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Reaction rate mass changes

As pointed out, the influence of mass transfer on the observed reaction rate depends on the ratio between the characteristic reaction time and the characteristic time for mass transfer. By increasing the temperature, the intrinsic reaction rate increases more strongly (exponentially) than the rates of external and internal mass transfer. Consequently, the Thiele modulus and the second Damkohler number augment with increasing temperature, and transport phenomena become more and more important and will finally control the transformation process. In addition, the temperature dependence of the observed reaction rate will change as indicated. [Pg.81]

The rate of mass transfer was found to be limited by the reaction rate R. Changing the particle diameter and solvent superficial velocity, f/, did not influence the rate of mass transfer within experimental error [77]. The usefulness of the approximate models could thus not be fully evaluated. However, the approximation Cav = (bed exit concentration)/2 is only valid for very short beds. [Pg.215]

Reaction and Transport Interactions. The importance of the various design and operating variables largely depends on relative rates of reaction and transport of reactants to the reaction sites. If transport rates to and from reaction sites are substantially greater than the specific reaction rate at meso-scale reactant concentrations, the overall reaction rate is uncoupled from the transport rates and increasing reactor size has no effect on the apparent reaction rate, the macro-scale reaction rate. When these rates are comparable, they are coupled, that is they affect each other. In these situations, increasing reactor size alters mass- and heat-transport rates and changes the apparent reaction rate. Conversions are underestimated in small reactors and selectivity is affected. Selectivity does not exhibit such consistent impacts and any effects of size on selectivity must be deterrnined experimentally. [Pg.509]

For many laboratoiy studies, a suitable reactor is a cell with independent agitation of each phase and an undisturbed interface of known area, like the item shown in Fig. 23-29d, Whether a rate process is controlled by a mass-transfer rate or a chemical reaction rate sometimes can be identified by simple parameters. When agitation is sufficient to produce a homogeneous dispersion and the rate varies with further increases of agitation, mass-transfer rates are likely to be significant. The effect of change in temperature is a major criterion-, a rise of 10°C (18°F) normally raises the rate of a chemical reaction by a factor of 2 to 3, but the mass-transfer rate by much less. There may be instances, however, where the combined effect on chemical equilibrium, diffusivity, viscosity, and surface tension also may give a comparable enhancement. [Pg.2116]

Therefore, the sum of the component balances is the total material balance while the net rate of change of any component s mass within the control volume is the sum of the rate of mass input of that component minus the rate of mass output these can occur by any process, including chemical reaction. This last part of the dictum is important because, as we will see in Chapter 6, chemical reactions within a control volume do not create or destroy mass, they merely redistribute it among the components. In a real sense, chemical reactions can be viewed from this vantage as merely relabeling of the mass. [Pg.152]

The rate of a chemical reaction can be described in any of several different ways. The most commonly used definition involves the time rate of change in tlie amount of one of the components participating in tlie reaction tliis rate is usually based on some arbitrary factor related to tlie reacting system size or geometry, such as volume, mass, or interfacial area. Tlie definition shown in Eq. (4.6.7), wliich applies to homogeneous reactions, is a convenient one from an engineering point of view. [Pg.124]

A pure gas is absorbed into a liquid with which it reacts. The concentration in the liquid is sufficiently low for the mass transfer to be governed by Pick s law and the reaction is first order with respect to the solute gas. It may be assumed that the film theory may be applied to the liquid and that the concentration of solute gas falls from the saturation value to zero across the film. Obtain an expression for the mass transfer rate across the gas-liquid interface in terms of the molecular diffusivity, 1), the first order reaction rate constant k. the film thickness L and the concentration Cas of solute in a saturated solution. The reaction is initially carried our at 293 K. By what factor will the mass transfer rate across the interface change, if the temperature is raised to 313 K7... [Pg.856]

Isotopic molecules will have force fields which are identical to a high degree of accuracy. The vibrational amplitudes, on the other hand, will be mass-dependent, which means that the steric requirements of isotopic molecules will be slightly different. For this reason it is to be expected quite generally that isotopic molecules will respond differently to the change in steric conditions imposed by a chemical reaction, and hence that their reaction rates will differ somewhat. [Pg.2]

The diffusivity in gases is about 4 orders of magnitude higher than that in liquids, and in gas-liquid reactions the mass transfer resistance is almost exclusively on the liquid side. High solubility of the gas-phase component in the liquid or very fast chemical reaction at the interface can change that somewhat. The Sh-number does not change very much with reactor design, and the gas-liquid contact area determines the mass transfer rate, that is, bubble size and gas holdup will determine reactor efficiency. [Pg.352]

Using Numbers Because the mass of magnesium is the same in each reaction, assume the change in quantity to be 1. Thus, the rate of reaction is calculated by dividing 1 by the reaction time. Calculate and record in the data tables the average temperature and the rate of reaction for each tube in Part A and the rate of reaction for each tube in Part B. Why was an average temperature used in Part A ... [Pg.131]

The RHSE has the same limitation as the rotating disk that it cannot be used to study very fast electrochemical reactions. Since the evaluation of kinetic data with a RHSE requires a potential sweep to gradually change the reaction rate from the state of charge-transfer control to the state of mass transport control, the reaction rate constant thus determined can never exceed the rate of mass transfer to the electrode surface. An upper limit can be estimated by using Eq. (44). If one uses a typical Schmidt number of Sc 1000, a diffusivity D 10 5 cm/s, a nominal hemisphere radius a 0.3 cm, and a practically achievable rotational speed of 10000 rpm (Re 104), the mass transfer coefficient in laminar flow may be estimated to be ... [Pg.201]

Component mass balance An equation relating the rate of change of the mass of a component in the system to the rates of inflow, outflow, and chemical reaction. See Eq. (2). [Pg.37]

See other pages where Reaction rate mass changes is mentioned: [Pg.368]    [Pg.368]    [Pg.41]    [Pg.70]    [Pg.209]    [Pg.329]    [Pg.1016]    [Pg.112]    [Pg.1151]    [Pg.307]    [Pg.259]    [Pg.1117]    [Pg.1351]    [Pg.2123]    [Pg.265]    [Pg.22]    [Pg.66]    [Pg.505]    [Pg.219]    [Pg.15]    [Pg.26]    [Pg.207]    [Pg.84]    [Pg.175]    [Pg.250]    [Pg.692]    [Pg.275]    [Pg.297]    [Pg.15]    [Pg.10]    [Pg.457]    [Pg.224]    [Pg.650]    [Pg.5]    [Pg.336]    [Pg.270]    [Pg.31]    [Pg.194]    [Pg.16]   
See also in sourсe #XX -- [ Pg.272 ]



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