Column Flotation

Better Recovery for a Lower Cost

Eriez Column Flotation delivers step-change improvements in concentrate grade and recovery, with up to 50% lower energy costs and up to 40% less capital than equivalent mechanical circuits. Proven across over 1,200 installations in over 40 countries.

Advantages Over Conventional Flotation

Mechanical cells have dominated flotation for over a century, but their design imposes fundamental constraints that limit metallurgical performance and inflate both capital and operating costs. More equipment, more energy, more maintenance — yet still compromised grade and recovery.

Coarse Bubble Generation: Rotor-stator shear produces bubble diameters typically greater than 1 mm — significantly reducing collision probability for fine and ultrafine particles, where an increasing proportion of ore value is locked as orebodies grow more complex.
High Entrainment, Poor Selectivity: Shallow froths limit wash water use, allowing fine gangue to report to concentrate and dilute product grade. Multiple cleaning stages are required just to reach acceptable quality — adding cost, footprint, and complexity.
Energy Wasted on Suspension: The majority of a mechanical cell's power draw goes to keeping solids suspended — not to flotation. That's energy cost with no metallurgical return. Power runs 40–50% higher than equivalent column circuits.
Poorly Mixed Reactor Behaviour: Mechanical cells operate as nearly perfectly mixed reactors with inherent bypassing and dead zones. Industry practice requires a minimum of three cells in series to compensate — increasing capital before you've floated a single tonne.

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Three Design Principles for Measurable Performance Gains

Flotation columns were engineered to overcome the fundamental limitations of mechanical cells. Every performance advantage flows from three structural design characteristics, each delivering a quantifiable improvement in metallurgical outcome and operating cost.

Counter-Current Contacting

Feed slurry flows down while fine bubbles rise up, maximising contact time and attachment probability. Columns operate with a higher Péclet number, closer to plug flow, delivering higher recovery for the same residence time.

Lower Energy Cost: No rotor-stator means no energy wasted on mechanical agitation. Eriez columns consume 40–50% less power than mechanical circuits, and up to 68% less than downcomer-aspirated pneumatic cells.

Deep Froth Washing

Positive bias wash water displaces entrained gangue back to pulp while retaining attached hydrophobic particles. A single column routinely replaces two to three mechanical cleaner stages with equivalent or superior metallurgical results.

Circuit Simplification: Fewer cells means 15–40% lower total installed CAPEX, 50–75% reduction in structural and civil requirements, and less piping, electrical, and instrumentation — with freed floor space for additional capacity.

Fine Bubble Sparging

Eriez sparging systems generate bubbles up to 20× finer than mechanical cell aeration — exponentially more surface area per unit of air and a directly proportional increase in the flotation rate constant.

Low Maintenance Requirements: No rotating internals, no high-wear rotor-stator components. SlamJet spargers are externally serviceable without draining the column — supporting high availability and lower total lifecycle cost.

Two Spargers — One for Every Application

SlamJet

Internal Lance Sparger

Proven in thousands of flotation applications worldwide, the SlamJet forces high-pressure air through a converging nozzle, generating microbubbles averaging 0.8 mm in diameter. Its fail-closed self-sealing mechanism prevents slurry backflow — eliminating plugging and fouling common in other systems. High-wear components are externally replaceable without draining the column or interrupting operation.

The SlamJet improves the operating efficiency of flotation columns, leach tanks, and other processes that depend on the generation of fine gas bubbles.

Benefits

2.5× Increase in bubble surface area flux vs. mechanical cell aeration — directly proportional increase in flotation rate constant k
0.8mm Mean bubble diameter — versus >1 mm for rotor-stator shear

Applications

Feeds containing large tramp items that cause plugging in recirculating spargers
Cost-constrained applications requiring high upgrading performance
Mineralogy where quiescent conditions and counter-current contacting are preferred
Retrofit into existing column infrastructure

CavTube

External Cavitation Sparger

The only technology to simultaneously leverage two kinetic intensification mechanisms, the CavTube recirculates a slipstream of slurry through an external manifold where hydrodynamic cavitation generates a bimodal bubble size distribution: ~100 µm microbubbles from high-shear fragmentation, and ~1 µm picobubbles nucleated directly on hydrophobic particle surfaces — bypassing the conventional collision-attachment limitation for ultrafine particles.

