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Статті в журналах з теми "Magnetic-pulse installation"
1
Ljutenko, L. A., and V. M. Mikhailov. "Expansion of cylindrical tubular workpieces on high-voltage magnetic-pulse installation with controlled vacuum discharger." Electrical Engineering & Electromechanics, no. 3 (June 23, 2021): 42–46. http://dx.doi.org/10.20998/2074-272x.2021.3.07.
Повний текст джерелаАнотація:
Purpose. An experimental verification of the existence of a range of values for the parameters of the capacitive energy storage of the magnetic-pulse installations with controlled vacuum discharger, in which, with a high probability, there is a «cut» of the discharge current pulses and the expansion of cylindrical thin-walled tubular workpieces using an external coil. Methodology. High voltage magnetic-pulse installation of NTU «KhPI» with controlled vacuum discharger, multiturn coil with inside dielectrical die and inside aluminum alloy workpiece are used. The capacitance and charge voltage of capacitive energy storage are changed. Discharge current pulses are measured by Rogowski coil and the oscillograph. Results. Parts of complicated shape are made by expansion of cylindrical tubular workpieces with help of external coil. Pressed metallic tubular part is removable from inner dielectric rod. Originality. The frequency of «cut» pulse is defined by negative magnetic field pressure amplitude. It is shown that we must coordinate this frequency and charge voltage with capacitive storage parameters by high probability of pulse «cut». Practical value. It is shown how to use installations with controlled vacuum dischargers in magnetic forming technology based on «cut» pulses.
2
Batygin, Yu V., S. O. Shinderuk, E. O. Chaplygin, and D. V. Fendrikov. "DOUBLE-CIRCUIT RESONANT ELECTRIC POWER AMPLIFIER FOR MAGNETIC-PULSE PROCESSING OF METALS." Tekhnichna Elektrodynamika 2022, no. 3 (May 23, 2022): 29–36. http://dx.doi.org/10.15407/techned2022.03.029.
Повний текст джерелаАнотація:
The authors propose and substantiate the functionality of a magnetic-pulse installation consisting of two blocks, the first of which is a resonant double-circuit charger of a capacitive energy storage, and the second block is a discharge circuit with an inductor-tool for performing a given production operation. It is shown that the voltage changes in time according to an exponentially growing harmonic law. It was found that the amplitude of the voltage across the capacitor can be regulated by varying the characteristics of the coupling transformer between the circuits and the characteristics of the circuit of the reactive power conversion unit. Numerical assessments of the characteristics of the charging process showed a high efficiency of voltage formation on the capacitive storage due to resonance phenomena (the transformation ratio is equal to the Q-factor of the circuit ~ 20), which is not comparable with the well-known traditional indicators of induction methods. In terms of phase – the length in time to the maximum charge in the adopted circuit of the active electric power amplifier is set by the inequality - That is, after ~ 30 periods of charging current, the excited voltage reaches a maximum (~ 20 times higher than the source voltage), which will correspond to the end of the transient process and the establishment of a steady state of operation. An example of calculating the characteristics of an elementary resonant base illustrates the effective capabilities of a magnetic-pulse installation, consisting of a resonant charger of a capacitive energy storage and a load in the form of an inductor-tool for flat stamping of metal products. It was found that the square of the ratio of operating frequencies in the load unit and the reactive power amplification unit quantitatively determines the fundamental possibility of resonant amplification of the active electrical energy of a harmonic signal. References 12, figures 5.
3
Alifanov, A. V., D. A. Tsionenko, A. M. Miliukova, A. I. Harchanin, and V. V. Maleronak. "SPECIAL FEATURES OF MAGNETIC PULSE HARDENING PROCESSING OF STEEL CYLINDRICAL PRODUCTS OF VARIABLE CROSS-SECTION." Litiyo i Metallurgiya (FOUNDRY PRODUCTION AND METALLURGY), no. 2 (July 4, 2017): 88–96. http://dx.doi.org/10.21122/1683-6065-2017-2-88-96.
