International Journal of Science, Technology and Society

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Holography of the Surface Layer in the Visible Range of Electromagnetic Radiation for Its Geometric Modeling

Received: Aug. 22, 2018    Accepted: Oct. 05, 2018    Published: Nov. 06, 2018
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Abstract

One of the main problems of modern measurement technology and Metrology is that no non-destructive testing device, due to its design features, allows to make metrological measurements necessary for the construction of a three-dimensional geometric model of the part surface, which is a superposition of the geometric image of the surface and the topography of its microrelief. As a rule, in the calculation of the forming surface of the tool there is no calculation of the topography of its microrelief. This is due to the lack of sufficient information about the geometric structure of the microrelief as a three-dimensional image, due to the use of one-dimensional evaluation parameter. Application for geometric modeling of the microrelief shape of a one-dimensional evaluation parameter-the height of the microrelief, gives an idea of the microrelief as a surface with numerical marks. In the description of the surface with numerical marks, the curvature in the local neighborhood of the given point is not determined, which makes it impossible to construct its full geometric image. The solution to the problem is to create a non-destructive testing device-an optical profilograph, the design of which would allow to measure the geometric characteristics of the surface of the part necessary for structuring its full geometric image and the development of a new geometric approach that allows to obtain this complete geometric image of the part. Installation - optical profilograph refers to measuring equipment, in particular to devices for roughness control. This installation is designed as a complex of non-destructive testing devices of new generation, which is aimed at solving the actual problem in the conduct of metrological measurements required to build a three-dimensional geometric model of the surface of the part, which would be a superposition of the geometric image of the surface of the part and the topography of its microrelief. The principle of operation of the installation is that the holographic image of the part, the scanning indicator of the electromagnetic field are removed cards, which are fixed microrelief profiles of the surface layer, profiles of internal and external surfaces of the part. With these profiles remove the geometric characteristics, which are based on the modular geometric approach allows you to structure the topography of the surface layer microrelief, as well as the internal and external geometry of the surfaces of the part, having a complex shape.

DOI 10.11648/j.ijsts.20180605.11
Published in International Journal of Science, Technology and Society ( Volume 6, Issue 5, September 2018 )
Page(s) 72-77
Creative Commons

This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited.

Copyright

Copyright © The Author(s), 2024. Published by Science Publishing Group

Keywords

Optical Profilograph Plant, Optical Circuits of Leith-Upatnieks and Denisyuk, Surface Layer Topography

