Your search keyword '"Experimental Measurements"' showing total 668 results

1. Experimental measurements, thermodynamic modeling and molecular dynamics simulation of the multiphase equilibria of {1-butanol + n-butyl acetate + [EMIM][EtSO4]} systems at 101.3 kPa

Author

Freire, Nian V., Biswas, Rima, and Arce, Pedro F.

Published

2025

2. Characterization of the solidity of knotted single-twine diamond mesh netting

Author

Bottero, Francisco and González, Manuel

Published

2025

3. Experimentally verified numerical model for asymmetric ferrite core wireless power transfer with on-chip interfacing circuits

Author

Ghanem, Ahmed A. and Abdellatif, Sameh O.

Published

2023

4. Heat Emissions from Mining Machinery: Implications for Microclimatic Conditions in Underground Workings.

Author

Zaitsev, Artem, Parshakov, Oleg, and Semin, Mikhail

Subjects

POTASH mining, MINE ventilation, MINES & mineral resources, MINING machinery, OIL well drilling rigs, CONVEYING machinery

Abstract

The thermal regime of underground mines, shaped by air temperature, velocity, and relative humidity, is a crucial factor for production and the health and safety of miners. While many aspects of this thermal regime have been thoroughly studied in the literature, local heat sources from mechanized equipment, such as load–haul–dump machines, conveyors, and auxiliary fans, have received comparatively little attention despite their significant impact on the thermal environment in mining development areas and stopes. This paper presents findings from a comprehensive study of the microclimatic air parameters in several nickel–copper and potash mines. We focus specifically on variations in air temperature in areas where mining equipment is operational. The heat output from different types of equipment, including load–haul–dump units, cutter–loaders, drilling rigs, conveyors, and auxiliary fans, has been quantified. We established empirical relationships for heat emissions from these machines and conducted a comparative analysis of their heat outputs. The main advantage of these relationships is their simplicity and the minimal number of input parameters required, making them practical for use in the field. [ABSTRACT FROM AUTHOR]

Published

2024

5. Heat Emissions from Mining Machinery: Implications for Microclimatic Conditions in Underground Workings

Author

Artem Zaitsev, Oleg Parshakov, and Mikhail Semin

Subjects

mine ventilation, heat source, mechanized equipment, microclimatic parameters, experimental measurements, Mining engineering. Metallurgy, TN1-997

Abstract

The thermal regime of underground mines, shaped by air temperature, velocity, and relative humidity, is a crucial factor for production and the health and safety of miners. While many aspects of this thermal regime have been thoroughly studied in the literature, local heat sources from mechanized equipment, such as load–haul–dump machines, conveyors, and auxiliary fans, have received comparatively little attention despite their significant impact on the thermal environment in mining development areas and stopes. This paper presents findings from a comprehensive study of the microclimatic air parameters in several nickel–copper and potash mines. We focus specifically on variations in air temperature in areas where mining equipment is operational. The heat output from different types of equipment, including load–haul–dump units, cutter–loaders, drilling rigs, conveyors, and auxiliary fans, has been quantified. We established empirical relationships for heat emissions from these machines and conducted a comparative analysis of their heat outputs. The main advantage of these relationships is their simplicity and the minimal number of input parameters required, making them practical for use in the field.

Published

2024

6. INFLUENCE OF TEMPERATURE SENSOR (PT100) ACCURACY ON THE INTERPRETATION OF EXPERIMENTAL RESULTS OF MEASURING TEMPERATURE ON THE SURFACE.

Author

MAŁEK, Maria Teresa and KOCZYK, Halina

Subjects

TEMPERATURE sensors, TEMPERATURE measurements, WALLS, MEASUREMENT errors, THERMAL insulation

Abstract

This article presents the impact of accuracy of sensors, or more specifically Pt100 temperature sensors, on result analysis of experimental studies. For this purpose, an experiment was carried out consisting in measuring the temperature on the surface of a partition - a concrete wall, beneath its insulation layer. The tested surface was separated from external environment and could only be influenced by the wall structure. Therefore, the expected result of the experiment, i.e. the difference in temperature sensor readings in identical locations on both sides of the partition, should reach a value close to 0. This article also presents the values of absolute error for sensors which were determined before their installation on the surface, and on which their location depended. The obtained deviations were included in the results of the experiment, which led to a decrease in temperature differences on both sides of the partition, in some cases even reaching the expected value of 0. This analysis showed how important it is to know the measurement error and then eliminate it in result interpretation. [ABSTRACT FROM AUTHOR]

Published

2024

7. Experimental Forced Convection Study Using a Triply Periodic Minimal Surface Porous Structure with a Nanofluid: Comparison with Numerical Modeling.

Author

Saghir, Mohamad Ziad and Kilic, Gulenay Alevay

Subjects

NUSSELT number, POROUS materials, HEAT sinks, MINIMAL surfaces, BOUNDARY layer (Aerodynamics), NANOFLUIDICS

Abstract

Triply periodic minimal surfaces (TPMSs) show potential as porous materials in different engineering applications. Amongst them, heat sink is the subject of this paper. The advantage of such a structure is the ability to design it based on the intended applications. In the present paper, an attempt is made to experiment with a better understanding of the performance of TPMSs in heat sink applications. The experiment was conducted for different flow rates, and two heat sink materials, aluminum and silver, were used. In addition, two fluids were used experimentally: The first was water, and the second was a mixture of water containing 0.6% aluminum nanoparticles and identified as a nanofluid. The applied heat flux was maintained constant at 30,800 W/m2. The results reveal experimentally and confirm numerically that the TPMS structure secures a uniform heat extraction in the system. The development of the boundary layer in the porous structure is reduced due to the current structure design. A higher Nusselt number is obtained when the nanofluid is used as the circulating fluid. The performance evaluation criteria in the presence of the nanofluid exceed 100. [ABSTRACT FROM AUTHOR]

Published

2024

8. Statistical Synthesis and Analysis of Functionally Deterministic Signal Processing Techniques for Multi-Antenna Direction Finder Operation.

Author

Zhyla, Semen, Tserne, Eduard, Volkov, Yevhenii, Shevchuk, Sergey, Gribsky, Oleg, Vlasenko, Dmytro, Kosharskyi, Volodymyr, and Kovalchuk, Danyil

Subjects

REMOTE sensing by radar, REMOTE sensing, RADIO engineering, ENGINEERING systems, SIGNAL processing

Abstract

This manuscript focuses on the process of measuring the angular positions of radio sources using radio engineering systems. This study aims to improve the accuracy of measuring the angular positions of sources that radiate functionally determined signals and to expand the range of the unambiguous operation angles for multi-antenna radio direction finders. To achieve this goal, the following tasks were addressed: (1) defining the models of signals, noise, and their statistical characteristics, (2) developing the theoretical foundations of statistical optimization methods for measuring the angular positions of radio sources in multi-antenna radio direction finders, (3) optimizing the structures of radio direction finders with different configurations, (4) analyzing the accuracy and range of the unambiguous measurement angles in the developed methods, and (5) conducting experimental measurements to confirm the main results. The methods used are based on the statistical theory of optimization for remote sensing and radar systems. For the specified type of signals, given by functionally deterministic models, a likelihood function was constructed, and its maxima were determined for different multi-antenna direction finder configurations. The results of statistical synthesis were verified through simulation modeling and experiments. The primary approach to improving measurement accuracy and expanding the range of unambiguous angles involves combining antennas with different spatial characteristics and optimally integrating classical radio direction-finding methods. The following results were obtained: (1) theoretical studies and simulation modeling confirmed the existence of a contradiction between high resolution and the width of the range of the unambiguous measurements in two-antenna radio direction finders, (2) an improved signal processing method was developed for a four-antenna radio direction finder with a pair of high-gain and a pair of low-gain antennas, and (3) to achieve maximum direction-finding accuracy within the unambiguous measurement range, a new signal processing method was synthesized for a six-element radio receiver, combining processing in two amplitude direction finders and one phase direction finder. This work provides a foundation for further theoretical studies, highlights the specifics of combining engineering measurements in direction-finding systems, and offers examples of rapid verification of new methods through computer modeling and experimental measurements. [ABSTRACT FROM AUTHOR]

Published

2024

9. Impacts of sintering temperature on the mechanical properties and gamma ray protection capacity of clay bricks

Author

Aljawhara H. Almuqrin, K.A. Mahmoud, M.I. Sayyed, and H. Al-Ghamdi

Subjects

Bricks, Metallic waste, Porosity, Shielding properties, Experimental measurements, Nuclear engineering. Atomic power, TK9001-9401

Abstract

The current study aims to develop new clay bricks doped with metallic waste for radiation shielding applications. The aforementioned new bricks were fabricated with various metallic waste concentrations under a pressure rate reaching ≈114 MPa and firing temperature of 1100 °C. The impacts of the metallic waste and the firing temperature on the developed brick samples' physical, radiation shielding, and structural properties were studied. In order to identify the fabricated bricks' mineral content, the X-ray diffraction pattern was used. Additionally, the fabricated bricks' porosity and density were experimentally determined, where the porosity was reduced by 28.03%, while their densities increased by ≈ 10.5% by raising the concentration of metallic waste. The linear attenuation coefficient (LAC) for the developed brick was investigated experimentally using a NaI (Tl) scintillation detector over the 0.033–1.408 MeV energy interval. The measured LAC values were enhanced by increasing the concentrations of metallic waste within the fabricated bricks over the examined energy interval. The fabricated brick's LAC enhancement improves the gamma-ray shielding characteristics. Therefore, the fabricated bricks are a cheap and suitable choice for radiation protection applications.