Повний текст джерелаАнотація:
The calculations of the magnetic field induction and the magnetic field intensity were carried out by the Finite Element Method (FEM) with the use of the software FEMM. The cylindrical inductor of the Magnetic-Pulse Installation (MPI) generates the magnetic field near the surface of the cylindrical steel product as of the uniform as well as variable cross section. It is shown that the regions of the products of the complex cross-section located at the minimal distance to the helix inductor are exposed to highest level of hardening. It is necessary to increase the current pulse in the inductor or to use a split inductor with the variable inner diameter repeating the product profile for hardening of the product regions located at large distances from inductor. The side surfaces of protrusions that are perpendicular to the axis of the system are not exposed to hardening due to the low gradient of the energy density of magnetic field near its surface. In the case of close proximity of the protrusions (for distance less than 1 cm), the material on the product surface in the space between protrusions is not exposedto sufficient hardening.
4
Sudenkov, Yuri V., Svetlana Atroshenko, Ivan Smirnov, Natalya Naumova, and Xue Yin Sun. "Investigation of High-Speed Loading Effects on the Properties of Ferromagnetic Alloys Processed in an External Magnetic Field." Applied Mechanics and Materials 566 (June 2014): 542–47. http://dx.doi.org/10.4028/www.scientific.net/amm.566.542.
Повний текст джерелаАнотація:
The behavior of the ferromagnetic alloy based on Fe-Cr-Co under high-speed loading is presented. Three types of samples were prepared with different pre-treatments: quenching only; quenching and ageing; and quenching and ageing under an intense external magnetic field. The sub-microsecond impact load was created by the installation for the electrical explosion of foils. The developed method of loading allows a pressure pulse to be registered before impact on a flat sample and after its exit to a free surface of this sample. Changes in the mechanical properties of the ferromagnetic alloy with various technologies of preliminary processing before and after shock loading are discussed.
5
Glushchenkov, V. A., L. T. Volova, I. A. Belyaeva, V. V. Boltovskaya, V. V. Rossinskaya, A. I. Ignatenko, I. F. Nefedova, and L. N. Kulagina. "ACTION OF A HIGH-INTENSITY PULSED MAGNETIC FIELD ON A HUMAN DERMAL FIBROBLASTS IN CULTURE." Izvestiya of Samara Scientific Center of the Russian Academy of Sciences 22, no. 5 (2020): 14–22. http://dx.doi.org/10.37313/1990-5378-2020-22-5-14-22.
Повний текст джерелаАнотація:
The influence of pulsed magnetic fields (PMF) with different values of field intensity H, discharge current frequency f and a number of pulses n on dermal fibroblasts was studied in vitro. A specialized pulse-magnetic installation «PMI-Bio» and a measuring stand for creating and monitoring the specified parameters of the PMF were created. Four series of experiments with longitudinal and transverse action of the PMF at a field intensity of 3.76⋅106 – 8.7⋅106 A/m (500 and 1000 J) were carried out. It was found that the longitudinal action of the PMF at 500 J does not lead to cell death, preserves all their structural components, and is safe for primary fibroblast cultures. The use of high-intensity pulsed magnetic fields (HI PMF) at 1000 J in both longitudinal and transverse directions leads to a violation of cell adhesion to the culture plastic and changes in the structure of dermal fibroblasts, up to their death.
6
Titov, M., G. Nepomnyashchev, and D. Dorofeeva. "Application of electro-hydraulic shock in concrete technology." Journal of Physics: Conference Series 2131, no. 5 (December 1, 2021): 052002. http://dx.doi.org/10.1088/1742-6596/2131/5/052002.
