The effect of surface roughness of the impeller to the performance of pump as turbine pico power plant

Authors

  • D. L. Zariatin Department of Mechanical Engineering, Universitas Pancasila Jln. Srengseng Sawah, Jakarta Indonesia Phone: +6282124588227 Fax: +62217270128
  • Dwi Rahmalina Department of Mechanical Engineering, Universitas Pancasila Jln. Srengseng Sawah, Jakarta Indonesia Phone: +6282124588227 Fax: +62217270128
  • Eko Prasetyo Department of Mechanical Engineering, Universitas Pancasila Jln. Srengseng Sawah, Jakarta Indonesia Phone: +6282124588227 Fax: +62217270128
  • A. Suwandi Department of Mechanical Engineering, Universitas Pancasila Jln. Srengseng Sawah, Jakarta Indonesia Phone: +6282124588227 Fax: +62217270128
  • M. Sumardi Department of Mechanical Engineering, Universitas Pancasila Jln. Srengseng Sawah, Jakarta Indonesia Phone: +6282124588227 Fax: +62217270128

DOI:

https://doi.org/10.15282/jmes.13.1.2019.24.0394

Keywords:

Pump as turbine, surface roughness, impeller, impeller rounding

Abstract

Pump as Turbine (PAT) is one of a hydropower plant that applies a pump with a reversed flow, working as a turbine to generate electrical power. It has the advantages of low-cost, widely available in the market and user-friendly. However, like other hydropower plants, PAT technology has low performance in term of power output. The impeller surface roughness is one of critical aspect, which influences PAT performance because poor surface roughness causes losses and cavitation. The objective of the research is to increase the PAT performance by improving the quality of the surface roughness and validate by the experimental tests. A low-cost and customize hand grinding process was applied to produce five impellers with three different levels of surface roughness (average surface roughness of 0.16 mm, 0.24 mm, and 0.40 mm), an edge rounded impeller, and a varnish lacquer coated impeller. All of the impellers undergo performance testing. The performance of the original impeller (without modification) used as a comparison. The experiment result shows that an impeller with a lower surface roughness (lower Ra number) has a higher performance. An impeller with an average surface roughness of 0.16 mm improved 10.9% of its initial performance. Additional edge rounding for a 0.16 mm surface roughness impeller would improve its performance by 13.1%.  The optimum turbine efficiency of 15.45% was achieve-able by implementing an impeller with the lowest surface roughness.

References

A. Carravetta, S. D. Houreh, and H. M. Ramos. Pumps as Turbines. Springer;2018.

D. A. Himawanto, D. D. D. P. Tjahjana, and Hantarum. 2016. Experimental study on optimization of curvature blade impeller pump as turbine which functioned as power plant picohydro. International Conference on Engineering, Science and Nanotechnology 2016 (ICESNANO 2016) AIP Conference Proceeding 1788.: 030008 1-7;2016.

N. Raman, K. P. Hussein and B. FooAn experimental investigation of pump as turbine for micro hydro application. 4th International Conference on Energy and Environment 2013 (ICEE 2013) - IOP Conf. Series: Earth and Environmental Science 16: 012064 1-4; 2013.

H. Nautiyal, Varun, A. Kumar, and S. Yadav. Experimental Investigation of Centrifugal Pump Working as Turbine for Small Hydropower Systems. Energy Science and Technology 2011; 1: 79-86.

J. Fernández, E. Blanco, J. Parrondo and M. T. Stickland. Performance of a centrifugal pump running in inverse mode. Proceedings of the Institution of Mechanical Engineers, Part A: Journal of Power and Energy 2004; 218: 265-271.

S. V. Jain and R. N. Patel. Investigation on pump running in turbine mode: A review of the state-of-the-art. Renewable and Sustainable Energy Reviews 2014; 30: 841-868.

A. Elbratran, O. Yaakob, Y. Ahmed and H. Shabara.. Operation, performance and economic analysis of low head micro-hydropower turbines for rural and remote areas: A review. Renewable and Sustainable Energy Reviews 2015; 43: 40-50.

