Your search keyword '"V. A. Potachits"' showing total 12 results

1. Simulation of Vertical Thin-Film Solar Battery under Exposure of Concentrated Solar Radiation

Author

A. K. Esman, G. L. Zykov, V. A. Potachits, and V. K. Kuleshov

Subjects

solar panel, cuinse2, 3d simulation model, comsol multiphysics, heat transfer, temperature stabilization, temperature gradient, heat flux, efficiency, Hydraulic engineering, TC1-978, Engineering (General). Civil engineering (General), TA1-2040

Abstract

Solar energy is one of the most important and promising energy sectors in the world. Batteries that convert sunlight into electrical energy could become a replacement for traditional carbon-based energy sources. Vertical thin-film solar batteries are one of the new approaches to solar energy generation. The vertical configuration of solar panels provides maximum absorption of sunlight throughout the day. This orientation allows the batteries to capture solar energy even at low angles of incidence of the sun’s rays, which prolongs their operating time and improves the efficiency of electricity production. In this work, the authors proposed a three-dimensional model of a vertically oriented solar battery, as well as they calculated and evaluated the temperature characteristics and the efficiency obtained under conditions of changing ambient temperature. Herewith the power densities of concentrated solar radiation with maximum values from 1 to 10 kW/m2 were varied. The distribution of the maximum values of the surface temperature of the solar battery has been studied. Also, the dependences of the maximum values of the solar battery temperature and the temperature gradient inside it, as well as the dependences of the minimum and maximum values of the heat flux from the solar battery surface on the time of day in the middle of January and July have been studied and plotted. As the calculations have shown, the maximum values of the temperature gradient inside the solar battery in January are ~47–50 % higher than in July. The potential difference, generated by the battery, reaches its maximum values from 11 a.m. to 4 p.m. both in January and July. The use of vertical thin-film solar batteries will improve the power generation efficiency and lower operating costs by reducing the influence of dust, rain and snow.

Published

2024

2. Simulation of Photovoltaic Thermoelectric Battery Characteristics

Author

A. K. Esman, G L. Zykov, V. A. Potachits, and V. K. Kuleshov

Subjects

thermoelectric converter on the basis of cuinse2, numerical simulation, comsol multiphysics, solar radiation concentrator, solar power density, temperature stabilization, temperature gradient, output voltage amplitude, Hydraulic engineering, TC1-978, Engineering (General). Civil engineering (General), TA1-2040

Abstract

Solar radiation is an environmentally friendly and affordable energy source with high release of energy. The use of a photovoltaic thermoelectric battery makes it possible to increase the efficiency of converting solar and thermal radiation into electrical energy, both on serene and cloudy days. An original battery structure with photovoltaic and thermoelectric converters is proposed. The 3D model of the proposed photovoltaic thermoelectric battery was realized in the COMSOL Multiphysics software environment with the use of a heat transfer module. The simulation was performed for the geographical coordinates of Minsk and taking into account the diurnal and seasonal variations of both the ambient temperature and the power density of the concentrated AM1.5 solar spectrum, the maximum value of which being varied from 1 to 500 kW/m2. The dependences of the maximum temperature values of the photovoltaic thermoelectric battery and the thermoelectric converters as well as temperature gradient patterns in the thermoelectric converters have been calculated. The dependences of the maximum temperature gradient values inside the thermoelectric converters on the solar power density are obtained. The graphs of the temperature gradients inside the thermoelectric converters of the photovoltaic thermoelectric battery by concentrated solar radiation versus the time of day in the middle of July and January are provided. It is shown that the output voltage increases up to the maximum values of 635 and 780 mV, respectively, in January and in July were achieved due to the temperature stabilization of the back side of the external electrodes of the proposed device

