• Operation and control of all processes in the system • Materials of construction • Equipment and instrumentation (
controllers,
sensors) and their cost.
Fundamental design heuristics A few important design heuristics and their assessment are discussed below: • When treating raw contaminated fluids, hard sharp materials can wear and tear the porous cavities in the micro-filter, rendering it ineffective. Liquids must be subjected to pre-treatment before passage through the micro-filter. This may be achieved by a variation of macro separation processes such as
screening, or granular media filtration. • When undertaking cleaning regimes the membrane must not dry out once it has been contacted by the process stream. Thorough water rinsing of the membrane modules, pipelines, pumps and other unit connections should be carried out until the end water appears clean. • Microfiltration modules are typically set to operate at pressures of 100 to 400 kPa. Such pressures allow removal of materials such as sand, slits and clays, and also bacteria and protozoa. • When the membrane modules are being used for the first time, i.e. during plant start-up, conditions need to be well devised. Generally a slow-start is required when the feed is introduced into the modules, since even slight perturbations above the critical flux will result in irreversible fouling. Like any other membranes, microfiltration membranes are prone to fouling.
(See Figure 4 below) It is therefore necessary that regular maintenance be carried out to prolong the life of the membrane module. • Routine '
backwashing', is used to achieve this. Depending on the specific application of the membrane, backwashing is carried out in short durations (typically 3 to 180 s) and in moderately frequent intervals (5 min to several hours). Turbulent flow conditions with Reynolds numbers greater than 2100, ideally between 3000 - 5000 should be used. This should not however be confused with 'backflushing', a more rigorous and thorough cleaning technique, commonly practiced in cases of particulate and colloidal fouling. • When major cleaning is needed to remove
entrained particles, a CIP (Clean In Place) technique is used. Cleaning agents/
detergents, such as
sodium hypochlorite,
citric acid,
caustic soda or even special enzymes are typically used for this purpose. The concentration of these chemicals is dependent on the type of the membrane (its sensitivity to strong chemicals), but also the type of matter (e.g. scaling due to the presence of calcium ions) to be removed. • Another method to increase the lifespan of the membrane may be feasible to design two microfiltration membranes in
series. The first filter would be used for pre-treatment of the liquid passing through the membrane, where larger particles and deposits are captured on the cartridge. The second filter would act as an extra "check" for particles which are able to pass through the first membrane as well as provide screening for particles on the lower spectrum of the range.
Design economics The cost to design and manufacture a membrane per unit of area are about 20% less compared to the early 1990s and in a general sense are constantly declining. Microfiltration membranes are more advantageous in comparison to conventional systems. Microfiltration systems do not require expensive extraneous equipment such as flocculates, addition of chemicals, flash mixers, settling and filter basins. However the cost of replacement of capital equipment costs (membrane cartridge filters etc.) might still be relatively high as the equipment may be manufactured specific to the application. Using the design heuristics and general plant design principles (mentioned above), the membrane life-span can be increased to reduce these costs. Through the design of more intelligent process control systems and efficient plant designs some general tips to reduce
operating costs are listed below • Running plants at reduced fluxes or pressures at low load periods (winter) • Taking plant systems off-line for short periods when the feed conditions are extreme. • A short shutdown period (approximately 1 hour) during the first flush of a river after rainfall (in water treatment applications) to reduce cleaning costs in the initial period. • The use of more cost effective cleaning chemicals where suitable (sulphuric acid instead of citric/ phosphoric acids.) • The use of a flexible control design system. Operators are able to manipulate variables and setpoints to achieve maximum cost savings. Table 1 (below) expresses an indicative guide of membrane filtration capital and operating costs per unit of flow. Table 1 Approximate Costing of Membrane Filtration per unit of flow Note: •
Capital Costs are based on dollars per gallon of the treatment plant capacity • Design flow is measured in millions of gallons per day. • Membrane Costs only (No Pre-Treatment or Post-Treatment equipment considered in this table) • Operating and Annual costs, are based on dollars per thousand gallons treated. • All prices are in US dollars current of 2009, and is not adjusted for inflation.
Process equipment Membrane materials The materials which constitute the membranes used in microfiltration systems may be either organic or inorganic depending upon the contaminants that are desired to be removed, or the type of application. • Organic membranes are made using a diverse range of polymers including
cellulose acetate (CA),
polysulfone,
polyvinylidene fluoride,
polyethersulfone and
polyamide. These are most commonly used due to their flexibility, and chemical properties. ;Spiral-wound This particular design is used for cross-flow filtration. The design involves a
pleated membrane which is folded around a
perforated permeate core, akin to a spiral, that is usually placed within a pressure vessel. This particular design is preferred when the solutions handled is heavily concentrated and in conditions of high temperatures and extreme
pH. This particular configuration is generally used in more large scale industrial applications of microfiltration.
Fundamental design equations As separation is achieved by sieving, the principal mechanism of transfer for microfiltration through micro porous membranes is bulk flow. Generally, due to the small diameter of the pores the flow within the process is laminar (
Reynolds Number v = \frac{D^2*\Delta P}{32*\mu *L}
Transmembrane Pressure (TMP) The transmembrane pressure (TMP) is defined as the mean of the applied pressure from the feed to the concentrate side of the membrane subtracted by the pressure of the permeate. This is applied to dead-end filtration mainly and is indicative of whether a system is fouled sufficiently to warrant replacement. : v = \frac{P_F + P_C}{2} - P_P Where • P_f is the pressure on the Feed Side • P_c is the pressure of the Concentrate • P_p is the pressure of the Permeate
Permeate Flux The permeate flux in microfiltration is given by the following relation, based on
Darcy's Law : J_v = \frac{1}{A_M}*\frac{dV}{dt} = \frac{\Delta P}{\mu *(R_u + R_c)} Where • R_u = Permeate membrane flow resistance (m-1) • R_c = Permeate cake resistance (m-1) • μ = Permeate viscosity (kg m-1 s-1) • ∆P = Pressure Drop between the cake and membrane The cake resistance is given by: : R_c= r*\frac{V_S}{A_m} Where • r = Specific cake resistance (m-2) • Vs = Volume of cake (m3) • AM = Area of membrane (m2) For micron sized particles the Specific Cake Resistance is roughly. : r= \frac{180*(1-\epsilon)}{\epsilon^3*d_s^2 } Where • ε = Porosity of cake (unitless) • d_s = Mean particle diameter (m)
Rigorous design equations To give a better indication regarding the exact determination of the extent of the cake formation, one-dimensional quantitative models have been formulated to determine factors such as • Complete Blocking (Pores with an initial radius less than the radius of the pore) • Standard Blocking • Sublayer Formation • Cake Formation See External Links for further details ==Environmental issues, safety and regulation==