A rotor for use in a slurry separation flotation cell having a tank within which the rotor is contained. The rotor has a shaft that has a conduit adapted to communicate a fluid, preferably a gas such as air, therethrough. The rotor also has impeller blades extending radially from the shaft and a baffle adjacent the bottom of the impeller blades. The baffle extends from an end of the shaft to at or near an outer edge of the impeller blades, directing the gas to the outer edges of the impeller blades for dispersion into the slurry. The rotor is located adjacent a floor of the tank and, in use, draws slurry downwards into the impeller portion and forces it outwards with the gas being mixed therein.

A system for the continuous monitoring of wear is disclosed. The system comprises a flotation cell having at least one flotation component. At least one detector is provided to the at least one flotation component, and at least one sensor is provided to the flotation cell which is configured to communicate with the at least one detector during operation of the flotation cell. In use, the at least one flotation component wears away and ultimately affects a function of the least one detector. The at least one sensor is configured to monitor said function of the least one detector. When the at least one sensor detects a change in the signal of the at least one detector, an operator is notified that maintenance or flotation component replacement may be necessary.

A system for the continuous monitoring of wear is disclosed. The system comprises a flotation cell having at least one flotation component. At least one detector is provided to the at least one flotation component, and at least one sensor is provided to the flotation cell which is configured to communicate with the at least one detector during operation of the flotation cell. In use, the at least one flotation component wears away and ultimately affects a function of the least one detector. The at least one sensor is configured to monitor said function of the least one detector. When the at least one sensor detects a change in the signal of the at least one detector, an operator is notified that maintenance or flotation component replacement may be necessary.

A froth bubble moving speed measuring device includes a light source configured to illuminate an upper surface of a flotation tank, an imaging unit configured to capture at least a part of the upper surface of the flotation tank, and an arithmetic processing unit configured to calculate a moving speed of a froth bubble by calculating a moving distance of the froth bubble based on the image processed by the image processing unit.

A froth bubble moving speed measuring device includes a light source configured to illuminate an upper surface of a flotation tank, an imaging unit configured to capture at least a part of the upper surface of the flotation tank, and an arithmetic processing unit configured to calculate a moving speed of a froth bubble by calculating a moving distance of the froth bubble based on the image processed by the image processing unit.

A system for the continuous monitoring of wear is disclosed. The system comprises a flotation cell having at least one flotation component. At least one detector is provided to the at least one flotation component, and at least one sensor is provided to the flotation cell which is configured to communicate with the at least one detector during operation of the flotation cell. In use, the at least one flotation component wears away and ultimately affects a function of the least one detector. The at least one sensor is configured to monitor said function of the least one detector. When the at least one sensor detects a change in the signal of the at least one detector, an operator is notified that maintenance or flotation component replacement may be necessary.

A system for the continuous monitoring of wear is disclosed. The system comprises a flotation cell having at least one flotation component. At least one detector is provided to the at least one flotation component, and at least one sensor is provided to the flotation cell which is configured to communicate with the at least one detector during operation of the flotation cell. In use, the at least one flotation component wears away and ultimately affects a function of the least one detector. The at least one sensor is configured to monitor said function of the least one detector. When the at least one sensor detects a change in the signal of the at least one detector, an operator is notified that maintenance or flotation component replacement may be necessary.

A method of recovering particles from a liquid, a froth flotation apparatus, and a method of recovering particles in a flotation cell are disclosed. In an embodiment, the method comprises a technique of exposing the particles to first-size bubbles having a first predetermined size; the first-size bubbles adhering to the particles; and exposing the particles in a liquid, with the first-size bubbles adhering to the particles, to second-size bubbles having a second predetermined size, the second predetermined size being at least approximately ten times larger than the first predetermined size. The method further comprises the second-size bubbles adhering to the particles and engulfing the first-size bubbles on the particles; and using the second-size bubbles adhering to the particles to recover the particles from the liquid. In one embodiment a first surfactant is used to form the first-size bubbles, and a second surfactant is used to form the second-size bubbles.

A froth flotation cell for treating mineral ore particles suspended in slurry includes a tank, a gas supply, a first froth collection channel, a second froth collection channel arranged between the centre of the tank and the first froth collection channel, and a radial froth collection launder including a radial froth overflow lip, and extending from the first froth collection channel towards the second froth collection channel. The froth flotation cell further includes a radial froth crowder including a crowding sidewall, and extending from the second froth collection channel to the first froth collection channel. Further, a froth flotation line, its use and a froth flotation method are presented.

A froth flotation cell for treating mineral ore particles suspended in slurry includes a tank, a gas supply, a first froth collection channel, a second froth collection channel arranged between the centre of the tank and the first froth collection channel, and a radial froth collection launder including a radial froth overflow lip, and extending from the first froth collection channel towards the second froth collection channel. The froth flotation cell further includes a radial froth crowder including a crowding sidewall, and extending from the second froth collection channel to the first froth collection channel. Further, a froth flotation line, its use and a froth flotation method are presented.