U. Primožič, G. Bobovnik, J. Kutin
PVTt primary flow standard for small gas flow rates

A PVTt primary flow standard operates on the principle of determining the change of density of the measured gas in the tank of a known volume and the corresponding time interval. The PVTt standard presented in this paper is based on the diverter-operated flying start and finish method. It contains the gas collection tank that is constructed as a dismountable assembly, which enables determining its internal volume by dimensional measurements. The standard is designed for the flow range from 0.12 mg/min to 12 mg/min and it achieves the relative expanded measurement uncertainty between 0.12% and 0.24%. We performed a comparison of the realized PVTt flow standard with the piston-prover flow standard for flow rates above 1.2 mg/min, and the results were found successful in view of normalized errors, En.

Chen Hui-yu, Cui Li-shui
Experimental Investigation to Measure the Natural Flow by Gas Laser Doppler Laser Doppler Velocimetry

In order to solving the natural gas flow measurement problem about measuring flow under the complicated conditions and the measurement traceability of large diameter instruments, a set of optical natural gas flow metering devices based on Laser Doppler Velocimetry was established, translating the traditional flow volume measurement into pipeline section velocity field measurement to achieve the accurate measurement of natural gas flow. Results show that: the facility can achieve 1.45Mpa, 500m³/h the largest experiment measuring ability and the expanded uncertainty was 1.42% (k = 2); The relative deviation between the experimental results and the standard flow based on the ultrasonic flowmeter was 0.09% ~ 2.93%; The results verify the feasibility of optical method measuring natural gas flow, and the established experiment system can be used for broader flow range of the research of high pressure natural gas flow measurement.

D. Jonker, W. M. Dlamini, R. M. Molefe
Flow Instability Evaluation at the NMISA Gas Flow Laboratory

Interlaboratory comparison and verification measurements performed in the Gas Flow Laboratory indicated stability problems in the flow ranges below 50 mL/min and above 30 L/min. Initially the stability problems in the low flow range below 50 mL/min were attributed to the flow cell used as reference standard. The unstable measurements above 30 L/min were attributed to the lack of sufficient pressure drop in the flow path from the gas cylinder to the measuring point. However, further measurements performed indicated that this might not be the cause of the instabilities experienced. To further investigate the matter, a second reference standard was acquired, and the flow path was lengthened and equipped with more pressure regulators to ensure better pressure control and a larger pressure drop. This paper discusses the methods to determine the causes of the instability, the measurements performed, analysis of the measurement results and measures implemented to eliminate further problems.
This paper includes a discussion of the possible flow instability generated by the insertion of thermistors in the flow path to perform temperature measurements of volume flow devices. The Flow Laboratory regularly receives volumetric flow devices and to calculate standardised flow conditions, it is necessary to measure the gas temperature and pressure at the unit under test (UUT) location. Emphasis is given to the determination of the immersion depth and measurement position of the temperature sensor in the flow path to ensure no, or negligible, disturbances in the gas flow path.

M. Olbrich, E. Schmeyer, M. Bär, M. Sieber, K. Oberleithner, S. Schmelter
Identification of coherent structures in horizontal slug flow

Multiphase flow measurement devices are significantly affected by the occurring flow pattern, such as, e.g., slug flow, leading to large uncertainties. In this context, the slug flow pattern in horizontal pipes is investigated with the aim of finding a statistical characterization of the structures in space and time. For this, two different instances of slug flow are analyzed with a snapshot proper orthogonal decomposition and an additional mode coupling algorithm, which provides an energy-ranked mode basis of the underlying coherent structures. For the considered flows, the most energetic mode pair has been identified with the corresponding slugging structures. Thereby, the temporal and spatial information of these mode pairs enables a statistical characterization of the slugs. In this context, a length scale, a dominant frequency, and an energy representation of the slugging structures is obtained from this method.

S. Schmelter, M. Olbrich, E. Schmeyer, M. Bär
Numerical simulation, validation, and analysis of twophase slug flow in large horizontal pipes

Multiphase flow, especially two-phase gas-liquid flow, is of great importance for a variety of applications and industrial processes, for example in the nuclear, chemical, or oil and gas industries. In this contribution, we present simulation results for gas-liquid slug flow in large horizontal pipes. Six test cases with different oil, water, and gas flow rates are considered, which cover a wide range of different slug flows. The numerical predictions are validated by comparison with experimental data obtained from video observations, which have been recorded at NEL as part of the European research project “Multiphase flow metrology in oil and gas production”. The relative error of the mean liquid level between experiment and simulation is less than 10.8 per cent for all but one test cases. Furthermore, a frequency analysis is performed. The single-sided amplitude spectrum as well as the smoothed power spectral density are calculated. For both, experimental and simulation data, one observes an increase of the dominant frequencies if the ratio of liquid and gas superficial velocity is increased.