Range Extension down to 1 mL/h of Micro Liquid Flow Calibration Facility at CSIR-NPL, India

The present paper outlines the efforts for the range extension of the existing CSIR-NPL micro liquid flow calibration facility (having flow range of (10–1500) mL/h) from 10 mL/h  down to 1 mL/h and its metrological assessment. The major challenges in this study are evaporation, flow rate stability a...

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Bibliographic Details
Published in:MĀPAN : journal of Metrology Society of India 2024-12, Vol.39 (4), p.955-966
Main Authors: Sanjeet Kumar, Jaiswal, S. K., Varshney, A., Singh, C., Yadav, S.
Format: Article
Language:English
Subjects:
Calibration
Confidence intervals
Distilled water
Evaporation rate
Flow measurement
Flow stability
Flow velocity
Liquid flow
Mathematical and Computational Physics
Mathematical Methods in Physics
Measurement Science and Instrumentation
Mineral oils
Numerical and Computational Physics
Original Paper
Physics
Physics and Astronomy
Reproducibility
Simulation
Syringes
Theoretical
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Summary:The present paper outlines the efforts for the range extension of the existing CSIR-NPL micro liquid flow calibration facility (having flow range of (10–1500) mL/h) from 10 mL/h  down to 1 mL/h and its metrological assessment. The major challenges in this study are evaporation, flow rate stability and repeatability. To reduce the evaporation, a small quantity of mineral oil was mixed with distilled water in the collection beaker, forming a thin layer of oil over the beaker water surface, leading to reduced evaporation. For improving the flow stability and repeatability, a high-accuracy syringe pump with a 10 mL syringe and a precision balance of 82 g capacity have been used. The static weighing with standing start and standing finish method has been used for flow measurement. The expanded uncertainty (at k  = 2 for approx. 95% confidence level) of the facility is found to be (1.0–0.30) % in the flow range (1–1500) mL/h for both totalized volume and volume flow rate measurements. Thus, CSIR-NPL is now able to maintain NMI status in micro liquid flow measurement.
ISSN:0970-3950
0974-9853
DOI:10.1007/s12647-024-00768-9