Effective Utilization of Grinding and Mechanochemistry to Recycling and Separation

Resources Processing Pub Date : 2013-01-01 DOI:10.4144/RPSJ.60.36

Qiwu Zhang, J. Kano, F. Saito

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Abstract

The authors introduce novel research results on material synthesis and recycling by grinding. The research is focused at first mechanical activation of fine particles of solid material caused by grinding, and this leads to synthesize functional material from two starting materials without heating. One of the examples is to show the formation of complex oxides such as CaTiO 3 from CaO and TiO 2 . Another one is dechlorination of PVC by its grinding with CaO to form CaOHCl and hydrocarbon. This means that it is possible to separate chlorine from PVC by its washing with water. Grinding operation enables us to reduce indium (In) by from indium oxide (In 2 O 3 ) and ITO in the presence of Li 3 N under NH 3 /N 2 gaseous environment. The reaction can be given by: In 2 O 3 + Li 3 N + NH 3 → 2In + 3LiOH + N 2 . The purity of In and its recover are quite high over 90%. Further example of the mechanical activation followed by heating up to about 400 ° C is to generate hydrogen (H 2 ) from biomass such as wood and straw. The biomass is milled with inorganic substance such as CaO, followed by heating at non-oxidative environment. The generation of H 2 in high concentration can be attained during heating, due to adsorption of CO 2 and CO by CaO to form CaCO 3 . This implies that the grinding plays a big role to bring out many possible applications for material synthesis, material and waste processing.

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研磨和机械化学在回收和分选中的有效应用

介绍了磨矿法合成和回收材料的新研究成果。首先研究了固体材料的研磨引起的细颗粒的机械活化，从而实现了两种原料在不加热的情况下合成功能材料。其中一个例子是由CaO和TiO 2形成复杂的氧化物，如catio3。另一种是PVC与CaO研磨，形成碳酸氢盐和烃类，进行脱氯。这意味着可以通过用水洗涤将氯从PVC中分离出来。在nh3 / n2气体环境下，通过研磨操作，可以在Li 3n存在下，由氧化铟(in2o3)和ITO还原铟(In)。反应过程为:In 2o3 + Li 3n + nh3→2In + 3LiOH + n2。In的纯度和回收率均在90%以上。机械活化后加热至约400°C的另一个例子是从木材和秸秆等生物质中产生氢(h2)。将生物质用无机物(如CaO)碾磨，然后在非氧化环境下加热。在加热过程中，由于CaO吸附co2和CO形成caco3，可以产生高浓度的h22。这意味着研磨在材料合成、材料和废料处理等方面发挥着巨大的作用。

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Resources Processing

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