There is provided a means capable of recovering a valuable material such as cobalt and nickel, with a low grade of a metal derived from a negative electrode current collector, a low grade of fluorine, and a low grade of a material derived from a negative electrode active material. A method for recovering a valuable material from a lithium ion secondary battery, is characterized in that it includes: a heat treatment step of performing heat treatment on a lithium ion secondary battery; a crushing step of crushing a heat-treated object obtained through the heat treatment step; a classification step of classifying a crushed object obtained through the crushing step into a coarse particle product and a fine particle product; and a wet magnetic separation step of performing wet magnetic separation on the fine particle product obtained through the classification step.

The present invention relates to a grinder using induced electric fields. The grinder comprises: a grinding unit on which a plurality of protrusions for cutting are disposed on an outer circumferential surface thereof; a power unit disposed in the grinding unit to generate electric fields and attach the conductive materials to the grinding unit; and a chamber disposed outside the grinding unit and comprising beads that disperse and grind the conductive materials attached to the grinding unit, wherein the conductive materials have directionality by the electric fields of the power unit.

The present invention relates to a grinder using induced electric fields. The grinder comprises: a grinding unit on which a plurality of protrusions for cutting are disposed on an outer circumferential surface thereof; a power unit disposed in the grinding unit to generate electric fields and attach the conductive materials to the grinding unit; and a chamber disposed outside the grinding unit and comprising beads that disperse and grind the conductive materials attached to the grinding unit, wherein the conductive materials have directionality by the electric fields of the power unit.

A system for processing red mud comprising: a first heating section controlled to heat red mud to a first temperature; a second heating section controlled to heat the red mud to a second temperature lower than the first temperature; a crusher configured to grind the red mud to a predetermined particle size; and one or more separators for physically extracting at least iron and aluminum from the red mud.

A system for processing red mud comprising: a first heating section controlled to heat red mud to a first temperature; a second heating section controlled to heat the red mud to a second temperature lower than the first temperature; a crusher configured to grind the red mud to a predetermined particle size; and one or more separators for physically extracting at least iron and aluminum from the red mud.

A vertical roll mill may include a grinding plate, a grinding roll, a nozzle ring that horizontally surrounds the grinding plate, an air feed apparatus disposed under the nozzle ring, a discharge element disposed below or in a region of the air feed apparatus, and a bypass apparatus disposed in the nozzle ring. The bypass apparatus may form a connection between the nozzle ring and the discharge element. Further, the bypass apparatus can discharge particles that are difficult to grind, for example, ductile particles such as iron particles, from the grinding process. In some examples, the bypass apparatus includes a gas-impermeable outer skin in the region of the air feed apparatus.

A vertical roll mill may include a grinding plate, a grinding roll, a nozzle ring that horizontally surrounds the grinding plate, an air feed apparatus disposed under the nozzle ring, a discharge element disposed below or in a region of the air feed apparatus, and a bypass apparatus disposed in the nozzle ring. The bypass apparatus may form a connection between the nozzle ring and the discharge element. Further, the bypass apparatus can discharge particles that are difficult to grind, for example, ductile particles such as iron particles, from the grinding process. In some examples, the bypass apparatus includes a gas-impermeable outer skin in the region of the air feed apparatus.

A system and method for recovering metals from electronic scrap and auto shred residue (ASR) are described. Electronic scrap and ASR materials initially undergo size reduction processes. The reduced materials are thereafter separated according to size and magnetic properties to remove ferrous materials from the processing stream. Non-magnetic materials remaining in the processing stream are separated using oxygen encapsulated separators. The oxygen encapsulated separators strategically encounter materials to generate waste, a precious metals concentrate, and a metal concentrate.

A system and a process for dry recovery of iron oxide fines from iron hearing compact and semicompact rocks are provided, which system and process utilize primary, secondary and tertiary crushing components for preliminarily reducing the granulometry of ores containing the iron oxide fines in compact and semicompact rocks. Dynamic air classifier components are provided for finely grinding iron oxide minerals reduced through primary, secondary and tertiary crushing, along with static air classification components arranged in series for intermediate granulometric cuts and bag filters for retaining fine fraction. The system and process further comprise magnetic rolls, for magnetic separation, arranged in cascade at a variable leaning angle and formed by at least one of high or low magnetic intensity magnets.

A system and a process for dry recovery of iron oxide fines from iron hearing compact and semicompact rocks are provided, which system and process utilize primary, secondary and tertiary crushing components for preliminarily reducing the granulometry of ores containing the iron oxide fines in compact and semicompact rocks. Dynamic air classifier components are provided for finely grinding iron oxide minerals reduced through primary, secondary and tertiary crushing, along with static air classification components arranged in series for intermediate granulometric cuts and bag filters for retaining fine fraction. The system and process further comprise magnetic rolls, for magnetic separation, arranged in cascade at a variable leaning angle and formed by at least one of high or low magnetic intensity magnets.