Published

2021

3. Simulation of Thin-Film Solar Cells with a CuInSe2 Chalcopyrite Structure

Author

A. K. Esman, G. L. Zykov, V. A. Potachits, and V. K. Kuleshov

Subjects

cuinse2 thin-film solar cell, numerical simulation, comsol multiphysics, scaps-1d, thermoelectric layer, photoelectric converter, solar concentrator, solar radiation density, currentvoltage characteristic, fill factor, efficiency, Hydraulic engineering, TC1-978, Engineering (General). Civil engineering (General), TA1-2040

Abstract

By using numerical simulation, the operating temperatures of a thin-film solar cell based on CuInSe2 have been determined and the solar radiation density values, at which stabilization of the temperature operating conditions of the thin-film solar cell is not required, have been optimized. The maximum possible efficiency value of ~14.8 % is achieved under actual operating conditions, and is maintained by the incoming thermal energy as both emitted in this cell and infrared radiation of the sun and the environment. A model of the proposed thin-film solar cell was implemented in the COMSOL Multiphysics program environment with the use of the Heat Transfer Module. The operating temperatures of the solar cell without thermal stabilization under conditions of the diurnal and seasonal variations of both the ambient temperature and the power density of the AM1.5 solar spectrum have been determined. The maximum value of this power density was varied from 1.0 to 500 kW/m2 when using concentrators. The obtained values of operating temperatures of the thin-film solar cell were used to determine its main parameters in the SCAPS-1D program. The graphs of the operating temperature, efficiency and fill factor of the thin-film solar cell versus the solar radiation density are provided. It is shown that in order to obtain the highest possible efficiency of a solar cell, it is necessary to use concentrated solar radiation with a power density, the maximum value of which should be 8 kW/m2 in July and 10 kW/m2 in January. In the case of lower and higher values of power density, an appropriate thermal stabilization of the cell under consideration is necessary. The dependencies of efficiency, fill factor and open-circuit voltage versus the stabilization temperature of the solar cell, temperature gradients at the interfaces of the thermoelectric layer were also calculated. It is shown that by choosing optimal values of the thermal stabilization, the efficiency of the proposed solar cell may be about 15 % or more.

Published

2020

4. Simulation of Tandem Thin-Film Solar Cell on the Basis of CuInSe2

Author

A. K. Esman, V. K. Kuleshov, V. A. Potachits, and G. L. Zykov

Subjects

cuinse2 thin-film solar cell, numerical simulation, comsol multiphysics, thermoelectric layer, photoelectric converter, temperature gradient, temperature stabilization, substrate, solar concentrator, Hydraulic engineering, TC1-978, Engineering (General). Civil engineering (General), TA1-2040

Abstract

CuInSe2 thin-film solar cells are promising materials for photovoltaic devices. One of the main tasks of researchers is to find ways to increase the solar cells efficiency. In this paper we propose an original structure of a thin-film solar cell based on a tandem connection of a photoelectric converter and a thermoelectric layer based on CuInSe2. The photoelectric converter consists of CuInSe2 and CdS layers. A 3D model of the proposed thin-film solar cell was implemented in the COMSOL Multiphysics environment with using the Heat Transfer module. The simulation was carried out taking into account the diurnal and seasonal variations of both the ambient temperature and the power density of the AM1.5 solar spectrum for the geographical coordinates of Minsk. The solar radiation power density of about 500 kW/m2 can be achieved by using concentrators. The temperature pattern and temperature gradients are calculated in each layer of the solar cell without and with the temperature stabilization of the substrate back side as well as without and with the thermal insulation of the substrate ends. Graphs of the temperature gradients of the thermoelectric layer and the temperature variations of the photoelectric converter of the solar cell are given. As a result of the simulation, it is shown how the uneven heating of both the surface of a thin-film solar cell and its layers occur under conditions of diurnal and seasonal variations of both the ambient temperature and the solar radiation power density. Under concentrated solar radiation exposure, the photoelectric converter surface can be heated up to 700 °C without temperature stabilization of the solar cell substrate. The operating temperature of the photoelectric converter was maintained at no more than 2.35 °C in January and at no more than 14.23 °C in July due to the temperature stabilization of the substrate back side of the proposed device. This made it possible to achieve an increase in the output power of the solar cell both by summing the photoand thermoelectric output voltages and by the concentration of solar radiation.

