The Determination of the Parameters of a Vibration Machinef the Internal Compaction of Concrete Mixtures

  • Authors

    • Alexander Maslov
    • janar Batsaikhan
    • Ruslan Puzyr
    • Yulia Salenko
    2018-09-15
    https://doi.org/10.14419/ijet.v7i4.3.19545
  • amplitude, concrete mixture, internal compaction, parameters, stresses, vibration machine.
  • Abstract

    The determination of the rational parameters of a vibration machine for the internal compaction of concrete mixtures. We researched the “vibration machine – concrete medium†system wherein the concrete medium is represented by a system with distributed parameters that takes into account the resilient, viscous, inertial and energy properties of the compacted concrete medium. We researched the propagation of the viscous-resilient-plastic deformation waves in the contracted concrete mixture represented in the form of a half-space. We determined the amplitudes of the oscillations and stresses occurring in the compacted mixture depending on its physical and mechanical characteristics. We determined the oscillation amplitude of the vibration machine, identified its rational parameters. We determined the regularity of the motion of the compacted mixture and the vibration machine depending on the physical and mathematical characteristics of the compacted mixture, the thickness and width of the compacted layer, the angular oscillation frequency and the amplitude of the exciting force. The presented dependences enable the substantiation of the rational parameters of the vibration machine and the modes of vibratory action.

     

  • References

    1. [1] Juradin S, Baloević G & Harapin A (2014), Impact of Vibrations on the Final Characteristics of Normal and Self-compacting Concrete. Journal of Materials Research, 17(1), pp. 178-185.

      [2] Sudarshan NM & Chandrashekar Rao T (2017), Vibration Impact on Fresh Concrete of Conventional and UHPFRC. International Journal of Applied Engineering Research, Vol. 12, 8thedn, pp. 1683-1690.

      [3] Koh HB, Yeoh D & Shahidan S (2017), Effect of re-vibration on the compressive strength and surface hardness of concrete. IOP Conf. Series: Materials Science and Engineering , 271, 012057

      [4] Gutierrez J, Ruiz E & Trochu F (2013), High-frequency vibrations on the compaction of dry fibrous reinforcements. Journal of Advanced Composite Materials, Vol. 22 (1)

      [5] Volkov SA & Evtyukov, S.A. (2012), Construction machinery. DNK, SPb, Russia.

      [6] Stacenko AS (2010) Technology of stone works in construction. Vysh. shk., Minsk, Belorussiya.

      [7] Gerasimov MD & Gerasimov DM (2013), Determination of the law of motion, speed and acceleration of the center of mass of the planetary vibration exciter. International Journal of Applied and Fundamental Research, Vol. 12, pp. 8-11.

      [8] Chen X, Wu S & Zhou J, (2013), Experimental study and analytical formulation of mechanical behavior of concrete, Journal of Construction and Buildings Materials, Vol. 47, pp. 662–670.

      [9] Banfill PFG, Teixeira MAOM & Craik RJM (2011), Rheology and vibration of fresh concrete: Predicting the radius of action of poker vibrators from wave propagation. Journal of Cement and Concert Research, Vol. 41, 9thedn, pp. 932-941.

      [10] Braun CA, Schumaker M, Rice J & Borg JP (2015), Comparison of Static and Dynamic Powder Compaction: Experiment and Simulation. Journal of Engineering Materials and Technology, Vol 138, 1thedn, 011003.

      [11] Abdellaoui H & Echaabi J (2014), Rheological models for modeling the viscoelastic behavior in liquid composite molding processes (LCM) review. Journal of Reinforced Plastics and Composites, Vol. 33, 8thedn, 714.

      [12] Sepani H, Polak MA & Penlidis A (2018), Constitutive Equations and Finite Element Implementation of Isochronous Nonlinear Viscoelastic Behavior. Journal of Engineering Materials and Technology, Vol 140, 4thedn, 041004.

      [13] Maslov A.G. & Salenko Y.S. (2014), Vibrating machines and processes in road construction industry: monograph. PB Cherbatyh, Kremenchuk, Ukraine.

      [14] Maslov A.G, Itkin A.F. & Salenko Y.S. (2014), Vibrating machines for the preparation and compaction of concrete mixes. PB Cherbatyh, Kremenchuk, Ukraine.

  • Downloads

  • How to Cite

    Maslov, A., Batsaikhan, janar, Puzyr, R., & Salenko, Y. (2018). The Determination of the Parameters of a Vibration Machinef the Internal Compaction of Concrete Mixtures. International Journal of Engineering & Technology, 7(4.3), 12-19. https://doi.org/10.14419/ijet.v7i4.3.19545

    Received date: 2018-09-12

    Accepted date: 2018-09-12

    Published date: 2018-09-15