Experimental study on effect of structural parameters on pressure drop characteristics of multi-orifice plates

Owing to the advantages of rectification, low noise, low pressure loss, and more stable pressure drop signal compared with the characteristics of the conventional single-orifice plate, multi-orifice plates (MOPs) offer a wide range of application prospects in various industrial pipelines. However, o...

Full description

Saved in:
Bibliographic Details
Published in:Flow measurement and instrumentation 2023-06, Vol.91, p.102346, Article 102346
Main Authors: Wu, Yuxin, Ma, Youfu, Lyu, Junfu, Niu, Fangfang, Jiao, Qianfeng
Format: Article
Language:English
Subjects:
Orifice plate
Pressure drop
Structural effect
Throttling
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Owing to the advantages of rectification, low noise, low pressure loss, and more stable pressure drop signal compared with the characteristics of the conventional single-orifice plate, multi-orifice plates (MOPs) offer a wide range of application prospects in various industrial pipelines. However, owing to its various orifice shapes and orifice layouts, the pressure drop characteristics of MOPs are not fully understood. In this study, the pressure drop characteristics of single-phase flow across a multi-orifice plate, which implies a stable zone (turbulent flow) pressure loss coefficient and the minimum critical Reynolds number of the stable zone, are experimentally investigated in the Reynolds number range of 29,000–146,000 using water as the fluid. Nine MOPs with circular holes evenly arranged in an equilateral triangle are tested. Their structures differ in terms of the equivalent diameter ratio (0.30–0.60), orifice number (64–400), and relative orifice thickness (0.40–1.60). The results show that the minimum critical Reynolds number deceases as the equivalent diameter ratio decreases, the relative orifice thickness increases, and the orifice number increases, which allows an enlarged Reynolds number range for the stable zone. As the equivalent diameter ratio, orifice number, and relative orifice thickness increase, the stable zone pressure loss coefficient of MOPs initially decreases rapidly and gradually approaches a constant. Finally, based on the experimental results of this study, a correlation of the stable zone pressure loss coefficient of MOPs is proposed, which provides a reference for using MOPs in various industrial applications. •Effect of structural factors on pressure drop of multi-orifice plates was experimentally studied.•The critical Reynolds numbers of achieving a stable pressure loss coefficient were determined.•Show the influencing degree of different structural factors on the pressure-loss coefficient.•A new correlation for predicting the pressure drop of multi-orifice plates was proposed.•Prediction deviations of the existing correlations were discussed based on the test results.
ISSN:0955-5986
1873-6998
DOI:10.1016/j.flowmeasinst.2023.102346