Published

2018

5. HIGH-EFFICIENCY INFRARED RECEIVER

Author

A. K. Esman, V. I. Kostenko, N. I. Mukhurov, G. L. Zykov, and V. A. Potachits

Subjects

electrodes of the elliptical convex-concave shape, reflection losses, voltage standing wave ratio, directivity, Engineering (General). Civil engineering (General), TA1-2040

Abstract

Recent research and development show promising use of high-performance solid-state receivers of the electromagnetic radiation. These receivers are based on the low-barrier Schottky diodes. The approach to the design of the receivers on the basis of delta-doped low-barrier Schottky diodes with beam leads without bias is especially actively developing because for uncooled receivers of the microwave radiation these diodes have virtually no competition. The purpose of this work is to improve the main parameters and characteristics that determine the practical relevance of the receivers of mid-infrared electromagnetic radiation at the operating room temperature by modifying the electrodes configuration of the diode and optimizing the distance between them. Proposed original design solution of the integrated receiver of mid-infrared radiation on the basis of the low-barrier Schottky diodes with beam leads allows to effectively adjust its main parameters and characteristics. Simulation of the electromagnetic characteristics of the proposed receiver by using the software package HFSS with the basic algorithm of a finite element method which implemented to calculate the behavior of electromagnetic fields on an arbitrary geometry with a predetermined material properties have shown that when the inner parts of the electrodes of the low-barrier Schottky diode is performed in the concentric elliptical convex-concave shape, it can be reduce the reflection losses to -57.75 dB and the standing wave ratio to 1.003 while increasing the directivity up to 23 at a wavelength of 6.09 μm. At this time, the rounded radii of the inner parts of the anode and cathode electrodes are equal 212 nm and 318 nm respectively and the gap setting between them is 106 nm. These parameters will improve the efficiency of the developed infrared optical-promising and electronic equipment for various purposes intended for work in the mid-infrared wavelength range.

Published

2016

6. DETECTOR FOR SUBMILLIMETER WAVELENGTH RANGE ON THE BASIS OF THE MAN-MADE MATERIALS

Author

A. K. Esman, V. A. Potachits, G. L. Kuleshov, and V. K. Zykov

Subjects

detector for submillimeter wavelength range, array of planar resonant elements, reflection losses, standing wave ratio, conversion efficiency, Engineering (General). Civil engineering (General), TA1-2040

Abstract

The uncooled high-performance bolometric detector based on an array of planar resonant elements, located on the double-threaded spiral trajectory in a strictly geometrical order, with microand nanoscales is developed. It is shown that the proposed detector for submillimeter wavelength range can reach the reflection losses of –26,4 dB, the standing wave ratio of 1,1 and conversion efficiency of ~ 98 %.

Published

2015

7. ELECTROOPTICAL CHARACTERISTICS OF SPACE-INTEGRATED MODULATING STRUCTURES ON TWIST EFFECT IN LIQUID CRYSTALS

Author

Yu. V. Razvin and V. A. Potachits

Subjects

electro-optics, twist effect, liquid crystals, deformation, Technology

Abstract

The paper demonstrates that the process of twist LC-pixel switching can be associated not only with a reorientation of liquid crystal molecules in the controlling electric field, but also with the effect of compression of the LC-spiral to the central area through layer thickness. In this case the time of LC-pixel total switching is decreased by almost three orders.