Published

2024

10. Spectral manifestations of hyaluronic acid intermolecular interaction with nitrogen-containing amino acids

Author

Plastun, Inna L'vovna, Bryksin, Kirill A., Mayorova, Oksana Aleksandrovna, and Babkov, Lev Mikhailovich

Subjects

hyaluronic acid, ir spectrum, experimental measurements, molecular modeling, amino acids, density functional theory, hydrogen bonds, Physics, QC1-999

Abstract

Background and Objectives: Manifestations of intermolecular interaction based on hydrogen bonding in hyaluronic acid IR spectra and in multicomponent mixtures of hyaluronic acid with nitrogen-containing amino acids, which are part of mucin of the mucous membrane of the bladder and protein carrier microgels, have been studied using experimental and theoretical IR spectroscopy. Materials and Methods: Comparison of measured and calculated hyaluronic acid IR spectra in harmonic approximation is performed. Calculations of molecular complexes structure and their corresponding IR spectra were carried out, followed by an analysis of the parameters of the hydrogen bonds formed. Results: Estimates of hyaluronic acid complexation with amino acids strength, which are part of protein microgels used in targeted therapy, and in target cells proteins were given. Conclusion: It has been found that the presence of an additional protein structure significantly increases the hyaluronic acid interaction with mucous membrane mucin protein due to intermolecular complexation based on polar basic amino acids.

Published

2024

11. Experimental Permeability and Porosity Determination of All-Oxide Ceramic Matrix Composite Material.

Author

Szwaba, Ryszard, Madejski, Pawel, Kaczynski, Piotr, Kurowski, Marcin, Kunz, Mathias, Berent, Katarzyna, and Ochrymiuk, Tomasz

Subjects

*POROUS materials, *PARTICLE size distribution, *CERAMIC materials, *SCANNING electron microscopy, *COMPOSITE materials

Abstract

This paper presents an investigation into the water permeability of an all-oxide ceramic matrix composite. To determine the parameters and characterize the water permeability of the ceramic composite material, an experimental study was carried out in which a dedicated test rig was constructed and commissioned. A total of five different configurations of composite tubes were tested. They differed in fibre roving strength, winding angle, fibre bundle arrangement during winding, and matrix grain size distribution. To better understand the internal structure of the analysed ceramic matrix composite material, the experimental study used scanning electron microscopy for microstructure and porosity observation. The tested tubes will be used as liners in an oxy-combustion chamber in future studies. The experiments obtained new and interesting results regarding the water permeability of the ceramic matrix composite with different structural parameters. It was also observed that, as with some porous materials, the permeability of ceramic matrix composites decreases with time as more and more liquid is pressed through it. [ABSTRACT FROM AUTHOR]

Published

2024

12. Controlling non-uniform blank holder pressures in an extra-deep drawing process for enhancing formability and product quality.

Author

Hadj Amar, Adel, Zidane, Ibrahim, Zahloul, Hamou, and Belguebli, Amina

Subjects

*MANUFACTURING defects, *ULTRASONIC measurement, *INDUSTRIAL equipment, *DIES (Metalworking), *INDUSTRIAL costs, *DEEP drawing (Metalwork)

Abstract

In this study, the focus is on investigating prevalent issues of rupture and wrinkling that occur during the extra-deep drawing process. These defects are very common in a local sanitary equipment industrial company, mainly in the manufacture of bathtubs, which increases scrap and leads to loss of time and costs in production. To analyze these defects, a numerical simulation of the bathtub extra-deep drawing process was performed with industrial parameters. The originality lies in controlling non-uniform blank holder pressures generated from six actuators in order to control the flow of the blank between the blank holder and the die and ensure the production of defect-free bathtubs. 3D and ultrasonic thickness measurements were performed on a bathtub manufactured without defects. Numerical and experimental plots of the thickness reduction show that the two approaches are in good agreement. The numerical results demonstrate that there are no rupture or wrinkling defects in the bathtub final shape, which exactly matches the actual case manufactured by the company. The numerical analysis was also performed on different cases that can cause rupture and wrinkling defects, namely: the influence of the blank holder pressure, the blank initial shape, and the die design using draw beads. [ABSTRACT FROM AUTHOR]

Published

2024

13. A unique Vietnam's red clay-based brick reinforced with metallic wastes for γ-ray shielding purposes: Fabrication, characterization, and γ-ray attenuation properties

Author

Ta Van Thuong, O.L. Tashlykov, and K.A. Mahmoud

Subjects

Vietnam's red clay, Industrial metal waste, Clay-based bricks, Radiation shielding parameters, Experimental measurements, Nuclear engineering. Atomic power, TK9001-9401

Abstract

A unique brick series based on Vietnamese clay was manufactured at 114.22 MPa pressure rate for γ-ray attenuation purposes, consisting of (x) metallic waste & (90%-x) red clay mineral & 10% (hardener mixed with epoxy resin), where (x) is equal to the values 0%, 20%, 40%, 50%, and 70%. The impacts of industrial metal waste ratio in the structure and radiation protective characteristics were evaluated experimentally. The increase in metallic waste doping concentrations from 0% to 70% was associated with an increase in the manufactured brick's density (ρ) from 2.103 to 2.256 g/cm3 while the fabricated samples' porosity (Φ) decreased from 11.7 to 1.0%, respectively. Together with a rise in fabricated brick's density and a decrease in their porosities, the manufactured bricks' γ-ray attenuation capacities improved. The measured linear attenuation coefficient (μ, cm−1) was improved by 30.8%, 22.1%, 21.6%, and 19.7%, at Eγ equal to the values respectively 0.662, 1.173, 1.252, and 1.332 MeV, when the metallic waste concentration increased from 0% to 70%, respectively. The study demonstrates that manufactured bricks exhibit superior radiation shielding properties, with radiation protection efficiencies of 88.4%, 90.0%, 91.7%, 92.1%, and 92.4% for bricks with industrial metal waste contents of 0%, 20%, 40%, 50%, and 70%, respectively, at γ-ray energy (Eγ) of 1.332 MeV.

Published

2024

14. Modeling Time-Evolving Electrical Conductivity in Air Ionization Plasma under DC Voltage: A Finite-Difference Time-Domain Approach for Needle-Plate Setup Based on Laboratory Experiments.

Author

de Oliveira, Rodrigo M. S., de Lima, Thiago S., Nascimento, Júlio A. S., and Girotto, Gustavo G.

Subjects

*ELECTRIC conductivity, *MAXWELL equations, *VOLTAGE, *FINITE difference time domain method, *HIGH voltages, *ELECTRICAL conductivity measurement, *GLOW discharges

Abstract

In this paper, we develop a finite-difference time-domain (FDTD) model in which the time-evolving electrical conductivity of the air ionization plasma in DC voltage needed-plate setup is represented. Maxwell's equations are solved using the FDTD method, and the associated currents and discharge fields are computed over time and in three-dimensional space. The proposed model for the electrical conductivity is dependent on time, the applied DC voltage, and the gap length. The necessary data for developing the proposed model is obtained experimentally using a standard discharge needle, with its spherical tip measuring approximately 40 μ m in diameter. Once high voltage is applied, a steady state is achieved. The electrical conductivity σ (t) and its associated parameters are then calculated using nonlinear equations proposed to reproduce the experimentally obtained plasma behavior in the full-wave FDTD model. Voltage ranges from 4 kV to 9 kV, and gap distances are between 4 mm and 8 mm. [ABSTRACT FROM AUTHOR]

Published

2024

15. ANALYSIS OF THE EFFECT OF HYDRATION HEAT RESULTING IN THE FORMATION OF CRACKS ON THE EXPERIMENTAL BLOCK OF THE SPILLWAY AT ORLIK RESERVOIR.

