Statistical Express Control of the Peak Values of the Differential-Thermal Analysis of Solid Materials

Andriy Semenov; Serhii Baraban; Olena Semenova; Oleksandr Voznyak; Andrii Vydmysh; Leonid Yaroshenko

doi:10.4028/www.scientific.net/SSP.291.28

Paper Titles

Evaluation of Wear Properties of Stir Cast AA7050 -10% B₄C Ex Situ Composite through Fuzzy-TOPSIS MCDM Method
p.1

The Elaboration of Modernized Technology of Controlled Rolling Directed at the Formation of High Strengthening and Viscous Qualities in HSLA Steel
p.13

Porous Structures and their Effect on Thermophysical Properties of Thermal Protection Elements
p.20

Statistical Express Control of the Peak Values of the Differential-Thermal Analysis of Solid Materials
p.28

Influence of Overheating and Cooling Rate on the Structure and Physicochemical Properties of Al-Cu Alloys
p.42

Characteristic of Possible Obtained Products during the well Underground Coal Gasification
p.52

Thermomechanical Controlled Rolling of Hot Coils of Steel Grade S355MC at the Wide-Strip Rolling Mill 1700
p.63

Simulation of Electrical Heating of Materials in Metallic Capacity of Cylindrical Form
p.72

HomeSolid State PhenomenaSolid State Phenomena Vol. 291Statistical Express Control of the Peak Values of...

Statistical Express Control of the Peak Values of the Differential-Thermal Analysis of Solid Materials

Abstract:

The method of non-destructive control of the molecular structure of solid materials is improved, the distinguishing feature of which is a new sign of suitability for the peak values of the thermodynamic process in solid materials, which made it possible to increase the reliability of the non-destructive control. A statistical norm for deciding on the suitability of solid materials was introduced, which made it possible to organize statistical express control of solid materials under conditions of industrial production of electronic devices. In the practical plan, a structural scheme and an algorithm for measuring control of the peak values of the differential-thermal analysis of solid materials are proposed, on the basis of which a microprocessor based device for statistical express control is developed.

You might also be interested in these eBooks

Materials Properties and Technologies of Processing

View Preview

Info:

Periodical:

Solid State Phenomena (Volume 291)

Pages:

28-41

DOI:

https://doi.org/10.4028/www.scientific.net/SSP.291.28

Citation:

Cite this paper

Online since:

May 2019

Authors:

Andriy Semenov*, Serhii Baraban, Olena Semenova, Oleksandr Voznyak, Andrii Vydmysh, Leonid Yaroshenko

Keywords:

Differential-Thermal Analysis, Express Control, F-Test, Peak Values, Solid Materials, Statistical Criteria, T-Test

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] Poplavko, U.M., Pereverzeva, L.P., Voronov, S.А., Iakymenko, U.І. (2007). Physical material science: tutorial handbook. Ch. 2: Dielectriki, NTUU KPI, Kyiv, Ukraine.

Google Scholar

[2] Gorlov, М.I., & Grischenko, V.Т. (1993). Vhodnoi control izdeliy electronnoy tehniki. Preprint АОО Videofon, Voronezh, Russia.

Google Scholar

[3] Osadchuk, V. S., & Osadchuk, A. V. (2011). The Microelectronic Radiomeasuring Transducers of Magnetic Field with a Frequency Output. Electronics and Electrical Engineering, 110(4). https://doi.org/10.5755/j01.eee.110.4.289.

DOI: 10.5755/j01.eee.110.4.289

Google Scholar

[4] Osadchuk, V. S., & Osadchuk, A. V. (2011). The Magneticreactive Effect in Transistors for Construction Transducers of Magnetic Field. Electronics and Electrical Engineering, 109(3). https://doi.org/10.5755/j01.eee.109.3.185.

DOI: 10.5755/j01.eee.109.3.185

Google Scholar

[5] Osadchuk, V. S., & Osadchuk, А. V. (2012). The Microelectronic Transducers of Pressure with the Frequency Output. Electronics and Electrical Engineering, 121(5). https://doi.org/10.5755/j01.eee.121.5.1661.

DOI: 10.5755/j01.eee.121.5.1661

Google Scholar

[6] Osadchuk, V.S., Osadchuk, A.V., & Yushchenko, Y.A. (2008). Radiomeasuring Thermal Flowmeter of Gas on the Basis of Transistor Structure with Negative Resistance. Elektronika & Elektrotechnika, (84), 47-52.

Google Scholar

[7] Knotko, А.V., Presniakov, I.А., Tretiakov, U.D. (2006). Solid State Chemistry. Izdatelskii zentr «Academia», Moscow, Russia.

Google Scholar

[8] Kendziro, О., Lifshiz, V.G., Saranin, А.А., Zotov, А.V., & Kataiama, М. (2006). Introduction to surface physics. Nauka, Moscow.

Google Scholar

[9] Korsanov, V.S., Kotomzeva, М.G., & Unusov, R.I. (2007). Thermogravimetria: uchebnoe posobie dlia studentov 3 cursa chimicheskogo faculteta. Permskii universitet, Perm, Russia.

Google Scholar

[10] Zukovskiy, V.S., & Petrov, А.N. (1987). Thermodinamika i kinetica tverdofasnych reakciy, Uralskiy gosudarstvenyy universitet. Sverdlovsk, Russia.

Google Scholar

[11] Osadchuk, О.V., Baraban, S.V., Semenov, A.О. (2012). The method of input control of structural-sensitive parameters of non-crystalline semiconductors. Visnyk Khmelnytskogo Natsionalnoho Universytetu, (3), 90-93.

Google Scholar

[12] Fesenko, A.I., Ishuk, I.N., & Shteinbreher, V.V. (2008). Methods and devices for the technical diagnosis of thermal protection and radio-absorbing coatings of aerospace vehicles. Mashinostroenie, Moscow, Russia.

Google Scholar

[13] Osadchuk, О.V., Baraban, S.V., & Semenov, A.О. (2012).. Increasing the probability of non-destructive control of structural transformations of non-crystalline semiconductors. Vymiruvalna ta obchysluvalna tehnika v technologichnyh procesah, (2), 79-82.

Google Scholar

[14] Osadchuk, A.V., Semenov, A.A., Baraban, S.V., Semenova, E.A., Koval, K.O. (2013). Noncontact infrared thermometer based on a self-oscillating lambda type system for measuring the human body's temperature, Proceedings of the 23rd International Crimean Conference Microwave and Telecommunication Technology (CriMiCo), 8-14 Sept. 2013, Sevastopol, Ukraine, 1069-1070.

Google Scholar

[15] Osadchuk, V.S., Osadchuk, A.V., Semenov, A.A., & Semenova, E.A. (2010). Experimental research and simulation of microwave oscillator based on structure of static inductance transistor with negative resistance. 2010 20th International Crimean Conference Microwave & Telecommunication Technology., https://doi.org/10.1109/crmico.2010.5632543.

DOI: 10.1109/crmico.2010.5632543

Google Scholar