Published

2014

8. IMPROVEMENT OF THE ENERGY EFFICIENCY OF THE PHOTOVOLTAIC THERMOELECTRIC BATTERY

Author

G. L. Zykov, A. K. Esman, and V. A. Potachits

Subjects

Materials science, Photovoltaic system, Engineering physics, Thermoelectric battery, Efficient energy use

Published

2021

9. Simulation of Thin-Film Solar Cells with a CuInSe2 Chalcopyrite Structure

Author

V. K. Kuleshov, A. K. Esman, V. A. Potachits, and G. L. Zykov

Subjects

Materials science, Nuclear engineering, Energy Engineering and Power Technology, Radiation, fill factor, law.invention, comsol multiphysics, thermoelectric layer, Operating temperature, law, Thermal, Solar cell, Thermoelectric effect, cuinse2 thin-film solar cell, solar radiation density, Power density, Renewable Energy, Sustainability and the Environment, business.industry, photoelectric converter, currentvoltage characteristic, Hydraulic engineering, Engineering (General). Civil engineering (General), solar concentrator, scaps-1d, Nuclear Energy and Engineering, efficiency, numerical simulation, Physics::Space Physics, Heat transfer, Astrophysics::Earth and Planetary Astrophysics, TA1-2040, TC1-978, business, Thermal energy

Abstract

By using numerical simulation, the operating temperatures of a thin-film solar cell based on CuInSe2 have been determined and the solar radiation density values, at which stabilization of the temperature operating conditions of the thin-film solar cell is not required, have been optimized. The maximum possible efficiency value of ~14.8 % is achieved under actual operating conditions, and is maintained by the incoming thermal energy as both emitted in this cell and infrared radiation of the sun and the environment. A model of the proposed thin-film solar cell was implemented in the COMSOL Multiphysics program environment with the use of the Heat Transfer Module. The operating temperatures of the solar cell without thermal stabilization under conditions of the diurnal and seasonal variations of both the ambient temperature and the power density of the AM1.5 solar spectrum have been determined. The maximum value of this power density was varied from 1.0 to 500 kW/m2 when using concentrators. The obtained values of operating temperatures of the thin-film solar cell were used to determine its main parameters in the SCAPS-1D program. The graphs of the operating temperature, efficiency and fill factor of the thin-film solar cell versus the solar radiation density are provided. It is shown that in order to obtain the highest possible efficiency of a solar cell, it is necessary to use concentrated solar radiation with a power density, the maximum value of which should be 8 kW/m2 in July and 10 kW/m2 in January. In the case of lower and higher values of power density, an appropriate thermal stabilization of the cell under consideration is necessary. The dependencies of efficiency, fill factor and open-circuit voltage versus the stabilization temperature of the solar cell, temperature gradients at the interfaces of the thermoelectric layer were also calculated. It is shown that by choosing optimal values of the thermal stabilization, the efficiency of the proposed solar cell may be about 15 % or more.

Published

2020

10. Simulation of Photovoltaic Thermoelectric Battery Characteristics

Author

V. A. Potachits, A. K. Esman, G. L. Zykov, and V. K. Kuleshov

Subjects

Battery (electricity), Materials science, 020209 energy, Energy Engineering and Power Technology, 02 engineering and technology, solar radiation concentrator, temperature gradient, solar power density, comsol multiphysics, thermoelectric converter on the basis of cuinse2, Thermoelectric effect, 0202 electrical engineering, electronic engineering, information engineering, output voltage amplitude, Solar power, Renewable Energy, Sustainability and the Environment, business.industry, Photovoltaic system, Hydraulic engineering, 021001 nanoscience & nanotechnology, Engineering (General). Civil engineering (General), Engineering physics, Thermoelectric battery, Nuclear Energy and Engineering, Thermal radiation, numerical simulation, temperature stabilization, TA1-2040, 0210 nano-technology, Energy source, business, TC1-978, Voltage

