Keywords cloud
3 , Solod S. М., Solod S. М., Solod S. М., Solod S. М., Solod S. М., Solod S. М., Solod S.
]]>26. State of the Art and Prospects for Nuclear-Quadrupole Resonance Thermometry in Ukraine
Organization:
Yangel Yuzhnoye State Design Office, Dnipro, Ukraine1; Ivan Franko National University of Lviv, Lviv, Ukraine2; Research and Production Center for Standartization, Metrology, Lviv, Ukraine3
Page: Kosm. teh. Raket. vooruž. 2017 (2); 146-150
Language: Russian
Annotation: The information is presented on the development of nuclear quadrupole resonace thermometry instruments at Yuzhnoye SDO and other Ukrainian companies. The problems are analyzed arising at the creation of standard wide-band nuclear quadrupole resonance temperature meters, the ways to overcome them, and the possibilities of improving due to the use of modern integrated electronics. It is shown that the methods of building the instruments based on nuclear quadrupole resonance proposed and implemented in Ukraine are not inferior to the foreign ones.
Key words:
Bibliography:
1. Dehmelt H. G., Krüger H. Kurze Originalmitteilungen. Kernquadrupolfrequenzen in festem Dichloräthylen. Naturwiss. No. 37. 1950. P. 111–112.
2. Bayer H. On the Theory of Spin-lactice Relaxation in Molecular Crystals. J. Phys. 1951. Vol. 129, No. 4. P. 227-238.
3. Lenovenko A. M. Quantum Portable Working Frequency Standard / А. М. Lenovenko, V. V. Parakuda, N. O. Koval’chuk. The ІХ International Scientific-Technical Conference “Gyro Technologies, Navigation, Motion Control, and Aerospace Hardware Designing” (Ukraine, Kyiv, 17–18 April, 2013): Proceedings, Part 1. К., 2013. P. 218–223.
4. Benedek G. B., Kushida T. Precise Nuclear Resonance Thermometry. The Review of Scientific Instruments. 1957. Vol. 28, No. 2. P. 92-95.
5. Vanier J. Temperature Dependence of the Pure Nuclear Quadrupole Resonance Frequency in KClO3. Canadian Journal of Physics. 1960. Vol. 38, No. 11. P. 1397-1405.
6. Utton D. B. Nuclear Resonance Thermo-metry. Metrologia. 1967. Vol. 3, No. 4. P. 98-104.
7. NQR standard Thermometer (model 2571). Catalogue of Yokogawa Electric Works. Japan, 1983.
8. Ohte A., Iwaoka H. A Precision on Nuclear Quadrupole Resonance Thermometer. IEEE Trans. on Instrum. аnd Measurement. 1976. Vol. IM-25, No. 4. P. 357-362.
9. Ohte A., Iwaoka H. Accurate Calibration A Precision of New NQR Thermometer (203 K to 398 K Range Calibration at the NRML). Metrologia. 1979. Vol. 15, No. 4. P. 195–199.
10. Utton D. B. Sample purity and the N.Q.R. of Cl35 in KClO3 at 0-C. J. Res. NBS. 1967. 71A. P. 125.
11. Lenovenko A. M., Koval’chuk N. O. Standard Nuclear-Quadrupole Resonance Thermometer YaKRT-5M. Proceedings of VІІ International Scientific-Technical Conference “Metrology and Measuring Instruments ” (Metrology 2010) in 2 volumes (Kharkiv, 12-14 October, 2010). P. 247-250.
12. Lenovenko A. Measuring Complex for Calibration, Checking and Certification of Temperature Measurement Instruments Based on Standard Nuclear-Quadrupole Thermometer of First Class YaKRT-5M / А. Lenovenko, B. Stadnik, P. Stolyarchuk, V. Parakuda, N. Koval’chuk. Measuring Instruments and Metrology. Lviv, 2013. No. 74. P. 127-132.
13. Lenovenko A. M. Theoretical and Experimental Investigations of Super-Regenatory Detectors of Nuclear Quadrupole Resonance / Dissertation of Candidate of Physical and Mathematical Sciences. Lviv, 1971. 136 p.
14. Vasilyuk V. et al. Nature of Signal in Super-Regenatory Detectors of Nuclear Quadrupole Resonance / Vasilyuk V., Lenovenko А., Stolyarchuk P. Measuring Instruments and Metrology. 2005. No. 65. P. 7–10.
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, Solod S. D., Solod S. D., Solod S. D., Solod S. D., Solod S. D., Solod S. D., Solod S.