Benefits

6×+ Improvement in flotation kinetics vs. mechanical cell bubble sizes — from ~0.1 mm mean bubble diameter
+20% Fine particle recovery improvement achievable versus conventional sparging systems
–50% Reduction in collector consumption for certain ores through picobubble pre-coating

Applications

Fine and ultrafine particle recovery as the primary metallurgical objective
Complex or finely disseminated ores with slow flotation kinetics
Rougher and scavenger duties — previously considered unsuitable for columns
Retrofit of existing conventional columns without column replacement

Industrial Results Across Major Applications

Copper Cleaner and Cleaner-Scavenger Duties

Column flotation is the industry standard for copper cleaner and polymetallic final cleaning duties. CavTube columns deliver their greatest kinetic advantage precisely where mechanical cells are most constrained: ultrafine particle recovery and gangue rejection in the cleaner circuit.

Prior to column installation, the all-mechanical cleaner circuit was chronically overloaded — operators were forced to choose between recovery and grade, with cleaner block copper recovery averaging 67–80%. A single 4,250 mm diameter CavTube column installed as a cleaner scalper transformed circuit performance.

98.5% Cleaner block copper recovery: Up from 67–80% prior to column installation

+2.6pp Global plant copper recovery: From 89.1% to 91.7% — from a single column

Eliminated Circulating load: Between cleaner scavenger tailings and scavenger feed — reducing regrind mill load

$9M+ Indicative annual revenue uplift: At 10 Mt/y, 0.5% Cu — a 2pp recovery gain equals ~1,000 additional payable tonnes at $9,000/t

Case Study: DeGrussa Copper-Gold Concentrator, WA (Sandfire Resources, 1.5 Mtpa)

Iron Ore Reverse Flotation in Brazil

Column flotation is the cornerstone of reverse flotation flowsheets for iron ore — every concentrator commissioned in Brazil since 1990 has adopted column-only flotation in rougher-cleaner-scavenger configuration.

Columns maintain concentrate SiO₂ levels within tight specification limits while delivering recovery improvements that translate directly to higher pellet feed quality, reduced blast furnace costs, and improved downstream efficiency.

100% Adoption for Brazilian iron ore concentrators: Every concentrator commissioned since 1990 has adopted column flotation

+2%+ Recovery vs. mechanical and pneumatic cells: In reverse flotation — translating to higher pellet feed quality

Tight SiO₂ grade control: Froth washing maintains concentrate specification within limits mechanical cells cannot consistently achieve

R-C-S Full circuit configuration: Rougher-cleaner-scavenger duties all served by column flotation — widespread brownfield retrofits

Source: Araujo, Viana & Peres (2005)

Ultrafine Recovery in Potash, Phosphate & Specialty Minerals

Eriez columns are widely adopted across phosphate, potash, graphite, and specialty industrial mineral applications. The CavTube column has demonstrated exceptional performance in applications previously considered unfloatable by conventional means.

Potash — Ultrafine Tailings Recovery: A CavTube column was applied to flotation of ultrafine insoluble minerals from fine potash tailings (P80 ~30 µm, 50% insols by mass). At industrial scale, near-perfect separation was achieved with no reagent addition.

Phosphate: Column replacement across five circuit duties at a North American phosphate operation delivered a 2% P₂O₅ concentrate grade increase — installed during routine maintenance shutdowns with no lost production.

>90% Insoluble mineral rejection: At >90% KCl recovery — single stage, no reagent addition

>5% Increase in mill recovery: At a 4 MTPY potash operation from a single column installation

$125M+ Estimated additional annual revenue: At prevailing potash prices — alongside 30% reduction in fine tailings storage

+2% P₂O₅ Phosphate concentrate grade: Across five circuit duties — installed with no lost production

Source: Tuchscherer (2022); Eriez (2016)

