials to be laminated. The materials used in laminates can be identical or different, depending on the object to be laminated, the process and the desired properties.
Textile
[edit]Laminated fabric are widely used in different fields of human activity, including medical and military.[2]: 148 Woven fabrics (organic and inorganic based) are usually laminated by different chemical polymers to give them useful properties like chemical resistance, dust, grease, photoluminescence (glowing and other light-effects e.g. in high-visibility clothing), tear strength, stiffness, thickness, and being wind proof .[3][2]: 2, 16, 18 Coated fabrics may be considered as a subtype of laminated fabrics.[2]: 1 Nonwoven fabrics (e.g. fiberglass) are also often laminated. According to a 2002 source, the nonwovens fabric industry was the biggest single consumer of different polymer binding resins.[2]: 16
Materials used in production of coated and laminated fabrics are generally subjected to heat treatment.[2]: 32 Thermoplastics and thermosetting plastics (e.g. formaldehyde polymers) are equally used in laminating and coating textile industry.[2]: 32 In 2002 primary materials used included polyvinyl acetate, acrylics, polyvinyl chloride (PVC), polyurethanes, and natural and synthetic rubbers.[2]: 33 Copolymers and terpolymers were also in use.[2]: 33
Thin-films of plastics were in wide use as well. Materials varied from polyethylene and PVC to kapton depending on application. In automotive industry for example the PVC/acrylonitrilebutadiene-styrene (ABS) mixtures were often applied for interiors by laminating onto a polyurethane foam to give a soft-touch properties.[2]: 42 Specialty films were used in protective clothing, .e.g. polytetrafluoroethylene (PTFE), polyurethane etc.[2]: 42
Glass
[edit]Plastic film can be used to laminate either side of a sheet of glass. Vehicle windshields are commonly made as composites created by laminating a tough plastic film between two layers of glass. This is to prevent shards of glass detaching from the windshield in case it breaks.
Wood
[edit]Plywood is a common example of a laminate using the same material in each layer combined with an adhesive. Glued and laminated dimensional timber is used in the construction industry to make beams (glued laminated timber, or Glulam), in sizes larger and stronger than those that can be obtained from single pieces of wood. Another reason to laminate wooden strips into beams is quality control, as with this method each and every strip can be inspected before it becomes part of a highly stressed component.
Examples of laminate materials include melamine adhesive countertop surfacing and plywood.[4] Decorative laminates and some modern millwork components are produced with decorative papers with a layer of overlay on top of the decorative paper, set before pressing them with thermoprocessing into high-pressure decorative laminates (HPDL).[5] A new type of HPDL is produced using real wood veneer or multilaminar veneer as top surface.[citation needed] High-pressure laminates consists of laminates "molded and cured at pressures not lower than 1,000 lb per sq in.(70 kg per cm2) and more commonly in the range of 1,200 to 2,000 lb per sq in. (84 to 140 kg per cm2).[6] Meanwhile, low pressure laminate is defined as "a plastic laminate molded and cured at pressures in general of 400 pounds per square inch (approximately 27 atmospheres or 2.8 × 106 pascals).[7]
Paper
[edit]Corrugated fiberboard boxes are examples of laminated structures, where an inner core provides rigidity and strength, and the outer layers provide a smooth surface. A starch-based adhesive is usually used.
Laminating paper products, such as photographs, can prevent them from becoming creased, faded, water damaged, wrinkled, stained, smudged, abraded, or marked by grease or fingerprints. Photo identification cards and credit cards are almost always laminated with plastic film. Boxes and other containers may be laminated using heat seal layers, extrusion coatings, pressure sensitive adhesives, UV coating, etc.
Lamination is also used in sculpture using wood or resin. An example of an artist who used lamination in his work is the American Floyd Shaman.
Laminates can be used to add properties to a surface, usually printed paper, that would not have them otherwise, such as with the use of lamination paper. Sheets of vinyl impregnated with ferro-magnetic material can allow portable printed images to bond to magnets, such as for a custom bulletin board or a visual presentation. Specially surfaced plastic sheets can be laminated over a printed image to allow them to be safely written upon, such as with dry erase markers or chalk. Multiple translucent printed images may be laminated in layers to achieve certain visual effects or to hold holographic images. Printing businesses that do commercial lamination keep a variety of laminates on hand, as the process for bonding different types is generally similar when working with thin materials.
Paper is normally laminated on particle or fiberboards giving a good-looking and resistant surface for use as furniture, decoration panels and flooring.[8]
Paper laminations are also used in packaging. For example, juiceboxes are fabricated from liquid packaging board which is usually six layers of paper, polyethylene, and aluminum foil. Paper is used in the lamination to shape the product and give the juicebox an extra source of strength.
