Sunday, June 2, 2019
Heat Transfer Within A Jacketed Reactor System
Heat Transfer Within A Jacketed Reactor SystemModeling of instigate shipping in spite of appearance a jacketed reactor requires basic knowledge on process light up channel reactor design etc. literature review sum up the fundamental on energy balance, method of overall warmheartedness enchant coefficient determination and basic understanding of quartz. These are the basic methods which allow engineers to predict to a greater extent accurate capabilities during chemical process as well as timing on the process.IntroductionHeat transfer is important in agitated vessels out-of-pocket to fluid temperature is the most significant factor for controlling the outcome of chemical, biochemical and pharmaceutical processes. 6Jacketed agitated vessels for arouseing and imperturbableing are commonly used in vary lawsuits of process applications. Engineers should have working knowledge of how agitate transfer and temperature control principles applied to such vessels. Cooling or heati ng agitated politic in vessels is a basic technologarithmical operation on the chemical, biochemical, pharmaceutical, food and processing industries. The cooling or heating rate depends on how the heat is supplied or removed, the mixing intensity and many other parameters. 5 The temperature needs to be controlled precisely at its desired to meet the requirement of downstream operations. Hence a mathematical model is essential which can predict temperatures accurately.The rate of heat transfer to or from an agitated liquid mass in a vessel is a function of the physical properties of that liquid and of the heating or cooling medium, the vessel geometry, and the degree of agitation. 8 Other factors which may affect the rate of heat transfer implicate type and size of the agitator and agitator location in the vessel. Most of the jacketed agitated vessels are used as reactor, thus chemical reactions with exothermic or endothermic effects must be taken into account as well. In a vesse l containing an agitated liquid, heat transfer takes place in general through conduction and forced convection, as it does in heat exchangers. 8Crystallization is a unit operation for separation and production of pure solid materials with desired properties. To fall in a batch cooling crystallization process, various operation strategies need to be investigated in relation to seeding, cooling, mixing, fines dis resultant role, and so forth. 18 In commercial exfoliation process, the reactor size grows larger. In this situation, various problems like ancillary nucleation, attrition, breakage, agglomeration, and dead zone may become severer in relation to the increasing inhomogeneities in the solution temperature and hydrodynamics.Literature ReviewModeling of reactors is useful for analyzing data, estimating performance, reactor scale-up, simulating start-up and shut down behavior, and control. 12 Uncertainties such as scale-up options, explosion hazards, runaway reactions, environm ental emissions, reactor internals etc, may be explored through modeling. 12 A key aspect of modeling is to derive the appropriate momentum, mass or energy conservation equations for the reactor.One typical application in heat transfer with batch operation is heating the process fluid in reactor, maintaining temperature during the reaction period and cooling the product after reaction complete. 11 muscularity BalanceThe overall thermal energy balance includes the heat entering the system, heat leaving the system, heat accumulation and heat sledding. The equation can be written asIn batch process, there is no liquid or fluid entering or leaving the system. If the system is assumed to be perfectly insulated, the energy balance equation can be simplified in 7By integration of both sidesFor a batch manufacturing process, heat transfer in an agitated vessel is used to design a suitable process or reaction. It is necessary to calculate the time to heat or cool a batch or the cooling capa city required to hold an exothermic or endothermic reaction at constant temperature. 1 The technique is to develop an expression which is relating time for heating or cooling agitated batches to coil or jacket area, heat-transfer coefficient, and the heat capacity of the vessel contents. 11 By rearranging the energy equilibrize equation, the relevant equation to calculate time is as followThis equation only can be used in where the utility fluid temperature carcass constant or the fluid temperature difference between deferral and outlet is not greater than 10% of the log mean temperature difference between the add up temperature of the jacket and the temperature of the vessels content. 