Author

Potůčková, Simona, Holý, Milan, and Kolísko, Jiří

Subjects

*SPILLWAYS, *HEAT, *TEMPERATURE measurements, *HYDRATION, *NUMERICAL analysis

Abstract

This article concentrates on the numerical analysis of hydration heat resulting in formation of cracks on the experimental block of the spillway at Orlik Reservoir and its verification with the experimental measurement. In order to eliminate the maximum of critical factors which could lead to appearance of early age cracking and faulty execution of the spillway, an experimental block was concreted. It served as a trial block for all steps of the execution process as well as a validating temperature measurement during cement hydration to confirm with the preliminary numerical analysis. [ABSTRACT FROM AUTHOR]

Published

2024

16. Enhancing solar façade thermal performance with PCM spheres: A CFD investigation.

Author

Berville, Charles, Bode, Florin, Croitoru, Cristiana, Calota, Razvan, and Nastase, Ilinca

Subjects

*HEAT storage, *SUSTAINABILITY, *PHASE change materials, *SOLAR collectors, *TECHNOLOGICAL innovations

Abstract

To improve building energy efficiency and address thermal storage challenges during periods without a heat source, such as cloudy weather or night-time, a range of solutions is required. Innovative technologies and sustainable practices are essential for combating climate change and reducing carbon emissions. This study primarily focuses on Thermal Energy Storage (TES) systems, specifically those using Phase Change Materials (PCMs), to increase energy efficiency for Transpired Solar Collectors used in buildings applications. During the last 30 years Transpired Solar Collectors (TSC) have been extensively investigated. However, a primary concern still exists regarding thermal storage when the heat source is unavailable, such as during periods of cloudy weather or at night. Thus, a Thermal Energy Storage (TES) system coupled with the TSC is a potential solution. In this study we are investigating using numerical simulation the arrangement of encapsulation for TES, integrating phase change materials (PCM) in spherical elements when compared with plate encapsulation elements. The model reproduces a part of a real scale thermal energy storage inserted in a Double Skin TSC. The model consists of a Plexiglas duct in which four different arrangements for the spherical encapsulated PCM were studied. For each of the arrangements the heat transfer between the TES elements and the air passing through the collector was analyzed. The primary finding of the study indicates that the hexagonal arrangement offers better passive airflow control, thus enhancing the heat transfer up to 12.3% compared to the rectangular arrangements [ABSTRACT FROM AUTHOR]

Published

2024

17. Experimental Analysis of the Influence of Seasonality on the Temperature Regime of Extensive Roofs in Central Europe.

Author

Chabada, Marek, Durica, Pavol, and Juras, Peter

Subjects

SEASONAL temperature variations, GREEN roofs, HEAT flux, BUILDING envelopes, URBAN renewal

Abstract

Current building envelope greening systems are not just areas covered with vegetation. Today's systems can maximise the functional contribution of vegetation to a building's performance and become part of a sustainable urban renewal strategy. The impact of the vegetation layer directly affects the building in its immediate vicinity, from the outside, while also having a significant impact on the indoor environment. Green roofs are the most widespread vegetated structures worldwide. This paper aims to demonstrate the behaviour of the temperature regime of an extensive green roof over a production hall and an administrative area in comparison to that of a roof without vegetation cover. In evaluating the results, a period with weather representative of winter and summer was selected to show the importance of seasonality. The fact that this is a new building, and that the extensive roof is not fully covered with vegetation, is very well reflected in the results, as the absence of a vegetated area significantly affects the temperature of as well as the heat flux through the roof structure. The dark colour of the substrate absorbs significantly more solar radiation than the light surface of the waterproofing, resulting in an increase in temperature and heat flux into the structure. [ABSTRACT FROM AUTHOR]

Published

2024

18. Experimental and Numerical Assessment of the Thermal Bridging Effect in a Reinforced Concrete Corner Pillar.

Author

Evola, Gianpiero and Gagliano, Antonio

Subjects

COLUMNS, REINFORCED concrete, TRANSVERSE reinforcements, THERMAL insulation, THERMOGRAPHY, SURFACE temperature, COMPOSITE columns

Abstract

This paper discusses experimental and simulated data regarding the thermal bridging effect in a reinforced concrete corner pillar, which belongs to a building dating back to the 1980s and located in Southern Italy. The thermal field determined by the concrete pillar corner has been evaluated, introducing an experimental procedure based on both direct measurements and indirect observations of the inner superficial temperature by means of thermal imaging techniques and surface temperature probes. Moreover, indoor and outdoor air temperature and relative humidity were measured to provide suitable boundary conditions in the numerical simulations, performed with a commercial software tool widely used in Italy based on 2D finite element techniques. The experimental measurements show that, at more than 50 cm from the corner, the surface temperatures become almost constant, meaning that the thermal bridging effect becomes less evident. However, the surface temperature in the corner is around 1.5 °C lower than in the undisturbed flanking walls. In terms of local heat flux, the discrepancy between simulations and measurements is below 3%. Finally, this paper verifies the effectiveness of External Thermal Insulation Composite System (ETICS) renovation in reducing the thermal bridging effect of the corner pillar. The results also include the calculation of the linear thermal transmittance with a series of relations available in well-known atlases for thermal bridges and show that these relations are more reliable in the case of uninsulated pillar than for the insulated one. [ABSTRACT FROM AUTHOR]

Published

2024

19. Physics-Informed Machine Learning Modelling of RF-EMF Exposure in Massive MIMO Systems

Author

Samuel Bilson, Tian Hong Loh, Fabien Heliot, and Andrew Thompson

Subjects

5G new radio (NR), beamforming, electromagnetic field (EMF) exposure, experimental measurements, machine learning, massive multiple-input-multiple-output (mMIMO), Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Beamforming and massive multiple-input-multiple-output (mMIMO) technologies are key features of base stations (BSs) in the fifth-generation (5G) of mobile networks. This technology is used to focus more radio frequency (RF) energy towards actively connected users to improve their connection/performance, resulting in high variations in the radio frequency electromagnetic fields (RF-EMFs). This paper proposes a new methodology for modelling the RF-EMF exposure for 5G new radio (NR) mMIMO BS by means of a physics-informed machine learning (ML) approach using empirical measurement data. More precisely, the main focus of our work is to develop a suitable traceable RF-EMF exposure prediction tool in the context of 5G mMIMO BSs that can serve multiple mobile users (i.e. multiple-user MIMO (MU-MIMO)) within realistic real-world environments and scenarios. Our RF-EMF prediction tool relies on empirical measurement data acquired via a user-controllable mMIMO beamforming testbed and traceable RF-EMF measurement capability, where both indoor and outdoor RF-EMF measurement campaigns have been carried out. During the measurement campaigns various factors such as number of users, position of users and data duty cycles were considered. Using an ensemble of gradient boosted decision trees, we show that a physics-informed approach can improve predictive performance of RF-EMF compared with a purely data-driven approach, with the ability to extrapolate values of RF-EMF exposure to larger distances. Results show a coefficient of determination value of 0.86 on a 10-fold cross-validated experimental dataset. We also compare the sensitivity of RF-EMF exposure to various factors in the model, and show that model predictions become isotropic for large numbers of beam configurations, simplifying the exposure measurement methodology of 5G systems.

Published

2024

20. Experimental Forced Convection Study Using a Triply Periodic Minimal Surface Porous Structure with a Nanofluid: Comparison with Numerical Modeling

Author

Mohamad Ziad Saghir and Gulenay Alevay Kilic

Subjects

TPMS, nanofluid, water, porous structure, convection, experimental measurements, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

Triply periodic minimal surfaces (TPMSs) show potential as porous materials in different engineering applications. Amongst them, heat sink is the subject of this paper. The advantage of such a structure is the ability to design it based on the intended applications. In the present paper, an attempt is made to experiment with a better understanding of the performance of TPMSs in heat sink applications. The experiment was conducted for different flow rates, and two heat sink materials, aluminum and silver, were used. In addition, two fluids were used experimentally: The first was water, and the second was a mixture of water containing 0.6% aluminum nanoparticles and identified as a nanofluid. The applied heat flux was maintained constant at 30,800 W/m2. The results reveal experimentally and confirm numerically that the TPMS structure secures a uniform heat extraction in the system. The development of the boundary layer in the porous structure is reduced due to the current structure design. A higher Nusselt number is obtained when the nanofluid is used as the circulating fluid. The performance evaluation criteria in the presence of the nanofluid exceed 100.

Published

2024

21. Statistical Synthesis and Analysis of Functionally Deterministic Signal Processing Techniques for Multi-Antenna Direction Finder Operation

Author

Semen Zhyla, Eduard Tserne, Yevhenii Volkov, Sergey Shevchuk, Oleg Gribsky, Dmytro Vlasenko, Volodymyr Kosharskyi, and Danyil Kovalchuk

Subjects

multi-antenna direction finders, statistical optimization, optimal signal processing, experimental measurements, Electronic computers. Computer science, QA75.5-76.95

Abstract

This manuscript focuses on the process of measuring the angular positions of radio sources using radio engineering systems. This study aims to improve the accuracy of measuring the angular positions of sources that radiate functionally determined signals and to expand the range of the unambiguous operation angles for multi-antenna radio direction finders. To achieve this goal, the following tasks were addressed: (1) defining the models of signals, noise, and their statistical characteristics, (2) developing the theoretical foundations of statistical optimization methods for measuring the angular positions of radio sources in multi-antenna radio direction finders, (3) optimizing the structures of radio direction finders with different configurations, (4) analyzing the accuracy and range of the unambiguous measurement angles in the developed methods, and (5) conducting experimental measurements to confirm the main results. The methods used are based on the statistical theory of optimization for remote sensing and radar systems. For the specified type of signals, given by functionally deterministic models, a likelihood function was constructed, and its maxima were determined for different multi-antenna direction finder configurations. The results of statistical synthesis were verified through simulation modeling and experiments. The primary approach to improving measurement accuracy and expanding the range of unambiguous angles involves combining antennas with different spatial characteristics and optimally integrating classical radio direction-finding methods. The following results were obtained: (1) theoretical studies and simulation modeling confirmed the existence of a contradiction between high resolution and the width of the range of the unambiguous measurements in two-antenna radio direction finders, (2) an improved signal processing method was developed for a four-antenna radio direction finder with a pair of high-gain and a pair of low-gain antennas, and (3) to achieve maximum direction-finding accuracy within the unambiguous measurement range, a new signal processing method was synthesized for a six-element radio receiver, combining processing in two amplitude direction finders and one phase direction finder. This work provides a foundation for further theoretical studies, highlights the specifics of combining engineering measurements in direction-finding systems, and offers examples of rapid verification of new methods through computer modeling and experimental measurements.