S.-S. Yang, F.-Y. Kong, C. Hao, and X.-H. Su.. Effects of blade wrap angle influencing a pump as turbine. Journal of Fluids Engineering 2012;134 (061102): 1-8.

S. Derakhshan, B. Mohammadi and A. Nourbakhsh.. Efficiency Improvement of Centrifugal Reverse Pumps. Journal of Fluids Engineering 2009;131(021103); 1-9.

Y. Sun-Sheng, K. Fan-Yu, J. Wan-Ming and Q. Xiao-Yun. Effects of Impeller Trimming Influencing Pump as Turbine. Computers & Fluids 2012; 67: 72-78.

S. V. Jain, A. Swarnkar, K. H. Motwani and R. N. Patel. Effects of impeller diameter and rotational speed on performance of pump running in turbine mode. Energy Conversion and Management 2015. 89: 808-824.

P. Singh and F. Nestmann. Internal hydraulic analysis of impeller rounding in centrifugal pumps as turbines. Experimental Thermal and Fluid Science 2011; 35: 121-134.

M. Suarda, N. Suarnadwipa, and W. B. Adyana. Experimental Work on Modification of Impeller Tips of a Centrifugal Pumps as a Turbine. The 2nd Joint International Conference on Sustainable Energy and Environment (SEE 2006). B-008 (O): 1-5; 2006.

D. Zariatin, S. Kumbarasari, D. Rahmalina. The Performance of Pump as Turbine with Machined Impellers. The 2nd International Joint Conference on Advanced Engineering and Technology (IJCAET 2017) and International Symposium on Advanced Mechanical and Power Engineering (ISAMPE 2017) MATEC Web Conference 2017;159 (02024): 1-6;.

F. Varle Y. Effects of Impeller design and surface roughness on the performance of centrifugal pumps. The proceedings of the Institution of Mechanical Engineers 1961; 175: 955 - 989.

A. Poullikkas. Surface roughness effect on induced flow and frictional resistance of enclosed rotating disks. Journal of Fluids Engineering1995;117: 526 - 528.

S. Kaewnai, M. Chamaoot, and S. Wongwises. Predicting performance of radial flow type impeller of centrifugal pump using CFD. Journal of Mechanical Science and Technology 2009; 23: 1620 - 1627.

R. Singh, S. Tiwari, S. K. Mishra. Cavitation Erosion in Hydraulic Turbine Components and Mitigation by Coatings: Current Status and Future Needs. Journal of Materials Engineering and Performance 2012;21:1539-1551.

J. Gȕlich. Effect of Reynolds Number and Surface Roughness on the Efficiency of Centrifugal Pumps. Journal of Fluids Engineering 2003; 125: 670-679.

J. Gȕlich.. Disk friction losses of closed turbomachine impellers. Forschung im Ingenieurwesen 2003; 68: 87-95.

D. L. Zariatin, D. Rhakasywi, F. Ade and A. Setyo. Design of Pump as Turbine Experimental Test Facility. International Conference on Mechanical. Aeronautical and Automotive Engineering (ICMAA 2017) MATEC Web of Conferences 108 (04014): 1-4; 2017.

S. N. Indonesia, SNI 8277: Panduan komisioning pengkit listrik tenaga mikro hidro (PLTMH) kapasitas hingga 100 kW. Badan Standarisasi Nasional, BSN;2016.

Downloads

Published

2019-03-29

How to Cite

[1]
D. L. Zariatin, D. Rahmalina, E. Prasetyo, A. Suwandi, and M. Sumardi, “The effect of surface roughness of the impeller to the performance of pump as turbine pico power plant”, J. Mech. Eng. Sci., vol. 13, no. 1, pp. 4693–4703, Mar. 2019.

Similar Articles

<< < 13 14 15 16 17 18 19 20 21 > >> 

You may also start an advanced similarity search for this article.