8 Precisely, for heating and cooling condition, this equation must be represented in separatelyFor heatingFor coolingIf the situation is greater than 10% of the log mean temperature difference, the apply equation allow for beW = the mass flow rate through the jacket,C = the specific heat of the f luid in the jacketK =Assumptions are made for solving energy balance equation 11 17U is constant for the process and over the entire surface liquefiable flow rates are constantSpecific heats are constant for the processThe heating or cooling medium has a constant inlet temperatureAgitation produces a uniform batch fluid temperatureNo partial phase changes occursHeat losses are negligibleAgitated vessel heat transfer coefficientProcess side heat transfer coefficient can be determined by speed and agitator type. For low viscosity fluids, high-speed turbine type agitators will lead good performance. For high viscosity fluids and non-newtonian fluids, larger diameter agitators will be more suitable. 1Various types of agitators are used for mixing and mingle as well as to promote heat transfer in vessels. The correlations used to estimate the heat transfer coefficient to the vessel wall. 2For agitated vesselsWherehv = heat transfer coefficient to vessel wall or coil, Wm-2-1D = agitator diameter, mN = agitator, speed, rps (revolutions per second) = liquid density, kg/m3kf = liquid thermal conductivity, Wm-1-1Cp = liquid specific heat capacity, J Kg-1-1 = liquid viscosity, Nm-2s.The values of constant C and the indices a, b and c depend on the type of agitator the use of baffles, and whether the transfer is to the vessel wall or to coils. Some typical correlations are given below 2Flat blade disc turbine, baffled or unbaffled vessel, transfer to vessel wall, Re cdFlat blade disc turbine, baffled vessel, transfer to vessel wall, Re 400Overall heat transfer coefficientMost utility and process fluid will foul the heat transfer surfaces in an exchanger to a greater or lesser extent. The deposited material will normally have a comparatively low thermal conductivity and will reduce the overall coefficient.Fouling factors usually are considered in determining the Overall heat transfer coefficient U. The overall heat transfer coefficient is calculated in this wayWhere a nd s are the heat transfer coefficients for the process and utility side respectively. On the utility side, fouling resistance 1/f can be found from local experience or from Kern (1950). 1Heat transfer utility fluidSyltherm 800 is a silicone heat transfer fluid. It is a highly stable, long-lasting silicone fluid designed for high temperature liquid phase operation. It exhibits low potential for fouling and can often repose in service for 10 years or more. The recommended using temperature range is. 15CrystallizationCrystallization occurs with generating a sufficient level of supersaturation. The method of generation of supersaturation is to provide heat transfer, which is used in cooling and evaporative crystallization processes. There are two essential steps for crystallization nucleation and crystal growth.The problems of scale-up in crystallization process can be classified into induced, hydrodynamically induced, and mixes. For prototype, attrition, breakage, and agglomeration are related to solution mixing and are investigated from the hydrodynamic point of view. On the other hand, ancillary nucleation is caused by increased temperature gradient within the solution together with seed particles generated by attrition or fluid shear and can be considered as an example where the thermal and hydrodynamic effects are mixed. To improve the hydrodynamics deterioration during the scale-up, impeller type, agitation power, and baffle or draft tube design2,8,9 can be circumscribed or newly designed as required. The thermal aspect improvement is performed by the heat transfer enhancement, but the remedies are limited because the heat transfer area to volume ratio decreases inevitably during the scale-up unless other techniques such as vacuum or evaporative crystallization is introduced.MethodologyCalculation of time to heat or cool a fixed amount of liquid intimate a batch reactor usually assume the process and utility heat capacity and the overall heat transfer c oefficient to be constant throughout the calculations.Equations (liquid in jacket) heat input to reactor at T = heat loss by utility liquid with inlet temperature T1 and outlet temperature T2Rearrange the equation to solve unknown jacket outlet temperature T2The rate of temperature change of the liquid inside the vessel is given bySolving the above two equations to get process temperature as a function of timeFinally, solving for time t where T = TfConclusion
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