Drying Geankoplis Methods of drying Moisture content kg
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Drying Geankoplis
Methods of drying
Moisture content (kg /kg dry solids) Drying rate, d. W/dt (kg/h) A B B C A 1 b 1 a C tc D time )hrs( tc D time) hrs( Fig. 1 a &b Typical drying rate curve of for food solids.
AB = Settling down period where the solid surface conditions come into equilibrium with the drying air. BC = Constant rate period which the surface of the solid remains saturated with liquid because the movement of water vapour to the surface equals the evaporation rate. Thus the drying rate depends on the rate of heat transfer to the drying surface and temperature remains constant. C = Critical moisture content where the drying rate starts falling and surface temperature rises. CD = Falling rate period which surface is drying out and the drying rate falls. This is influenced by the movement of moisture within the solid and take time.
Typical drying curve
Drying process
Rate of drying curves for constant -drying conditions n Conversion of data to rate-of-drying curve n Data obtained as W total weight of solid at different times t hours in the drying period. Ws is weight of dry soild. n If X* is equilibrium moisture content (kg moisture/kg dry solid), X is free moisture content (kg water/kg dry solid).
Slope = R = drying rate X = free moisture (kg water/kg dry solid) R = drying rate (kg water/h. m 2) Ls = kg of dry solid A = exposed surface area for drying (m 2)
Time of drying from drying curve n A solid is to be dried from free moisture content X 1 = 0. 38 kg water/ kg dry soild to X 2 = 0. 25 kg water/ kg dry soild. Estimate the time required. n t 1 = 1. 28 h, t 2 = 3. 08 h Time for drying = 3. 08 -1. 28 = 1. 80 h. n
Constant drying rate period R = drying rate (kg dry solid/h. m 2) Rc = drying rate for constant drying rate period = constant
Time of drying from drying curve n n A solid is to be dried from free moisture content X 1 = 0. 38 kg water/ kg dry soild to X 2 = 0. 25 kg water/ kg dry soild. Estimate the time required. Given: Ls/A = 21. 5 kg/m 2 Rc = 1. 51 kg/h. m 2
Method to predict transfer coefficient for constant-rate period NAMA=Rc MA NA A=m =Rc. A q = m w NA = mass flux = kg mol/s. m 2, M = molecular weight, H = humidity ratio Relate drying rate with heat y = mole fraction of water vapor in gas, transfer and mass transfer to yw = mole fraction of water vapor in gas at surface, determine the coefficient A = water, B = air, ky = mass transfer coefficient, w = latent heat of vaporization
For air temperature of 45 -150 C and mass velocity G of 2450 -29300 kg/h. m 2 or a velocity of 0. 61 -7. 6 m/s and air is flowing parallel to drying surface. Mass velocity (G) = v For air temperature of 45 -150 C and mass velocity G of 3900 -19500 kg/h. m 2 or a velocity of 0. 9 -4. 6 m/s and air is flowing perpendicular to drying surface. To estimate time of drying during constant-rate period:
Calculation methods for falling-rate drying period n Method using graphical integration
Calculation methods for special cases in falling-rate region n Rate is a linear function of X
Calculation methods for special cases in falling-rate region n Rate is a linear function through origin
Heat and Mass Transfer Drying
n n Heat transfer occurs within the product structure and is related to the temperature gradient between product surface and water surface at same location within the product. The vapors are transported from water surface within the product to product surface.
n n The gradient causing moisture-vapor diffusion is vapor pressure at water surface, compared to vapor pressure of air at product surface. The heat and mass transfer within the product structure occurs at molecular level, with heat transfer being limited by thermal conductivity of product structure, while mass transfer is proportional to molecular diffusion of water vapor in air.
n n At product surface, simultaneous heat and mass transfer occurs but is controlled by convective processes. The transport of vapor from product surface to air and transfer of heat from air to product surface is a function of existing vapor pressure and temperature gradients, respectively.
Mass and energy balance for dehydration process m a = air flow rate (kg dry air / hr) m p = product flow rate (kg dry solids / hr) W = absolute humidity (kg water / kg dry air) w = product moisture content (kg water / kg dry solid)
For counter-current system Overall moisture balance m a W 2 + m p w 1 = m a W 1 + m p w 2 n Energy balance m a Ha 2 + m p Hp 1 = m a Ha 1 + m p Hp 2 + qloss n q = heat losses Ha = heat content of air) k. J/kg dry air( Hp = heat content of product) k. J/kg dry solids(
Ha = CS (Ta – TO )+ WHL CS = humid heat (k. J/kg dry air. K) = 1. 005 + 1. 88 W Ta = air temperature ( C) TO = reference temperature (0 C) HL = latent heat of vaporization of water) k. J/kg water( HP = CPP (TP – TO )+ w. CPw (TP – TO) CPP= specific heat of dry solid (k. J/kg. K) TP = product temperature ( C) CPW = specific heat of water
Example n A cabinet dryer is being used to dry a food product from 68% moisture content (wet basis). The drying air enters the system at 54 C and 10% RH and leaves at 30 C and 70% RH. The product temperature is 25 C throughout drying. Compute the quantity of air required for drying on the basis of 1 kg of product solids.
Example n A fluidized-bed dryer is being used to dried. The product enters the dryer with 60% moisture content (wet basis) at 25 C. The air used for drying enters the dryer at 120 C after being heated from ambient air with 60%RH at 20 C. Estimate the production rate when air is entering the dryer at 700 kg dry air/hr and product leaving the dryer is at 10% moisture content (wet basis). Assume product leaves the dryer at wet bulb temperature of air and the specific heat of product solid is 2. 0 k. J/kg. C. Air leaves the dryer 10 C above the product temperature.
Drying Model: Thin layer drying n n Application: Dryer design, Simulation Three forms of model n Diffusion form n n D = diifusivity constant , D = f(T, RH, etc. ) Log model, modified log model MR = exp(-kt) n k = f(t, RH, IMC) n n MR = exp(-ktn) Quadratic form t = A ln(MR) + B[ln(MR)]2 n A = f(T, RH, IMC), B = f(T, RH, IMC) n
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