Numerical and experimental investigation on the depressurization capacity of a new type of depressure-dominated jet mill bit

Efficient cuttings transport and improving rate of penetration (ROP) are two major challenges in horizontal drilling and extended reach drilling. A type of jet mill bit (JMB) may provide an opportunity to catch the two birds with one stone: not only enhancing cuttings transport efficiency but also i...

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Veröffentlicht in:	Petroleum science 2020-12, Vol.17 (6), p.1602-1615
Hauptverfasser:	Chen, Xu-Yue, Cao, Tong, Yu, Kai-An, Gao, De-Li, Yang, Jin, Wei, Hong-Shu
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Sprache:	eng
Schlagworte:	Capacity Cleaning Drilling Earth and Environmental Science Earth Sciences Economics and Management Energy & Fuels Energy Policy Engineering Engineering, Petroleum Flow rates Industrial and Production Engineering Industrial Chemistry/Chemical Engineering Low flow Mineral Resources Nozzles Original Paper Pressure reduction Science & Technology Technology Throats Transport
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creator	Chen, Xu-Yue Cao, Tong Yu, Kai-An Gao, De-Li Yang, Jin Wei, Hong-Shu
description	Efficient cuttings transport and improving rate of penetration (ROP) are two major challenges in horizontal drilling and extended reach drilling. A type of jet mill bit (JMB) may provide an opportunity to catch the two birds with one stone: not only enhancing cuttings transport efficiency but also improving ROP by depressuring at the bottom hole. In this paper, the JMB is further improved and a new type of depressure-dominated JMB is presented; meanwhile, the depressurization capacity of the depressure-dominated JMB is investigated by numerical simulation and experiment. The numerical study shows that low flow-rate ratio helps to enhance the depressurization capacity of the depressure-dominated JMB; for both depressurization and bottom hole cleaning concern, the flow-rate ratio is suggested to be set at approximately 1:1. With all other parameter values being constant, lower dimensionless nozzle-to-throat-area ratio may result in higher depressurization capacity and better bottom hole cleaning, and the optimal dimensionless nozzle-to-throat-area ratio is at approximately 0.15. Experiments also indicate that reducing the dimensionless flow-rate ratio may help to increase the depressurization capacity of the depressure-dominated JMB. This work provides drilling engineers with a promising tool to improve ROP.
doi_str_mv	10.1007/s12182-020-00472-8
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Sci</stitle><stitle>PETROL SCI</stitle><date>2020-12-01</date><risdate>2020</risdate><volume>17</volume><issue>6</issue><spage>1602</spage><epage>1615</epage><pages>1602-1615</pages><issn>1672-5107</issn><eissn>1995-8226</eissn><abstract>Efficient cuttings transport and improving rate of penetration (ROP) are two major challenges in horizontal drilling and extended reach drilling. A type of jet mill bit (JMB) may provide an opportunity to catch the two birds with one stone: not only enhancing cuttings transport efficiency but also improving ROP by depressuring at the bottom hole. In this paper, the JMB is further improved and a new type of depressure-dominated JMB is presented; meanwhile, the depressurization capacity of the depressure-dominated JMB is investigated by numerical simulation and experiment. The numerical study shows that low flow-rate ratio helps to enhance the depressurization capacity of the depressure-dominated JMB; for both depressurization and bottom hole cleaning concern, the flow-rate ratio is suggested to be set at approximately 1:1. With all other parameter values being constant, lower dimensionless nozzle-to-throat-area ratio may result in higher depressurization capacity and better bottom hole cleaning, and the optimal dimensionless nozzle-to-throat-area ratio is at approximately 0.15. Experiments also indicate that reducing the dimensionless flow-rate ratio may help to increase the depressurization capacity of the depressure-dominated JMB. This work provides drilling engineers with a promising tool to improve ROP.</abstract><cop>Beijing</cop><pub>China University of Petroleum (Beijing)</pub><doi>10.1007/s12182-020-00472-8</doi><tpages>14</tpages><oa>free_for_read</oa></addata></record>
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subjects	Capacity Cleaning Drilling Earth and Environmental Science Earth Sciences Economics and Management Energy & Fuels Energy Policy Engineering Engineering, Petroleum Flow rates Industrial and Production Engineering Industrial Chemistry/Chemical Engineering Low flow Mineral Resources Nozzles Original Paper Pressure reduction Science & Technology Technology Throats Transport
title	Numerical and experimental investigation on the depressurization capacity of a new type of depressure-dominated jet mill bit
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