TY  - CONF
AU  - Hasan, Mohammad Sakib
AU  - Svorcan, Jelena
PY  - 2022
UR  - https://machinery.mas.bg.ac.rs/handle/123456789/4263
AB  - The design of high-altitude unmanned aerial vehicles is one of the most current research
topics today in the field of aviation. The possible purposes of such flying platforms are
numerous, from communication hubs, terrain observations, performing various measurements
in the upper layers of the atmosphere, to various military uses. However, these are complex
systems that involve many unresolved scientific and research challenges such as: the necessity
of extremely low airframe weight, low air pressure and density cruising at high altitudes where
air pressure and density are much lower than in the Earth’s vicinity, sub-zero temperatures,
exposure to increased radiation, low Re implying accentuated viscosity effects and decreased
aerodynamic characteristics, assuring complete flight autonomy, need to generate the required
energy for flight solely from solar energy, adequate sizing and control of rechargeable batteries,
etc.
At the beginning, the initial mission requirements, mission profile, assessment of daily
power consumption and battery mass as well as methodologies for the initial estimation of
aircraft structural mass and wing loads are discussed. Then a novel high-lift airfoil specially
designed for low-Re high-altitude flight through multi- objective optimization was designed
by using genetic algorithm. Subsequently, aerodynamic analysis of the wing carried out by the
methods of computational fluid mechanics, specifically by solving Navier-Stokes equations
averaged by Reynolds statistics and closed by a 4-equation turbulent model is shown. Finally,
static analyses of the behavior of wing structures under the combined action of calculated
aerodynamic and gravitational loads were performed, as well as dynamic, modal analyses
(important for knowing the response of the structure in non-stationary operating conditions)
using the finite element method.
PB  - University of Belgrade, Faculty of Mechanical Engineering
C3  - Booklet of Abstracts - 1st International Conference on Mathematical Modelling in Mechanics and Engineering
T1  - Conceptual design of solar-powered high-altitude long endurance aircraft
SP  - 87
UR  - https://hdl.handle.net/21.15107/rcub_machinery_4263
ER  - 

@conference{
author = "Hasan, Mohammad Sakib and Svorcan, Jelena",
year = "2022",
abstract = "The design of high-altitude unmanned aerial vehicles is one of the most current research
topics today in the field of aviation. The possible purposes of such flying platforms are
numerous, from communication hubs, terrain observations, performing various measurements
in the upper layers of the atmosphere, to various military uses. However, these are complex
systems that involve many unresolved scientific and research challenges such as: the necessity
of extremely low airframe weight, low air pressure and density cruising at high altitudes where
air pressure and density are much lower than in the Earth’s vicinity, sub-zero temperatures,
exposure to increased radiation, low Re implying accentuated viscosity effects and decreased
aerodynamic characteristics, assuring complete flight autonomy, need to generate the required
energy for flight solely from solar energy, adequate sizing and control of rechargeable batteries,
etc.
At the beginning, the initial mission requirements, mission profile, assessment of daily
power consumption and battery mass as well as methodologies for the initial estimation of
aircraft structural mass and wing loads are discussed. Then a novel high-lift airfoil specially
designed for low-Re high-altitude flight through multi- objective optimization was designed
by using genetic algorithm. Subsequently, aerodynamic analysis of the wing carried out by the
methods of computational fluid mechanics, specifically by solving Navier-Stokes equations
averaged by Reynolds statistics and closed by a 4-equation turbulent model is shown. Finally,
static analyses of the behavior of wing structures under the combined action of calculated
aerodynamic and gravitational loads were performed, as well as dynamic, modal analyses
(important for knowing the response of the structure in non-stationary operating conditions)
using the finite element method.",
publisher = "University of Belgrade, Faculty of Mechanical Engineering",
journal = "Booklet of Abstracts - 1st International Conference on Mathematical Modelling in Mechanics and Engineering",
title = "Conceptual design of solar-powered high-altitude long endurance aircraft",
pages = "87",
url = "https://hdl.handle.net/21.15107/rcub_machinery_4263"
}

Hasan, M. S.,& Svorcan, J.. (2022). Conceptual design of solar-powered high-altitude long endurance aircraft. in Booklet of Abstracts - 1st International Conference on Mathematical Modelling in Mechanics and Engineering
University of Belgrade, Faculty of Mechanical Engineering., 87.
https://hdl.handle.net/21.15107/rcub_machinery_4263

Hasan MS, Svorcan J. Conceptual design of solar-powered high-altitude long endurance aircraft. in Booklet of Abstracts - 1st International Conference on Mathematical Modelling in Mechanics and Engineering. 2022;:87.
https://hdl.handle.net/21.15107/rcub_machinery_4263 .

Hasan, Mohammad Sakib, Svorcan, Jelena, "Conceptual design of solar-powered high-altitude long endurance aircraft" in Booklet of Abstracts - 1st International Conference on Mathematical Modelling in Mechanics and Engineering (2022):87,
https://hdl.handle.net/21.15107/rcub_machinery_4263 .

TY  - JOUR
AU  - Hasan, Mohammad Sakib
AU  - Svorcan, Jelena
AU  - Simonović, Aleksandar
AU  - Mirkov, Nikola
AU  - Kostić, Olivera
PY  - 2022
UR  - https://machinery.mas.bg.ac.rs/handle/123456789/3784
AB  - The ability of flying continuously over prolonged periods of time has become target of numerous research studies performed in recent years in both the fields of civil aviation and unmanned drones. High altitude platform stations are aircrafts that can operate for an extended period of time at altitudes 17 km above sea level and higher. The aim of this paper is to design and optimize a wing for such platforms and computationally investigate its aerodynamic performance. For that purpose, two-objective genetic algorithm, class shape transformation and panel method were combined and used to define different airfoils with the highest lift-to-drag ratio and maximal lift coefficient. Once the most suitable airfoil was chosen, polyhedral half wing was modeled and its aerodynamic performances were estimated using the CFD approach. Flow simulations of transitional flow at various angles-of-attack were realized in ANSYS FLUENT and various quantitative and qualitative results are presented, such as aerodynamic coefficient curves and flow visualizations. In the end, daily mission of the aircraft is simulated and its energy requirement is estimated. In order to be able to cruise above Serbia in July, an aircraft weighing 150 kg must accumulate 17 kWh of solar energy per day.
PB  - Univerzitet u Beogradu - Institut za nuklearne nauke Vinča, Beograd
T2  - Thermal Science
T1  - Optimal airfoil design and wing analysis for solar-powered high altitude platform station
EP  - 2175
IS  - 3
SP  - 2163
VL  - 26
DO  - 10.2298/TSCI210419241S
ER  - 

@article{
author = "Hasan, Mohammad Sakib and Svorcan, Jelena and Simonović, Aleksandar and Mirkov, Nikola and Kostić, Olivera",
year = "2022",
abstract = "The ability of flying continuously over prolonged periods of time has become target of numerous research studies performed in recent years in both the fields of civil aviation and unmanned drones. High altitude platform stations are aircrafts that can operate for an extended period of time at altitudes 17 km above sea level and higher. The aim of this paper is to design and optimize a wing for such platforms and computationally investigate its aerodynamic performance. For that purpose, two-objective genetic algorithm, class shape transformation and panel method were combined and used to define different airfoils with the highest lift-to-drag ratio and maximal lift coefficient. Once the most suitable airfoil was chosen, polyhedral half wing was modeled and its aerodynamic performances were estimated using the CFD approach. Flow simulations of transitional flow at various angles-of-attack were realized in ANSYS FLUENT and various quantitative and qualitative results are presented, such as aerodynamic coefficient curves and flow visualizations. In the end, daily mission of the aircraft is simulated and its energy requirement is estimated. In order to be able to cruise above Serbia in July, an aircraft weighing 150 kg must accumulate 17 kWh of solar energy per day.",
publisher = "Univerzitet u Beogradu - Institut za nuklearne nauke Vinča, Beograd",
journal = "Thermal Science",
title = "Optimal airfoil design and wing analysis for solar-powered high altitude platform station",
pages = "2175-2163",
number = "3",
volume = "26",
doi = "10.2298/TSCI210419241S"
}

Hasan, M. S., Svorcan, J., Simonović, A., Mirkov, N.,& Kostić, O.. (2022). Optimal airfoil design and wing analysis for solar-powered high altitude platform station. in Thermal Science
Univerzitet u Beogradu - Institut za nuklearne nauke Vinča, Beograd., 26(3), 2163-2175.
https://doi.org/10.2298/TSCI210419241S

Hasan MS, Svorcan J, Simonović A, Mirkov N, Kostić O. Optimal airfoil design and wing analysis for solar-powered high altitude platform station. in Thermal Science. 2022;26(3):2163-2175.
doi:10.2298/TSCI210419241S .

