闂備浇宕垫慨宕囩矆娴e浜归柣鎰仛鐎氬鏌i弮鍫熶氦缂佽鲸妫冮弻鈥愁吋鎼粹€崇闂侀€炲苯澧鹃柟鍑ゆ嫹 | 闂傚倷娴囬妴鈧柛瀣崌閺岀喖顢涘⿰鍐炬毉濡炪們鍎婚幏锟� 闂傚倷娴囬崑鎰櫠濡ゅ懎绀夋俊銈勭椤曢亶鏌嶈閸撶喖寮婚埄鍐ㄧ窞閻庯綆浜滈~宥夋⒑閸濆嫷鍎滅紒杈ㄦ礈濡叉劙寮崼鐔告闂佽法鍣﹂幏锟�
闂備浇宕垫慨宕囩矆娴e浜归柣鎰仛鐎氬鏌i弮鍫熶氦缂佽鲸妫冮弻鈥愁吋鎼粹€崇闂侀€炲苯澧鹃柟鍑ゆ嫹 | 闂傚倷娴囬妴鈧柛瀣崌閺岀喖顢涘⿰鍐炬毉濡炪們鍎婚幏锟� 闂傚倷娴囬崑鎰櫠濡ゅ懎绀夋俊銈勭椤曢亶鏌嶈閸撶喖寮婚埄鍐ㄧ窞閻庯綆浜滈~宥夋⒑閸濆嫷鍎滅紒杈ㄦ礈濡叉劙寮崼鐔告闂佽法鍣﹂幏锟�
作者:Lukas Wiszniewski; Irmtraud Marschall; Thomas Hochsteiner; Thomas McFarlane Hoad; Klaus Doschek Held; Harald Raupenstrauch
作者单位:Montanuniversität Leoben, Chair of Thermal Processing Technology, Leoben, Austria;K1-MET GmbH, in cooperation with Montanuniversität Leoben, Chair of Ceramics, Leoben, Austria;Chair of Thermal Processing Technology,Montanuniversität Leoben,Franz Josef-Str. 18,Leoben,8700,Austria
刊名:Ceramics International
ISSN:0272-8842
出版年:2024-10-10
卷:50
期:21
起页:43683-43698
止页:
分类号:
语种:英文
关键词:Batteries;Refractories (E);SiC (C);Crucible test;Pyrometallurgical recycling;InduRed
内容简介Pyrometallurgical recycling of lithium-ion batteries (LIB) has emerged as the go-to approach in industrial recycling solutions, yet it encounters significant challenges, such as lithium (Li) slagging. This study explores a reactor for pyrometallurgical recycling, that offers the potential to overcome this bottleneck by simultaneously recovering lithium and phosphorous (P) via the gas stream, more noble elements including cobalt (Co), nickel (Ni) and copper (Cu) as an alloy and less noble elements like aluminum (Al), calcium (Ca) and silicium (Si) as a slag. However, to enhance the efficiency and performance of this reactor, a critical focus is placed on evaluating refractory materials with reduced corrosion and diffusion characteristics. Already explored refractory materials, including aluminum oxide (Al2O3) or magnesium oxide (MgO), have exhibited severe issues, such as accelerated corrosion and diffusion rates, leading to diminished performance and compromised efficiency. To evaluate a more suitable refractory material for pyrometallurgical recycling of LIB, tests using silicon carbide (SiC), chromium(III)-oxide (Cr2O3) and zirconium dioxide (ZrO2) were performed up to 1600 °C. The test results indicate that the investigated refractory materials offer distinct advantages and disadvantages. While SiC shows minimal to no wear by corrosion, Cr2O3 exhibits higher resistance to Li diffusion. Contrary, ZrO2 experienced severe corrosion and crack formation, showing unsuitability for LIB recycling. Based on these findings, a continuously operated reactor could use different refractory materials in specific zones. While the degasification zone could benefit from Cr2O3's minimal diffusion properties, areas with intense contact between the crucible and melt could utilize SiC's corrosion resistance. However, partial oxidation at the outer surface of the SiC crucible led to the formation of SiO2, another critical point to consider for scale-up plans, as it might influence the mechanical integrity long-term.
所需耐材币:0