Eliphas Wagner Simões, Rogerio Furlan, Roberto Eduardo Bruzetti Leminski, Mário Ricardo Gongora-Rubio, Marcos Tadeu Pereira, Nilton Itiro Morimoto
Micro fluidic Oscillator for Gas Flow Control and Measurement

Micro fluidic oscillators were obtained from wall attachment micro fluidic amplifiers using a feedback loop from the outputs to the control inputs. These devices can be used as actuators, as mixers, and also as flow meters, when the oscillation frequency is proportional to the volumetric flow in subsonic and moderately compressible conditions. The devices were then made in a SU-8 based epoxy photo resist using photolithography ultraviolet process. The article shows the results obtained in the experimental tests of the devices with gases (nitrogen, argon, and carbon dioxide). The dimensions are of the order of 280 µm. The typical variation of the frequency with volumetric flow presents a range close to thousands of Hz. The oscillation frequencies were obtained using hot wire filaments (in this case with 12 µm of diameter). The experimental results indicated which operation of the micro fluidic oscillator were direct function of the length of feedback loop and the velocity inside of the interaction region.

Ernst von Lavante, Udo Banaszak
Effects of Shape Change due to Wear on the Accuracy of Vortex-shedding Flow Meters

In the present investigation, the problem of accurate determination of volumetric flows by means of the so-called vortex-shedding flowmeter in the case of shape changes from the original specifications due to wear was studied. To this end, the flow about the bluff body used in the presently studied vortex-shedding flow meter was numerically simulated using a solver of the unsteady, compressible Navier-Stokes equations in two and three dimensions. The computations were carried out for several Reynolds numbers using modified geometry in which rounded edges representing wear were introduced. The results were compared, where possible, with experimental data obtained by the manufacturer. The effects of turbulence were modeled by using the realizable k-e turbulence model. The resulting flow fields were analyzed using various methods, including visualization, evaluation of several of their global features and DFT of properly chosen variables.

Yaoying Lin, Volker Hans
Influence of Inclination of Bluff Body in Flowmeters

This paper studies a factor which might influence the Strouhal number, that is, the inclination of the bluff body. The inclination of the bluff body happens in flow industry when the bluff body is inclined relative to its pipe parallel axis. Triangular bluff bodies are thoroughly discussed in this paper. Normally, the flat side is facing the inflow which is called conventional setup. It is turned around with 180 degrees facing the sharp side to the inflow, which is called unconventional setup in this paper. The inclination of bluff body has different influences in each setup. This paper shows that the flowmeter with bluff body in conventional setup makes lower Strouhal number but has more robustness to the inclination. On the contrary, it makes higher Strouhal number but less robustness. With fixed width, the different length of the triangular bluff body also causes influence to the Strouhal. In addition, the inclination of a rectangular plate bluff body is studied.

Lei Lin, Li Ning, Wang Hou-Jun
Theory Conversion Method and Uncertainty Analysis for Critical Flow Coefficient of Venturi Nozzle

Without actual flow standard equipment of certain type of flow media or on the occasion of requiring no high measuring accuracy, critical flow coefficient of Venturi nozzle may be disposed by other methods instead of being actual flow calibrated through this flow media. The flow coefficient calibrated by other media, being enough analyzed and computed can be directly applied to a flow measurement of the other media. This article mainly researches on conversion method and analysis and computation of uncertainty of critical flow coefficient when Venturin nozzle works in critical flow state. In this article, on the premise of ensuring enough accuracy, the theory method of conversion between air and the natural gas, aiming at the flow coefficient of critical flow Venturin nozzle, is practical and feasible by experiments, furthermore this method may be popularized to other flow media on some conditions.

Jae-Hyung Kim, Heuy-Dong Kim, Kyung-Am Park
Computational / Experimental Study of a Variable Critical Nozzle Flow

Recently, critical nozzles have been extensively utilized to measure the mass flow rate in a variety of industrial applications. For the measurement of the mass flow rates at a wide range of operation conditions, the critical nozzle is required to be designed with different diameters. The objective of the present study is to investigate the effectiveness of a variable critical nozzle. A rod with a small diameter is inserted into the critical nozzle to change the effective cross-sectional area of the critical nozzle. Experimental work is performed to measure the mass flow rate of the critical nozzle with rod. Computational work is carried out using the 2-dimensional, axisymmetric compressible Navier-Stokes equations which are discretized using a fully implicit finite volume method. The diameter of the rod is varied to obtain different mass flow rates through the variable critical nozzle. Computational results predict well the measured mass flow rates. The boundary layer displacement and momentum thickness at the throat of the critical nozzle are given as a function of Reynolds number. The discharge coefficient of the critical nozzle is given as an empirical equation.