Published

2024

22. Comparative analysis of numerical solutions of 2D unsteady dambreak waves using FVM and SPH method

Author

Rahou Ibrahim and Korichi Khaled

Subjects

2d shallow water, unsteady flow, dambreak, finite volume, sph, experimental measurements, Hydraulic engineering, TC1-978

Abstract

This work presents a comparison of two-dimensional numerical solutions of unsteady free surface flow. This is a simulation of the dam-break wave with different configurations using based-mesh finite volume method and meshless smoothed particle hydrodynamics (SPH). Two well-known approaches, widely used in the computational fluid dynamics (CFD). These techniques have proven their robustness in the numerical treatment of such conservation laws. The main goal is to check the ability of the SPH method and the first order finite volume HLLC solver to reproduce the numerical solutions of the 2D shallow water equations. Based on many benchmark tests, one investigates the effect of the topographic variation along the x and y directions on behavior of the numerical solutions namely at the wet-dry front. The comparison between the simulated results, the analytical solutions and the experimental measurements shows a good correlation, although the finite volume approach remains more advantageous in terms of accuracy and the CPU time.

Published

2023

23. Insights on the Impacts of Accelerometer Location on the Dynamics and Characteristics of Complex Structures.

Author

Takeshita, Adam, Madrid, Jonah, Granillo, Ezekiel, and Abdelkefi, Abdessattar

Subjects

*RANDOM vibration, *ACCELEROMETERS, *MODE shapes, *FREE vibration, *FINITE element method, *DYNAMICAL systems, *SOIL vibration

Abstract

There exists a high level of difficulty in understanding the physical responses of complex dynamical systems. To this end, researchers have previously used different measurement techniques, such as displacement sensors or accelerometers, in the laboratory to capture a system's dynamics. A well-known structure in the literature is the Box Assembly with Removable Component (BARC) whose purpose is to gain a deep understanding of testing complex systems. Further breaking down the structure, the Removable Component (RC) portion is often used as a relatively simplified version which retains significant complexity from the original system. However, the placement of accelerometers on the RC have varied greatly throughout the literature which presents a challenge in comparing results and may not accurately represent the system's dynamics. Finite Element Analysis (FEA) is performed for three common accelerometer locations to determine how their placement affects the frequencies and mode shapes for the RC and results are compared against those without accelerometers. Free vibration experiments are carried out to understand the variation of frequencies and damping for each accelerometer location to obtain the overall response for the first mode of vibration. Next, random vibration experiments are run to gain insight on the interaction between linear and nonlinear responses based on excitation level, while showing the influence of an accelerometer's location on system dynamics. The results demonstrate that the location of the accelerometer is highly influential on the linear and nonlinear characteristics of the system. It is proved that for the first mode of vibration, nonlinear softening and nonlinear damping behaviors may take place due to the interaction between the location of accelerometers, direction of excitation, and response axis analyzed. [ABSTRACT FROM AUTHOR]

Published

2023

24. Development and Validation of a Double-Sensor Hump Calibration Method for Articulated Vehicle Model Identification.

Author

Wu, Yuhang and Li, Yuanqi

Subjects

*ARTICULATED vehicles, *VEHICLE models, *POSITION sensors, *CALIBRATION, *SYSTEM identification, *SENSOR placement

Abstract

The realistic simulation of the dynamic responses of a moving articulated vehicle has attracted considerable attention in various disciplines, with the identification of the vehicle model being the prerequisite. To this end, a double-sensor hump calibration method (DHCM) was developed to identify both unladen and laden vehicle models, consisting of a sensor layout optimization step and a system identification step. The first step was to optimize the number and position of sensors via parameter sensitivity analysis; the second was to inversely identify the vehicle system based on sensor responses. For comparison, the DHCM and the existing single-sensor hump calibration method (SHCM) were used to calibrate a small-sized vehicle model and a multi-axle articulated vehicle model. Vertical accelerations of the vehicle models were then simulated and characterized by power spectral densities (PSDs). Validation against experimental measurements indicated that the PSDs of the models identified with the DHCM matched the measured PSDs better than those of the SHCM, i.e., the DHCM-identified model accurately simulated the dynamic response of an articulated vehicle with relative errors below 16% in the low-frequency range. Therefore, the DHCM could identify models of small-sized vehicles and multi-axle articulated vehicles, while the SHCM was only suitable for the former. [ABSTRACT FROM AUTHOR]

Published

2023

25. Enhancing Fire Safety: Real-Scale Experimental Analysis of External Thermal Insulation Composite System Façades' Behavior in Fire.

Author

Bode, Florin, Simion, Adrian, Anghel, Ion, Sandu, Mihnea, and Banyai, Daniel

Subjects

*THERMAL insulation, *FIRE prevention, *HEAT release rates, *THERMAL analysis, *PLASTIC containers, *FIRE resistant materials

Abstract

In the unfortunate event of a fire, within the context of the evolution of façade fires, with a specific focus on the utilization of polystyrene thermal insulation (external thermal insulation composite system façades—ETICS façades), this study delves into the investigation of fires ignited by containers containing plastic bottles. Through an examination of the fluctuating temperatures within the affected room and its adjacent areas, as well as an assessment of the fire's impact on polystyrene thermal insulation, this paper underscores the significance of incorporating non-combustible barriers into the building's thermal insulation system. The tests conducted revealed that the temperature inside the room reached a maximum of 1100 °C, subsequently decreasing to 800 °C at a height of 2.5 m and approximately 400 °C at a height of 5 m. For this research, two 1100-L containers of household waste were employed, each weighing 45.5 kg and possessing a gross calorific value of 46.97 MJ/kg, with 10.7 kg of PET bottles inside, characterized by a higher calorific value of 23.90 MJ/kg as the source of the fire. Heat release rate highest values were obtained between 11 and 17 min, with a maximum value of 4919 kW. Thus, even in the absence of specific legislation, this study emphasizes the imperative need to establish safety distances for the storage of household waste away from the building's façade to mitigate the risk of fire propagation, particularly in relation to materials such as polystyrene thermal insulation. Furthermore, in certain situations, extensive fire experiments on a grand scale, like the one undertaken in this research, hold a crucial position in confirming numerical findings for global researchers. This process assures the reliability and real-world usefulness of fire safety studies through the experimental outcomes presented in this investigation. [ABSTRACT FROM AUTHOR]

Published

2023

26. Implementation of Data from Wind Tunnel Tests in the Design of a Tall Building with an Elliptic Ground Plan.

Author

Hubová, Oľga, Macák, Marek, Franek, Michal, Ivánková, Oľga, and Konečná, Lenka Bujdáková

Subjects

WIND tunnel testing, TALL buildings, AERODYNAMICS of buildings, WIND tunnels, ENGINEERING standards, TEST design, WIND pressure

Abstract

The design of a 69 m tall multipurpose building was investigated in this paper. The shape of the structure above the ground was an elliptical cylinder. Under the ground, the building was extended into a cuboid shape (for car parking). External wind pressure coefficients were determined using three methods: wind tunnel tests, CFD, and "the simplification of the shape" (using information defined in building standards). From the obtained results, it was evident that the simplification did not provide results with sufficient accuracy. The external wind pressure coefficients presented in this paper should be used for the design of a similar structure. The shape of the elliptical cylinder is very sensitive to applied wind. Positive pressures only occur on a small area of the windward side. The rest of the windward side is loaded with negative pressures. Therefore, torsional effects can occur, and these can be dangerous for the structure. The leeward side is completely loaded with negative pressures. In our case, this information was necessary for a follow-on static and dynamic analysis of the building. Various subsoil stiffness coefficients were considered. The calculated horizontal displacement was compared with the limit value. A measured wind direction of 20° caused the maximum obtained torsional moment, and a wind direction of 90° induced the maximum obtained force. The commercial program Ansys Fluent 2022 was used for the CFD simulation. The SCIA ENGINEER 21 program was used for follow-on analysis. This paper presents brief information on the selected turbulence model and details the settings used for the CFD simulation. Also, a description of the wind tunnel laboratory utilized in this study is provided, along with a description of the measuring devices used and the methodologies of the tests carried out. The main purpose of this paper is to show how important it is to consider the wind load for the static analysis of a structure like this. [ABSTRACT FROM AUTHOR]