Abstract

Solar radiation is an environmentally friendly and affordable energy source with high release of energy. The use of a photovoltaic thermoelectric battery makes it possible to increase the efficiency of converting solar and thermal radiation into electrical energy, both on serene and cloudy days. An original battery structure with photovoltaic and thermoelectric converters is proposed. The 3D model of the proposed photovoltaic thermoelectric battery was realized in the COMSOL Multiphysics software environment with the use of a heat transfer module. The simulation was performed for the geographical coordinates of Minsk and taking into account the diurnal and seasonal variations of both the ambient temperature and the power density of the concentrated AM1.5 solar spectrum, the maximum value of which being varied from 1 to 500 kW/m2. The dependences of the maximum temperature values of the photovoltaic thermoelectric battery and the thermoelectric converters as well as temperature gradient patterns in the thermoelectric converters have been calculated. The dependences of the maximum temperature gradient values inside the thermoelectric converters on the solar power density are obtained. The graphs of the temperature gradients inside the thermoelectric converters of the photovoltaic thermoelectric battery by concentrated solar radiation versus the time of day in the middle of July and January are provided. It is shown that the output voltage increases up to the maximum values of 635 and 780 mV, respectively, in January and in July were achieved due to the temperature stabilization of the back side of the external electrodes of the proposed device

Published

2021

11. Simulation of Tandem Thin-Film Solar Cell on the Basis of CuInSe2

Author

Kuleshov Vladimir K, V. A. Potachits, G. L. Zykov, and A. K. Esman

Subjects

Materials science, 020209 energy, Energy Engineering and Power Technology, 02 engineering and technology, substrate, law.invention, temperature gradient, comsol multiphysics, Operating temperature, thermoelectric layer, law, Thermoelectric effect, Solar cell, 0202 electrical engineering, electronic engineering, information engineering, cuinse2 thin-film solar cell, Power density, Renewable Energy, Sustainability and the Environment, business.industry, Photovoltaic system, photoelectric converter, Hydraulic engineering, 021001 nanoscience & nanotechnology, Engineering (General). Civil engineering (General), solar concentrator, Temperature gradient, Solar cell efficiency, Nuclear Energy and Engineering, numerical simulation, Heat transfer, Optoelectronics, temperature stabilization, TA1-2040, 0210 nano-technology, business, TC1-978

Abstract

CuInSe2 thin-film solar cells are promising materials for photovoltaic devices. One of the main tasks of researchers is to find ways to increase the solar cells efficiency. In this paper we propose an original structure of a thin-film solar cell based on a tandem connection of a photoelectric converter and a thermoelectric layer based on CuInSe2. The photoelectric converter consists of CuInSe2 and CdS layers. A 3D model of the proposed thin-film solar cell was implemented in the COMSOL Multiphysics environment with using the Heat Transfer module. The simulation was carried out taking into account the diurnal and seasonal variations of both the ambient temperature and the power density of the AM1.5 solar spectrum for the geographical coordinates of Minsk. The solar radiation power density of about 500 kW/m2 can be achieved by using concentrators. The temperature pattern and temperature gradients are calculated in each layer of the solar cell without and with the temperature stabilization of the substrate back side as well as without and with the thermal insulation of the substrate ends. Graphs of the temperature gradients of the thermoelectric layer and the temperature variations of the photoelectric converter of the solar cell are given. As a result of the simulation, it is shown how the uneven heating of both the surface of a thin-film solar cell and its layers occur under conditions of diurnal and seasonal variations of both the ambient temperature and the solar radiation power density. Under concentrated solar radiation exposure, the photoelectric converter surface can be heated up to 700 °C without temperature stabilization of the solar cell substrate. The operating temperature of the photoelectric converter was maintained at no more than 2.35 °C in January and at no more than 14.23 °C in July due to the temperature stabilization of the substrate back side of the proposed device. This made it possible to achieve an increase in the output power of the solar cell both by summing the photoand thermoelectric output voltages and by the concentration of solar radiation.

