BULGARIAN ACADEMY OF SCIENCES NATIONAL COMMITTEE OF THEORETICAL AND APPLIED MECHANICS Journal of Theoretical and Applied Mechanics
Print ISSN: 0861-6663 Online ISSN: 1314-8710
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JTAM, Sofia, vol. 53 Issue 4 (2023) |
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PREFACE TO THE SPECIAL ISSUE DEDICATED TO THE 90th ANNIVERSARY OF PROFESSOR ZAPRYAN ZAPRYANOV Sonia Tabakova, Stefan Radev Institute of Mechanics, Bulgarian Academy of Sciences
We are delighted to announce that this issue of the Journal of Theoretical and Applied
Mechanics is dedicated to Prof. Zapryan Zapryanov, honouring him on his 90th
birthday.
JTAM, Sofia, vol. 53 Issue 4 pp. 315-318 (2023), [Full Article]
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STABILITY OF LIQUID-VAPOR INTERFACE AT STEADY-STATE EVAPORATION AND CONDENSATION K.D. Danov Department of Chemical and Pharmaceutical Engineering, Faculty of Chemistry and Pharmacy, University of Sofia, 1 James Bourchier Blvd., 1164 Sofia, Bulgaria
The aim of this study is to perform a stability analysis of a
thermo-capillary flow in a steady-state evaporating/condensing liquid layer applying
the statistical rate theory expression for the mass flux across the interface.
In the general mass, momentum and energy balance equations, the effects
of gravity, temperature gradients in the surface tension, the interfacial momentum
and energy loss due to the net mass flux are taken into account. Assuming
a non-deformable surface and low dynamic viscosity and thermal conductivity
of the vapor, the stability problem of the liquid phase is separated from that for
the vapor. The exact solution is found and the dispersion relationship is solved
numerically for water. The numerical results show that the interfacial instability
mode always takes place in spite of the direction of the mass flux across
the interface. The main physical reason for this kind of instability is the strong
dependence of the mass flux on the vapor pressure predicted from the statistical
rate theory. Other internal instability modes are described as a function of the
Rayleigh and Marangoni numbers. The stability diagrams are discussed in the
light of the available experiments for controllable water steady-state evaporation
and condensation.
JTAM, Sofia, vol. 53 Issue 4 pp. 319-347 (2023), [Full Article]
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MATHEMATICAL MODELING OF THE EFFECT OF VISCOELASTICITY ON THE FILM DRAINAGE BETWEEN INTERACTING DROPS I. Bazhlekov, E. Bazhlekova Institute of Mathematics and Informatics, Bulgarian Academy of Sciences, Acad. Georgi Bonchev Str., Block 8, 1113 Sofia, Bulgaria
Mathematical model of the deformation and drainage of film
between interacting drops is presented in the case when dispersed or continuous
phases are viscoelastic fluids. The model is based on the assumptions of
a gentle collision at small Reynolds numbers and small deformation at small
capillary numbers. It consists of lubrication approximation in the film and
creeping flow equation in the dispersed phase. The equations in the continuous
and dispersed phases are coupled by continuity of the velocity and stress
boundary conditions at the interface. Generalizations of the Maxwell-type rheological
constitutive relation are used to model the viscoelastic effects: upperconvected
Maxwell model in the drop and fractional Maxwell model in the film
phase. Predictions of the effect of the extra elastic stresses on the film drainage
are given.
JTAM, Sofia, vol. 53 Issue 4 pp. 348-365 (2023), [Full Article]
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SOME PROBLEMS RELATED TO THE MATHEMATICAL MODELING OF CONVECTION FLOWS IN WATER FLOW GLAZING M. Rashevski, S.G. Slavtchev Institute of Mechanics, Bulgarian Academy of Sciences
This paper is a review of recent studies of the present authors
related to the modeling of hydrodynamic and heat transfer processes in waterfilled
glazing chambers exposed to sunlight. Due to the absorption properties
of water, solar visible and near-infrared irradiance induces a volumetric heat
source with exponential decay. Three different scenarios of mixed natural and
forced convection are discussed: two fully-developed flows in vertical flat and
rectangular channels and a developing flow in a slender channel with a rectangular
cross-section (similar to a Hele-Shaw cell). Three cases of temperature
boundary conditions are studied for the lighted and the opposite walls, whereas
in the case of the rectangular channel, linear declination of the side wall temperatures
is applied. Analytical solutions for fully-developed flows in both flat
and rectangular channels are reported and discussed. Some physical characteristics
of the flows such as bulk liquid temperature and Nusselt number are
calculated. The problem of developing flows in the slender rectangular channel
is formulated in a "stream function-vorticity" version. The main conclusion is
that the presented models predict quite well the average physical parameters of
the mixed convection flows in the glazing chamber under solar radiation.