Hasan, Mohammad Sakib, Svorcan, Jelena, Simonović, Aleksandar, Mirkov, Nikola, Kostić, Olivera, "Optimal airfoil design and wing analysis for solar-powered high altitude platform station" in Thermal Science, 26, no. 3 (2022):2163-2175,
https://doi.org/10.2298/TSCI210419241S . .

TY  - CONF
AU  - Hasan, Mohammad Sakib
AU  - Svorcan, Jelena
AU  - Tanović, D.
AU  - Baş, G.
AU  - Durakbasa, Numan M.
PY  - 2021
UR  - https://machinery.mas.bg.ac.rs/handle/123456789/3683
AB  - High altitude platforms or Pseudo-satellites (HAPS) are unmanned aerial vehicles that can fly above 17 km from sea level. It can take advantage of weak stratospheric winds and solar energy to operate without interfering with current commercial aviation and with enough endurance to provide long-term services as satellites do. The technological innovations and the growing urgency to expand the availability of broadband led to the development of HAPS. Besides that, Earth observation, positioning, astronomy, and science are the main applications of High altitude platforms, or Pseudo-satellites (HAPS). In this paper, the conceptual design of the novel HAPS UAV based on the initial requirements regarding cruising height of 20 km, the cruising velocity of 25 m/s, and payload of 15 kg were performed and described. The HAPS wing was defined and aerodynamically studied in detail. The computed nominal load was used as input parameter for structural analysis of the wing’s inner structure comprising outer shell, main spars, and ribs made of composite and plastic materials. All computations were performed using commercial software package ANSYS. The obtained results are discussed and graphically presented by computed stress and deformation fields.
PB  - Springer Science and Business Media Deutschland GmbH
C3  - Lecture Notes in Mechanical Engineering
T1  - Conceptual Design and Fluid Structure Interaction Analysis of a Solar Powered High-Altitude Pseudo-Satellite (HAPS) UAV Wing Model
EP  - 105
SP  - 93
DO  - 10.1007/978-3-030-62784-3_8
ER  - 

@conference{
author = "Hasan, Mohammad Sakib and Svorcan, Jelena and Tanović, D. and Baş, G. and Durakbasa, Numan M.",
year = "2021",
abstract = "High altitude platforms or Pseudo-satellites (HAPS) are unmanned aerial vehicles that can fly above 17 km from sea level. It can take advantage of weak stratospheric winds and solar energy to operate without interfering with current commercial aviation and with enough endurance to provide long-term services as satellites do. The technological innovations and the growing urgency to expand the availability of broadband led to the development of HAPS. Besides that, Earth observation, positioning, astronomy, and science are the main applications of High altitude platforms, or Pseudo-satellites (HAPS). In this paper, the conceptual design of the novel HAPS UAV based on the initial requirements regarding cruising height of 20 km, the cruising velocity of 25 m/s, and payload of 15 kg were performed and described. The HAPS wing was defined and aerodynamically studied in detail. The computed nominal load was used as input parameter for structural analysis of the wing’s inner structure comprising outer shell, main spars, and ribs made of composite and plastic materials. All computations were performed using commercial software package ANSYS. The obtained results are discussed and graphically presented by computed stress and deformation fields.",
publisher = "Springer Science and Business Media Deutschland GmbH",
journal = "Lecture Notes in Mechanical Engineering",
title = "Conceptual Design and Fluid Structure Interaction Analysis of a Solar Powered High-Altitude Pseudo-Satellite (HAPS) UAV Wing Model",
pages = "105-93",
doi = "10.1007/978-3-030-62784-3_8"
}

Hasan, M. S., Svorcan, J., Tanović, D., Baş, G.,& Durakbasa, N. M.. (2021). Conceptual Design and Fluid Structure Interaction Analysis of a Solar Powered High-Altitude Pseudo-Satellite (HAPS) UAV Wing Model. in Lecture Notes in Mechanical Engineering
Springer Science and Business Media Deutschland GmbH., 93-105.
https://doi.org/10.1007/978-3-030-62784-3_8

Hasan MS, Svorcan J, Tanović D, Baş G, Durakbasa NM. Conceptual Design and Fluid Structure Interaction Analysis of a Solar Powered High-Altitude Pseudo-Satellite (HAPS) UAV Wing Model. in Lecture Notes in Mechanical Engineering. 2021;:93-105.
doi:10.1007/978-3-030-62784-3_8 .

Hasan, Mohammad Sakib, Svorcan, Jelena, Tanović, D., Baş, G., Durakbasa, Numan M., "Conceptual Design and Fluid Structure Interaction Analysis of a Solar Powered High-Altitude Pseudo-Satellite (HAPS) UAV Wing Model" in Lecture Notes in Mechanical Engineering (2021):93-105,
https://doi.org/10.1007/978-3-030-62784-3_8 . .

TY  - CONF
AU  - Svorcan, Jelena
AU  - Hasan, Mohammad Sakib
AU  - Kovačević, A.
AU  - Ivanov, Toni
PY  - 2021
UR  - https://machinery.mas.bg.ac.rs/handle/123456789/3648
AB  - HALE (high-altitude long-endurance) aircrafts, relatively novel, unmanned air vehicles specifically designed to fly at high altitudes for extended periods of time, require state-of-theart technological solutions in order to operate properly. Likewise, their propulsion system (that usually implies propelled flight) should be optimized with respect to both aerodynamic and structural aspects. This paper presents a conceptual design of a HALE propeller realized through multi-objective and multidisciplinary optimization procedure. A tightly coupled aerostructural two-criteria optimization by genetic algorithm is performed to define a laminated blade of best aerodynamic performance (expressed through maximal aerodynamic efficiency) and minimal mass that is both statically and dynamically reliable when subjected to conjugate aerodynamic, inertial and gravitational loads while cruising at the altitude of 20 km. Numerous geometric, aerodynamic and structural constraints are introduced, and different materials and laminate lay-up sequences are considered. Obtained Pareto sets (of optimal solutions) and Pareto fronts are presented and analyzed in detail. In the end, some recommendations and further research possibilities are given.
PB  - American Institute of Aeronautics and Astronautics Inc, AIAA
C3  - AIAA Propulsion and Energy Forum, 2021
T1  - Design of HALE Propeller through Multi-objective Optimization
DO  - 10.2514/6.2021-3730
ER  - 

@conference{
author = "Svorcan, Jelena and Hasan, Mohammad Sakib and Kovačević, A. and Ivanov, Toni",
year = "2021",
abstract = "HALE (high-altitude long-endurance) aircrafts, relatively novel, unmanned air vehicles specifically designed to fly at high altitudes for extended periods of time, require state-of-theart technological solutions in order to operate properly. Likewise, their propulsion system (that usually implies propelled flight) should be optimized with respect to both aerodynamic and structural aspects. This paper presents a conceptual design of a HALE propeller realized through multi-objective and multidisciplinary optimization procedure. A tightly coupled aerostructural two-criteria optimization by genetic algorithm is performed to define a laminated blade of best aerodynamic performance (expressed through maximal aerodynamic efficiency) and minimal mass that is both statically and dynamically reliable when subjected to conjugate aerodynamic, inertial and gravitational loads while cruising at the altitude of 20 km. Numerous geometric, aerodynamic and structural constraints are introduced, and different materials and laminate lay-up sequences are considered. Obtained Pareto sets (of optimal solutions) and Pareto fronts are presented and analyzed in detail. In the end, some recommendations and further research possibilities are given.",
publisher = "American Institute of Aeronautics and Astronautics Inc, AIAA",
journal = "AIAA Propulsion and Energy Forum, 2021",
title = "Design of HALE Propeller through Multi-objective Optimization",
doi = "10.2514/6.2021-3730"
}

Svorcan, J., Hasan, M. S., Kovačević, A.,& Ivanov, T.. (2021). Design of HALE Propeller through Multi-objective Optimization. in AIAA Propulsion and Energy Forum, 2021
American Institute of Aeronautics and Astronautics Inc, AIAA..
https://doi.org/10.2514/6.2021-3730

Svorcan J, Hasan MS, Kovačević A, Ivanov T. Design of HALE Propeller through Multi-objective Optimization. in AIAA Propulsion and Energy Forum, 2021. 2021;.
doi:10.2514/6.2021-3730 .

Svorcan, Jelena, Hasan, Mohammad Sakib, Kovačević, A., Ivanov, Toni, "Design of HALE Propeller through Multi-objective Optimization" in AIAA Propulsion and Energy Forum, 2021 (2021),
https://doi.org/10.2514/6.2021-3730 . .

