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Liquid Biofuels


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and 21 holes; 2 bar pressure 98.1 [98, 99] Nagchampa oil KOH 6:1 1% 333 20 Orifice plate; 1.4 bar pressure 91.8 [100] Used frying oil KOH 5:1 1% 333 10 Orifice – 2 mm and 25 holes; 2 bar pressure 95 [26] Thumba oil NaOH 4.5:1 38 g 323 30 Orifice – 3 mm and 5 holes; 1.5 bar pressure 80 [101]

      The next section deals with the quantification of cavitational zonesbased analysis for the efficient design of hydrodynamic reactors.

      As discussed in the previous sections, the chemical and physical effects of a cavitational phenomenon will be able to initiate as well as promote various chemical reactions. Thus, to design an efficient cavitational or sonochemical (either acoustic or hydrodynamic cavitation) reactor, one must be able to produce a cavitation zone, i.e., the area in the reactor in which formation, growth and the transient collapse of tiny bubbles should occur. Hence, the measurement of cavitation zone as well as cavitational intensity will ultimately impart the effectiveness of a selected cavitational reactor design. Along with cavitational intensity, analysis of pressure difference is also done, which leads to the development of a high number of cavitational bubbles and increases the impacts of physical effects of cavitational phenomena (especially in the case of a hetero-phasic reaction system). Moreover, application of either acoustic (either probe or ultrasound bath) or hydrodynamic (either orifice or venturi based) cavitational reactors is typically based on the size of reactants processed. In the following paragraphs, the basic methodology to determination of cavitational intensity in both cases is discussed elaborately.

      (2.1)image

      where power density can be determined as the amount of actual electrical energy input per unit volume of the medium.

      The value of cavitational yield roughly indicates the capability of performing the desired chemical reaction at a given input of electrical energy per unit reaction mixture. On the other hand, calorimetric analysis is used to determine the power dissipated in the reaction mixture. In the calorimetric study, the variation in temperature (rise) of a known quantity of water is measured for a given period. Based on these data the actual power dissipated can be determined using the following expression [19, 87]:

      (2.2)image

      where Cp – specific heat capacity of water (solvent) in J/kg K; m – mass of water (solvent) in kg; dT is the temperature difference (in K) over the time period dt (in s).

      The alternate procedure to evaluate the effectiveness or performance of cavitational reactors is mathematical modeling or simulations. The primary objective of mathematical modelling is to determine the pressure and temperature attained during the cavitational process, along with numbers and types of free radicals generated. There are several models available to estimate the cavitational intensity; most of these models are predictive only as assumptions defined in forming and solving mathematical equations makes them unrealistic in nature. For example, all the models assume that the shape of bubbles is spherical and remains the same throughout the process, which holds good but due to sudden change in pressure amplitude on either side of bubbles deformed the shape of bubbles. Secondly, these models are representative in nature as the number of formation of bubbles are not uniform throughout the course of operation but the model assumes it to be constant. Moreover, these models do not account for energy and heat losses as well as a molecule – molecule interaction during the process of cavitation. Most of these models ignore the change in viscosity, pressure, and temperature gradient as well as Bjerknes forces during the transient cavitation process. Still, the results (simulated profiles) of temperature, pressure, size of bubbles, etc. obtained from these models meaningfully predicts the cavitational intensity and corresponding effect on yield of the reaction precisely. The most commonly employed model for determination of cavitational effects is single–bubble dynamics model – based on considering the single bubble in isolation, as discussed below:

      The model consists of four ODE (ordinary differential equations) and can be solved by taking boundary conditions based on the physical properties of liquids. The model starts with the radial motion equation for a bubble derived from the work of Keller and Miksis [105]:

      (2.3)image

      (2.4)image

      (2.5)image

      The ODE for determining the diffusive flux of solvent is as follows:

      (2.6)image

      During the expansion of bubbles, the instantaneous diffusive penetration depth of solvent vapors into the cavitation bubbles can be predicted by:

      (2.7)