The base is most often particle- or fiberboards, then some layers of absorbent kraft paper. The last layers are a decor paper covered with an overlay. The lamination papers are covered with an inert resin, often melamine, which is cured to form a hard composite with the structure of paper. The laminates may also have a lining on the back side of laminating kraft to compensate for the tension created by the top side lamination. Cheaper particle boards may have only a lining of laminating kraft to give surface washability and resistance to wear.
The decor paper can also be processed under heat and low/high pressure to create a melamine laminated sheet, that has several applications. The absorbent kraft paper is a normal kraft paper with controlled absorbency, which means a high degree of porosity. It is made of clean low kappa hardwood kraft with good uniformity. The grammage is 80 - 120 g/m2 and normally 2-4 plies are used.[8] The decor paper is the most critical of the lamination papers as it gives the visual appearance of the laminate. The impregnation resin and cellulose have about the same refraction index which means that the cellulose fibers of the paper appear as a shade and only the dyestuffs and pigments are visible. Due to this the decor paper demands extreme cleanness and is produced only on small paper machines with grammage 50 - 150 g/m2.[8] The overlay paper have grammage of 18 – 50 m2 and is made of pure cellulose, thus it must be made of well delignified pulp. It becomes transparent after impregnation letting the appearance of the decor paper come through. The laminating kraft have a grammage of 70 - 150 g/m2 and is a smooth dense kraft paper.[8]
Metal
[edit]Electrical equipment such as transformers and motors usually use an electrical steel laminate coatings to form the core of the coils used to produce magnetic fields. The thin lamination reduces the power loss due to eddy currents. Fiber metal laminate is an example of thin metal laminated by, a glass fiber-reinforced and epoxy-glued sheets.
Microelectronics
[edit]Lamination is widely used in production of electronic components such as PV solar cells.[9]
Film types
[edit]Laminate plastic film is generally categorized into these five categories:
- Standard thermal laminating films
- Low-temperature thermal laminating films
- Heat set (or heat-assisted) laminating films
- Pressure-sensitive films
- Liquid laminate
See also
[edit]- Laminated bow – Type of archery bow
- Laminator – Device used to laminate paper or card stock
- Converting – Specialist in combining raw materials to create new products
- Cladding (metalworking) – bonding together of dissimilar metals
- Composite laminates – Assembly of layers of fibrous composite materials
- Composite material – Material made from a combination of two or more unlike substances
- Carbon-fibre reinforced plastic – Light, strong and rigid composite material
- Glass-reinforced plastic – Type of plastic reinforced by glass fibre
- Delamination – Mode of failure for which a material fractures into layers
- Void (composites) – Empty space in mixed materials
References
[edit]- ^ Carter, Richard. "Method of laminating multiple layers". Google Patents. Archived from the original on 24 June 2016. Retrieved 15 February 2015.
- ^ a b c d e f g h i j Fung, Walter (2002). Coated and laminated textiles. Textile Institute. Boca Raton, FL: CRC Press. ISBN 1-59124-756-X. OCLC 57250766.
- ^ Fung, W. (9 May 2002). Coated and Laminated Textiles | ScienceDirect. Woodhead. ISBN 9781855735767. Retrieved 2021-11-26.
- ^ Martin, Alan; Harbison, Sam; Beach, Karen; Cole, Peter (2012-03-30). An Introduction to Radiation Protection 6E. CRC Press. ISBN 9781444146073.
- ^ "What Is Post-Formed Plastic Laminate?". Delorie Countertops and Doors. 21 January 2015. Archived from the original on 11 July 2018. Retrieved 15 February 2015.
- ^ McGraw-Hill Dictionary of Architecture & Construction
- ^ McGraw-Hill Dictionary of Scientific & Technical Terms, 6E, Copyright © 2003 by The McGraw-Hill Companies, Inc.
- ^ a b c d Paulapuro, Hannu (2000). "5". Paper and Board grades. Papermaking Science and Technology. Vol. 18. Finland: Fapet Oy. pp. 108–111. ISBN 952-5216-18-7.
- ^ Steim, R.; Chabrecek, P.; Sonderegger, U.; Kindle-Hasse, B.; Siefert, W.; Kroyer, T.; Reinecke, P.; Lanz, T.; Geiger, T.; Hany, R.; Nüesch, F. (2015-05-11). "Laminated fabric as top electrode for organic photovoltaics". Applied Physics Letters. 106 (19): 193301. Bibcode:2015ApPhL.106s3301S. doi:10.1063/1.4919940. ISSN 0003-6951. S2CID 119779721.