TY  - CONF
AU  - Svorcan, Jelena
AU  - Kovačević, Aleksandar
AU  - Hasan, Mohammad Sakib
PY  - 2021
UR  - https://machinery.mas.bg.ac.rs/handle/123456789/4260
AB  - Contemporary, light-weight, unmanned air vehicles almost exclusively imply propeller rotors that enable them to hover, as well as to move vertically and horizontally at acceptable amount of required power (that is usually supplied by electric motors). Rotor main parts are blades − curved, rotational lifting surfaces subject to conjugate aerodynamic, inertial and gravitational loads. Their skin is usually made of composite materials, i.e. glass or carbon fibres (or their combination) immersed in epoxy resin. Additional inner structural elements may include shear webs, spar caps, ribs or foam fillers. The goal of the presented research study is conducting and validating structural analysis of a propeller blade by finite element method. Different structural models (containing just skin, or skin with foam filler), materials (glass or carbon, uni-or biaxial plies), and ply-up sequences (differing in layer numbers and orientations) are considered. The complete blade geometry is modelled, including the root and tip sections. The blade is clamed at the root, while computed aerodynamic, inertial and gravitational forces are distributed along its surface (and volume). Since the blade operates in axisymmetric conditions, it was possible to perform static structural analyses. Obtained results include deflection (and deformation) fields, normal and shear stress distributions along the plies, etc. From the acquired numerical values, it is possible to define an adequate blade structure that will be able to withstand all working loads (multiplied by necessary safety factors) and ensure safe flight of the aircraft. Future research may include modal or fatigue analyses of propeller blades.
PB  - Belgrade : Innovation Center of Faculty of Mechanical Engineering
C3  - The Book of Abstracts - International Conference of Experimental and Numerical Investigations and New Technologies CNN TECH
T1  - Structural analysis of small-scale composite propeller blade
SP  - 63
UR  - https://hdl.handle.net/21.15107/rcub_machinery_4260
ER  - 

@conference{
author = "Svorcan, Jelena and Kovačević, Aleksandar and Hasan, Mohammad Sakib",
year = "2021",
abstract = "Contemporary, light-weight, unmanned air vehicles almost exclusively imply propeller rotors that enable them to hover, as well as to move vertically and horizontally at acceptable amount of required power (that is usually supplied by electric motors). Rotor main parts are blades − curved, rotational lifting surfaces subject to conjugate aerodynamic, inertial and gravitational loads. Their skin is usually made of composite materials, i.e. glass or carbon fibres (or their combination) immersed in epoxy resin. Additional inner structural elements may include shear webs, spar caps, ribs or foam fillers. The goal of the presented research study is conducting and validating structural analysis of a propeller blade by finite element method. Different structural models (containing just skin, or skin with foam filler), materials (glass or carbon, uni-or biaxial plies), and ply-up sequences (differing in layer numbers and orientations) are considered. The complete blade geometry is modelled, including the root and tip sections. The blade is clamed at the root, while computed aerodynamic, inertial and gravitational forces are distributed along its surface (and volume). Since the blade operates in axisymmetric conditions, it was possible to perform static structural analyses. Obtained results include deflection (and deformation) fields, normal and shear stress distributions along the plies, etc. From the acquired numerical values, it is possible to define an adequate blade structure that will be able to withstand all working loads (multiplied by necessary safety factors) and ensure safe flight of the aircraft. Future research may include modal or fatigue analyses of propeller blades.",
publisher = "Belgrade : Innovation Center of Faculty of Mechanical Engineering",
journal = "The Book of Abstracts - International Conference of Experimental and Numerical Investigations and New Technologies CNN TECH",
title = "Structural analysis of small-scale composite propeller blade",
pages = "63",
url = "https://hdl.handle.net/21.15107/rcub_machinery_4260"
}

Svorcan, J., Kovačević, A.,& Hasan, M. S.. (2021). Structural analysis of small-scale composite propeller blade. in The Book of Abstracts - International Conference of Experimental and Numerical Investigations and New Technologies CNN TECH
Belgrade : Innovation Center of Faculty of Mechanical Engineering., 63.
https://hdl.handle.net/21.15107/rcub_machinery_4260

Svorcan J, Kovačević A, Hasan MS. Structural analysis of small-scale composite propeller blade. in The Book of Abstracts - International Conference of Experimental and Numerical Investigations and New Technologies CNN TECH. 2021;:63.
https://hdl.handle.net/21.15107/rcub_machinery_4260 .

Svorcan, Jelena, Kovačević, Aleksandar, Hasan, Mohammad Sakib, "Structural analysis of small-scale composite propeller blade" in The Book of Abstracts - International Conference of Experimental and Numerical Investigations and New Technologies CNN TECH (2021):63,
https://hdl.handle.net/21.15107/rcub_machinery_4260 .

TY  - CONF
AU  - Svorcan, Jelena
AU  - Hasan, Mohammad Sakib
AU  - Tanović, Dragoljub Lj.
AU  - Popović, Lazar
PY  - 2021
UR  - https://machinery.mas.bg.ac.rs/handle/123456789/4216
AB  - Investigated topic of the presented research is transitional and turbulent flow around smallscale
propeller blade airfoils that are characterized by small chords, low speeds and therefore, low
Reynolds numbers. Here, an airfoil of medium relative thickness designed for nominal operating
conditions of 0.3 MRe is considered. Prior studies by simpler computational models (including
panel methods and 2D CFD simulations) have demonstrated that best lift-to-drag ratio (that is the
desired working regime) ranging from 60 to 80 can be achieved at angles-of-attack 4-6°. Here,
that observation is checked by more advanced turbulence models that incorporate the resolution
of at least a portion of turbulence spectrum, in particular transition SST scale-adaptive simulation
(SAS). Such complex turbulence models require 3D models and quite refined computational
grids. Furthermore, the necessary computational effort is truly enormous due to small time-steps
and slow convergence. The conducted computational process is presented and explained. Various
obtained results, both quantitative and qualitative, are provided. In the end, it can be concluded
that the choice of turbulence modeling (and/or resolving) greatly affects the final output, even at
medium angles-of-attack where laminar, attached flow dominates. Distinctive flow phenomena
still exist, and in order to be adequately simulated, a comprehensive modeling approach should be
adopted.
PB  - Belgrade : Serbian Society of Mechanics
C3  - Proceedings / The 8th International Congress of Serbian Society of Mechanics, Kragujevac, Serbia, June 28-30, 2021
T1  - Simulating transitional and turbulent flow around airfoils at medium angles-of-attack
EP  - 526
SP  - 519
UR  - https://hdl.handle.net/21.15107/rcub_machinery_4216
ER  - 

@conference{
author = "Svorcan, Jelena and Hasan, Mohammad Sakib and Tanović, Dragoljub Lj. and Popović, Lazar",
year = "2021",
abstract = "Investigated topic of the presented research is transitional and turbulent flow around smallscale
propeller blade airfoils that are characterized by small chords, low speeds and therefore, low
Reynolds numbers. Here, an airfoil of medium relative thickness designed for nominal operating
conditions of 0.3 MRe is considered. Prior studies by simpler computational models (including
panel methods and 2D CFD simulations) have demonstrated that best lift-to-drag ratio (that is the
desired working regime) ranging from 60 to 80 can be achieved at angles-of-attack 4-6°. Here,
that observation is checked by more advanced turbulence models that incorporate the resolution
of at least a portion of turbulence spectrum, in particular transition SST scale-adaptive simulation
(SAS). Such complex turbulence models require 3D models and quite refined computational
grids. Furthermore, the necessary computational effort is truly enormous due to small time-steps
and slow convergence. The conducted computational process is presented and explained. Various
obtained results, both quantitative and qualitative, are provided. In the end, it can be concluded
that the choice of turbulence modeling (and/or resolving) greatly affects the final output, even at
medium angles-of-attack where laminar, attached flow dominates. Distinctive flow phenomena
still exist, and in order to be adequately simulated, a comprehensive modeling approach should be
adopted.",
publisher = "Belgrade : Serbian Society of Mechanics",
journal = "Proceedings / The 8th International Congress of Serbian Society of Mechanics, Kragujevac, Serbia, June 28-30, 2021",
title = "Simulating transitional and turbulent flow around airfoils at medium angles-of-attack",
pages = "526-519",
url = "https://hdl.handle.net/21.15107/rcub_machinery_4216"
}

Svorcan, J., Hasan, M. S., Tanović, D. Lj.,& Popović, L.. (2021). Simulating transitional and turbulent flow around airfoils at medium angles-of-attack. in Proceedings / The 8th International Congress of Serbian Society of Mechanics, Kragujevac, Serbia, June 28-30, 2021
Belgrade : Serbian Society of Mechanics., 519-526.
https://hdl.handle.net/21.15107/rcub_machinery_4216

Svorcan J, Hasan MS, Tanović DL, Popović L. Simulating transitional and turbulent flow around airfoils at medium angles-of-attack. in Proceedings / The 8th International Congress of Serbian Society of Mechanics, Kragujevac, Serbia, June 28-30, 2021. 2021;:519-526.
https://hdl.handle.net/21.15107/rcub_machinery_4216 .

Svorcan, Jelena, Hasan, Mohammad Sakib, Tanović, Dragoljub Lj., Popović, Lazar, "Simulating transitional and turbulent flow around airfoils at medium angles-of-attack" in Proceedings / The 8th International Congress of Serbian Society of Mechanics, Kragujevac, Serbia, June 28-30, 2021 (2021):519-526,
https://hdl.handle.net/21.15107/rcub_machinery_4216 .

