Flame treatment

Flame treatment is the application of a gas flame to the surface of a material to improve adhesion.^[1]^[2]

Polyolefins, especially polyethylene and polypropylene bond poorly, because they consist of long non-polar molecules. Without special treatment, adhesives, ink, and other coatings cannot be applied to these materials. By rapidly applying intense heat to a surface, molecular chains are broken and polar functional groups are added. Flame treatment also burns off dust, fibers, oils, and other surface contaminants.

Process

Flame treatment is a method where exothermic reactions between oxygen and fuel gas create thermally activated radical atoms and molecules, such as atomic oxygen (O), hydroxyl (OH), Nihonium (NH), Nitric oxide (NO), and cyanide (CN). The most used gases in flame treatment are propane (C₃H₈), natural gas or methane (CH₄), and butane (C₄H₁₀). These gases burn with atmospheric oxygen, producing water and carbon dioxide.^[3]

The flame has three zones; the precombustion zone (the blue outer cone), the main reaction zone (the dark blue middle cone), and the post-combustion zone (the light blue inner cone). The precombustion area is the coolest part of the flame because the amount of released energy (heat) is low. The main reaction zone is used for the surface treatment because this zone has the highest temperature and number of oxidizing agents. The flame reaches its highest temperature (1900–2000°C) when all the propane has reacted with the air. The concentration of oxidizing agents reaches the maximum just before the post-combustion zone.^[3]

To treat a surface quickly and evenly, many gas jets, similar to the one on the right, are lined up in a long row on a single burner. The material being treated is quickly passed directly in front of or under the inner cones. The surface is in contact with the flame for less than a second. The surface is treated quickly, without time for the material to melt.

The reactive chemical species in the gas flame break the long-chain molecules in the plastic material, and attach themselves to the break points, resulting in polar point charges on the surface. On a microscopic scale, the surface also becomes rougher.^[4]

References

^ "Aerogen flame treatment improves surface adhesion". Materials Today. {{cite journal}}: Cite journal requires |journal= (help)
^ Farris, Stefano; Pozzoli, Simone; Biagioni, Paolo; Duó, Lamberto; Mancinelli, Stefano; Piergiovanni, Luciano (2010). "The fundamentals of flame treatment for the surface activation of polyolefin polymers – A review". Polymer. 51 (16): 3591–3605. doi:10.1016/j.polymer.2010.05.036. hdl:2434/149825. ISSN 0032-3861.
^ a b Johansson, Kenth S. (2017), "Surface Modification of Plastics", Applied Plastics Engineering Handbook, Elsevier, pp. 443–487, doi:10.1016/b978-0-323-39040-8.00020-1, ISBN 9780323390408, retrieved 2023-02-14
^ "The principle of flame treatment". Arcotec GmbH. Archived from the original on January 28, 2020. Retrieved September 10, 2016.

External links

Comparing Flame, Plasma, and Corona Treatments

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[1] "Aerogen flame treatment improves surface adhesion". Materials Today. {{cite journal}}: Cite journal requires |journal= (help)

[FarrisPozzoli2010-2] Farris, Stefano; Pozzoli, Simone; Biagioni, Paolo; Duó, Lamberto; Mancinelli, Stefano; Piergiovanni, Luciano (2010). "The fundamentals of flame treatment for the surface activation of polyolefin polymers – A review". Polymer. 51 (16): 3591–3605. doi:10.1016/j.polymer.2010.05.036. hdl:2434/149825. ISSN 0032-3861.

[:0-3] Johansson, Kenth S. (2017), "Surface Modification of Plastics", Applied Plastics Engineering Handbook, Elsevier, pp. 443–487, doi:10.1016/b978-0-323-39040-8.00020-1, ISBN 9780323390408, retrieved 2023-02-14

[4] "The principle of flame treatment". Arcotec GmbH. Archived from the original on January 28, 2020. Retrieved September 10, 2016.

Flame treatment

Process

See also

References

External links