Повний текст джерелаАнотація:
Abstract The aspects, related to the influence of the electrohydraulic shock method use in a water-cement slurry passing in a closed chamber (activation reactor) with a pre-applied pressure to the system under various processing modes are highlighted in the article. In order to test the effect of this method on water-cement slurry, an installation was developed, consisting of: a high-voltage source, a high-voltage diode, capacitor banks, a closing element and an activation reactor. The necessary experiments were carried out on the completed installation. The procedure for conducting experiments is described in the work, shows a schematic diagram of the installation for performing activation, a diagram of the reactor, and the processing modes. Several activation modes were considered, depending on: the number of pulses (1-4), pulse energy (0.5-8 kJ), water-cement ratio (0.2-0.35), time intervals for starting treatment from the moment the cement was mixed with water (0 -120 minutes), volume and shape of the container (activation reactor), holding temperature (20-60°C), etc. According to the results of the data obtained, it was experimentally established that the use of electric pulse treatment of water-cement suspension has a positive effect on strength (cup compressive strength) indicators, obtained as a result of processing cement stone samples at different times of hardening (1-3 days). The compressive strength of the treated specimens’ increases in comparison with the untreated specimens, increase in strength reaches up to 45%, depending on the activation mode. The resulting effect was achieved due to many factors (high pressure, magnetic, temperature, energy, ultrasonic and other influences), which were applied in the most optimal period of time (stage) of the cement grain hydration process.
7
Baev, A. R., A. I. Мitkovets, M. V. Asadchaya, and A. L. Mayorov. "Impulsively-Laser Excitation and Propagation of Ultrasonic Waves through Nanomagnetic Fluid." Devices and Methods of Measurements 12, no. 3 (October 15, 2021): 211–19. http://dx.doi.org/10.21122/2220-9506-2021-12-3-211-219.
Повний текст джерелаАнотація:
Magnetic fluids belong to the class of nanomaterials with a high gain of light absorption, aggregative and sedimentation stability as well as controllability by external fields, which is of interest to use in the field of optoacoustics. The purpose of the work was to experimentally study the effect of the optoacoustic transformation in a magnetic fluid, depending on the concentration of magnetic colloidal particles, boundary conditions, intensity of the laser as well as to identify the possibilities of using the magnetic fluid as an element of the optoacoustic transformation in a number of applications.A brief analysis of the optoacoustic transformation mechanism in a magnetic fluid was carried out and a technique and an installation that implements the shadow measurement variant developed. A Lotis type laser was used as a source of ultrasonic pulse-laser excitation in magnetic fluids. A quartz and air were used as a material transmitting the energy of laser radiation in a magnetic fluid. Receiving of ultrasound signals was made by a piezoelectric probe at a working frequency of 5 MHz. In the measurement process, the concentration of the dispersed phase in tmagnetic fluid was varied from zero to 8 % and the energy in the impulse – from zero to 10 mJ.For the first time, it was established that: a) an amplitude of the function of the optoacoustic transformation in a magnetic fluid, depending on the concentration of the dispersed phase, has a maximum determined by the fluid physical properties and boundary conditions; b) for all samples within the measurement error, a quasilinear dependence of the specified amplitude of energy in the laser pulse in the range of 0–8 MJ has been established.A number ways of the optoacoustic effects in magnetic fluids to use in ultrasonic testing, measuring the intensity of the laser radiation had been suggested.
8
Sanchez, Francisco, Ferran Albajar, Alessandro Lo Bue, Stephano Alberti, Konstantinos Avramidis, Tullio Bonicelli, Alex Bruschi, et al. "Metrology techniques for the verification of the alignment of the EU gyrotron prototype for ITER." EPJ Web of Conferences 203 (2019): 04015. http://dx.doi.org/10.1051/epjconf/201920304015.
Повний текст джерелаАнотація:
The EU gyrotron for the ITER Electron Cyclotron (EC) heating system has been developed in coordinated efforts of the EGYC Consortium, Thales ED (TED) and Fusion for Energy (F4E) and under the supervision of ITER Organization Central Team. After the successful verification of the design of the 1MW, 170 GHz hollow cylindrical cavity gyrotron operating at the nominal TE32,9 mode with a short pulse gyrotron prototype at KIT, an industrial CW gyrotron prototype was manufactured by TED and tested at ~0.8 MW output power and 180 s pulse duration, which is the limit of the HV power supply currently available at KIT. The experiments are being continued at SPC in 2018 to extend further the pulse duration, taking advantage of the existing CW full-power capabilities of the gyrotron test facility recently upgraded for the FALCON project. The gyrotron cavity interaction is very sensitive to the alignment of the internal mechanical parts of the gyrotron tube with the magnetic field generated by the superconducting magnet within a typical range of 0.2 – 0.5 mm. The control of the tolerances and deformations becomes therefore critical to achieving the target performances. With the EU gyrotron prototype it was possible to adjust the alignment of the gyrotron tube with respect to the magnetic field axis during the installation and commissioning phase. The actual shift and tilt movements were verified using advanced metrology methods such as photogrammetry. In this paper, the alignment control techniques and procedures will be discussed also in view of enhancing the reproducibility of gyrotron performance during series production.