TY  - JOUR
AU  - Svorcan, Jelena
AU  - Kovačević, A.
AU  - Tanović, D.
AU  - Hasan, Mohammad Sakib
PY  - 2021
UR  - https://machinery.mas.bg.ac.rs/handle/123456789/3650
AB  - The paper focuses on the possibilities of adequately simulating complex flow fields that appear around small-scale propellers of multicopter aircraft. Such unmanned air vehicles (UAVs) are steadily gaining popularity for their diverse applications (surveillance, communication, deliveries, etc.) and the need for a viable (i.e. usable, satisfactory, practical) computational tool is also surging. From an engineering standpoint, it is important to obtain sufficiently accurate predictions of flow field variables in a reasonable amount of time so that the design process can be fast and efficient, in particular the subsequent structural and flight mechanics analyses. That is why more or less standard fluid flow models, e.g. Reynolds-averaged Navier—Stokes (RANS) equations solved by the finite volume method (FVM), are constantly being employed and validated. On the other hand, special attention must be given to various flow peculiarities occurring around the blade segments shaped like airfoils since these flows are characterized by small chords (length-scales), low speeds and, therefore, low Reynolds numbers (Re) and pronounced viscous effects. The investigated low-Re flows include both transitional and turbulent zones, laminar separation bubbles (LSBs), flow separation, as well as rotating wakes, which require somewhat specific approaches to flow modeling (advanced turbulence models, fine spatial and temporal scales, etc). Here, the conducted computations (around stationary blade segments as well as rotating rotors), closed by different turbulence models, are presented and explained. Various qualitative and quantitative results are provided, compared and discussed. The main possibilities and obstacles of each computational approach are mentioned. Where possible, numerical results are validated against experimental data. The correspondence between the two sets of results can be considered satisfactory (relative differences for the thrust coefficient amount to 15%, while they are even lower for the torque coefficient). It can be concluded that the choice of turbulence modeling (and/or resolving) greatly affects the final output, even in design operating conditions (at medium angles-of-attack where laminar, attached flow dominates). Distinctive flow phenomena still exist, and in order to be adequately simulated, a comprehensive modeling approach should be adopted.
PB  - Beograd : Srpsko društvo za mehaniku
T2  - Theoretical and Applied Mechanics
T1  - Towards viable flow simulations of small-scale rotors and blade segments
EP  - 157
IS  - 2
SP  - 143
VL  - 48
DO  - 10.2298/TAM211011008S
ER  - 

@article{
author = "Svorcan, Jelena and Kovačević, A. and Tanović, D. and Hasan, Mohammad Sakib",
year = "2021",
abstract = "The paper focuses on the possibilities of adequately simulating complex flow fields that appear around small-scale propellers of multicopter aircraft. Such unmanned air vehicles (UAVs) are steadily gaining popularity for their diverse applications (surveillance, communication, deliveries, etc.) and the need for a viable (i.e. usable, satisfactory, practical) computational tool is also surging. From an engineering standpoint, it is important to obtain sufficiently accurate predictions of flow field variables in a reasonable amount of time so that the design process can be fast and efficient, in particular the subsequent structural and flight mechanics analyses. That is why more or less standard fluid flow models, e.g. Reynolds-averaged Navier—Stokes (RANS) equations solved by the finite volume method (FVM), are constantly being employed and validated. On the other hand, special attention must be given to various flow peculiarities occurring around the blade segments shaped like airfoils since these flows are characterized by small chords (length-scales), low speeds and, therefore, low Reynolds numbers (Re) and pronounced viscous effects. The investigated low-Re flows include both transitional and turbulent zones, laminar separation bubbles (LSBs), flow separation, as well as rotating wakes, which require somewhat specific approaches to flow modeling (advanced turbulence models, fine spatial and temporal scales, etc). Here, the conducted computations (around stationary blade segments as well as rotating rotors), closed by different turbulence models, are presented and explained. Various qualitative and quantitative results are provided, compared and discussed. The main possibilities and obstacles of each computational approach are mentioned. Where possible, numerical results are validated against experimental data. The correspondence between the two sets of results can be considered satisfactory (relative differences for the thrust coefficient amount to 15%, while they are even lower for the torque coefficient). It can be concluded that the choice of turbulence modeling (and/or resolving) greatly affects the final output, even in design operating conditions (at medium angles-of-attack where laminar, attached flow dominates). Distinctive flow phenomena still exist, and in order to be adequately simulated, a comprehensive modeling approach should be adopted.",
publisher = "Beograd : Srpsko društvo za mehaniku",
journal = "Theoretical and Applied Mechanics",
title = "Towards viable flow simulations of small-scale rotors and blade segments",
pages = "157-143",
number = "2",
volume = "48",
doi = "10.2298/TAM211011008S"
}

Svorcan, J., Kovačević, A., Tanović, D.,& Hasan, M. S.. (2021). Towards viable flow simulations of small-scale rotors and blade segments. in Theoretical and Applied Mechanics
Beograd : Srpsko društvo za mehaniku., 48(2), 143-157.
https://doi.org/10.2298/TAM211011008S

Svorcan J, Kovačević A, Tanović D, Hasan MS. Towards viable flow simulations of small-scale rotors and blade segments. in Theoretical and Applied Mechanics. 2021;48(2):143-157.
doi:10.2298/TAM211011008S .

Svorcan, Jelena, Kovačević, A., Tanović, D., Hasan, Mohammad Sakib, "Towards viable flow simulations of small-scale rotors and blade segments" in Theoretical and Applied Mechanics, 48, no. 2 (2021):143-157,
https://doi.org/10.2298/TAM211011008S . .

TY  - JOUR
AU  - Kovacević, Aleksandar
AU  - Svorcan, Jelena
AU  - Hasan, Mohammad Sakib
AU  - Ivanov, Toni
AU  - Jovanović, Miroslav
PY  - 2021
UR  - https://machinery.mas.bg.ac.rs/handle/123456789/3503
AB  - Purpose Modern unmanned air vehicles (UAVs) are usually equipped with rotors connected to electric motors that enable them to hover and fly in all directions. The purpose of the paper is to design optimal composite rotor blades for such small UAVs and investigate their aerodynamic performances both computationally and experimentally. Design/methodology/approach Artificial intelligence method (genetic algorithm) is used to optimize the blade airfoil described by six input parameters. Furthermore, different computational methods, e.g. vortex methods and computational fluid dynamics, blade element momentum theory and finite element method, are used to predict the aerodynamic performances of the optimized airfoil and complete rotor as well the structural behaviour of the blade, respectively. Finally, composite blade is manufactured and the rotor performance is also determined experimentally by thrust and torque measurements. Findings Complete process of blade design (including geometry definition and optimization, estimation of aerodynamic performances, structural analysis and blade manufacturing) is conducted and explained in detail. The correspondence between computed and measured thrust and torque curves of the optimal rotor is satisfactory (differences mostly remain below 15%), which validates and justifies the used design approach formulated specifically for low-cost, small-scale propeller blades. Furthermore, the proposed techniques can easily be applied to any kind of rotating lifting surfaces including helicopter or wind turbine blades. Originality/value Blade design methodology is simplified, shortened and made more flexible thus enabling the fast and economic production of propeller blades optimized for specific working conditions.
PB  - Emerald Group Publishing Ltd, Bingley
T2  - Aircraft Engineering and Aerospace Technology
T1  - Optimal propeller blade design, computation, manufacturing and experimental testing
EP  - 1332
IS  - 8
SP  - 1323
VL  - 93
DO  - 10.1108/AEAT-03-2021-0091
ER  - 

@article{
author = "Kovacević, Aleksandar and Svorcan, Jelena and Hasan, Mohammad Sakib and Ivanov, Toni and Jovanović, Miroslav",
year = "2021",
abstract = "Purpose Modern unmanned air vehicles (UAVs) are usually equipped with rotors connected to electric motors that enable them to hover and fly in all directions. The purpose of the paper is to design optimal composite rotor blades for such small UAVs and investigate their aerodynamic performances both computationally and experimentally. Design/methodology/approach Artificial intelligence method (genetic algorithm) is used to optimize the blade airfoil described by six input parameters. Furthermore, different computational methods, e.g. vortex methods and computational fluid dynamics, blade element momentum theory and finite element method, are used to predict the aerodynamic performances of the optimized airfoil and complete rotor as well the structural behaviour of the blade, respectively. Finally, composite blade is manufactured and the rotor performance is also determined experimentally by thrust and torque measurements. Findings Complete process of blade design (including geometry definition and optimization, estimation of aerodynamic performances, structural analysis and blade manufacturing) is conducted and explained in detail. The correspondence between computed and measured thrust and torque curves of the optimal rotor is satisfactory (differences mostly remain below 15%), which validates and justifies the used design approach formulated specifically for low-cost, small-scale propeller blades. Furthermore, the proposed techniques can easily be applied to any kind of rotating lifting surfaces including helicopter or wind turbine blades. Originality/value Blade design methodology is simplified, shortened and made more flexible thus enabling the fast and economic production of propeller blades optimized for specific working conditions.",
publisher = "Emerald Group Publishing Ltd, Bingley",
journal = "Aircraft Engineering and Aerospace Technology",
title = "Optimal propeller blade design, computation, manufacturing and experimental testing",
pages = "1332-1323",
number = "8",
volume = "93",
doi = "10.1108/AEAT-03-2021-0091"
}

Kovacević, A., Svorcan, J., Hasan, M. S., Ivanov, T.,& Jovanović, M.. (2021). Optimal propeller blade design, computation, manufacturing and experimental testing. in Aircraft Engineering and Aerospace Technology
Emerald Group Publishing Ltd, Bingley., 93(8), 1323-1332.
https://doi.org/10.1108/AEAT-03-2021-0091

Kovacević A, Svorcan J, Hasan MS, Ivanov T, Jovanović M. Optimal propeller blade design, computation, manufacturing and experimental testing. in Aircraft Engineering and Aerospace Technology. 2021;93(8):1323-1332.
doi:10.1108/AEAT-03-2021-0091 .