Published

2023

27. On entropic and compositional sound and its sources

Author

da Rocha Bragança Rodrigues, Jocelino Alexandre and Hochgreb, Simone

Subjects

indirect noise, direct noise, combustion noise, entropic waves, compositional waves, acoustics, gas injection, heat addition, thermoacoustics, fluid mechanics, nozzle flow, experimental measurements, computational fluid dynamics, spontaneous Raman spectroscopy

Abstract

Combustion noise is relevant to current aviation, rocket, and ground-based gas turbine engines, as it contributes to environmental noise pollution and can trigger thermoacoustic instabilities. These consequences are particularly prevalent in lean, premixed, prevaporised combustors, which are designed to reduce nitrous oxide (NOx) emissions. As a result, there is a need to better understand the mechanisms that drive sound generation in such systems. There are two components to combustion noise: direct noise - generated by the unsteady heat release of a flame - and indirect noise - produced by the acceleration of entropic, vortical, or compositional inhomogeneities. Separation of the respective contributions has proven to be complex to achieve in real engines - for this purpose, model experiments have been developed. These are non-reacting experiments that use unsteady, synthetic perturbations to emulate the fundamental physics of combustion acoustics processes and provide clear data for comparison with theory. Indirect noise models have been theorised for compositional perturbations and experimental validation has been provided via the measurement of acoustic waves (i.e. the output), while assuming a constant compositional perturbation (i.e. the input). This thesis follows on from such experiments by simultaneously measuring both acoustic and compositional waves in a model setup, making use of numerical, analytical, and experimental studies. It first builds upon a previous model experiment through a numerical investigation on the generation, mixing, and convection of entropic and compositional waves generated by heat addition and gas injection. The computed temperature and mass fraction fields are compared with experimental results and inform the design of a new model setup - the Canonical Wave Rig (CWR). The CWR is then used to study direct and indirect noise under simplified, well-controlled conditions. Subsonic and sonic (choked) conditions are investigated for a convergent-divergent nozzle. Acoustic, entropic, and compositional perturbations are generated via the co-flow injection of air or methane into a low Mach number mean flow of air. Spontaneous Raman spectroscopy (1.5 kHz) is employed for the time-resolved measurement of the local concentration upstream of the nozzle. Single pulse experiments in the infra-sound range are used to validate the derived analytical model for direct noise due to co-flow injection. The measurement of non-reverberated indirect noise is made for the first time and is contrasted with results obtained via dereverberation (i.e. removing the effect of pressure build up due to acoustic reflections). Indirect noise transfer functions are calculated using the acoustic and compositional measurements, and issues pertaining to the methods applied are highlighted. Lastly, the pulse burst injection of methane at frequencies up to 250 Hz is presented. The goal of these experiments is to provide data at more realistic frequencies and amplitudes.

Published

2021

28. Thermal transmittance of a composite lightweight wall panel with integrated load-bearing structure: Experimental versus numerical approach

Author

Mergim Gaši, Bojan Milovanović, Domagoj Tkalčić, and Marija Jelčić Rukavina

Subjects

Lightweight steel structures, Thermal transmittance, Experimental measurements, Numerical simulations, U-values, Heatflow method, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

One of the most important parameters when it comes to heat losses in buildings is the thermal transmittance or U-value. Therefore, great importance should be given to the determination of U-values, especially for elements where there is a high thermal bridge effect, as is the case with lightweight steel frame (LSF) structures. Since LSF structures are usually geometrically more complex, especially when diagonal elements are present, the determination of the overall U-value of these elements is usually done either on scale models in the laboratory or by numerical methods. This paper compares different methods for determining the total U-value for four different polyurethane foam-filled LFS walls and a reference wall made of EPS. Analytical (ISO 6946), experimental (Guarded Hot Box Method and HFM) and numerical 2D and 3D calculations were used to determine the U-value. The aim of the comparison was to verify which methods can be used for more complex geometries of LSF walls when there is a stronger influence of point thermal bridges due to the additional diagonal bracing. All methods showed similar U-values with the highest absolute deviation of 17.18% between the HFM and the 3D numerical calculations. The analytical method for inhomogeneous building elements given in ISO 6946 agrees well with all methods with the maximum absolute deviation of 8.83% between the analytical and HFM method. The work showed the importance of the placement of the HFM sensor for the determination of the surface heat flux, as incorrect placement of the sensor can result in inadequate U-values that deviate up to 167% from the true value.

Published

2023

29. Analysis of Ozone Production Reaction Rate and Partial Discharge Power in a Dielectric-Barrier Acrylic Chamber with 60 Hz High-Voltage Electrodes: CFD and Experimental Investigations.

Author

de Oliveira, Rodrigo M. S., Zampolo, Ronaldo F., Alcantara, Licinius D. S., Girotto, Gustavo G., Lopes, Frederico H. R., Lopes, Nathan M., Brasil, Fernando S., Nascimento, Júlio A. S., and Dmitriev, Victor

Subjects

*PARTIAL discharges, *OZONE, *GAS distribution, *ROOT-mean-squares, *VECTOR fields, *AIR pressure

Abstract

We present a synergistic investigation into ozone production dynamics within a high-voltage reaction chamber operating from 1.75 kV to 10 kV, at 60 Hz. The output ozone concentration dependence on a 60 Hz root mean square high-voltage for an air input pressure of 0.1 bar was measured using an ultraviolet-based sensor. A finite-element numerical model of the reaction chamber was developed and used for obtaining the reaction rate for the generated ozone for each level of input voltage and the internal distribution of the gas vector velocity field and ozone concentration. An expression to estimate the ozone reaction rates from the measured ozone concentrations was also derived. It was then compared and validated using the developed computational model. Therefore, in this work, a formula is proposed to estimate the ozone production by providing the experimental reaction rates. The other objective is to analyze the hysteresis phenomena observed in the partial discharges' levels in the reaction chamber and in the output ozone concentration. Finally, we establish a connection between the total power of partial discharges and the consequent ozone production, clarifying the role of cumulative partial discharges' power levels in governing the resultant output ozone concentration. [ABSTRACT FROM AUTHOR]

Published

2023

30. Experimental and Numerical Analysis of the Efficacy of a Real Downhole Heat Exchanger.

Author

Asad, Muhammad, Guida, Vincenzo, and Mauro, Alessandro

Subjects

*HEAT exchangers, *HEAT transfer coefficient, *NUMERICAL analysis, *HEAT transfer fluids, *FINITE element method, *NATURAL heat convection, *RESERVOIRS, *STRESS-strain curves

Abstract

In this paper, a three-dimensional (3D) numerical model based on the finite element method (FEM) is developed to determine the fluid flow and heat transfer phenomena in a real multi-tube downhole heat exchanger (DHE), designed ad hoc for the present application, considering natural convection inside a geothermal reservoir. The DHE has been effectively installed and tested on the island of Ischia, in southern Italy, and the measurements have been used to validate the model. In particular, the authors analyze experimentally and numerically the behavior of the DHE based on the outlet temperature of the working fluid, thermal power, overall heat transfer coefficient, and efficiency. Furthermore, the influence of the degree of salinity on the performance of the DHE has been studied, observing that it degrades with the increase in the degree of salinity. The results show that the DHE allows to exchange more than 40 kW with the ground, obtaining overall heat transfer coefficient values larger than 450 W/m2 K. At the degree of salinity of 180 ppt, a decrease in the efficiency of the DHE of more than 8% is observed. [ABSTRACT FROM AUTHOR]

Published

2023

31. Experimental and Theoretical Study of Combustion of a Coal Dust Particle–Air Mixture in a Closed Spherical Volume.

Author

Moiseeva, K. M., Krainov, A. Yu., Goloskokov, S. I., Sazonov, M. S., and Lukashov, O. Yu.

Subjects

*COAL dust, *COAL combustion, *DUST, *SHOCK waves, *THEORY of wave motion

Abstract

Experimental data are presented on pressure variation rate during the combustion of a coal dust particle–air mixture in a closed spherical volume at various mass concentrations of coal dust. A physical-mathematical model of the combustion of a coal dust particle–air mixture in a closed spherical volume is formulated on the basis of equations of mechanics of dispersed media in a one-velocity one-temperature approximation. The combustion wave propagation velocity relative to a gas suspension and the burning rate of a coal dust particle are model parameters determined by matching computational results with experimental data. There is good agreement between them. The proposed approach can be used to assess the effect of coal dust combustion on shock wave intensity in coal mines during accidental methane explosions involving coal dust. [ABSTRACT FROM AUTHOR]

Published

2023

32. Adaptive Height Optimization for Cellular-Connected UAVs: A Deep Reinforcement Learning Approach

Author

Erika Fonseca, Boris Galkin, Ramy Amer, Luiz A. DaSilva, and Ivana Dusparic

Subjects

Experimental measurements, massive MIMO, reinforcement learning, two-tier networks, unmanned aerial vehicles (UAVs), Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Providing reliable connectivity to cellular-connected Unmanned Aerial Vehicles (UAVs) can be very challenging; their performance highly depends on the nature of the surrounding environment, such as density and heights of the ground Base Stations (BSs). On the other hand, tall buildings might block undesired interference signals from ground BSs, thereby improving the connectivity between the UAVs and their serving BSs. To address the connectivity of UAVs in such environments, this paper proposes a Reinforcement Learning (RL) algorithm to dynamically optimise the height of a UAV as it moves through the environment, with the goal of increasing the throughput or spectrum efficiency that it experiences. The proposed solution is evaluated in two settings: using a series of generated environments where we vary the number of BS and building densities, and in a scenario using real-world data obtained from an experiment in Dublin, Ireland. Results show that our proposed RL-based solution improves UAV Quality of Service (QoS) by 6% to 41%, depending on the scenario. We also conclude that, when flying at heights higher than the buildings, building density variation has no impact on UAV QoS. On the other hand, BS density can negatively impact UAV QoS, with higher numbers of BSs generating more interference and deteriorating UAV performance.