References
[1] Belkin, E. A., Poyarkov, V. N. Profilographs of new generation based on holography. “Scientific Review”, No. 12. 2015. – pp. 205-208.
[2] Science, education, society: trends and outlooks. Transactions of the Inter. Scientific. Pract. Conf. Part II. August 31, 2013. Ar-Consult. Moscow, 2013. Belkin E. A., Poyarkov V. N. Holographic Profilograph of Passive Control. – pp. 33-35.
[3] Pat. RF No. 2215317. Profilograph /Stepanov Yu. S., Belkin E. A., Barsukov G. V. Appied: 08.01.2002. Published: 27.10.2003. Bull. 30.
[4] The 2nd Inter. Scientific Conf. Applied Sciences and Europe: Common Challenges and Scientific Findings. September 9-10, 2013. New York, USA. Microrelief Geometrics Simulation and Inspection Tools. Belkin E. A., Poyarkov V. N. pp. 115-118.
[5] Energy-saving twenty-first century. Collection of materials X International scientific and practical Internet conference. 01 March - 30 June. Eagle 2012. Geometric modeling of surface microrelief and development of new generation non-destructive testing devices. Y. S. Stepanov, E. A. Belkin, V. Poyarkov N. With 173-178.
[6] Materialy IX miedzynarodowej naukowi-praktycznej konferencji. Wschodnie partnerstwo – 2013. 07 – 15 września 2013 roku. Volume 31. Fizyka. Przemysl. Nauka I studia. 2013. Profiling the new generation. Belkin, E. A., Poyarkov, V. N. 8-10.
[7] Science, education, society: modern challenges and prospects. Collection of scientific papers on the materials of the International scientific-practical conference. Part II. June 28, 2013 AP-consult. Moscow 2013. Inspection tools for control of a microrelief formation process. Belkin E. A., Poyrkov V. N. 117-119.
[8] Science, education, society: trends and prospects. Collection of scientific papers on the materials of the International scientific-practical conference. Part II. August 31, 2013 AR-consult. Moscow 2013. Holographic profilograph of passive control. Belkin, E. A., Poyarkov, V. N.
[9] 2 nd International scientific conference Applied Sciences and Europe: common challenges and scientific findings. 9-10 th August 2013. New York, USA. Microrelief geometrics simulation and inspection tools. Belkin E. A., Poyrkov V. N. P. 115-118.
[10] Fundamental and applied problems of engineering and technology. FGBOU VPO "state University-unpk" No. 4 (300) 2013 July – Aug. Devices of non-destructive control over the process of formation of topography of the microrelief. Y. S. Stepanov, E. A. Belkin, V. Poyarkov N. С145-148.
[11] Industrial ACS and controllers. No. 4. 2016. Metrological assurance of non-destructive testing of new generation over the formation of the topography of the surface. Belkin, E. A., Poyarkov, V. N. 3-9.
[12] The devices and systems. Management, control, diagnostics. Installation for non-destructive holographic 3D-control. No. 3. 2016. Belkin, E. A., Poyarkov, V. N. From 23-28.
[13] The scientific review. No. 12. 2015. Profiling the new generation on the basis of holography. Belkin, E. A., Poyarkov, V. N. With 205-207.
[14] Belkin, E. A., Poyarkov, V. N., Stepanov. Installation of holographic control over the process of microrelief formation. Modern high-performance technologies and equipment in mechanical engineering. (MTET-2016). Proceedings of the international scientific and technical conference. 6-8.10.2016 St. Petersburg.
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    Evgeny Alexandrovich Belkin, Vyacheslav Nikolaevich Poyarkov, Oleg Ivanovich Markov. (2018). Holography of the Surface Layer in the Visible Range of Electromagnetic Radiation for Its Geometric Modeling. International Journal of Science, Technology and Society, 6(5), 72-77. https://doi.org/10.11648/j.ijsts.20180605.11

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    ACS Style

    Evgeny Alexandrovich Belkin; Vyacheslav Nikolaevich Poyarkov; Oleg Ivanovich Markov. Holography of the Surface Layer in the Visible Range of Electromagnetic Radiation for Its Geometric Modeling. Int. J. Sci. Technol. Soc. 2018, 6(5), 72-77. doi: 10.11648/j.ijsts.20180605.11

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    AMA Style

    Evgeny Alexandrovich Belkin, Vyacheslav Nikolaevich Poyarkov, Oleg Ivanovich Markov. Holography of the Surface Layer in the Visible Range of Electromagnetic Radiation for Its Geometric Modeling. Int J Sci Technol Soc. 2018;6(5):72-77. doi: 10.11648/j.ijsts.20180605.11

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  • @article{10.11648/j.ijsts.20180605.11,
      author = {Evgeny Alexandrovich Belkin and Vyacheslav Nikolaevich Poyarkov and Oleg Ivanovich Markov},
      title = {Holography of the Surface Layer in the Visible Range of Electromagnetic Radiation for Its Geometric Modeling},
      journal = {International Journal of Science, Technology and Society},
      volume = {6},
      number = {5},
      pages = {72-77},
      doi = {10.11648/j.ijsts.20180605.11},
      url = {https://doi.org/10.11648/j.ijsts.20180605.11},
      eprint = {https://download.sciencepg.com/pdf/10.11648.j.ijsts.20180605.11},
      abstract = {One of the main problems of modern measurement technology and Metrology is that no non-destructive testing device, due to its design features, allows to make metrological measurements necessary for the construction of a three-dimensional geometric model of the part surface, which is a superposition of the geometric image of the surface and the topography of its microrelief. As a rule, in the calculation of the forming surface of the tool there is no calculation of the topography of its microrelief. This is due to the lack of sufficient information about the geometric structure of the microrelief as a three-dimensional image, due to the use of one-dimensional evaluation parameter. Application for geometric modeling of the microrelief shape of a one-dimensional evaluation parameter-the height of the microrelief, gives an idea of the microrelief as a surface with numerical marks. In the description of the surface with numerical marks, the curvature in the local neighborhood of the given point is not determined, which makes it impossible to construct its full geometric image. The solution to the problem is to create a non-destructive testing device-an optical profilograph, the design of which would allow to measure the geometric characteristics of the surface of the part necessary for structuring its full geometric image and the development of a new geometric approach that allows to obtain this complete geometric image of the part. Installation - optical profilograph refers to measuring equipment, in particular to devices for roughness control. This installation is designed as a complex of non-destructive testing devices of new generation, which is aimed at solving the actual problem in the conduct of metrological measurements required to build a three-dimensional geometric model of the surface of the part, which would be a superposition of the geometric image of the surface of the part and the topography of its microrelief. The principle of operation of the installation is that the holographic image of the part, the scanning indicator of the electromagnetic field are removed cards, which are fixed microrelief profiles of the surface layer, profiles of internal and external surfaces of the part. With these profiles remove the geometric characteristics, which are based on the modular geometric approach allows you to structure the topography of the surface layer microrelief, as well as the internal and external geometry of the surfaces of the part, having a complex shape.},
     year = {2018}
    }
    

