Pump test bed is essential to ensure the proper functioning of a pump. However, a conventional pump test bed has some limitations during measuring the flow properties and variating the pump speed. As a result, a digital pump test bed can be a solution for measuring the flow properties more accurately. This article describes the construction process of a pressure sensing module for a digitalized pump test bed and control of flow by varying the speed of a prototype DC pump. A pressure sensing module and flow control system are constructed in this study to develop a prototype pump test bed as well as change the speed of the centrifugal pump. It is found that by using a piezoelectric pressure sensor in delivery pipe, the pressure sensing error is only 6.3% at the designed speed of pump and can be minimized by calibrating the sensor, fixing the leakage problem and increasing the pressure of flow. A wide variety of pump speeds can also be obtained by applying pulse width modulation principle without stopping the power supply.

[1] Wet and dry installation and operational efficiency of submersible pumps”, article, retrieved 25 October 2007, from World Pumps, www.worldpumps.com.

[2] Choate, R., Schmaltz, K., & Lenoir, J. Centrifugal Pump Test Bed: A Senior Capstone Project. In 2008 ASEE Annual Conference Proceedings, Pittsburgh, PA.

[3] “Pump test facility”, article, retrieved 25 October 2017, from KSB, www.ksb.com/centrifugal-pump-lexicon/pump-test-facility/191216/

[4] Karassik, I., & McGuire, J. T. (Eds.). (2012). Centrifugal pumps. Springer Science & Business Media. pp. 780

[5] Nelik, L. (1999). Centrifugal & Rotary Pumps: Fundamentals With Applications. CRC Press.

[6] Ferreira, F. J., Fong, J. A., & de Almeida, A. T. (2011). Ecoanalysis of variable-speed drives for flow regulation in pumping systems. IEEE Transactions on Industrial Electronics, 58(6), 2117-2125.

[7] Lobanoff, V. S., & Ross, R. R. (2013). Centrifugal pumps: design and application. Elsevier.

[8] Izquierdo, M. D. Z., Jimenez, J. J. S., & del Sol, A. M. (2008). Matlab software to determine the saving in parallel pumps optimal operation systems, by using variable speed. In Energy 2030 Conference. IEEE (pp. 1-8). IEEE.

[9] Ghafouri, J., Khayatzadeh, H., & Khayatzadeh, A. (2012). Dynamic modeling of variable speed centrifugal pump utilizing MATLAB/SIMULINK. International Journal of Science and Engineering Investigations, 1(5), 1-7.

[10] Li, X., & Song, Z. (2015). An ultrasound-based liquid pressure measurement method in small diameter pipelines considering the installation and temperature. Sensors, 15(4), 8253-8265.

[11] Roccamena, L., El Mankibi, M., & Stathopoulos, N. (2018). Experimental test bed design and development for PCM-water exchangers characterization. Sustainable cities and society, 37, 241-249.

[12] Cheng, M., Xu, B., Zhang, J., & Ding, R. (2017). Pump-based compensation for dynamic improvement of the electrohydraulic flow matching system. IEEE Transactions on Industrial Electronics, 64(4), 2903-2913.

[13] “MPX5050GP Pressure sensor”, article, retrieved 25 October 2017, from www.nxp.com/part/MPX5050GP

[14] “Arduino Nano V3.0”, article, retrieved 25 October 2017, from www.store.arduino.cc/usa/arduino-nano

[15] De Silva, C. W. (2015). Sensors and actuators: Engineering system instrumentation. CRC Press.

[16] Barr, M. (2001). Pulse width modulation. Embedded Systems Programming, 14(10), 103-104.

[17] Kays, W. M. (1994). Turbulent Prandtl number—where are we?. Journal of Heat Transfer, 116(2), 284-295.