Kovacević, Aleksandar, Svorcan, Jelena, Hasan, Mohammad Sakib, Ivanov, Toni, Jovanović, Miroslav, "Optimal propeller blade design, computation, manufacturing and experimental testing" in Aircraft Engineering and Aerospace Technology, 93, no. 8 (2021):1323-1332,
https://doi.org/10.1108/AEAT-03-2021-0091 . .

TY  - JOUR
AU  - Svorcan, Jelena
AU  - Peković, Ognjen
AU  - Simonović, Aleksandar
AU  - Tanović, Dragoljub
AU  - Hasan, Mohammad Sakib
PY  - 2021
UR  - https://machinery.mas.bg.ac.rs/handle/123456789/3547
AB  - Wind energy extraction is one of the fastest developing engineering branches today. Number of installed wind turbines is constantly increasing. Appropriate solutions for urban environments are quiet, structurally simple and affordable small-scale vertical-axis wind turbines (VAWTs). Due to small efficiency, particularly in low and variable winds, main topic here is development of optimal flow concentrator that locally augments wind velocity, facilitates turbine start and increases generated power. Conceptual design was performed by combining finite volume method and artificial intelligence (AI). Smaller set of computational results (velocity profiles induced by existence of different concentrators in flow field) was used for creation, training and validation of several artificial neural networks. Multi-objective optimization of concentrator geometric parameters was realized through coupling of generated neural networks with genetic algorithm. Final solution from the acquired Pareto set is studied in more detail. Resulting computed velocity field is illustrated. Aerodynamic performances of small-scale VAWT with and without optimal flow concentrator are estimated and compared. The performed research demonstrates that, with use of flow concentrator, average increase in wind speed of 20%-25% can be expected. It also proves that contemporary AI techniques can significantly facilitate and accelerate design processes in the field of wind engineering.
PB  - Sage Publications Ltd, London
T2  - Advances in Mechanical Engineering
T1  - Design of optimal flow concentrator for vertical-axis wind turbines using computational fluid dynamics, artificial neural networks and genetic algorithm
IS  - 3
VL  - 13
DO  - 10.1177/16878140211009009
ER  - 

@article{
author = "Svorcan, Jelena and Peković, Ognjen and Simonović, Aleksandar and Tanović, Dragoljub and Hasan, Mohammad Sakib",
year = "2021",
abstract = "Wind energy extraction is one of the fastest developing engineering branches today. Number of installed wind turbines is constantly increasing. Appropriate solutions for urban environments are quiet, structurally simple and affordable small-scale vertical-axis wind turbines (VAWTs). Due to small efficiency, particularly in low and variable winds, main topic here is development of optimal flow concentrator that locally augments wind velocity, facilitates turbine start and increases generated power. Conceptual design was performed by combining finite volume method and artificial intelligence (AI). Smaller set of computational results (velocity profiles induced by existence of different concentrators in flow field) was used for creation, training and validation of several artificial neural networks. Multi-objective optimization of concentrator geometric parameters was realized through coupling of generated neural networks with genetic algorithm. Final solution from the acquired Pareto set is studied in more detail. Resulting computed velocity field is illustrated. Aerodynamic performances of small-scale VAWT with and without optimal flow concentrator are estimated and compared. The performed research demonstrates that, with use of flow concentrator, average increase in wind speed of 20%-25% can be expected. It also proves that contemporary AI techniques can significantly facilitate and accelerate design processes in the field of wind engineering.",
publisher = "Sage Publications Ltd, London",
journal = "Advances in Mechanical Engineering",
title = "Design of optimal flow concentrator for vertical-axis wind turbines using computational fluid dynamics, artificial neural networks and genetic algorithm",
number = "3",
volume = "13",
doi = "10.1177/16878140211009009"
}

Svorcan, J., Peković, O., Simonović, A., Tanović, D.,& Hasan, M. S.. (2021). Design of optimal flow concentrator for vertical-axis wind turbines using computational fluid dynamics, artificial neural networks and genetic algorithm. in Advances in Mechanical Engineering
Sage Publications Ltd, London., 13(3).
https://doi.org/10.1177/16878140211009009

Svorcan J, Peković O, Simonović A, Tanović D, Hasan MS. Design of optimal flow concentrator for vertical-axis wind turbines using computational fluid dynamics, artificial neural networks and genetic algorithm. in Advances in Mechanical Engineering. 2021;13(3).
doi:10.1177/16878140211009009 .

Svorcan, Jelena, Peković, Ognjen, Simonović, Aleksandar, Tanović, Dragoljub, Hasan, Mohammad Sakib, "Design of optimal flow concentrator for vertical-axis wind turbines using computational fluid dynamics, artificial neural networks and genetic algorithm" in Advances in Mechanical Engineering, 13, no. 3 (2021),
https://doi.org/10.1177/16878140211009009 . .

TY  - CONF
AU  - Baltić, Marija
AU  - Hasan, Mohammad Sakib
AU  - Milovanović, Aleksa
PY  - 2020
UR  - https://machinery.mas.bg.ac.rs/handle/123456789/7362
AB  - Expansion of economic development also encourages the need for research, testing and application of new
advanced materials. Bearing in mind the development of technology and market dynamics in renewable energy
resources, especially wind potential, technology transfer in this field is very significant in all countries where
this industry is insufficiently developed. The advancement of wind turbines, as high-tech products and
components that require specific high quality characteristics, can influence the modernization of the
mechanical industry. For this reason, the development, testing, production and application of advanced highperformance
composite materials are of great importance.
The work presents the experimental testing and mechanical behaviour of composite structures under tensile
loading. Two types of carbon-epoxy plates and two types of glass-epoxy plates, of the same dimensions but
different ply lay-up sequences, were prepared and experimentally tested according to the procedure prescribed
by the tensile test standard ASTM D3039. The performance of the samples were first simulated in ANSYS
software in order to validate and verify the experimental set-up, and then experiments were performed under
tensile loading at the universal electromechanical test frame SHIMADZU AGS-X 100 kN. The experimentally
obtained modules of elasticity are presented. The measured values are also illustrated graphically in forcedisplacement
and stress-strain diagrams. The presented results acquired by this test method are important in
order to better understand the behaviour of composite structures under various load cases. The obtained
information and performed analysis of the measured parameters can be used in further experimental
investigations as well as in different comparative studies of conventional and unconventional empirical
methods.
C3  - International conference of experimental and numerical investigations and new technologies (2020 ; Zlatibor)
T1  - Experimental investigation of mechanical characteristics of composite plates under tensile loading
SP  - 53
UR  - https://hdl.handle.net/21.15107/rcub_machinery_7362
ER  - 

@conference{
author = "Baltić, Marija and Hasan, Mohammad Sakib and Milovanović, Aleksa",
year = "2020",
abstract = "Expansion of economic development also encourages the need for research, testing and application of new
advanced materials. Bearing in mind the development of technology and market dynamics in renewable energy
resources, especially wind potential, technology transfer in this field is very significant in all countries where
this industry is insufficiently developed. The advancement of wind turbines, as high-tech products and
components that require specific high quality characteristics, can influence the modernization of the
mechanical industry. For this reason, the development, testing, production and application of advanced highperformance
composite materials are of great importance.
The work presents the experimental testing and mechanical behaviour of composite structures under tensile
loading. Two types of carbon-epoxy plates and two types of glass-epoxy plates, of the same dimensions but
different ply lay-up sequences, were prepared and experimentally tested according to the procedure prescribed
by the tensile test standard ASTM D3039. The performance of the samples were first simulated in ANSYS
software in order to validate and verify the experimental set-up, and then experiments were performed under
tensile loading at the universal electromechanical test frame SHIMADZU AGS-X 100 kN. The experimentally
obtained modules of elasticity are presented. The measured values are also illustrated graphically in forcedisplacement
and stress-strain diagrams. The presented results acquired by this test method are important in
order to better understand the behaviour of composite structures under various load cases. The obtained
information and performed analysis of the measured parameters can be used in further experimental
investigations as well as in different comparative studies of conventional and unconventional empirical
methods.",
journal = "International conference of experimental and numerical investigations and new technologies (2020 ; Zlatibor)",
title = "Experimental investigation of mechanical characteristics of composite plates under tensile loading",
pages = "53",
url = "https://hdl.handle.net/21.15107/rcub_machinery_7362"
}

Baltić, M., Hasan, M. S.,& Milovanović, A.. (2020). Experimental investigation of mechanical characteristics of composite plates under tensile loading. in International conference of experimental and numerical investigations and new technologies (2020 ; Zlatibor), 53.
https://hdl.handle.net/21.15107/rcub_machinery_7362

Baltić M, Hasan MS, Milovanović A. Experimental investigation of mechanical characteristics of composite plates under tensile loading. in International conference of experimental and numerical investigations and new technologies (2020 ; Zlatibor). 2020;:53.
https://hdl.handle.net/21.15107/rcub_machinery_7362 .