]]>13. Experience of Developing Thermometric Instruments Based on Nuclear Quadrupole Resonance
Organization:
Yangel Yuzhnoye State Design Office, Dnipro, Ukraine
Page: Kosm. teh. Raket. vooruž. 2016 (2); 80-84
Language: Russian
Annotation: The paper describes development of the devices for the nuclear quadrupole resonance thermometry at Yuzhnoye SDO and other Ukraine’s enterprises and considers capabilities of the enterprises to manufacture such devices. Also given is refined analytical dependence for temperature calculation using the frequency of the nuclear quadrupole resonance in Bertholette salt within the ±40°C temperature range.
Key words:
Bibliography:
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, Solod S. Solod S. V., Solod S. V., Solod S. V., Solod S. V., Solod S. V., Solod S. V., Solod S.
]]>23. Calculation of Thermal-Physical Properties of Gaseous Xenon
Organization:
Yangel Yuzhnoye State Design Office, Dnipro, Ukraine
Page: Kosm. teh. Raket. vooruž. 2019, (1); 154-162
DOI: https://doi.org/10.33136/stma2019.01.154
Language: Russian
Annotation: This article contains information on the calculation of the thermodynamic and translational properties of the gaseous xenon in the amount sufficient for the most engineering applications. The equation of state of xenon was obtained in dimensionless form, enabling calculations of the thermodynamic values using already known methods, developed for the air and other extensively used gases. An example is made on the implementation of the method based on this equation for calculation of the density, enthalpy and entropy of the gaseous xenon. The accuracy of calculation of these properties in the temperature range from 300 to 3000 K from 0,1 up to 120 MPa pressure was from 0,2 to 1,6%. Sufficiently accurate and simple dependencies were obtained for calculation of the enthalpy and heat of vaporization at the saturation line. Accuracy of the enthalpy calculation of the liquid xenon at the saturation line is not below 0,2%, the accuracy of the calculation of the heat of vaporization is not below 0,5%. New, simpler method, as compared to standard reference data, to calculate the translational properties (thermal conductivity, viscosity) of xenon at atmospheric pressure has been proposed. It is shown that thermal conductivity and viscosity can be calculated from the expression of the same type with different coefficients. Accuracy of the calculation of these properties using the proposed method is not below 2,2%. Considering the unsatisfactory test results of the well-known methods of calculation of the translational properties at high pressures, the effective method for approximating the table values of these properties has been proposed. In this case, at first, the temperature data at fixed pressures are approximated, then using these approximations, the values of the properties are calculated at the given temperature and various pressure values. After this, the value of the property is interpolated at the given high pressure. As an example of the implementation of this method, the Mathcad software for calculations of the thermal conductivity of gaseous xenon at high pressure is given. The materials of the article are intended for the specialists dealing with heat exchange processes.
Key words: gas, equation of state, thermodynamic properties, thermophysical properties, thermal conductivity, viscosity
Bibliography:
1. Teplophysicheskie svoistva neona, argona, kriptona i xenona / Pod red. V. A. Rabinovicha. M.: Izd-vo standartov, 1976. 636 p.
2. Solod S. D. Raschety teplophysicheskykh svoistv sukhogo vozdukha. K.: Nauk. dumka, 2006. 49 p.
3. Teplophysicheskie svoistva technicheski vazhnykh gasov pri vysokikh temperaturakh I davleniyakh: Spravochnik / V. N. Zubarev, A. D. Kozlov, V. M. Kuznetsov i dr. M.: Energoatomizdat, 1989. 232 p.
4. Teplophysicheskie svoistva gazov i zhidkostyey: Spravochnik/ N. B. Vargaftik. М.: Nauka, 1972. 721 p.
5. Šifner O., Klomfar J. Thermodynamic Properties of Xenon from the Triple Point to 800 K with pressures up to 350 MPa // Kosmicheskaya technika. Raketnoe vooruzhenie. Space Technology. Missile Armaments. 2019. Vyp. 1 (117) 162 J. Phys. Ret. Data. Vol. 23, №1. 1994. P. 63-118. https://doi.org/10.1063/1.555956
6. GSSSD 17-81, Dinamicheskaya vyazkost’ i teploprovodnost’ geliaya, neona, argona, kriptona i xenona pri atmosfernom davlenii v intervale temperatur ot normalnykh tochek kipenia do 2500 K: Ofits. izd. M.: Izd-vo standartov, 1982.
7. Vyazkost’ gazov I gazovykh smesey: Spravochnoe rukovodstvo/ I. F. Golubev. M.: Pfysmatlit, 1959. 375 p.
8. Svoiskiy V. Z. Vyazkost’ i teploprovodnost’ gazov v diapazone temperatur ot 100 do 2000 K / Uchenye zapiski TsAGI. T. IV, №1. 1973. P. 126-132.
9. Basa dannykh po teplophysicheskim svoistvam gazov I ikh smesey, ispolzuemykh v YaEU / NIYaU MIFI “Rosatom”. Rezhim dostupa: http://www.gsssd-rosatom.mephi.ru// DB-tp-02/xe.php .
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