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Abstract

Pyrolysis is an attractive means of recovering resources from waste integrated printed circuit boards (PCBs) because organic materials they contain are converted into gas, tar, and char that can be recycled and valuable metals are left for further processing. In this study, we examined the effects of particle size (0.15 and 3.0 mm) and heating rate (5°C/min, 25°C/min, 100°C/min, 300°C/min, 600°C/min) on products evolved during rapid pyrolysis of phenolic PCBs. A PCB was pyrolyzed at 675°C under a nitrogen atmosphere in an experimental laboratory-scale fixed-bed reactor and decomposed at 700°C in a thermogravimetric analyzer. Data obtained suggest that rapid heating and large particles were associated with increased local overheating and pressure, which promoted the cracking of volatile compounds into lower molecular weight compounds and increased yield of volatile gases. Furthermore, microexplosions may have occurred within the pyrolyzing PCB, which cracked the surface of the char, released volatile gases, and increased the char's porosity.

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References

, Huang

, Li

, He

, Chen

, and Zhang

(2014). Pollution profiles and health risk assessment of vocs emitted during e-waste dismantling processes associated with different dismantling methods. Environ. Int., 73, 186.

Betts

(2008). Producing usable materials from e-waste. Environ. Sci. Technol., 42, 6782.

Bidini

, Fantozzi

, Bartocci

, D'Alessandro

, D'Amico

, Laranci

, Scozza

, and Zagaroli

(2015). Recovery of precious metals from scrap printed circuit boards through pyrolysis. J. Anal. Appl. Pyrolysis, 111, 140.

Cayumil

, Khanna

, Ikram-Ul-Haq

, Rajarao

, Hill

, and Sahajwalla

(2014). Generation of copper rich metallic phases from waste printed circuit boards. Waste Manag. 34, 1783.

Chiang

, Lo

, and Ma

(2010). Characteristics of exhaust gas, liquid products, and residues of printed circuit boards using the pyrolysis process. Environ. Sci. Pollut. Res., 17, 624.

Fogarasi

, Imre-Lucaci

, Egedy

, Imre-Lucaci

, and Ilea

(2015). Eco-friendly copper recovery process from waste printed circuit boards using fe3+/fe2+ redox system. Waste Manag. 40, 136.

Fujita

, Ono

, Dodbiba

, and Yamaguchi

(2014). Evaluation of a recycling process for printed circuit board by physical separation and heat treatment. Waste Manag. 34, 1264.

Guo

, Qin

F.G.F.

, Yang

, and Jiang

(2014). Study on low-temperature pyrolysis of large-size printed circuit boards. J. Anal. App. Pyrolysis, 105, 151.

Hadi

, Xu

, Lin

, Hui

, and McKay

(2015). Waste printed circuit board recycling techniques and product utilization. J. Hazard. Mater., 283, 234.

10.

Hall

, and Williams

(2007). Separation and recovery of materials from scrap printed circuit boards. Resour. Conserv. Recycling, 51, 691.

11.

, Li

, Ma

, Wang

, Huang

, Xu

, and Huang

(2006). WEEE recovery strategies and the WEEE treatment status in China. J. Hazard. Mater., 136, 502.

12.

Huang

, Chen

, and Sun

(2014). Leaching behavior of copper from waste printed circuit boards with bronsted acidic ionic liquid. Waste Manag. 34, 483.

13.

Kasper

, Berselli

, Freitas

, Tenório

, Bernardes

, and Veit

(2011). Printed wiring boards for mobile phones, characterization and recycling of copper. Waste Manag. 31, 2536.

14.

Kumar Prodhan

, and Kumar

(2014). Informal e-waste recycling: Environmental risk assessment of heaby metal contamination in Mandoli industrial area, Delhi, India. Environ. Sci. Pollutant Res., 21, 7913.

15.

Luyima

, Zhang

, Kers

, and Laurmaa

(2012). Recovery of metallic materials from printed wiring boards by green pyrolysis process. Mater. Sci., 18, 238.

16.

Marques

, Marrero

, and Malfatti

(2013). A review of the recycling of non-metallic fractions of printed circuit boards. SpringerPlus. 2, 521.

17.

Ministry of international trade and industry of Japan. (1998). Law for the Promotion of Effective Utilization of Resources. Available at: www.meti.go.jp/policy/kaden_recycle/en_cha/pdf/english.pdf (accessed September 15, 2012).

18.

Ortuno

, Molto

, Egea

, Font

, and Conesa

J.A.

(2013). Thermogravimetric study of the decomposition of printed circuit boards from mobile phones. J. Anal. App. Pyrolysis, 103, 189.

19.

Quan

, Li

, and Gao

(2009). Thermogravimetric analysis and kinetic study on large particles of printed circuit board wastes. Waste Manag. 29, 2353.

20.

Quan

, Li

, and Gao

(2012). Study on characteristics of printed circuit board liberation and its crushed products. Waste Manag. Res., 30, 1178.

21.

Schlummer

, Gruber

, Maurer

, Wolz

, and van Eldik

(2007). Characterisation of polymer fractions from waste electrical and electronic equipment (WEEE) and implications for waste management. Chemosphere, 67, 1866.

22.

Williams

(2010). Valorization of printed circuit boards from waste electrical and electronic equipment by pyrolysis. Waste Biomass. Valor., 1, 107.

23.

Zhan

, and Xu

(2014). Assessment of heavy metals exposure, noise and thermal safety in the ambiance of a vacuum metallurgy separation system for recycling heavy metals from crushed e-wastes. Waste Manag. Res., 32, 1247.

Effects of Particle Size and Heating Rate on Evolution of Products from Pyrolysis of Phenolic Circuit Boards

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