Baltić, Marija, Hasan, Mohammad Sakib, Milovanović, Aleksa, "Experimental investigation of mechanical characteristics of composite plates under tensile loading" in International conference of experimental and numerical investigations and new technologies (2020 ; Zlatibor) (2020):53,
https://hdl.handle.net/21.15107/rcub_machinery_7362 .

TY  - CONF
AU  - Tanović, Dragoljub Lj.
AU  - Svorcan, Jelena
AU  - Peković, Ognjen
AU  - Hasan, Mohammad Sakib
PY  - 2020
UR  - https://machinery.mas.bg.ac.rs/handle/123456789/4284
AB  - Rastuća zabrinutost zbog globalnog zagrevanja, zagađenja životne sredine i poskupljenja fosilnih goriva doveli su do interesovanja za razvoj obnovljivih i ekološki prihvatljivih izvora energije. Stoga istraživanja u oblasti obnovljivih izvora, posebno energije vetra, postaju izuzetno aktuelna. U radu je izvršena aerodinamička analiza vetroturbina sa vertikalnom osom obrtanja - VAWT, koje imaju različite aeroprofile. Korišćene su dve metode BEM - Blade Element Momentum i DMS - Double Multiple Streamtube, obično usvojene za rani dizajn i ocenu turbina. U radu je korišćen program Qblade, a dobijeni rezultati snage u zavisnosti od brzine vetra omogućuvaju upoređivanje performansi vetroturbine.
PB  - Univerzitet u Beogradu - Mašinski fakultet
C3  - Zbornik radova sa 42. JUPITER konferencije, 29. CAD/CAM simpozijum
T1  - Analiza performansi vetroturbina različitih aeroprofila
EP  - 2.40
SP  - 2.33
UR  - https://hdl.handle.net/21.15107/rcub_machinery_4284
ER  - 

@conference{
author = "Tanović, Dragoljub Lj. and Svorcan, Jelena and Peković, Ognjen and Hasan, Mohammad Sakib",
year = "2020",
abstract = "Rastuća zabrinutost zbog globalnog zagrevanja, zagađenja životne sredine i poskupljenja fosilnih goriva doveli su do interesovanja za razvoj obnovljivih i ekološki prihvatljivih izvora energije. Stoga istraživanja u oblasti obnovljivih izvora, posebno energije vetra, postaju izuzetno aktuelna. U radu je izvršena aerodinamička analiza vetroturbina sa vertikalnom osom obrtanja - VAWT, koje imaju različite aeroprofile. Korišćene su dve metode BEM - Blade Element Momentum i DMS - Double Multiple Streamtube, obično usvojene za rani dizajn i ocenu turbina. U radu je korišćen program Qblade, a dobijeni rezultati snage u zavisnosti od brzine vetra omogućuvaju upoređivanje performansi vetroturbine.",
publisher = "Univerzitet u Beogradu - Mašinski fakultet",
journal = "Zbornik radova sa 42. JUPITER konferencije, 29. CAD/CAM simpozijum",
title = "Analiza performansi vetroturbina različitih aeroprofila",
pages = "2.40-2.33",
url = "https://hdl.handle.net/21.15107/rcub_machinery_4284"
}

Tanović, D. Lj., Svorcan, J., Peković, O.,& Hasan, M. S.. (2020). Analiza performansi vetroturbina različitih aeroprofila. in Zbornik radova sa 42. JUPITER konferencije, 29. CAD/CAM simpozijum
Univerzitet u Beogradu - Mašinski fakultet., 2.33-2.40.
https://hdl.handle.net/21.15107/rcub_machinery_4284

Tanović DL, Svorcan J, Peković O, Hasan MS. Analiza performansi vetroturbina različitih aeroprofila. in Zbornik radova sa 42. JUPITER konferencije, 29. CAD/CAM simpozijum. 2020;:2.33-2.40.
https://hdl.handle.net/21.15107/rcub_machinery_4284 .

Tanović, Dragoljub Lj., Svorcan, Jelena, Peković, Ognjen, Hasan, Mohammad Sakib, "Analiza performansi vetroturbina različitih aeroprofila" in Zbornik radova sa 42. JUPITER konferencije, 29. CAD/CAM simpozijum (2020):2.33-2.40,
https://hdl.handle.net/21.15107/rcub_machinery_4284 .

TY  - CONF
AU  - Svorcan, Jelena
AU  - Peković, Ognjen
AU  - Tanović, Dragoljub Lj.
AU  - Hasan, Mohammad Sakib
PY  - 2020
UR  - https://machinery.mas.bg.ac.rs/handle/123456789/4283
AB  - Efikasno iskorišćenje energije vetra (kao jednog od najzastupljenijih obnovljivih izvora energije) je danas veoma aktuelna tema. Mnogo se radi na poboljšanju aerodinamičkih performansi vetroturbina u urbanim sredinama gde je raspoloživi prostor ograničen i postoji mnogo okolnih objekata koji mogu lokalno da unaprede ili unazade nadolazeći profil brzine. Iz tog razloga, često se postavljaju pomoćne geometrije (koncentratori) koje treba da usmere ili povećaju brzinu kroz rotor. Rad prikazuje olakšano određivanje takvog modifikovanog (ubrzanog) profila brzine pomoću sprege numeričkih simulacija opstrujavanja koncentratora i veštačkih neuronskih mreža. Geometrija koncentratora je parametrizovana da bi se postiglo najveće moguće ubrzanje za uslove na određenoj lokaciji.
PB  - Univerzitet u Beogradu - Mašinski fakultet
C3  - Zbornik radova sa 42. JUPITER konferencije, 29. CAD/CAM simpozijum
T1  - Određivanje modifikovanog profila brzine pomoću proračuna opstrujavanja i veštačkih neuronskih mreža
EP  - 2.32
SP  - 2.27
UR  - https://hdl.handle.net/21.15107/rcub_machinery_4283
ER  - 

@conference{
author = "Svorcan, Jelena and Peković, Ognjen and Tanović, Dragoljub Lj. and Hasan, Mohammad Sakib",
year = "2020",
abstract = "Efikasno iskorišćenje energije vetra (kao jednog od najzastupljenijih obnovljivih izvora energije) je danas veoma aktuelna tema. Mnogo se radi na poboljšanju aerodinamičkih performansi vetroturbina u urbanim sredinama gde je raspoloživi prostor ograničen i postoji mnogo okolnih objekata koji mogu lokalno da unaprede ili unazade nadolazeći profil brzine. Iz tog razloga, često se postavljaju pomoćne geometrije (koncentratori) koje treba da usmere ili povećaju brzinu kroz rotor. Rad prikazuje olakšano određivanje takvog modifikovanog (ubrzanog) profila brzine pomoću sprege numeričkih simulacija opstrujavanja koncentratora i veštačkih neuronskih mreža. Geometrija koncentratora je parametrizovana da bi se postiglo najveće moguće ubrzanje za uslove na određenoj lokaciji.",
publisher = "Univerzitet u Beogradu - Mašinski fakultet",
journal = "Zbornik radova sa 42. JUPITER konferencije, 29. CAD/CAM simpozijum",
title = "Određivanje modifikovanog profila brzine pomoću proračuna opstrujavanja i veštačkih neuronskih mreža",
pages = "2.32-2.27",
url = "https://hdl.handle.net/21.15107/rcub_machinery_4283"
}

Svorcan, J., Peković, O., Tanović, D. Lj.,& Hasan, M. S.. (2020). Određivanje modifikovanog profila brzine pomoću proračuna opstrujavanja i veštačkih neuronskih mreža. in Zbornik radova sa 42. JUPITER konferencije, 29. CAD/CAM simpozijum
Univerzitet u Beogradu - Mašinski fakultet., 2.27-2.32.
https://hdl.handle.net/21.15107/rcub_machinery_4283

Svorcan J, Peković O, Tanović DL, Hasan MS. Određivanje modifikovanog profila brzine pomoću proračuna opstrujavanja i veštačkih neuronskih mreža. in Zbornik radova sa 42. JUPITER konferencije, 29. CAD/CAM simpozijum. 2020;:2.27-2.32.
https://hdl.handle.net/21.15107/rcub_machinery_4283 .