What the Numbers Look Like Across the Install Base

Documented Performance Range

Performance Metric	Typical Improvement	Primary Mechanism
Concentrate grade	+3–8%	Froth washing, positive bias flow, reduced gangue entrainment — at equivalent recovery
Cleaner circuit recovery	+2–20%	Higher Peclet number approaching plug flow; higher bubble surface area flux; fine particle kinetics
Global plant recovery	+2–5%	Reduced circulating loads, elimination of cleaner tailings recycle, improved fine fraction recovery
Fine particle recovery (CavTube)	Up to +20%	Bimodal bubble generation — picobubbles nucleated on hydrophobic surfaces bypass collision-attachment limits
Reagent consumption	Up to –50%	Improved selectivity and picobubble pre-coating reduce collector dosage required for equivalent flotation response
Power vs. mechanical cells	–40–50%	No rotor-stator — low-intensity bubble field replaces high-energy mechanical mixing
Power vs. pneumatic cells (CavTube)	Up to –68%	CavTube air efficiency — lower superficial gas velocity delivers superior kinetic performance
Total installed CAPEX	–15–40%	Fewer stages, less auxiliary equipment, reduced structural and civil requirements

Eriez Column vs. Pneumatic Cells
Technology Comparison

For fine particle selectivity, deep cleaning duty, energy efficiency, and installation base, Eriez Column Flotation is the superior choice. Downcomer-aspirated pneumatic flotation cells are marketed as a replacement for column technology. Here's how the technologies compare across the criteria that matter most — on concentrator performance, operating cost, and confidence to capital.

Criteria	Eriez Column	Pneumatic Cell
Fine Particle Selectivity Separation of fine hydrophilic / hydrophobic particles	Superior — deep froth wash	Moderate
Wash Water / Froth Cleaning Elimination of entrained gangue in concentrate	Deep countercurrent wash	Limited froth depth
Energy Consumption vs. equivalent mechanical flotation circuit	Up to 68% lower (CavTube)	Moderate reduction
Circuit Simplification Ability to replace multiple cleaner stages	Replaces 2–3 stages	Single stage
Fine and Ultrafine Recovery CavTube picobubble mechanism	Up to +20% vs. conventional sparging	Standard kinetics
Sparger Customisation Optimise bubble size for feed characteristics	SlamJet or CavTube	Fixed internal downcomer
Retrofit / In-Situ Upgrade Upgrade existing column infrastructure	CavTube retrofit — no column replacement	Full unit replacement
Global Installations Proven operating references worldwide	1,280+ across 45 countries	Fewer references
Proven for Scale-Up Lab-to-industrial scale-up reliability	Validated 5 cm to 6 m diameter	Limited published scale-up data

DeGrussa Copper-Gold Concentrator

Case Study — Copper

A single CavTube column transformed a chronically overloaded cleaner circuit — eliminating the circulating load, recovering fine particles mechanical cells could not treat, and adding 2.6 percentage points to global plant copper recovery.

Operation: Sandfire Resources, Western Australia

Technology: 4,250 mm CavTube Column

Duty: Copper Cleaner Scalper

98.5% Cleaner block copper recovery

Up from 67 to 80% — mechanical cells were forcing a grade vs. recovery trade-off

+2.6 pp Global plant copper recovery

From 89.1% to 91.7% at a 1.5 Mtpa operation — from a single column

Eliminated Circulating load

Between cleaner scavenger tailings and scavenger feed — reducing regrind mill load and simplifying the circuit

30× Scale-up ratio confirmed

Grade-recovery curves from 150 mm lab, 500 mm pilot, and 4,250 mm industrial column all fell on the same curve

Lab Testing Available On-Site

Find out more

Mobile test columns can be brought to your site to predict metallurgical performance and de-risk installation before capital commitment.

We run pilot programs across all major mineral applications.

Technical Papers, Case Studies & Brochures

Column Flotation White Paper - Benchmarking Performance of Eriez Phospro Column Flotation cells against mechanical cells for reverse flotation of a sedimentary phosphate ore.

Improved Cleaner Circuit Performance - Improved Cleaner circuit performance at the degrussa copper mine with an in situ column sparging system.

Knoblauch et al CMP 2016 Copper Cleaner Paper - Improved Cleaner Circuit Performance at The Degrussa Copper Mine with An In Situ Column Sparging System

Column Flotation of Ultra-fine Phosphate ore

Column Flotation Brochure

Scale-up of an Eriez Cav-Tube Flotation Column in Copper Cleaning