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Zlobin, D. V., and L. V. Volkova. "INFLUENCE OF DYNAMIC MAGNETIZATION TO IMPROVE THE EFFICIENCY OF ELECTROMAGNETIC-ACOUSTIC TRANSFORMATION WITH WAVEGUIDE CONTROL RODS." Devices and Methods of Measurements 8, no. 3 (September 27, 2017): 236–45. http://dx.doi.org/10.21122/2220-9506-2017-8-3-236-245.
Повний текст джерелаАнотація:
The disadvantage of the electromagnetic-acoustic (EMA) method receiving ultrasonic waves are low efficiency. The traditional way to enhance its effectiveness is increase the bias field. The aim of the study was research the way to improve the efficiency of the EMA transformation, using a time-varying bias field.The researches held with the help of a specially designed installation that allows the magnetization to be performed by a constant and alternating magnetic field (dynamic bias), synchronously with the passage of the received pulse. The object of the study were rods made of different grades of steel with a diameter of 4–6 mm, in which the symmetrical zero mode S0 of the rod wave was excited by the EMA method (in the frequency range of about 40 kHz). A comparative analysis of the amplitudes and form pulses of multiple reflections during static and dynamic reversal of magnetization and with a full cycle of magnetization reversal conducted.The result of the efficiency measurements EMA reception during static and dynamic bias found a significant (up to 5 times) increase in the signal amplitude on the receiving transducer. Taking into account that the main contribution to the excitation mechanism and the reception mechanism made the magnetostrictive effect on low frecuncy, it can assumed that using a dynamic bias field is impacting significant on the effective mobility of magnetic domains (that is changes the dynamic magnetic susceptibility of the material). It is established that it is possible to monitor steel at lower values of the bias field, and, consequently, to reduce the mass dimensions of the magnetic system.Thus, in the course of the researchers found of effect of dynamic bias and effect of dynamic bias increase acoustic pulse amplitude of the signal of the received EMA method. Using this method will improve the quality EMA testing by creating more efficient EMA transducer. Taking into account that the value of the detected effect depends significantly on the steel grade, we can assume its possible application in the methods of express analysis, estimation of structural and stressed states.
10
Smeibidl, Peter, Karel Prokes, Mark Bird, Oleksandr Prokhnenko, Hartmut Ehmler, and David Tennant. "The High Magnetic Field Magnet for Neutron Studies at Helmholtz Zentrum Berlin." Acta Crystallographica Section A Foundations and Advances 70, a1 (August 5, 2014): C164. http://dx.doi.org/10.1107/s2053273314098350.
Повний текст джерелаАнотація:
High magnetic fields can create exotic states which challenge our basic understanding of matter. This requires a deep and precise knowledge of the spatial ordering of atoms and associated magnetic moments. Particularly interesting would be to disclose magnetic field dependency of various fluctuations and collective modes. Such information can be obtained from neutron scattering experiments. The Helmholtz Zentrum Berlin (HZB) is known for its sample environment that is available for both internal and external users. Presently, a project that combines dedicated scattering instrument (EXED) with a horizontal hybrid solenoid magnet with tapered 300cones is being finalized at HZB. To achieve an optimal performance, a 13 T superconducting Nb3Sn cable-in-conduit coil is combined with resistive insert coils of 12 T to 18 T (see figure), depending on electric power (between 4.4 and 8.0 MW), to give a maximum of 25 to 31 T. The magnet that has been developed in collaboration with the National High Magnetic Field Laboratory of Florida State University, Tallahassee, FL, USA [1] provides a 50 mm diameter room temperature bore. For sample cooling a 3He cryostat with a pulse tube precooling stage is being developed. The magnet will be permanently mounted at the dedicated time-of-flight instrument EXED at the end of a multispectral neutron guide NL4a, about 76 m away from the neutron source. The EXED instrument is optimized for diffraction under restricted geometrical conditions and is being upgraded to include inelastic option. This unique experimental setup is supposed to play a major role in high-field neutron studies and should be ready for use in early 2015. The contribution describes not only the most important design features of the system, the outline of the building for the technical infrastructure and the status of the installation and commissioning but also the scientific possibilities and limitations of the setup.