Published

2018

12. High-efficiency infrared receiver

Author

V. A. Potachits, G. L. Zykov, V. I. Kostenko, N. I. Mukhurov, and A. K. Esman

Subjects

Electromagnetic field, Engineering, business.industry, HFSS, Потери на отражение, reflection losses, Schottky diode, Электроды эллиптической выпукло-вогнутой формы, ЭЛЕКТРОДЫ ЭЛЛИПТИЧЕСКОЙ ВЫПУКЛО-ВОГНУТОЙ ФОРМЫ,ПОТЕРИ НА ОТРАЖЕНИЕ,КОЭФФИЦИЕНТ СТОЯЧЕЙ ВОЛНЫ,КОЭФФИЦИЕНТ НАПРАВЛЕННОГО ДЕЙСТВИЯ, Engineering (General). Civil engineering (General), Коэффициент направленного действия, Directivity, Electromagnetic radiation, Optics, voltage standing wave ratio, Optoelectronics, Коэффициент стоячей волны, electrodes of the elliptical convex-concave shape, directivity, Standing wave ratio, TA1-2040, business, Microwave, Diode

Abstract

Исследования и разработки последних лет показывают перспективность использования высокоэффективных твердотельных приемников электромагнитного излучения на основе низкобарьерных диодов Шоттки. Особенно активно развивается подход к конструированию приемников на основе δ-легированных низкобарьерных диодов Шоттки с балочными выводами без смещения, так как для неохлаждаемых приемников микроволнового излучения у них практически нет конкурентов. Целью работы являлось улучшение основных параметров и характеристик, определяющих практическую востребованность приемников электромагнитного излучения среднего инфракрасного диапазона длин волн, работающих при температурах, близких к комнатной, за счет изменения конфигурации электродов диода и оптимизации расстояния между ними. Предложенное оригинальное конструктивное решение интегрального приемника среднего диапазона ИК-излучения на основе низкобарьерных диодов Шоттки с балочными выводами позволяет эффективно корректировать его основные параметры и характеристики. Моделирование электродинамических характеристик предложенного приемника, используя программный пакет HFSS, с базовым алгоритмом метода конечных элементов, реализованным для расчета поведения электромагнитных полей на произвольной геометрии с предварительно заданными свойствами материалов, показало: что при выполнении внутренних частей электродов низкобарьерного диода Шоттки в виде концентрической эллиптической выпукло-вогнутой формы можно достичь снижения потерь на отражение до -57,75 дБ и уменьшения коэффициента стоячей волны до 1,003 при одновременном увеличении коэффициента направленного действия до 23 на длине волны 6,09 мкм. При этом радиусы закруглений внутренних частей анодного и катодного электродов составляли 212 нм и 318 нм соответственно, а зазор между ними 106 нм. Указанные параметры позволят повысить эффективность разрабатываемой инфракрасной перспективной оптикои радиоэлектронной аппаратуры различного целевого назначения, предназначенной для работы в среднем инфракрасном диапазоне длин волн., Recent research and development show promising use of high-performance solid-state receivers of the electromagnetic radiation. These receivers are based on the low-barrier Schottky diodes. The approach to the design of the receivers on the basis of delta-doped low-barrier Schottky diodes with beam leads without bias is especially actively developing because for uncooled receivers of the microwave radiation these diodes have virtually no competition. The purpose of this work is to improve the main parameters and characteristics that determine the practical relevance of the receivers of mid-infrared electromagnetic radiation at the operating room temperature by modifying the electrodes configuration of the diode and optimizing the distance between them. Proposed original design solution of the integrated receiver of mid-infrared radiation on the basis of the low-barrier Schottky diodes with beam leads allows to effectively adjust its main parameters and characteristics. Simulation of the electromagnetic characteristics of the proposed receiver by using the software package HFSS with the basic algorithm of a finite element method which implemented to calculate the behavior of electromagnetic fields on an arbitrary geometry with a predetermined material properties have shown that when the inner parts of the electrodes of the low-barrier Schottky diode is performed in the concentric elliptical convex-concave shape, it can be reduce the reflection losses to -57.75 dB and the standing wave ratio to 1.003 while increasing the directivity up to 23 at a wavelength of 6.09 μm. At this time, the rounded radii of the inner parts of the anode and cathode electrodes are equal 212 nm and 318 nm respectively and the gap setting between them is 106 nm. These parameters will improve the efficiency of the developed infrared optical-promising and electronic equipment for various purposes intended for work in the mid-infrared wavelength range.

Published

2016