Svorcan, Jelena, Peković, Ognjen, Tanović, Dragoljub Lj., Hasan, Mohammad Sakib, "Određivanje modifikovanog profila brzine pomoću proračuna opstrujavanja i veštačkih neuronskih mreža" in Zbornik radova sa 42. JUPITER konferencije, 29. CAD/CAM simpozijum (2020):2.27-2.32,
https://hdl.handle.net/21.15107/rcub_machinery_4283 .

TY  - CONF
AU  - Svorcan, Jelena
AU  - Hasan, Mohammad Sakib
AU  - Kovačević, Aleksandar
AU  - Ivanov, Toni
PY  - 2020
UR  - https://machinery.mas.bg.ac.rs/handle/123456789/4218
AB  - Over the past decade, multicopter unmanned aircrafts have gained extreme popularity. Since their application spans from children toys to video surveillance, surface mapping, payload delivery, communication, etc, much work is being done worldwide on their promotion and advancement. With many electric components commercially available, it has become imperative to develop customized and optimized mechanical parts. This paper investigates the possibility of defining the optimal two-bladed propeller for an existing small electric motor of known characteristics. The propeller should be geometrically simple to reduce the cost of product ion but still provide the greatest thrust for given angular speed and available torque. While cubic chord and linear pitch distributions along the blade are predefined, the airfoil is parameterized by the Class-Shape Transformation (CST) technique (by 6 input parameters). Rotor performance is estimated by an improved blade element momentum theory (BEMT) while the two-criteria optimization is performed by genetic algorithm (GA).
PB  - SARES
C3  - International Symposium on Electric Aviation and Autonomous Systems ISEAS 2020
T1  - Design of the optimal airfoil for a blade of a small-scale multi-rotor VTOL UAV
EP  - 55
SP  - 52
UR  - https://hdl.handle.net/21.15107/rcub_machinery_4218
ER  - 

@conference{
author = "Svorcan, Jelena and Hasan, Mohammad Sakib and Kovačević, Aleksandar and Ivanov, Toni",
year = "2020",
abstract = "Over the past decade, multicopter unmanned aircrafts have gained extreme popularity. Since their application spans from children toys to video surveillance, surface mapping, payload delivery, communication, etc, much work is being done worldwide on their promotion and advancement. With many electric components commercially available, it has become imperative to develop customized and optimized mechanical parts. This paper investigates the possibility of defining the optimal two-bladed propeller for an existing small electric motor of known characteristics. The propeller should be geometrically simple to reduce the cost of product ion but still provide the greatest thrust for given angular speed and available torque. While cubic chord and linear pitch distributions along the blade are predefined, the airfoil is parameterized by the Class-Shape Transformation (CST) technique (by 6 input parameters). Rotor performance is estimated by an improved blade element momentum theory (BEMT) while the two-criteria optimization is performed by genetic algorithm (GA).",
publisher = "SARES",
journal = "International Symposium on Electric Aviation and Autonomous Systems ISEAS 2020",
title = "Design of the optimal airfoil for a blade of a small-scale multi-rotor VTOL UAV",
pages = "55-52",
url = "https://hdl.handle.net/21.15107/rcub_machinery_4218"
}

Svorcan, J., Hasan, M. S., Kovačević, A.,& Ivanov, T.. (2020). Design of the optimal airfoil for a blade of a small-scale multi-rotor VTOL UAV. in International Symposium on Electric Aviation and Autonomous Systems ISEAS 2020
SARES., 52-55.
https://hdl.handle.net/21.15107/rcub_machinery_4218

Svorcan J, Hasan MS, Kovačević A, Ivanov T. Design of the optimal airfoil for a blade of a small-scale multi-rotor VTOL UAV. in International Symposium on Electric Aviation and Autonomous Systems ISEAS 2020. 2020;:52-55.
https://hdl.handle.net/21.15107/rcub_machinery_4218 .

Svorcan, Jelena, Hasan, Mohammad Sakib, Kovačević, Aleksandar, Ivanov, Toni, "Design of the optimal airfoil for a blade of a small-scale multi-rotor VTOL UAV" in International Symposium on Electric Aviation and Autonomous Systems ISEAS 2020 (2020):52-55,
https://hdl.handle.net/21.15107/rcub_machinery_4218 .

TY  - JOUR
AU  - Hasan, Mohammad Sakib
AU  - Ivanov, Toni
AU  - Vorkapić, Miloš
AU  - Simonović, Aleksandar
AU  - Daou, David
AU  - Kovacević, Aleksandar
AU  - Milovanović, Aleksa
PY  - 2020
UR  - https://machinery.mas.bg.ac.rs/handle/123456789/3371
AB  - Rapid innovations in 3D printing technology have allowed highly complex parts to be manufactured quickly and easily, particularly for prototyping purposes. Fused Deposition Modeling of thermoplastic materials is one of the most commonly used techniques in three-dimensional (3D) printing. The major aim of Fused Deposition Modeling (FDM) is to design and manufacture usable parts for fields such as engineering and medicine. Therefore, it is essential to investigate the mechanical properties of such FDM processed structures. One of the most commonly used materials currently on the market is Polylactic Acid (PLA). The main purpose of this paper is to investigate the effects of aging and heat treatment on the tensile properties of PLA printed test specimens. The tensile properties of parts manufactured by the 3D printer are influenced by various parameters such as extrusion temperature, infill density, building direction, layer height, etc. A total of 96 specimens were built by altering building orientation and layer height to estimate and compare the tensile properties of the printed parts. To investigate the aging effect, 30 of 96 specimens were printed 6 months before the tensile experiment. Half of both aged and new specimens were cured in an oven at 57.5 [degrees C] for 3 hours while the other half endured no heat treatment. After the performed measurement, it can be concluded that heat treatment generally improves structural strength of the printed parts, while aging decreases it. However, these effects are highly dependent on the layer thickness and printing quality. The tensile test is conducted according to the ASTM D638 standard. The fractured samples were further characterized using an electron microscope.
PB  - Revista Chimie Srl, Bucuresti
T2  - Materiale Plastice
T1  - Impact of Aging Effect and Heat Treatment on the Tensile Properties of PLA (Poly Lactic Acid) Printed Parts
EP  - 159
IS  - 3
SP  - 147
VL  - 57
DO  - 10.37358/MP.20.3.5389
ER  - 

@article{
author = "Hasan, Mohammad Sakib and Ivanov, Toni and Vorkapić, Miloš and Simonović, Aleksandar and Daou, David and Kovacević, Aleksandar and Milovanović, Aleksa",
year = "2020",
abstract = "Rapid innovations in 3D printing technology have allowed highly complex parts to be manufactured quickly and easily, particularly for prototyping purposes. Fused Deposition Modeling of thermoplastic materials is one of the most commonly used techniques in three-dimensional (3D) printing. The major aim of Fused Deposition Modeling (FDM) is to design and manufacture usable parts for fields such as engineering and medicine. Therefore, it is essential to investigate the mechanical properties of such FDM processed structures. One of the most commonly used materials currently on the market is Polylactic Acid (PLA). The main purpose of this paper is to investigate the effects of aging and heat treatment on the tensile properties of PLA printed test specimens. The tensile properties of parts manufactured by the 3D printer are influenced by various parameters such as extrusion temperature, infill density, building direction, layer height, etc. A total of 96 specimens were built by altering building orientation and layer height to estimate and compare the tensile properties of the printed parts. To investigate the aging effect, 30 of 96 specimens were printed 6 months before the tensile experiment. Half of both aged and new specimens were cured in an oven at 57.5 [degrees C] for 3 hours while the other half endured no heat treatment. After the performed measurement, it can be concluded that heat treatment generally improves structural strength of the printed parts, while aging decreases it. However, these effects are highly dependent on the layer thickness and printing quality. The tensile test is conducted according to the ASTM D638 standard. The fractured samples were further characterized using an electron microscope.",
publisher = "Revista Chimie Srl, Bucuresti",
journal = "Materiale Plastice",
title = "Impact of Aging Effect and Heat Treatment on the Tensile Properties of PLA (Poly Lactic Acid) Printed Parts",
pages = "159-147",
number = "3",
volume = "57",
doi = "10.37358/MP.20.3.5389"
}

Hasan, M. S., Ivanov, T., Vorkapić, M., Simonović, A., Daou, D., Kovacević, A.,& Milovanović, A.. (2020). Impact of Aging Effect and Heat Treatment on the Tensile Properties of PLA (Poly Lactic Acid) Printed Parts. in Materiale Plastice
Revista Chimie Srl, Bucuresti., 57(3), 147-159.
https://doi.org/10.37358/MP.20.3.5389

Hasan MS, Ivanov T, Vorkapić M, Simonović A, Daou D, Kovacević A, Milovanović A. Impact of Aging Effect and Heat Treatment on the Tensile Properties of PLA (Poly Lactic Acid) Printed Parts. in Materiale Plastice. 2020;57(3):147-159.
doi:10.37358/MP.20.3.5389 .