Дисертації з теми "Magnetic-pulse installation"
1
Сабокар, Олег Сергійович. "Удосконалення магнітно-імпульсного обладнання для технологій ремонту транспортних засобів". Thesis, Харківський національний автомобільно-дорожній університет, 2018. http://repository.kpi.kharkov.ua/handle/KhPI-Press/39634.
Повний текст джерелаАнотація:
Дисертація на здобуття наукового ступеня кандидата технічних наук за спеціальністю 05.09.13 – техніка сильних електричних та магнітних полів. Національний технічний університет "Харківський політехнічний інститут", Харків 2019.
Дисертація присвячена вирішенню завдання поліпшення технічних показників обладнання магнітно-імпульсної обробки металів (міоми) для використання в технологіях металообробки і технологіях ремонту транспортних засобів. У роботі представлена розробка альтернативної конструкції вузла заряду ємнісних накопичувачів енергії та розробка системи індукційного нагріву. Дано числові показники нагріву при варіації часових параметрів збуджуючого струму і конструктивних параметрів інструменту індуктора. Розглянута модель системи збудження струму індуктора доповнена експериментальними дослідженнями системи в режимі резонансу напруги. Запропоновано використання модифікованої часової форми біполярного меандру сигналу збудження для зменшення кількості спектральних складових. Сконструйована система індукційного нагріву, що працює в режимі резонансу напруги, показала свою працездатність і ефективність. Було запропоновано виконувати збудження коливань струму імпульсами напруги модифікованої форми з частотою нижче на 20% від резонансної частоти, що забезпечує прийнятний ККД в режимі роботи системи без навантаження. Розробка система індукційного нагріву пройшла апробацію і випробування на підприємствах "Веда Авто Сервіс" (м. Київ) і АТ "Елеватормлинмаш" (м. Харків). Результати дисертаційної роботи використовують при підготовці бакалаврів та магістрів на кафедрі автомобільної електроніки Харківського національного автомобільно-дорожнього університету.Thesis for the degree of Candidate of Technical Sciences for specialty 05.09.13 "Equipment of strong electric and magnetic fields" – National Technical University "Kharkiv Polytechnic Institute". Kharkiv, 2019. The thesis is dedicated to the solution of the problem of the technical performance of magnetic-impulse metal processing equipment improving for use in metal-working technologies and vehicle repair technologies. The paper presents the development of an alternative design for the capacitive energy storage charge system and the development of an induction heating system. The numerical heating indicators was given with a variation of the time parameters of the exciting current and the design parameters of the inductor tool. The system model of inductor current excitation in the mode of current resonance was considered and supplemented by experimental studies of the system in voltage resonance mode. The use of a modified time form of the bipolar meander of the excitation signal to reduce the number of spectral components was proposed. The induction heating system designed that operates in the voltage resonance mode has shown its efficiency. It was proposed to perform the excitation of current oscillations by voltage pulses of the modified form with a frequency lower than 20% of the resonant frequency, which ensures acceptable efficiency in the system operation without load. The development of the induction heating system has been tested and implicated at the enterprises of "Veda Auto Service" (Kyiv) and "Elevatormlinmash" (Kharkiv). The results of the thesis are used in the preparation of bachelors and masters degree at the department of automobile electronics of the Kharkiv National Automobile and Highway University.
2
Сабокар, Олег Сергійович. "Удосконалення магнітно-імпульсного обладнання для технологій ремонту транспортних засобів". Thesis, Національний технічний університет "Харківський політехнічний інститут", 2019. http://repository.kpi.kharkov.ua/handle/KhPI-Press/39631.