Published

2023

33. Path Loss Modeling of RFID Backscatter Channels With Reconfigurable Intelligent Surface: Experimental Validation

Author

Mohammed El-Absi, Ali Alhaj Abbas, Deeb Tubail, Furkan Ilgac, Ashraf Abuelhaija, Yamen Zantah, Salama Ikki, Aydin Sezgin, and Thomas Kaiser

Subjects

Path loss models, chipless RFID, RIS, experimental measurements, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

In the realm of radio frequency identification (RFID) technology, the integration of reconfigurable intelligent surfaces (RISs) has opened up new possibilities for real-time remote data capturing and seamless connectivity. By manipulating the electromagnetic properties of the environment, RIS enables the control of electromagnetic wave propagation and allows for virtual line-of-sight (LOS) in cases where physical LOS is blocked. This has tremendous implications for the future of RFID applications, particularly with the emergence of chipless RFID technology. In this regard, this paper develops free-space path loss models for RIS-assisted RFID wireless communications. The proposed models in this study have taken into account several crucial physical factors, including tag radar cross-section (RCS), the physical properties of the RIS, and the radiative near-field/far-field effects of the RIS. To further validate the theoretical findings, we have conducted experimental measurements using a fabricated RIS. Numerical simulations were also utilized to validate the models and verify our findings. The channel measurements have demonstrated good agreement with the proposed path loss models, further bolstering the potential of RIS-assisted RFID wireless communications.

Published

2023

34. The Wind Tunnel Study of the Influence of Terrain and Surrounding Structures on the Distribution of Wind Pressure on a Chimney

Author

Hubová Oľga, Franek Michal, and Véghová Ivana

Subjects

wind load, wind tunnel, distribution of wind pressure, experimental measurements, Engineering (General). Civil engineering (General), TA1-2040

Abstract

The value of the total aerodynamic resistance of the structure is depended on the values of the highly variable coefficients of external pressure, the quantification of which is a typical task of aerodynamics of structures solved on a rigid model in a wind tunnel. The aim of the paper is to analyze the distribution of wind pressure on a 150 m high chimney of a nuclear power plant. Due to today’s changing climate and the emergence of unwanted windstorms, it is necessary to pay increased attention to tall and slender structures, where the effects of wind play an important role. The effect of wind, the influence of the terrain and surrounding structures has a significant impact on the safety of the chimney, which is a part of the nuclear power plant, where increased safety is required not only for the chimney itself but also for buildings in its immediate vicinity. Surrounding structures can modify wind flow and cause increased chimney load. Experimental measurements were performed in the STU BLWT wind tunnel in Bratislava, where the influence of the changing terrain, as well as the influence of the surrounding objects on the external wind pressure coefficients at different altitude levels were monitored.

Published

2022

35. Experimental Analysis of the Influence of Seasonality on the Temperature Regime of Extensive Roofs in Central Europe

Author

Marek Chabada, Pavol Durica, and Peter Juras

Subjects

green roof, experimental measurements, vegetation, temperature, heat flux, Building construction, TH1-9745

Abstract

Current building envelope greening systems are not just areas covered with vegetation. Today’s systems can maximise the functional contribution of vegetation to a building’s performance and become part of a sustainable urban renewal strategy. The impact of the vegetation layer directly affects the building in its immediate vicinity, from the outside, while also having a significant impact on the indoor environment. Green roofs are the most widespread vegetated structures worldwide. This paper aims to demonstrate the behaviour of the temperature regime of an extensive green roof over a production hall and an administrative area in comparison to that of a roof without vegetation cover. In evaluating the results, a period with weather representative of winter and summer was selected to show the importance of seasonality. The fact that this is a new building, and that the extensive roof is not fully covered with vegetation, is very well reflected in the results, as the absence of a vegetated area significantly affects the temperature of as well as the heat flux through the roof structure. The dark colour of the substrate absorbs significantly more solar radiation than the light surface of the waterproofing, resulting in an increase in temperature and heat flux into the structure.

Published

2024

36. Assessing Indoor Air Quality and Ventilation to Limit Aerosol Dispersion—Literature Review.

Author

Hobeika, Nadine, García-Sánchez, Clara, and Bluyssen, Philomena M.

Subjects

INDOOR air quality, LITERATURE reviews, VENTILATION, AEROSOLS, MICROBIOLOGICAL aerosols, COVID-19 pandemic, AIRBORNE infection

Abstract

The COVID-19 pandemic highlighted the importance of indoor air quality (IAQ) and ventilation, which researchers have been warning about for years. During the pandemic, researchers studied several indicators using different approaches to assess IAQ and diverse ventilation systems in indoor spaces. To provide an overview of these indicators and approaches in the case of airborne transmission through aerosols, we conducted a literature review, which covered studies both from before and during the COVID-19 pandemic. We searched online databases for six concepts: aerosol dispersion, ventilation, air quality, schools or offices, indicators, and assessment approaches. The indicators found in the literature can be divided into three categories: dose-, building-, and occupant-related indicators. These indicators can be measured in real physical spaces, in a controlled laboratory, or modeled and analyzed using numerical approaches. Rather than organizing this paper according to these approaches, the assessment methods used are grouped according to the following themes they cover: aerosol dispersion, ventilation, infection risk, design parameters, and human behavior. The first finding of the review is that dose-related indicators are the predominant indicators used in the selected studies, whereas building- and occupant-related indicators are only used in specific studies. Moreover, for a better understanding of airborne transmission, there is a need for a more holistic definition of IAQ indicators. The second finding is that although different design assessment tools and setups are presented in the literature, an optimization tool for a room's design parameters seems to be missing. Finally, to efficiently limit aerosol dispersion in indoor spaces, better coordination between different fields is needed. [ABSTRACT FROM AUTHOR]

Published

2023

37. Flow measurement in a wind tunnel with blockage screens.

Author

Sharma, Dishant, Namboodiri V, Vishnu, and Goyal, Rahul

Subjects

*WIND tunnels, *WIND speed, *WIND measurement, *WIND power, *WIND turbines, *OFFSHORE wind power plants, *WIND power plants

Abstract

The small and medium-scale wind turbine development have been improved due to their adaptability in offshore and onshore localities for wind farm applications. Blockage effects caused by numerous impediments restrict the flow-field near the turbine and impact the turbine's performance. The testing and optimization of turbines in such conditions at laboratory-level are challenging due to the unavailability of customized wind tunnel configurations with blockage screens. The present work focuses on the design, development and evaluating aerodynamic performance of wind tunnel with and without blockage screens. A comprehensive design is established by evaluating losses in each section, uncertainties, velocity, forces, and turbulence intensity in the wind tunnel through the experimental analysis. The novel blockage screens are arranged to maintain 5 % and 10 % blockage percentage for wind velocity range of 2–14 m/s. The maximum velocity reduction with 5 % blockage is 41.40 % and this drop reaches to 67.84 % for 10 % blockage. Consequently, available wind power is seen to undergo a maximum reduction of 79.88 % and 96.67 %, respectively. • Design and development of a subsonic open-loop wind tunnel with a novel blockage screen for performance analysis in a skewed flow environment. • Detailed calibration, uncertainty, and losses analysis to quantify the accuracy of the measurements. • Flow investigation with different blockage percentages (5 % and 10 %) inside the wind tunnel. • The maximum velocity reduction with 5 % blockage is 41.40 % and this drop reaches to 67.84 % for 10 % blockage. [ABSTRACT FROM AUTHOR]

Published

2024

38. Construction of frustrated lewis pairs in ZnO surface for boosting electrocatalytic NO reduction to NH3: Theoretical prediction and experimental validation.

