Coordination of Variables of Nonautonomous Pneumatic Drive with Hydraulic Properties of Supply System

  • Authors

    • Yuri Pavlovich Kuznetsov
    • Lev Anatolevich Zakharov
    • Anatolii Alekseevich Mironov
    • Vladimir Leonidovich Khimich
    • Sergey Nikolaevich Khrunkov
    2018-12-03
    https://doi.org/10.14419/ijet.v7i4.38.24489
  • Air flow rate, Compressed air, Maximum power, Operation modes, Pneumatic drive.
  • Abstract

    This article discusses the issues of operability of nonautonomous pneumatic drive under workshop conditions. It is mentioned that in order to provide efficient operation and achievement of rated modes by nonautonomous pneumatic drive, it is required to coordinate its variables with variables of air supply system. On the basis of one-dimensional equation of adiabatic gas frictional flow in cylindrical pipe, the problem of determination of maximum achievable power by nonautonomous pneumatic drive at fixed hydraulic properties of supply system has been solved. The obtained dependences make it possible to calculate minimum allowed pipeline diameter of supply system providing preset maximum power of pneumatic drive. It is proved that the coefficient of total pressure conservation corresponding to maximum drive power is precisely determined by available pressure drop and does not depend on hydraulic properties of the system, and in order to achieve maximum drive power, strictly determined portion of available flow energy should be consumed for overcoming of the system hydraulic resistance not depending of reduced pipeline length.

     

  • References

    1. [1] Korenbaum VI, Tagiltsev AA, Gorovoi S.V, Kostiv AE, Shiryaev AD, Fershalov YuYa & Maryutin VS (2017), A low-frequency power-type pressure-gradient receiver for oceanological investigations. Instruments and Experimental Techniques 60(5), 728-732.

      [2] Kuznetsov YP, Khimich VL, Khrunkov SN & Krainov AA (2016), Radial two-stage microturbine for pneumatic actuation. Russian Aeronautics 59(2), 283-286.

      [3] Khimich VL, Chuvakov AB, Kikeyev VA, Khrunkov SN & Kraynov AA (2016), Two-rimming radial turbine for drive of manual pneumatic grinders. International Journal of Applied Engineering Research 116(16), 8982-8986.

      [4] Fershalov A, Fershalov Yu, Fershalov M et al (2016), Constructive and regime factors influence on turbine wheel characteristics with large rotation flow angle of blades. Polyarnaya mehanika 3, 976-985.

      [5] Fershalov AYu, Fershalov YuYa, Fershalov MYu, Tsygankova LP & Korshunov VN (2015), Influence of constructive and regime factors on the characteristics nozzle apparatus with small angles output nozzle. Modern technologies and development of polytechnic education, 514-516.

      [6] Fershalov AYu, Fershalov YuYa, Fershalov MYu, Tsygankova LP & Korshunov VN (2015), Influence of design and operational factors on the efficiency of the microturbine stages with small angles of nozzle. Modern technologies and development of polytechnic education, 516-518.

      [7] Fershalov AYu, Fershalov YuYa, Fershalov MYu & Sazonov TV (2015), Results of the study rotor wheels supersonic microturbines with a large angle of rotation of the flow. Applied Mechanics and Materials 752-753, 884-889.

      [8] Khimich VL, Chuvakov AB, Khrunkov SN & Kraynov AA (2016), The influence of aerodynamic characteristics of the elements of the flow range of the radial two-row range of the radial two-row microturbine on its dynamic characteristics. International Journal of Applied Engineering Research 11(23), 11501-11509.

      [9] Fershalov YuYa, Fershalov MYu, Fershalov AYu (2017), Energy efficiency of nozzles for axial microturbines. Procedia Engineering 206 499-504.

      [10] Fershalov AY, Fershalov YuYa & Tsigankova LP (2015), The degree of influence of constructive and regime factors on the characteristics turbine wheel steps shoulder who are more angles of rotation. RECENT ADVANCES in MATHEMATICS, Series "Mathematics and Computers in Science and Engineering Series", 130-133.

      [11] Fershalov AYu, Fershalov MYu, Fershalov YuYa, Sazonov TV & Ibragimov DI (2015), Research data of turbine nozzles of 5-9 degree outlet angles. Applied Mechanics and Materials 770, 547-550.

      [12] Fershalov AYu, Fershalov YuYa, Fershalov MYu, Sazonov TV & Ibragimov DI (2014), Analysis and optimization of efficiency rotor wheels microturbines. Applied Mechanics and Materials 635-637, 76-79.

      [13] Fershalov MYu, Fershalov YuYa, Fershalov AYu, Sazonov TV & Ibragimov DI (2014), Microturbines degree of reactivity. Applied Mechanics and Materials 635-637, 354-357.

      [14] Fershalov YuYa (2012), Technique for physical simulation of gasodynamic processes in the turbomachine flow passages. Russian Aeronautics 55(4), 424-429.

      [15] Fershalov MYu, Fershalov AYu & Fershalov YuYa (2014), Calculation reactivity degree for axial low-account turbines with small emergence angles of nozzle devices. Advanced Materials Research 915-916, 341-344.

      [16] Deich ME (1974), Tehnicheskaya gazodinamika [Engineering gas dynamics]. Moscow: Energiya.

      [17] Kuznetsov YuP & Kuznetsova TYu (2010), Soglasovanie parametrov neavtonomnogo pnevmaticheskogo privoda s gidravlicheskimi harakteristikami podvodyaschejj sistemy [Coordination of variables of nonautonomous pneumatic drive with hydraulic properties of supply system]. Trudy NGTU im. R.E. Alekseeva. T69, Energeticheskie ustanovki i teplotehnika 2, 86-94.

      [18] Khimich VL, Chuvakov AB & Khrunkov SN (2016), Maximum rotation frequency regulators of high-speed small-sized pneumatic actuators. International Journal of Applied Engineering Research 11(18), 9256-9260.

      [19] Fershalov AYu, Fershalov MYu, Fershalov YuYa, Sazonov TV & Ibragimov DI (2015), The design of the nozzle for the nozzle box microturbines. Applied Mechanics and Materials 789-790, 203-206.

      [20] Fershalov YuYa & Sazonov TV (2014), Experimental research of the nozzles. Advanced Materials Research 915-916, 345-348.

      [21] Sazonov TV, Fershalov YuYa, Fershalov MYu, Fershalov AYu & Ibragimov DI (2014), Experimental installation for the study of nozzles microturbines. Applied Mechanics and Materials 635-637, 155-158.

      [22] Ibragimov D, Mochalov A & Ilinskiy Yu (2017), Research Data of Microturbine Nozzles with Outlet Angles under 9 Degree (Conference Paper), Procedia Engineering 206, 493-498.

  • Downloads

  • How to Cite

    Pavlovich Kuznetsov, Y., Anatolevich Zakharov, L., Alekseevich Mironov, A., Leonidovich Khimich, V., & Nikolaevich Khrunkov, S. (2018). Coordination of Variables of Nonautonomous Pneumatic Drive with Hydraulic Properties of Supply System. International Journal of Engineering & Technology, 7(4.38), 300-304. https://doi.org/10.14419/ijet.v7i4.38.24489

    Received date: 2018-12-21

    Accepted date: 2018-12-21

    Published date: 2018-12-03