Повний текст джерелаАнотація:
Дисертація на здобуття наукового ступеня кандидата технічних наук за спеціальністю 05.09.13 – техніка сильних електричних та магнітних полів. Національний технічний університет "Харківський політехнічний інститут", Харків 2019.
Дисертація присвячена вирішенню завдання поліпшення технічних показників обладнання магнітно-імпульсної обробки металів (міоми) для використання в технологіях металообробки і технологіях ремонту транспортних засобів. У роботі представлена розробка альтернативної конструкції вузла заряду ємнісних накопичувачів енергії та розробка системи індукційного нагріву. Дано числові показники нагріву при варіації часових параметрів збуджуючого струму і конструктивних параметрів інструменту індуктора. Розглянута модель системи збудження струму індуктора доповнена експериментальними дослідженнями системи в режимі резонансу напруги. Запропоновано використання модифікованої часової форми біполярного меандру сигналу збудження для зменшення кількості спектральних складових. Сконструйована система індукційного нагріву, що працює в режимі резонансу напруги, показала свою працездатність і ефективність. Було запропоновано виконувати збудження коливань струму імпульсами напруги модифікованої форми з частотою нижче на 20% від резонансної частоти, що забезпечує прийнятний ККД в режимі роботи системи без навантаження. Розробка система індукційного нагріву пройшла апробацію і випробування на підприємствах "Веда Авто Сервіс" (м. Київ) і АТ "Елеватормлинмаш" (м. Харків). Результати дисертаційної роботи використовують при підготовці бакалаврів та магістрів на кафедрі автомобільної електроніки Харківського національного автомобільно-дорожнього університету.Thesis for the degree of Candidate of Technical Sciences for specialty 05.09.13 "Equipment of strong electric and magnetic fields" – National Technical University "Kharkiv Polytechnic Institute". Kharkiv, 2019. The thesis is dedicated to the solution of the problem of the technical performance of magnetic-impulse metal processing equipment improving for use in metal-working technologies and vehicle repair technologies. The paper presents the development of an alternative design for the capacitive energy storage charge system and the development of an induction heating system. The numerical heating indicators was given with a variation of the time parameters of the exciting current and the design parameters of the inductor tool. The system model of inductor current excitation in the mode of current resonance was considered and supplemented by experimental studies of the system in voltage resonance mode. The use of a modified time form of the bipolar meander of the excitation signal to reduce the number of spectral components was proposed. The induction heating system designed that operates in the voltage resonance mode has shown its efficiency. It was proposed to perform the excitation of current oscillations by voltage pulses of the modified form with a frequency lower than 20% of the resonant frequency, which ensures acceptable efficiency in the system operation without load. The development of the induction heating system has been tested and implicated at the enterprises of "Veda Auto Service" (Kyiv) and "Elevatormlinmash" (Kharkiv). The results of the thesis are used in the preparation of bachelors and masters degree at the department of automobile electronics of the Kharkiv National Automobile and Highway University.
3
Веселова, Надія Вікторівна. "Становлення і розвиток харківських наукових шкіл у галузі техніки та електрофізика високих напруг (1930–2010 рр.)". Thesis, НТУ "ХПІ", 2015. http://repository.kpi.kharkov.ua/handle/KhPI-Press/17177.
