Mining of Mineral Deposits

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The impact of vibration mechanism’ installation place on the process of retrieving stuck drill pipe

V. Moisyshyn1, K. Levchuk2

1Higher Mathematics Department, Ivano-Frankivsk National Technical University of Oil and Gas, Ivano-Frankivsk, Ukraine

2Oil and Gas Equipment Department, Ivano-Frankivsk National Technical University of Oil and Gas, Ivano-Frankivsk, Ukraine


Min. miner. depos. 2016, 10(3):65-76


https://doi.org/10.15407/mining10.03.065

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      ABSTRACT

      Purpose. The present paper studies the dependence of the dynamic oscillatory movements in the area of drill string sticking on the parameters of vibrating mechanism and place of its installation in the heavy weight drill pipe. The authors focus specifically on conditions responsible for resonant vibrations excitation in the drill string, which facilitates the release of stuck drill pipe. The aim is to use the results of the research in the development of the method for vibrator application, to work out recommendations concerning the choice of its installation place in the heavy weight drill pipe, its tuning to the resonant frequency, the choice of induced force amplitude.

      Methods. The authors proposed a mathematical model of the drill string functioning with vibration mechanism installed into the heavy weight drill pipe. The vibrator is needed to eliminate sticking of the drilling tool. The suggested discrete-continuum model which takes wave processes into account allows to conduct grounded experimental research.

      Findings. The developed mathematical model served as the basis for designing a computer program aimed to visualize oscillatory processes taking place in the string of pipes, and to calculate basic dynamic and kinematic characteristics of the analyzed system. Frequency oscillation spectrum was calculated for the selected layout of the drill string and the resonant amplitudes at these frequencies. We have obtained amplitude-frequency characteristics of the system induced oscillations, as well as dependences of strains and stresses in cross sections of drill pipes on the place of vibrator installation. The impact of the system energy characteristics on the efficiency of the drilling tool sticking elimination was analyzed.

      Originality. The proposed technique allows to significantly more accurately determine strains, stresses and safety margins in the arbitrary drill string section and to predict its sticking while drilling oil and gas boreholes.

      Practical implications. A specific method of selecting a place for the vibrator installation was elaborated. Recommendations concerning the choice of installation site, amplitude of excitation force, resonant frequencies for elimination of pipes’ sticking and prevention of drill strings destruction are provided.

      Keywords: drilling, drill string, elastic waves, mathematical model, vibrations, sticking, vibrator, stress, energy of the stuck drill string


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