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Jun 19, 2017

Beginners guide to concentrate filtration

Filtration of mineral concentrates produced in flotation concentrators is an area where we have significant experience with hundreds of filters delivered over 40 years. Along with the large number of deliveries is a wide range of product offering reflecting changes in the industry requirements. The delivered filters include vacuum filters, Ceramec disc filter, simple and fast opening membrane filter presses and Larox tower filters generally as per the figure below.
Operating areas for concentrate filters
Figure 1: Operating areas for concentrate filters

Mineral concentrates require filtration targeted to transportable limits and reducing transport costs. The transportable limit (TML) is a must for the product to be saleable and filtration technologies are selected based on their ability to reliably achieve this limit. The ability to reduce the moisture significantly below this limit may have limited effect on the product quality, transport cost or overall plant water balance.

The term TML is derived from the solid bulk cargo industries where cargoes such as metal concentrates may appear to be in a relatively dry granular state when loaded, however they may still contain sufficient moisture to become fluid under the stimulus of the compaction and vibration that occurs during a voyage. The resulting cargo shift can be sufficient to capsize the vessel.

To achieve this level of dewatering filters retain solids on a cloth or ceramic membrane allowing the liquid to pass through. This concentration continues until a suitable cake thickness is achieved where the product is close to the incompressible limit and then further reduces the water content in the cake by gas displacement.

By example a typical copper concentrate may have a TML of 9% moisture. Given that at the incompressible limit the cake will have a solids fraction of about 50% v/v and for solids with an sg of 4.3 the moisture would be 18.9% w/w without gas displacement. The filtration process must displace about 50% of the remaining water with air to achieve the required moisture. The TML varies with particle size and typical TML values are shown below.

Typical TML vs. particle size
Figure 2: Typical TML vs. particle size

From a plant perspective the factors which affect filter performance are generally beyond the control of the operator. Particle size, grade and surface chemistry all have significant effects but seldom can be adjusted without negative effects on the plant performance. Understanding their effect can be a useful guide to the parameters that should be adjusted in filtration.

The structure of incompressible residue and methods for retaining the residual moisture
Figure 3: The structure of incompressible residue and methods for retaining the residual moisture. 1: local zones, 2: capillary moisture, 3: structured moisture, 4: working channels
Figure 4: Equation 1

For air to enter the pores the differential pressure must exceed the capillary pressure. This pressure as shown in equation 1 is a function of the pore diameter D, surface tension τ and the solid wetting angle θ. Flotation concentrates generally have a hydrophilic surface and a large wetting angle that increases the threshold pressure.

Putting these relationships into context for vacuum filters to be effective with differential pressure of 0.8 bar, vacuum filter possibilities should extend to a mean particle size in the range of 25 to 30 μm.

Pressure filters remain a possibility for dewatering difficult slurries and here a differential pressure of 10 bar, pressure filter possibilities should extend to a mean particle size in the range of 2.5 μm.

In cases where cake moistures are too high they can be adjusted by increasing the apparent pressure during drying either by increasing the available pressure or reducing the cake thickness.

Grade Low grade has a negative effect from several perspectives. The lower solids sg dilutes the cake and requires lower cake moisture to achieve the TML. The gangue may in the case of clays have plate like particles that create tighter pores and the surface properties can have a lower wetting angle also increasing the pore pressure.  In general it is best to improve grade but in cases where this is impractical increasing filtration pressure may help to compensate. pH changes (when allowed) and coagulation can have beneficial effects.

Surface chemistry The pH required for the separation of concentrates usually means that they gave a high surface charge. This is generally detrimental to filtration where the best results are achieved when the surface charge is a minimum. Where it is not possible to change the surface chemistry coagulants and flocculants can be effective in improving filtration rates. Flocculants can be effective on vacuum filters where the slurry can be handled gently.

Factors which can be modified to improve filter performance

Feed density With the exception of some vacuum filters where low feed density can be used to produce thin cakes generaly the higher the feed density the better for filtration performance. Low feed densities can significantly impact on both the unit capacity and achievable moisture. Capacity is decreased because more liquid has to pass through the pores in the cake. The consequences of low feed solids go beyond the increased flow in the pores. As liquid passes through the cake fine particles are entrained in the liquid concentrating the fine particles close to the cloth and in extreme case can form an impermeable layer that prevents air passing through the cake. The higher differential pressues from the low feed density may initiate precipitation and accelerate cloth blinding further affecting filtration rates.

Filtration parameters Differing filter technologies have differing parameters that can be adjusted to effect filtration results. In vacuum filters the adjustable parameters are least effective, cake thickness has the greatest effect but can be difficult to adjust. Pressure can be effected to a limited extent. The longer the filter is in drying the more liquid will be removed from the pores but at the expense of capacity.  In pressure filters times and pressures are more easily adjusted.

Cake thickness In general the thinner the cake the higher the capacity, up to the point where technical time or the unit function limits capacity. In vacuum filters this is the disc or belt speed which have a practical limit and the cake discharge which requires a minimum thickness to be effective. In pressure filters the cake thickness is largely determined by the chamber depth. Chamber filters have to be completely filled and have no flexibility whereas membrane filters can be adjusted within certain limits.

Cake compression As concentrates become finer the inter particle forces become more significant. As air enters the cake pores with an air water intercace apply forces to the adjacet particles. Where to cake is inadequatly compressed during cake formation these forces lead to cake shrinkage and air bypassing during drying. This shrinking is possibly the most common cause of filter technology failure.

Drying Once the filters enter the drying phase the variables are pressure and time. Pressure should be enough to exceed the capillary pressure without being too high and generating excessive air flow that can damage filter elements and filtrate lines. The time required varies with the cake and pressure. Initialy the liquid is displaced and effective drying occours, next the gas flow helps to break liquid traped in local zones by capillay pressure and then after several minutes drying occours by mass transfer and evaporation and is least effective.


Material properties

  • Improving grade improves filtration and moisture
  • Chemistry Eh to zero improves filtration
  • Improving Feed density improves filtration

Filtration parameters

  • Thinner cakes reduce cake moisture
  • Cake compression reduces cake cracking
  • Drying pressure should be high enough
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