Повний текст джерелаАнотація:
Дисертація на здобуття наукового ступеня кандидата історичних наук за спеціальністю 07.00.07 – історія науки і техніки. – Національний технічний університет "Харківський політехнічний інститут". – Харків, 2015. У дисертації комплексно досліджується створення та розвиток харківських наукових шкіл у галузі техніки та електрофізики високих напруг у 1930–2010 рр. В роботі визначені харківські наукові школи в цій галузі, а саме: наукова школа високовольтних прискорювачів в УФТІ, яку очолив академік АН УРСР А. К. Вальтер; наукова школа техніки високих напруг ХПІ, засновником якої став академік АН УРСР В. М. Хрущов; наукова школа магнітно-імпульсної обробки металів ХПІ, що була заснована проф. І. В. Білим. Проведено цілісний науково-історичний аналіз процесу виникнення технічних рішень в електрофізиці і створення установок високої напруги в провідних харківських наукових центрах. Розкрито процес формування складу наукових установ і лабораторій, внесок окремих вчених у розвиток техніки і електрофізики високих напруг в м. Харкові. Показана важливість та унікальність створених високовольтних установок, визначено передумови їх створення та досліджено застосування цих пристроїв у вітчизняній науці та промисловості.The thesis for the competition of the academic degree of the candidate of the historical sciences, the speciality 07.00.07 – The history of science and technique. – National Technical University "Kharkiv Polytechnic Institute". – Kharkiv, 2015. The thesis is devoted to the complex research of the establishment and the development of Kharkiv scientific schools in the field of the technique and the electrophysics of the high-voltages in 1930's – 2010's. In this work the Kharkiv scientific schools in this field were identified for the first time. They are: the scientific school of the high-voltage accelerators in the UFTI headed by academician of USSR A.K. Walter; the scientific school of the technique of high-voltages in the KhPI, the founder of which was the acacademician of the Academy of Sciences of USSR V. M. Khrushchev; the scientific school of magnetic-pulse treatment of metals in KhPI which was founded by professor I. V. Belii. A holistic scientific-historical analysis of the process of technical solutions in electrophysics and the creation of high-voltage installations in leading scientific centers of Kharkiv is carried out in this work. The importance and uniqueness of the high-voltage installations is shown here. The importance and the uniqueness of the high-voltage structures, the conditions of their creation usage in home industry and science are shown here.
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Веселова, Надія Вікторівна. "Становлення і розвиток харківських наукових шкіл у галузі техніки та електрофізика високих напруг (1930–2010 рр.)". Thesis, НТУ "ХПІ", 2015. http://repository.kpi.kharkov.ua/handle/KhPI-Press/17176.
Повний текст джерелаАнотація:
Дисертація на здобуття наукового ступеня кандидата історичних наук за спеціальністю 07.00.07 – історія науки і техніки. – Національний технічний університет "Харківський політехнічний інститут". – Харків, 2015.
У дисертації комплексно досліджується створення та розвиток харківських наукових шкіл у галузі техніки та електрофізики високих напруг у 1930–2010 рр. В роботі визначені харківські наукові школи в цій галузі, а саме: наукова школа високовольтних прискорювачів в УФТІ, яку очолив академік АН УРСР А. К. Вальтер; наукова школа техніки високих напруг ХПІ, засновником якої став академік АН УРСР В. М. Хрущов; наукова школа магнітно-імпульсної обробки металів ХПІ, що була заснована проф. І. В. Білим. Проведено цілісний науково-історичний аналіз процесу виникнення технічних рішень в електрофізиці і створення установок високої напруги в провідних харківських наукових центрах. Розкрито процес формування складу наукових установ і лабораторій, внесок окремих вчених у розвиток техніки і електрофізики високих напруг в м. Харкові. Показана важливість та унікальність створених високовольтних установок, визначено передумови їх створення та досліджено застосування цих пристроїв у вітчизняній науці та промисловості.The thesis for the competition of the academic degree of the candidate of the historical sciences, the speciality 07.00.07 – The history of science and technique. – National Technical University "Kharkiv Polytechnic Institute". – Kharkiv, 2015. The thesis is devoted to the complex research of the establishment and the development of Kharkiv scientific schools in the field of the technique and the electrophysics of the high-voltages in 1930's – 2010's. In this work the Kharkiv scientific schools in this field were identified for the first time. They are: the scientific school of the high-voltage accelerators in the UFTI headed by academician of USSR A.K. Walter; the scientific school of the technique of high-voltages in the KhPI, the founder of which was the acacademician of the Academy of Sciences of USSR V. M. Khrushchev; the scientific school of magnetic-pulse treatment of metals in KhPI which was founded by professor I. V. Belii. A holistic scientific-historical analysis of the process of technical solutions in electrophysics and the creation of high-voltage installations in leading scientific centers of Kharkiv is carried out in this work. The importance and uniqueness of the high-voltage installations is shown here. The importance and the uniqueness of the high-voltage structures, the conditions of their creation usage in home industry and science are shown here.