JTAM, Sofia, vol. 53 Issue 4 pp. 366-388 (2023), [Full Article]
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MODELLING OF POLYMER FLOW INSTABILITIES WITH APPLICATION TO 3D PRINTING Sonia Tabakova, Rumiana Kotsilkova Institute of Mechanics, Bulgarian Academy of Sciences, Acad. G. Bonchev Str. Bl.4, 1113 Sofia, Bulgaria
Complex flow instabilities including wall slip and shear banding
occur in many industrial applications, such as in polymer extrusion processes,
thus affecting the throughput and the quality of the final product. The modelling
of rheological data is a key point when studying different polymeric
flows. The present survey incorporates three different ways to model the shear
stress of shear thinning polymers as nonlinear functions of shear stress: generalized
Newtonian model (Carreau-Yasuda model), wall shear slipping and
banding with yield (Herschel–Bulkley model). Based on these models, the flow
in the nozzle tube of a 3D printer is analyzed by a numerical model and two
analytical models: the classical Weissenberg–Rabinowitsch–Mooney (WRM)
model with slip; a simple model in three different regions in the tube (including
yield, parabolic and band, which match their boundaries). The real data
of measured shear stress by a plate–plate rheometer for three nanocomposites
is used to compare the three models. The experimentally measured flow rates
during the extrusion of the same nanocomposites are used to give insight into
the corresponding flow structures in the nozzle tube.
JTAM, Sofia, vol. 53 Issue 4 pp. 389-403 (2023), [Full Article]
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AIR POLLUTION STUDY FOR BULGARIAN PART OF BULGARIA–ROMANIA TRANS-BORDER AREA Ivanka Zheleva Department of Heat, Hydraulics, Engineering Ecology, Ruse University, 7000, Ruse, Studentska Str. 7, Bulgaria
The paper presents statistical analysis of air pollutants in the
Bulgarian part of trans-border BG–RO area. Air contamination charcteristics
and norms are also presented and commented in the present survey. Ecological
monitoring system in the BG–RO trans-border area is described. Particulate
matter (PM), nitrogen dioxide (NO2) and ground-level ozone (O3), are now
generally recognised as the three pollutants that most significantly affect human
health. Because of this, further in the paper concentration levels of these
three pollutants are statistically studied, based on official monitoring data. Results
are graphically presented and commented. Ambient air quality in the
BG–RO trans-borer area is better today than it was two decades ago, but despite
improvements, pollutant levels still show significant adverse effects on
human health and the environment. To improve air quality in the future, it will
be necessary to increase the use of "green" and more efficient technologies
in terms of thermal insulation of buildings, as well as the use of alternative
sources of fuel in the household and transport, use of best available technology
in the industry, green roofs in urban areas and more. Also it is nessessary more
precise mathematical modeling of the data series, which take into account more
factors to be developed and used for better understanding and forecasting the
air contamination processes.
JTAM, Sofia, vol. 53 Issue 4 pp. 404-423 (2023), [Full Article]
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ION FLUX IN THE MAGNETOSHEATH: RESULTS FROM GAS-DYNAMIC MODELLING AND INTERBALL-1 MEASUREMENTS Polya Dobreva1,2, Olga Nitcheva1,2, Georgy Zastenker3, Natalia Borodkova3, Monio Kartalev1 1Institute of Mechanics, Bulgarian Academy of Sciences, Acad. G. Bonchev“ Str., Bl. 4, Sofia 2Climate, Atmosphere and Water Research Institute, Bulgarian Academy of Sciences, Tsarigradsko Shose 66 blvd, Sofia 3Space Research Institute, Russian Academy of Sciences, Profsoyuznaya St. 84/32, Moscow, 117997, Russia
In this work, the possibilities of the magnetosheath-magnetosphere
model for describing the plasma parameters in the magnetosheath are
demonstrated. We consider the problem of a flow around a body (the Earth’s
magnetosphere) with two movable boundaries – the bow shock (BS) and the
magnetopause (MP). The grid-characteristic method is applied to describe an
ideal gas flow in the transition region (magnetosheath). A theoretical finite
element model and the semi-empirical Tsyganenko model are used to describe
the magnetic field in the magnetosphere. The model allows a self-consistent
determination of the magnetosheath boundaries for a given momentary state of
the solar wind. For these input parameters the three-dimensional solution in
the transition region is calculated. An analysis of the ion flux was made based
on the model and the data measured by the Interball-1 satellite in several cases
of magnetosheath crossings. The advantages and limitations of the model for
describing the magnetosheath flow are analyzed.
JTAM, Sofia, vol. 53 Issue 4 pp. 424-435 (2023), [Full Article]
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