Hasan, Mohammad Sakib, Ivanov, Toni, Vorkapić, Miloš, Simonović, Aleksandar, Daou, David, Kovacević, Aleksandar, Milovanović, Aleksa, "Impact of Aging Effect and Heat Treatment on the Tensile Properties of PLA (Poly Lactic Acid) Printed Parts" in Materiale Plastice, 57, no. 3 (2020):147-159,
https://doi.org/10.37358/MP.20.3.5389 . .

TY  - CONF
AU  - Hasan, Mohammad Sakib
AU  - Svorcan, Jelena
AU  - Simonović, Aleksandar
AU  - Daou, David
AU  - Perić, Bojan
PY  - 2019
UR  - https://machinery.mas.bg.ac.rs/handle/123456789/4299
AB  - The aerodynamic performance of an airfoil provides specific information on wing design of
HALE UAV and is considered as eminent for enhancing its flight conditions. In this paper,
numerical investigation of a wing is conducted to predict its preliminary aerodynamic quality. A
concise comparison of lift and drag curve obtained from numerical analysis conducted in two
different programs, will be the scope of this research. Preliminary aerodynamic performance
study including 12 different wings were previously performed in Fortran program GLAUERT-trapezoidal wing. From those 12 wings, one wing was selected which has the best aerodynamic
performance at an operational altitude of 15000 m. Computational fluid dynamic (CFD) software
package, ANSYS Fluent is used for numerical analysis of the selected wing. Two different
turbulence models were simulated in this work. Lift and drag coefficients were calculated
respectively by varying angle of attacks. Hence, the resulted lift and drag curve generated in
GLAUERT were compared with those obtained from ANSYS FLUENT. Additionally, other
parameters like flow separation, pressure and velocity contours obtained by different turbulent
models were also discussed.
PB  - Belgrade : Serbian Society of Mechanics
C3  - Proceedings  / The 7th International Congress of Serbian Society of Mechanics, Sremski Karlovci, June 24-26, 2019
T1  - CFD analysis of a high altitude long endurance UAV WING
SP  - M3h
UR  - https://hdl.handle.net/21.15107/rcub_machinery_4299
ER  - 

@conference{
author = "Hasan, Mohammad Sakib and Svorcan, Jelena and Simonović, Aleksandar and Daou, David and Perić, Bojan",
year = "2019",
abstract = "The aerodynamic performance of an airfoil provides specific information on wing design of
HALE UAV and is considered as eminent for enhancing its flight conditions. In this paper,
numerical investigation of a wing is conducted to predict its preliminary aerodynamic quality. A
concise comparison of lift and drag curve obtained from numerical analysis conducted in two
different programs, will be the scope of this research. Preliminary aerodynamic performance
study including 12 different wings were previously performed in Fortran program GLAUERT-trapezoidal wing. From those 12 wings, one wing was selected which has the best aerodynamic
performance at an operational altitude of 15000 m. Computational fluid dynamic (CFD) software
package, ANSYS Fluent is used for numerical analysis of the selected wing. Two different
turbulence models were simulated in this work. Lift and drag coefficients were calculated
respectively by varying angle of attacks. Hence, the resulted lift and drag curve generated in
GLAUERT were compared with those obtained from ANSYS FLUENT. Additionally, other
parameters like flow separation, pressure and velocity contours obtained by different turbulent
models were also discussed.",
publisher = "Belgrade : Serbian Society of Mechanics",
journal = "Proceedings  / The 7th International Congress of Serbian Society of Mechanics, Sremski Karlovci, June 24-26, 2019",
title = "CFD analysis of a high altitude long endurance UAV WING",
pages = "M3h",
url = "https://hdl.handle.net/21.15107/rcub_machinery_4299"
}

Hasan, M. S., Svorcan, J., Simonović, A., Daou, D.,& Perić, B.. (2019). CFD analysis of a high altitude long endurance UAV WING. in Proceedings  / The 7th International Congress of Serbian Society of Mechanics, Sremski Karlovci, June 24-26, 2019
Belgrade : Serbian Society of Mechanics., M3h.
https://hdl.handle.net/21.15107/rcub_machinery_4299

Hasan MS, Svorcan J, Simonović A, Daou D, Perić B. CFD analysis of a high altitude long endurance UAV WING. in Proceedings  / The 7th International Congress of Serbian Society of Mechanics, Sremski Karlovci, June 24-26, 2019. 2019;:M3h.
https://hdl.handle.net/21.15107/rcub_machinery_4299 .

Hasan, Mohammad Sakib, Svorcan, Jelena, Simonović, Aleksandar, Daou, David, Perić, Bojan, "CFD analysis of a high altitude long endurance UAV WING" in Proceedings  / The 7th International Congress of Serbian Society of Mechanics, Sremski Karlovci, June 24-26, 2019 (2019):M3h,
https://hdl.handle.net/21.15107/rcub_machinery_4299 .

TY  - CONF
AU  - Hasan, Mohammad Sakib
AU  - Svorcan, Jelena
AU  - Kostić, Ivan
AU  - Simonović, Aleksandar
AU  - Kostić, Srđan
AU  - Ivanov, Toni
PY  - 2018
UR  - https://machinery.mas.bg.ac.rs/handle/123456789/4303
AB  - Observation, maintenance, surveillance, monitoring, remote sensing and security tasks could be defined as the main application of UAVs (Unmanned Air Vehicle). In spite of the fact that all UAV systems have many elements other than the air vehicle, they are frequently classified by the capability or size of the UAVs that is required to perform the mission. Air forces are using HALE (High Altitude Long Endurance) UAVs from fixed bases which can carry out extremely long-range
reconnaissance and surveillance. Different types of wing are used in unmanned air vehicle. This paper represents preliminary aerodynamic performance estimation of HALE UAV wings.
PB  - Belgrade :  Military Technical Institute - VTI
C3  - Proceedings / 8th International Scientific Conference on Defensive Technologies OTEH 2018
T1  - Preliminary aerodynamic performance estimation of HALE UAV wings
EP  - 43
SP  - 39
UR  - https://hdl.handle.net/21.15107/rcub_machinery_4303
ER  - 

@conference{
author = "Hasan, Mohammad Sakib and Svorcan, Jelena and Kostić, Ivan and Simonović, Aleksandar and Kostić, Srđan and Ivanov, Toni",
year = "2018",
abstract = "Observation, maintenance, surveillance, monitoring, remote sensing and security tasks could be defined as the main application of UAVs (Unmanned Air Vehicle). In spite of the fact that all UAV systems have many elements other than the air vehicle, they are frequently classified by the capability or size of the UAVs that is required to perform the mission. Air forces are using HALE (High Altitude Long Endurance) UAVs from fixed bases which can carry out extremely long-range
reconnaissance and surveillance. Different types of wing are used in unmanned air vehicle. This paper represents preliminary aerodynamic performance estimation of HALE UAV wings.",
publisher = "Belgrade :  Military Technical Institute - VTI",
journal = "Proceedings / 8th International Scientific Conference on Defensive Technologies OTEH 2018",
title = "Preliminary aerodynamic performance estimation of HALE UAV wings",
pages = "43-39",
url = "https://hdl.handle.net/21.15107/rcub_machinery_4303"
}

Hasan, M. S., Svorcan, J., Kostić, I., Simonović, A., Kostić, S.,& Ivanov, T.. (2018). Preliminary aerodynamic performance estimation of HALE UAV wings. in Proceedings / 8th International Scientific Conference on Defensive Technologies OTEH 2018
Belgrade :  Military Technical Institute - VTI., 39-43.
https://hdl.handle.net/21.15107/rcub_machinery_4303

Hasan MS, Svorcan J, Kostić I, Simonović A, Kostić S, Ivanov T. Preliminary aerodynamic performance estimation of HALE UAV wings. in Proceedings / 8th International Scientific Conference on Defensive Technologies OTEH 2018. 2018;:39-43.
https://hdl.handle.net/21.15107/rcub_machinery_4303 .

Hasan, Mohammad Sakib, Svorcan, Jelena, Kostić, Ivan, Simonović, Aleksandar, Kostić, Srđan, Ivanov, Toni, "Preliminary aerodynamic performance estimation of HALE UAV wings" in Proceedings / 8th International Scientific Conference on Defensive Technologies OTEH 2018 (2018):39-43,
https://hdl.handle.net/21.15107/rcub_machinery_4303 .