Author

Su, Qiwen, Zhang, Guike, Zhao, Tiantian, Chu, Ke, Cai, Qinghai, and Zhao, Jingxiang

Subjects

*LEWIS pairs (Chemistry), *LEWIS bases, *ZINC oxide, *LEWIS acids, *DENSITY functional theory, *DOPING agents (Chemistry), *NITRIC oxide

Abstract

Herein, we reported the design of unique FLPs for electrocatalytic reduction of nitric oxide (NOER) through anion doping on the ZnO (100) surface. The results demonstrated that the introduced dopant and its adjacent non−bonding Zn site function as a Lewis base and Lewis acid, respectively, to synergistically activate NO molecules. Using density functional theory for material screening, P−doped ZnO is predicted to exhibit rather high NOER activity with an ultralow limiting potential (−0.04 V), accompanied by the excellent suppression effect on the competitive side reactions to guarantee its high selectivity for NH 3 production. Motivated by the theoretical prediction, the synthesized P−doped ZnO catalyst showed a high NH 3 yield rate (218.2 μmol h−1cm−2 at −0.7 V) and a high Faradaic efficiency (91.4 %), as confirmed by our experimental measurements. This work not only suggests a high−performance catalyst for NO reduction but also expands upon the potential applications of FLPs in electrocatalysis. [Display omitted] • The introduced dopant and its adjacent non−bonding Zn site can be identified as the FLPs. • The P-doped ZnO (100) exhibits the rather high NOER activity. • The high NH 3 yield rate (218.2 μmol h−1cm−2 at −0.7 V) and FEs (91.4 %) can be achieved in experiments. [ABSTRACT FROM AUTHOR]

Published

2024

39. Innovative strengthening of RC columns using a layer of a fibre reinforced concrete

Author

Peter Koteš, Martin Vavruš, and Wioletta Raczkiewicz

Subjects

columns, experimental measurements, fibre reinforced concrete, numerical modelling, reinforced concrete, strengthening, Engineering (General). Civil engineering (General), TA1-2040

Abstract

Reinforced concrete structures that are influenced by degradation, overloading, the thawing and freezing cycles, abrasive damage and corrosion of reinforcement, should be repaired or strengthened. Each of those mentioned situations lead to decreasing the load-carrying capacity of the construction. The damage of a structure or its member causes exceeding the serviceability limit states and ultimate limit states. For this reason, for further use of the structures, they have to be strengthened to increase the load-carrying capacity and to extend the remaining lifetime. A new method for strengthening the vertical members, e.g., columns, is using the fibre reinforced concrete layer and its increased tensile strength in comparison to common RC concrete. This article deals with the theoretical design of dimensioning the columns using a layer of fibre concrete around a column (wrapping). In this case, it is necessary to calculate the residual strength of fibre concrete, which is a crucial factor for the tensile strength of the element.

Published

2022

40. Thermal Transport in 2D Materials.

Author

Kalantari, Mohammad Hassan and Zhang, Xian

Subjects

*THERMAL conductivity measurement, *THERMAL conductivity, *THERMAL properties, *TRANSITION metals

Abstract

In recent decades, two-dimensional materials (2D) such as graphene, black and blue phosphorenes, transition metal dichalcogenides (e.g., WS2 and MoS2), and h-BN have received illustrious consideration due to their promising properties. Increasingly, nanomaterial thermal properties have become a topic of research. Since nanodevices have to constantly be further miniaturized, thermal dissipation at the nanoscale has become one of the key issues in the nanotechnology field. Different techniques have been developed to measure the thermal conductivity of nanomaterials. A brief review of 2D material developments, thermal conductivity concepts, simulation methods, and recent research in heat conduction measurements is presented. Finally, recent research progress is summarized in this article. [ABSTRACT FROM AUTHOR]

Published

2023

41. Numerical Analysis of Wind Effects on a Residential Building with a Focus on the Linings, Window Sills, and Lintel.

Author

Hubová, Oľga, Macák, Marek, Franek, Michal, Lobotka, Peter, Konečná, Lenka Bujdáková, and Ivánková, Oľga

Subjects

NUMERICAL analysis, BOUNDARY layer (Aerodynamics), WIND pressure, COMPUTATIONAL fluid dynamics, PASSIVE components

Abstract

This article deals with the investigation of wind effects on a façade of a rectangular residential building with explicit modelling of the windows for specific wind conditions. The external wind pressure coefficients were treated on the façade and at the places of the window sills, linings, and lintel for the direction of the wind from 0° to 90° with increments of 22.5°. For a detailed analysis, the CFD simulation using Ansys Fluent was used. The method selected for the CFD simulation solution and its setting (quality of meshing, horizontal homogeneity of the boundary layer, etc.) were verified by known results of similar objects. The purpose of this analysis is to show how important it is to consider wind effects to determine the suitable placement of passive ventilation devices. Research shows the potential optimal position of ventilation units in terms of favourable pressure distribution. Zones with negative pressure and corners or façades in a wake are not suitable for applying passive ventilation units. The results can serve as a basis for designers to achieve optimal comfort in residential buildings. [ABSTRACT FROM AUTHOR]

Published

2023

42. Experimental Validation of Ultra-Shortened 3D Finite Element Models for Frequency-Domain Analyses of Three-Core Armored Cables.

Author

del-Pino-Lopez, Juan Carlos and Cruz-Romero, Pedro

Subjects

*FREQUENCY-domain analysis, *FINITE element method, *OFFSHORE wind power plants, *CABLES, *PARTIAL discharges

Abstract

Recently, large offshore wind power plants have been installed far from the shore, using long HVAC three-core armored cables to export power. Its high capacitance may contribute to the appearance of unwanted phenomena, such as overvoltages or resonances at low frequencies. To adequately assess these problems, detailed and reliable cable models are required to develop time-domain/frequency-domain analyses on this type of cables. This paper presents, for the first time in the literature, an assessment on the performance of 3D finite element method-based (3D-FEM) models for developing frequency-domain analyses on three-core armored cables, confronting simulation results with experimental measurements found in the literature for three real cables. To this aim, a simplified ultra-shortened 3D-FEM model is proposed to reduce the simulation time during frequency sweeps, through which relevant aspects never analyzed before with frequency-domain 3D-FEM simulations are addressed, such as total losses, induced sheath current, magnetic field around the power cable, positive and zero sequence harmonic impedances, as well as resonant frequencies. Also, a time-domain example derived from the frequency-domain analysis is provided. Remarkable results are obtained when comparing computed values and measurements, presenting the simplified ultra-shortened 3D-FEM model as a valuable tool for the frequency-domain analysis of these cables. [ABSTRACT FROM AUTHOR]

Published

2022

43. Theoretical and Experimental Studies of Acoustic Reflection of Bubbly Liquid in Multilayer Media.

Author

Wang, Yu, Chen, Dehua, Cao, Xueshen, and He, Xiao

Subjects

ACOUSTIC reflection, REFLECTANCE, TRACE gases, PETROLEUM reservoirs, MULTIPHASE flow, OCEAN bottom

Abstract

Bubbly liquids are widely present in the natural environment and industrial fields, such as seawater near the ocean bottom, the multiphase flow in petroleum reservoirs, and the blood with bubbles resulting in decompression sickness. Therefore, accurate measurement of the gas content is of great significance for hydroacoustic physics, oil and gas resources exploration, and disease prevention and diagnosis. Trace bubbles in liquids can lead to considerable changes in the acoustic properties of gas–liquid two-phase media. Acoustic measurements can therefore be applied for trace bubble detection. This study derived the reflection coefficient of acoustic waves propagating in a sandwich layering model with liquid, bubbly liquid, and liquid. The influences of gas contents on the reflection coefficient at the layer interface were analyzed based on theoretical calculations. It was revealed that the magnitude of the reflection coefficient and the frequency interval between its valleys have a quantitative correlation with the gas contents. Thus, a novel means to detect the contents of trace bubbles was proposed by evaluating the reflection coefficients. The reflection features of a thin layer with bubbly liquid were then studied through experiments. It was validated by acoustical measurements and theories that the reflection coefficient is considerably sensitive to the change of gas contents as long as the gas content is tiny. With the increasing gas content, the maximum value of the reflection coefficient increases; meanwhile, the frequency intervals between the valleys become smaller. However, when the gas content is extensive enough, e.g., greater than 1%, the effect of the change of gas content on the reflection coefficient becomes inapparent. In that case, it is not easy to measure the gas content by the acoustic reflection signals with satisfying precision. This proposed method has potential applications for the detection of trace gas bubble content in several scenarios, e.g., decompression illness prevention and diagnosis. [ABSTRACT FROM AUTHOR]

Published

2022

44. Experimental Investigation and Optimization of a Glazed Transpired Solar Collector.

Author

Teodosiu, Catalin Ioan, Sima, Catalin, Croitoru, Cristiana, and Bode, Florin

Subjects

SOLAR collectors, ENERGY consumption of buildings, SOLAR radiation, ENERGY consumption

Abstract

Featured Application: Evaluation of energy saving for implementation of optimized glazed transpired solar collectors within the façades of buildings. Solar air collectors are increasingly used nowadays due to their important potential in reducing the energy consumption of buildings. In this context, glazed transpired solar collectors (GTCs) represent an interesting solution, but this type of solar air collector is less studied. Consequently, the objective of this work is to thoroughly assess the performance of a GTC prototype under real long-term climatic conditions. First, the design of the GTC is optimized based on methodically experimental tests. The results show that the GTC configuration with a 30 mm air gap among the absorber and the glazing leads to improved heat transfer efficiency and superior global effectiveness, regardless of airflow rates through the solar air collector. This optimized GTC configuration is further studied by integration within the façade of a full-scale experimental building (container-type, light structure). Comparative experimental studies are then carried out concerning the heating energy consumption and ventilation load of the experimental building without/with GTC implemented in the ventilation system, under Bucharest real weather conditions. The data achieved indicate that the GTC prototype is capable of substantially reducing the ventilation load: up to 25% for low solar radiation (below 200 W/m2) and over 50% (achieving even 90%) for moderate solar radiation (between 250 and 380 W/m2). Finally, for high solar radiation (over 400 W/m2), the GTC outlet air temperature exceeds the interior temperature set-point (22 °C) of the experimental building. [ABSTRACT FROM AUTHOR]

