Abstract
Alkaline nickel-cadmium batteries are among the most used industrial high-power sources. Despite stricter environmental requirements, nickel-cadmium batteries still remain as the main choice for highly reliable power sources for heavy-loaded equipment. Therefore, recovery of cadmium (Cd) from spent batteries is a challenge for the modern recycling industry, particularly as it displays high bio-toxicity. The present study describes a new green approach for Cd recovery from cadmium oxide (CdO). The paper discusses using a ternary chloride composition consisting of calcium, potassium and sodium chloride, thereby avoiding the release of Cd vapour from the reaction volume during the reduction reaction from CdO. For the protective slag layer during the reduction process (which occurs at 650 °C), a 0.515:0.0796:0.405 molar ratio of CaCl2:KCl:NaCl was chosen, with the aim of achieving a melting point at 483 °C. To describe phase and elemental composition of obtained products X-ray diffraction analysis and energy dispersive X-ray spectroscopy, respectively, were applied. Electron and optical microscopy were used for morphological observations. The presence of the metallic Cd was noted. During the reduction reaction, it was noted that slag separated into two parts: a protective upper layer and bottom layer. It was also noted that metallic Cd accumulated with increasing reaction time in the bottom part of the slag.
Highlights
Alkaline nickel-cadmium (Ni-Cd) batteries are widely used as autonomous sources of industrial and household current due to a successful combination of technical, economic and electrical characteristics [1]
It has been estimated that the extraction of cadmium and nickel from spent Ni-Cd batteries requires up to 46 and 75% less energy, respectively, compared to primary production of these metals [4]
The goal of this research is to estimate the effect of salt slag on cadmium oxide (CdO) reduction efficiency
Summary
Alkaline nickel-cadmium (Ni-Cd) batteries are widely used as autonomous sources of industrial and household current (power banks) due to a successful combination of technical, economic and electrical characteristics [1]. Metals 2020, 10, 981 batteries offer a long storage life, the ability work stably at low temperatures (up to −40 ◦ C) and the absence of the possibility of ignition at depressurisation in comparison to Li-ion batteries, as well as lower internal resistance compared to NiMH batteries It has been estimated that the extraction of cadmium and nickel from spent Ni-Cd batteries requires up to 46 and 75% less energy, respectively, compared to primary production of these metals [4]
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