JOURNAL OF CHEMICAL ENGINEERING OF JAPAN 15 巻, 5 号

THERMAL CONDUCTIVITIES OF LIQUID ALCOHOLS AND THEIR BINARY MIXTURES

The thermal conductivities of ten pure liquid alcohols and four of their binary mixtures were measured by use of the relative horizontal parallel-plate method (steady-state type) under atmospheric pressures Measurements for pure alcohols were carried out at temperatures from 20 to 70°C and for binary mixtures at 25.0 and 50.0°C.
A previous correlation model developed for the thermal conductivities of nonpolar liquids on the basis of the lattice model coupled with the hole theory concept has been successfully extended to polar liquids such as alcohols by the introduction of a new empirical parameter to represent the polar effect. Reduced values of the potential parameters and the empirical parameter, needed in the calculation of thermal conductivities, could be correlated by quadratic functions of Pitzer''s acentric factor and Stiel''s polar factor. The present model is also extended to alcohol mixtures by use of binary interaction parameters.

JET MIXING OF FLUIDS IN TANKS

An experimental investigation was made of the mixing of liquids in a tank where the liquid jet was injected through a nozzle. The mixing time was defined as the time required to reduce the concentration variation within 1% of the mixed mean value and was measured by an impulse response. The circulation time was also obtained from the response curve.
It was found that in the circulation flow regime of mixing (Re>3 ×10⁴) there exists an optimum nozzle depth for rapid mixing. It ranges from the liquid surface level to three-quarters of the liquid depth when the liquid depth is equal to the tank diameter, and is the mid-depth of the liquid when the liquid depth is smaller than the tank diameter. When the nozzle height is within one-fourth of the tank diameter, it is efficient for rapid mixing to tilt the nozzle upwards enough to prevent the formation of a wall jet, which induces circulations of small variance of circulation time.

FORMATION OF SINGLE CHARGED DROPS IN LIQUID MEDIA UNDER A UNIFORM ELECTRIC FIELD

Volumes and charges of water drops formed in a uniform electric field (0-4 kV/cm) have been measured in cyclohexane, toluene, insulating oil and three kinds of silicone oils as continuous phase. Effects of nozzle length extended from an electrode, flow rate of dispersed phase and liquid viscosity of continuous phase on the volume and the charge are examined. Experimental values are compared with those calculated by equations presented.
It is clarified that experimental volumes of the drops formed in a liquid having viscosity up to ten centipoises can be predicted by the presented equation. The experimental drop charges at low flow rates of dispersed phase are also represented by the equation. In a range of high flow rates of dispersed phase, however, a sudden decrease of charge has been observed.

EFFECT OF NATURAL CONVECTION ON LAMINAR FLOW HEAT TRANSFER IN HORIZONTAL CIRCULAR TUBES

The temperature distribution was measured in a horizontal circular tube with a high uniform wall temperature in the case where gas flowed through the tube in the laminar flow range. The temperature in the upper portion of the cross section was higher than that in the lower portion. The isothermal lines estimated from the measured temperature distribution in the cross section were symmetrical to the vertical centerline of the cross section.
The heat transfer coefficient from the tube wall is affected by tube diameter, distance from tube inlet, wall temperature and Reynolds number. The empirical equation for the heat transfer coefficient from the tube wall is obtained.
To analyze the heat transfer in the tube the fundamental equations are derived under suitable assumptions based upon observation of the flow pattern in the tube and are solved numerically. The calculated temperature distribution and the calculated heat transfer coefficient from the tube wall agree approximately with the experimental findings.

SIMULTANEOUS ABSORPTION OF NO AND NO2 INTO ALKALINE SOLUTIONS

Simultaneous absorption of NO₂ and NO into alkaline solutions was studied in a wide range of gaseous concentrations, NO₂ from 5 to 2000 ppm and NO from 0.066 to 1.2%. The absorption rate was not dependent on the concentration of hydroxide ion in the solution, if the alkalinity in the vicinity of the interface was maintained. In the presence of NO in excess of NO₂, the stoichiometry of the absorption is expressed by the reaction NO+NO₂+2OH^-→2NO₂^-+H₂O and the rate is proportional to the product of the interfacial concentrations of NO₂ and NO. The predominant mechanism is considered to be the solution of N₂O₃ in equilibrium with NO and NO₂ at the interface followed by its rapid hydration. The absorption rate is expressed by H√k₂D [N₂O₃]G, H√k₂D being 2.55 m•s^-1, which is about two orders of magnitude greater than the corresponding value for the absorption of N₂O₄.

KINETICS OF DYE-SENSITIZED PHOTO-DEGRADATION OF AQUEOUS PHENOL

The dye-sensitized photodegradation of aqueous phenol using rose bengal was carried out batchwise in the chemical region by using an annular bubble-column photoreactor, to evaluate the use of sunlight in wastewater treatment. Effects of both the partial pressure of oxygen and the initial concentration of phenol, [A]₀, on the initial reaction rate were analyzed according to the reaction scheme including the quenching reaction of triplet dye ³D^* with phenol, in order to determine the kinetic parameters. The reaction rate constant of phenol with singlet oxygen increased with increasing pH and was 2.66 ×10⁸ dm³/mol-s at pH 10.3. The reaction quantum yield at pH 10.3 was limited to a maximum of 0.29 at [A]₀=3 ×10^-3 mol/dm³ for O₂-bubbling and 0.13 at [A]₀=1.4 ×10^-3 mol/dm³ for air-bubbling by the quenching reaction of ³D^* with phenol, of which the rate constant was 4.0×10⁸ dm³/mol• s. p-Benzoquinone, the primary main product, underwent further degradation with both alkaline and ground-state oxygen to yield final products such as carboxylic acids. The reaction curves were simulated closely up to high conversions by taking account of the quenching effect of both phenol and the quinone-type intermediate products on ³D^*.

LONGITUDINAL CONCENTRATION DISTRIBUTION OF SUSPENDED SOLID PARTICLES IN MULTI-STAGE BUBBLE COLUMNS

The longitudinal concentration distribution of solid particles in 0.122- and 0.214-m i.d. multistage bubble columns was measured and analyzed by using a sedimentation-diffusion model with back-flow and the previously proposed empirical equations for single-stage bubble columns containing suspended solid particles and multi-stage bubble columns.
The mean settling velocity of solid particles through the partition plates was correlated with dimensionless groups. The values of concentration of solid particles in multi-stage bubble columns calculated from the proposed correlation and the previously proposed ones agreed with the observed values within ±30%.

CORRELATION OF VELOCITY DISTRIBUTIONS IN AN ANCHOR-AGITATED VESSEL USING A BICUBIC B-SPLINE FUNCTION

A surface-fitting method has been developed for the velocity data scattered on a given surface by using a bicubic B-spline function and is applied to data obtained from the analysis of the path lines of tracer particles in an anchor-agitated vessel.
This method has been proved to be of great use for expression of the velocity distributions throughout an agitated vessel if sufficient data for path lines are available.