Ore Dressing Flotation_Machines_Presentation.pptx
AjocNoel
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Aug 23, 2024
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Ore Dressing Flotation_Machines_Presentation.pptx
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Flotation Machines in Mineral Processing Detailed Overview and Analysis
Introduction to Flotation Machines Flotation machines are critical components in mineral processing, used to separate valuable minerals from gangue. There are three main types of flotation machines: mechanical, column, and reactor/separator machines. The choice of flotation machine affects plant design and is often debated in the industry.
Mechanical Flotation Machines Mechanical flotation machines are the most widely used type, characterized by a mechanically driven impeller that agitates the slurry and disperses air into bubbles. They can be self-aerated or forced-air machines, depending on the air introduction method.
Components of Mechanical Flotation Machines Key components include: - Rotor (Impeller): Creates air bubbles and maintains suspension. - Stator (Diffuser): Disperses bubbles throughout the cell. - Impeller Speed: Critical for maintaining particle suspension and bubble dispersion.
Historical Development of Mechanical Flotation Machines Mechanical flotation machines have evolved significantly since the 1960s, with a trend towards larger capacity cells. The development has focused on increasing productivity, reducing power consumption, and improving machine life.
Trends in Flotation Cell Design The most pronounced trend in recent years has been the move toward larger capacity cells. Modern tank cell designs are circular, fitted with froth crowders, multiple froth launders, and internal discharge systems.
Cell-to-Cell and Free-Flow Designs Cell-to-cell machines have individual tanks separated by weirs, while free-flow designs allow unrestricted slurry flow. Each design has its advantages, with cell-to-cell types often providing better selectivity.
Forced-Air Flotation Machines Forced-air machines, such as the Galigher Agitair and WEMCO designs, use external blowers to introduce air into the pulp. These machines are known for their high efficiency in handling large tonnages and producing fine bubbles.
The Denver Sub-A Machine The Denver Sub-A machine was widely used in the 1970s for small plants and multistage cleaning circuits. Its design includes a suspended impeller mechanism in a square cell with a quiescent zone above the impeller.
WEMCO and Dorr-Oliver Designs WEMCO machines are self-aerated with a vertical impeller system, while Dorr-Oliver designs feature a U-shaped tank with a unique rotor-stator assembly. Both designs are widely used and have evolved over the years to include modern features like large tank cells and advanced control systems.
Flotation Columns Overview Flotation columns have gained popularity since the 1980s for their ability to produce high-grade concentrates. They consist of two zones: the collection zone (pulp zone) and the froth zone, with fine bubbles produced by a sparging system.
Advantages of Flotation Columns Flotation columns offer several advantages, including: - Improved separation performance, particularly for fine materials. - Lower capital and operational costs. - Reduced floor space requirements and adaptability to automatic control.
Development of Flotation Columns Flotation columns were first developed in Canada in the 1960s and have since been widely adopted in the copper-molybdenum industry. Their use has expanded to roughing, scavenging, and cleaning applications in various ore types.
Column Design Considerations Modern flotation columns vary in size, with heights up to 13 meters and diameters up to 3.5 meters. Design considerations include the height/diameter ratio, sparger type, and the need for instrumentation and automatic control.
Sparger Systems in Flotation Columns Spargers introduce bubbles into the column. Initially, internal spargers were used, but modern designs favor jetting spargers and external bubble generation devices, which allow for easier maintenance and replacement.
External Bubble Generation Systems External systems like the CISA/Microcelt and Cavitation tube (CavTube) generate fine bubbles outside the column and inject them into the pulp. These systems improve bubble-particle contact and enhance flotation performance.
The Role of Frother in Bubble Production Frother is added to flotation systems to stabilize the bubbles formed by the sparger. The correct dosage of frother is critical as it influences bubble size and stability, which directly impacts flotation efficiency.
Cavitation Tube (CavTube) Technology Cavitation tube technology produces fine bubbles through hydrodynamic cavitation. This method enhances bubble-particle collision and attachment, leading to improved recovery of fine particles in the flotation process.
Jetting Sparger Systems Jetting spargers introduce high-pressure air through a small orifice to produce bubbles. These systems are responsive to frother dosage and are effective in generating fine bubbles necessary for efficient flotation.
Summary and Best Practices Flotation machines are integral to mineral processing operations, and selecting the appropriate type and design is crucial for optimal performance. Understanding the differences between mechanical flotation machines and flotation columns, as well as the advancements in sparging technology, is essential for engineers.
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