TY - JOUR AB - Purpose The purpose of the current research is to study the turbulent flow through microchannels having a micropost in aligned and staggered arrangements.Design/methodology/approach Numerical calculations are performed on the basis of the finite volume approach, which is based on the SIMPLEC algorithm. In this work, the slip velocity, flow velocity distribution and friction factor for the two micropost patterns are examined at friction Reynolds numbers of Reτ = 395 and 590, relative module widths of Wm = 0.1 and 1 and cavity fraction range of Fc = 0.1 to 0.9.Findings Results reveal that for the two micropost patterns, as the friction Reynolds number, relative module width or cavity fraction increases, the slip velocity increases and friction factor decreases. It is found that the aligned micropost configuration leads to higher slip velocity and lower friction factor. Numerical findings indicate that the existence of the continuous cavity surface along the flow direction could be a significant criterion to realize if the velocity distribution deviates from that of the smooth channel. It is also shown that the turbulent flows are capable of producing more drag reduction than the laminar ones.Originality/value Previous studies have shown that microchannels consisting of a micropost pattern in aligned and staggered arrangements could be viewed as a promising alternative in the microscale flows for the heat removal purposes. Therefore, understanding the fluid flow through microchannels consisting of these configurations (which is a prerequisite to better understand thermal performance of such microchannels) is a significant issue, which is the subject of the present work. VL - 34 IS - 5 SN - 0264-4401 DO - 10.1108/EC-02-2016-0069 UR - https://doi.org/10.1108/EC-02-2016-0069 AU - Kharati-Koopaee Masoud AU - Rezaee Mahsa PY - 2017 Y1 - 2017/01/01 TI - Investigation of turbulent flow through microchannels consisting of different micropost arrangements T2 - Engineering Computations PB - Emerald Publishing Limited SP - 1367 EP - 1392 Y2 - 2024/03/29 ER -