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  • TY  - JOUR
    T1  - Holography of the Surface Layer in the Visible Range of Electromagnetic Radiation for Its Geometric Modeling
    AU  - Evgeny Alexandrovich Belkin
    AU  - Vyacheslav Nikolaevich Poyarkov
    AU  - Oleg Ivanovich Markov
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    N1  - https://doi.org/10.11648/j.ijsts.20180605.11
    DO  - 10.11648/j.ijsts.20180605.11
    T2  - International Journal of Science, Technology and Society
    JF  - International Journal of Science, Technology and Society
    JO  - International Journal of Science, Technology and Society
    SP  - 72
    EP  - 77
    PB  - Science Publishing Group
    SN  - 2330-7420
    UR  - https://doi.org/10.11648/j.ijsts.20180605.11
    AB  - One of the main problems of modern measurement technology and Metrology is that no non-destructive testing device, due to its design features, allows to make metrological measurements necessary for the construction of a three-dimensional geometric model of the part surface, which is a superposition of the geometric image of the surface and the topography of its microrelief. As a rule, in the calculation of the forming surface of the tool there is no calculation of the topography of its microrelief. This is due to the lack of sufficient information about the geometric structure of the microrelief as a three-dimensional image, due to the use of one-dimensional evaluation parameter. Application for geometric modeling of the microrelief shape of a one-dimensional evaluation parameter-the height of the microrelief, gives an idea of the microrelief as a surface with numerical marks. In the description of the surface with numerical marks, the curvature in the local neighborhood of the given point is not determined, which makes it impossible to construct its full geometric image. The solution to the problem is to create a non-destructive testing device-an optical profilograph, the design of which would allow to measure the geometric characteristics of the surface of the part necessary for structuring its full geometric image and the development of a new geometric approach that allows to obtain this complete geometric image of the part. Installation - optical profilograph refers to measuring equipment, in particular to devices for roughness control. This installation is designed as a complex of non-destructive testing devices of new generation, which is aimed at solving the actual problem in the conduct of metrological measurements required to build a three-dimensional geometric model of the surface of the part, which would be a superposition of the geometric image of the surface of the part and the topography of its microrelief. The principle of operation of the installation is that the holographic image of the part, the scanning indicator of the electromagnetic field are removed cards, which are fixed microrelief profiles of the surface layer, profiles of internal and external surfaces of the part. With these profiles remove the geometric characteristics, which are based on the modular geometric approach allows you to structure the topography of the surface layer microrelief, as well as the internal and external geometry of the surfaces of the part, having a complex shape.
    VL  - 6
    IS  - 5
    ER  - 

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Author Information
  • Department of Experimental and Theoretical Physics, Faculty of Physics and Mathematics, Orel State University I. S. Turgenev, Orel, Russia

  • Department of Experimental and Theoretical Physics, Faculty of Physics and Mathematics, Orel State University I. S. Turgenev, Orel, Russia

  • Department of Experimental and Theoretical Physics, Faculty of Physics and Mathematics, Orel State University I. S. Turgenev, Orel, Russia

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