Evaluation of Mass Loss in Different Stages of Printed Circuit Boards Recycling Employed in Temperature Controllers

Schneider, Eduardo Luís; Hamerski, Fernando; Veit, Hugo Marcelo; Krummenauer, Alex; Cenci, Marcelo Pilotto; Chaves, Rodrigo de Andrade; Hartmann, W.L.; Dias, Moisés de Mattos; Robinson, Luiz Carlos; Vargas, Alexandre Silva de

doi:10.1590/1980-5373-mr-2018-0833

Cited by 5 publications

(2 citation statements)

References 15 publications

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“…The modern society is becoming more and more dependent on electronic devices, which are characterized by a short replacement cycle . This tendency can be translated in a growing flow of new technologies to the market with a consequent increase of an electronic waste amount (e-waste). , An amount of 45 million tons of e-waste was generated in 2016 with an estimated annual growth rate of 3–4%. − There are four main sources of e-waste: small/large home appliances, hospital medical equipment, office machines, and industrial equipment/machines . Within the entire e-waste quantity, the WPCB percentage is relevant (3–6%). − The WPCBs are composed for more than 40% (w/w) of metals. , Cu has an average concentration of 20% (w/w) of whole metals, and it is 10–40 times higher than that in copper-rich minerals. ,− The annual Cu production is around 15 million tons, and about 30% is used for the electric and electronic devices .…”

Section: Introductionmentioning

confidence: 99%

Bioleaching of End-of-Life Printed Circuit Boards: Mathematical Modeling and Kinetic Analysis

Becci

Amato

Rodríguez‐Maroto

et al. 2021

Ind. Eng. Chem. Res.

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This work reports a kinetic study of the bioleaching process for Cu extraction from waste printed circuit boards (WPCBs), using iron as an oxidant agent. The kinetic study considered both the Fe2+ oxidation by bacteria metabolism and the chemical reaction between Fe3+ and Cu within WPCBs. The model was composed of a system of three differential equations characterized by three dependent variables and seven parameters. The first equation describes the bacteria abundance trend, the second one represents the variation of Fe2+ concentration, and the third one focuses on the Cu extraction by the biogenerated Fe3+. The developed model was consistent with experimental data with an R 2 higher than 0.97. The results showed that the bacteria metabolism was 1.8–2.5 times faster than the chemical reaction. The determined mathematical model, suitable for the implementation at an industrial scale, could be an important tool to predict the bioleaching mechanism in a metal recovery process.

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Section: Introductionmentioning

confidence: 99%

Bioleaching of End-of-Life Printed Circuit Boards: Mathematical Modeling and Kinetic Analysis

Becci

Amato

Rodríguez‐Maroto

et al. 2021

Ind. Eng. Chem. Res.

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“…By individual components, there is a prevalence of studies on PCBs (53 studies out of 93, 57%). The high concentration of base metals (mainly copper) and the presence of precious and critical metals are notable in these components (Table 1) and justify the preference for authors to address PCBs (D’Adamo et al, 2019; Schneider et al, 2019). For batteries, 31 studies were found (33.3%).…”

Section: Recyclingmentioning

confidence: 99%

Composition and recycling of smartphones: A mini-review on gaps and opportunities

2023

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After more than a decade since smartphones became consolidated in the market, many recycling solutions have been proposed to deal with them. To continue developing useful solutions and enable adjustment of routes, this mini-review aims to analyse the current research scenario, presenting relevant gaps, trends and opportunities. From a structured searching and screening procedure, a vast source of data was arranged and is available to extract useful information (43 studies on composition and 93 studies on recycling). The study provides discussions about the history of smartphone development, constituent materials and recycling methods for different components, comparisons between feature phones and smartphones and others. Among some conclusions, the authors highlight the lack of studies on pre-extractive methods, green chemistry, recovery of critical and precious metals, determination of priority materials for recovery and solutions for entire devices. In the end, a list containing six research gaps for composition studies and seven research gaps for recycling studies is provided and may be seen as opportunities for future research.

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Eco‐Friendly Electronics—A Comprehensive Review

Cenci

Scarazzato

München

et al. 2021

Adv Materials Technologies

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these two phenomena and it is now understood that EEE are both part of the environmental cure and the environmental disease: while the increasing production and disposal of EEE have harmful consequences to the planet, [1] the use of EEE can assist in saving energy and natural resources. The research concerning ecofriendly electronics increased greatly in recent decades due to environmental legislations becoming increasingly rigorous and because of the increase in eco-friendly sought devices, which required business models to adapt in order to participate in this new market share. The concepts of eco-friendly electronics or green electronics comprehends several dimensions of this electronic-environment relationship and has been used loosely for a myriad of initiatives. Hu and Ismail [2] explain that the concept may be used to refer to the i) manufacturing process, through the employment of environmentally friendly processes and the avoidance of hazardous components or chemicals; ii) waste generation (avoidance), via reducing the e-waste impacts through the use of cleaner materials, longer product life, introducing programs to raise awareness and promote reuse/recycling; iii) use of sustainable practice (green computing), through the responsible use of computer resources, for example, by powering down and up devices according to need, reducing energy consumption during inactivity; iv) design, through the development of more efficient components that required less energy to perform, reduce carbon emissions, produce less heat, etc. Yet eco-friendly electronics can also refer to electronics whose purpose is to assist the environment or that do so as a consequence of its main function. Both these groups may be understood as an overlap between the aforementioned categories, and are equipment that optimize energy usage, minimize carbon footprint, detect pollutant concentration, monitor oil spillage, generate renewable energy, etc. There are many and diverse examples of these, such as power electronics, smart grids, and photovoltaic systems. [3] This review is intended to discuss these interactions, define important concepts, and provide an extensive list of ways in which EEE can be eco-friendly, primarily focusing on information and communication technology (ICT) devices, but also addressing items that fall outside of this category such as washing machines and lighting equipment. Initially, the use of electronics in aiding with energy and pollution related Eco-friendliness is becoming an indispensable feature for electrical and electronic equipment to thrive in the competitive market. This comprehensive review is the first to define eco-friendly electronics in its multiple meanings: power saving devices, end-of-life impact attenuators, equipment whose manufacturing uses green processing, electronics that use materials that minimize environmental and health risks, designs that improve lifespan, reparability, etc. More specifically, this review discusses eco-friendly technologies and materials that are being introduced to ...

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Evaluation of Mass Loss in Different Stages of Printed Circuit Boards Recycling Employed in Temperature Controllers

Cited by 5 publications

References 15 publications

Bioleaching of End-of-Life Printed Circuit Boards: Mathematical Modeling and Kinetic Analysis

Bioleaching of End-of-Life Printed Circuit Boards: Mathematical Modeling and Kinetic Analysis

Composition and recycling of smartphones: A mini-review on gaps and opportunities

Eco‐Friendly Electronics—A Comprehensive Review

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