Published

2022

45. Modal analysis of a milling dynamometer considered as 1DOF system.

Author

Mupona, Munyaradzi Innocent and Roşca, Ioan Călin

Subjects

*DYNAMOMETER, *MODAL analysis, *TRANSFER functions

Abstract

A force transducer-based plate dynamometer for milling force measurements is presented in this paper. The main components of the designed dynamometer were described, and experimental modal analysis was carried out while considering the dynamometer as a 1DOF system. The values of the main components of the 1DOF systems such as mass, damping coefficient, and equivalent stiffness were identified, and the natural frequency for rings and dynamometer was calculated. The calculated natural frequencies of components were found in reacceptance FRF, obtained by modal analysis done with an impact hammer. A MATLAB simulation was done to validate the system using the transfer function based on the modal test. [ABSTRACT FROM AUTHOR]

Published

2022

46. Numerical Simulation and Experimental Validation of Thermal Break Strips' Improvement in Facade LSF Walls.

Author

Santos, Paulo, Mateus, Diogo, Ferrandez, Daniel, and Verdu, Amparo

Subjects

*WALLS, *LIGHTWEIGHT steel, *STEEL strip, *FACADES, *COMPUTER simulation, *STEEL framing

Abstract

Thermal bridges may have a significant prejudicial impact on the thermal behavior and energy efficiency of buildings. Given the high thermal conductivity of steel, in Lightweight Steel Framed (LSF) buildings, this detrimental effect could be even greater. The use of thermal break (TB) strips is one of the most broadly implemented thermal bridge mitigation technics. In a previous study, the performance of TB strips in partition LSF walls was evaluated. However, a search of the literature found no similar experimental campaigns for facade LSF walls, which are even more relevant for a building's overall energy efficiency since they are in direct contact with the external environmental conditions. In this article the thermal performance of ten facade LSF wall configurations were measured, using the heat flow meter (HFM) method. These measurements were compared to numerical simulation predictions, exhibiting excellent similarity and, consequently, high reliability. One reference wall, three TB strip locations in the steel stud flanges and three TB strip materials were assessed. The outer and inner TB strips showed quite similar thermal performances, but with slightly higher thermal resistance for outer TB strips (around +1%). Furthermore, the TB strips were clearly less efficient in facade LSF walls when compared to their thermal performance improvement in load-bearing partition LSF walls. [ABSTRACT FROM AUTHOR]

Published

2022

47. Line-Start Synchronous Reluctance Motor With V-Shaped Rotor Laminations

Author

Mbika Muteba

Subjects

Constant speed drives, dynamic response and transient analysis, experimental measurements, finite element analysis, IE4 efficiency, line-start motor, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

A line-start synchronous reluctance motor (LS-SynRM) that meets the IE4 efficiency and has satisfactory starting and synchronizing capabilities while operating with acceptable power factor will find application in constant speed drives. This paper introduces a line-start synchronous reluctance motor with V-shape rotor laminations (LS-SynRM-VSRL). The motor, which has been designed from an IE2-132S4 conventional foot mounted three-phase induction motor NEMA frame, was modeled using the three-dimensional (3D) Finite Element Method (FEM), then prototyped and tested for transient, dynamic, and steady-state performance under different load conditions. The Finite Element Analysis (FEA) and measured results of the LS-SynRM-VSRL are compared with those of a conventional line-start synchronous reluctance motor (CLS-SynRM). The results evidenced that both LS-SynRMs achieved successful synchronization on no-load, with the proposed LS-SynRM-VSRL reaching the steady state condition much quicker than the CLS-SynRM. Under steady-state operations, both LS-SynRMs achieved IE4 efficiency, with the proposed LS-SynRM-VSRL reaching an efficiency of 93.6% on full-load, in contrast to the 84.9% that the IE2-132S4 induction motor has achieved under the same loading condition.

Published

2022

48. An Empirical Study of the Stochastic Nature of Electromagnetic Field Exposure in Massive MIMO Systems

Author

Fabien Heliot, Tian Hong Loh, David Cheadle, Yunsong Gui, and Michael Dieudonne

Subjects

5G new radio (NR), electromagnetic field (EMF) exposure, massive multiple-input multiple-output (mMIMO), experimental measurements, statistical model, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Base stations (BSs) rely on the massive multiple-input multiple-output (mMIMO) technology in the fifth generation of mobile networks (5G). A technology having a major impact on the nature of the electromagnetic field (EMF) exposure in such systems. This work has used a fully reconfigurable mMIMO testbed (operating at 2.63 GHz), capable of mimicking realistic 5G new radio (NR) BS beamforming performance, to first gather experimental-based evidence of 5G BS EMF exposure within a real-world outdoor environment, to then analyze its stochastic behaviour, and to finally understand its impact on the definition of exclusion boundaries for 5G BSs. The exposure data of our testbed have been complemented by exposure data collected from a typical commercial 5G BS (operating at 3.65 GHz) to confirm the result trends and findings of our analysis. A robust metrology has been followed to obtain all the EMF exposure data. Our data and analysis indicate that significant exposure variations can be noticed according to the beam directions, i.e. the relative position of the exposure measurement location to the beam directions as well as the environment, confirming the stochastic nature of 5G BS exposure. The variance of the exposure tends to decrease as the number of users increase for a constant traffic load. Whereas the exposure grows sub-linearly with the traffic load, regardless of the number of users. As far as the exclusion boundary of 5G BS is concerned, its revised definition based on 95-th percentile seems still not flexible enough to accommodate the deployment of 5G BS in countries/places with stringent EMF exposure limits, as for instance in Belgium.

Published

2022

49. Implementation of Data from Wind Tunnel Tests in the Design of a Tall Building with an Elliptic Ground Plan

Author

Oľga Hubová, Marek Macák, Michal Franek, Oľga Ivánková, and Lenka Bujdáková Konečná

Subjects

tall building, external pressure coefficients, experimental measurements, boundary layer wind tunnel, computational fluid dynamics, static analysis, Building construction, TH1-9745

Abstract

The design of a 69 m tall multipurpose building was investigated in this paper. The shape of the structure above the ground was an elliptical cylinder. Under the ground, the building was extended into a cuboid shape (for car parking). External wind pressure coefficients were determined using three methods: wind tunnel tests, CFD, and “the simplification of the shape” (using information defined in building standards). From the obtained results, it was evident that the simplification did not provide results with sufficient accuracy. The external wind pressure coefficients presented in this paper should be used for the design of a similar structure. The shape of the elliptical cylinder is very sensitive to applied wind. Positive pressures only occur on a small area of the windward side. The rest of the windward side is loaded with negative pressures. Therefore, torsional effects can occur, and these can be dangerous for the structure. The leeward side is completely loaded with negative pressures. In our case, this information was necessary for a follow-on static and dynamic analysis of the building. Various subsoil stiffness coefficients were considered. The calculated horizontal displacement was compared with the limit value. A measured wind direction of 20° caused the maximum obtained torsional moment, and a wind direction of 90° induced the maximum obtained force. The commercial program Ansys Fluent 2022 was used for the CFD simulation. The SCIA ENGINEER 21 program was used for follow-on analysis. This paper presents brief information on the selected turbulence model and details the settings used for the CFD simulation. Also, a description of the wind tunnel laboratory utilized in this study is provided, along with a description of the measuring devices used and the methodologies of the tests carried out. The main purpose of this paper is to show how important it is to consider the wind load for the static analysis of a structure like this.

Published

2023

50. Investigation of Combustion of a Coal–Methane–Air Suspension in a Long Closed Channel.

Author

Moiseeva, K. M., Pinaev, A. V., Vasil'ev, A. A., Krainov, A. Yu., and Pinaev, P. A.

Subjects

*COAL dust, *DUST, *COMBUSTION, *SHOCK waves, *COAL combustion, *THEORY of wave motion

Abstract

Experimental data on the velocity of propagation of a combustion wave in a coal–methane–air mixture with respect to the walls of a closed channel for various concentrations of coal dust are presented. A physico-mathematical model of combustion of this mixture on the basis of equations of gas dynamics and mechanics of disperse media in the one-velocity one-temperature approximation is developed. In the proposed model, the velocity of propagation of the combustion wave with respect to the gas suspension and the burning rate of the coal dust particle are parameters of the model and are determined by providing the consistency between the computed and experimental results. A comparison of the calculated flame velocity with respect to the channel walls in a wide range of mass fractions of coal dust reveals reasonable agreement with the experiments. The proposed approach can be used for estimating the influence of coal dust combustion on the intensity of shock waves formed in coal mines in the case of accidental explosions of methane. [ABSTRACT FROM AUTHOR]

Published

2022