- Open Access
- Total Downloads : 498
- Authors : Miraj S. Desai, Brijesh R. Naik
- Paper ID : IJERTV4IS080505
- Volume & Issue : Volume 04, Issue 08 (August 2015)
- DOI : http://dx.doi.org/10.17577/IJERTV4IS080505
- Published (First Online): 25-08-2015
- ISSN (Online) : 2278-0181
- Publisher Name : IJERT
- License: This work is licensed under a Creative Commons Attribution 4.0 International License
Optimum Design on Impeller of Mixed Flow Pump using CFD Simulation
Miraj S. Desai
Mechanical Engg. Department C.G.Patel institute of Technology, Bardoli, Surat, India
Brijesh R. Naik
Asst. Professor Mechanical Engg. Department
-
G. Patel Institute of Technology, Bardoli, Surat, India
Abstract The effects of the pump-impeller operating conditions and geometries on its performance were investigated. The analysis was carried out to study the effect of some parameter on the performance of mixed flow pump impeller. These parameters such as inlet blade angle, outlet blade angle. The impeller has been designed and built to study the effect of these parameters with the help of software for analysis. In this paper change the inlet & outlet angle of blade with increase the angle 10%, 20% and decrease the angle 10%, 20% with respect to design angles. From these all simulation was done, we should consider the best inlet & outlet angle to take the best head & efficiency of mixed flow pump.
Keywords Computational Fluid Dynamics, Efficiency, Mixed Flow Pump Impeller, Head
-
INTRODUCTION
The concept of mixed-flow (MF) pumps is by no means new, having been applied to large scale liquid transfer tasks such as irrigation, flood control, dewatering and power station cooling systems for almost a century. In common with many other industrial products, their development has been steady. The advent of nuclear power stations and of significantly larger fossil fuel stations, as well as the need for large-area irrigation schemes to meet rising demands for food, has in recent years lent urgency to this trend. Because MF pumps are inherently versatile and reliable when operated within their performance envelope, increased efforts are being made to extend their range.
Impeller is an important flow passage component in a mixed-flow pump. To find out the causes of low hydraulic performance of the original pump, it is necessary to study the flow in the impeller. While the impeller of the pump is operating, the impeller will rotate, and the geometric shape of the flow passage will be distorted. The water flow in the impeller is a complicated three-dimensional turbulent flow. Therefore, observing the flow situations in the impeller through experiment not only will be a waste of time, but also will cause economic losses due to the shutdown.
In this present work design of mixed flow pump impeller was carried out and effect on head & efficiency with changing the inlet & outlet angle of impeller blade to find out the best design point of impeller.
Fig. 1 mixed flow direction on impeller[2]
-
ANALYSIS OF MIXED FLOW IMPELLER
In this work detail geometry of mixed flow impeller was done in software CFTURBO. The parameter used for the design is head developed (H) = 5 m , mass flowrate (Q) = 125 kg/s & speed of rotation (N) = 1000 RPM[5].
The parameter of the impeller for the modelling of impeller is given in table I.
TABLE I DESIGN PARAMETER OF IMPELLER
Parameter
specification
mass flow rate
0.125 m³/s
Rpm
1000
Suction Head
5 m
hub dia.
30.7 mm
thickness leading edge
3.6 mm
Intel blade angle
22.7°
suction dia.
168 mm
impeller dia.
254 mm
outlet width
33.7
number of blade
6
thickness trailing edge
4.2 mm
Outlet blade angle
45.5°
Fig. 2 model of impeller
-
CHANGE THE INLET AND OUTLET ANGLE OF BLADE
For the improvement in design of impeller to get the best efficiency of pump, we should change the inlet & outlet angle of the blade. We can change the inlet & outlet angle as increase inlet angle 10%, 20% & decrease 10%, 20% and
increase outlet angle 10%, 20% & decrease 10%, 20% from the calculating angles that we can use as the exiting parameter.
TABLE II VARIOUS INLET & OUTLET ANGLE
Sr no.
Variation in angles
Inlet angle
Outlet angle
1
20% decrease
17.76
36.32
2
10% decrease
19.98
40.86
3
Calculating angles
22.2
45.4
4
10% increase
24.42
49.9
5
20% increase
26.64
54.58
All simulation with different angles was carried out in ANSYS software. The equation which is use to find out head & efficiency is given below:
A. Equations
Head: (m)
Input power: (kw)
Output (kw) Efficiency:
-
RESULT & DISCUSSION
In the result & discussion we can find the various head & efficiency with the help of equations.
-
Head at various inlet & outlet angle
TABLE III HEAD AT VARIOUS INLET & OUTLET ANGLE
outlet angle
head (m) at 17.76
inlet
head (m) at 19.98
inlet
head (m) at 22.2 inlet
head (m) at 24.42
inlet
head
(m) at 26.64 inlet
36.32
24.1033
25.5184
24.768
25.7733
25.8787
40.86
23.5735
23.5432
22.7263
22.6132
20.2877
45.4
16.256
22.753
20.289
18.754
39.0105
49.9
8.821
16.4305
16.2239
15.892
21.9061
54.48
26.427
23.057
27.798
35.518
17.8579
Fig. 3 Head at various inlet angle vs outlet angle
-
Efficiency at various inlet & outlet angle
TABLE IV EFFICIENCY AT VARIOUS INLET & OUTLET ANGLE
outlet angle
effi. (%) at 17.76
inlet
effi. (%) at 19.98
inlet
effi. (%) at 22.2 inlet
effi. (%) at 24.42
inlet
effi. (%) at 26.64
inlet
36.32
76.07
78.58
79.5
87.8
84.34
40.86
70.7
74.29
71.35
70.63
75.75
45.4
41.17
46.86
60.23
28.63
33.1
49.9
26.61
9.899
55.05
19.07
17.622
54.48
74.29
63.34
71.48
52.87
59.8
Fig. 4 Efficiency at vrious inlet angle vs outlet angle
-
-
CONCLUSION From result & analysis we can conclude that,
-
Inlet angle changes will changes range between 17.76° to 26.64° & outlet angle changes will changes range between 36.32° to 54.58°. from the fig. 3 maximum head at the point of inlet angle 26.64° & outlet angle 45.4°.
From fig. 4 maximum efficiency at the point of inlet angle 24.42° and outlet angle 36.32°.
So that we can conclude that best design point of impeller of pump that we can give the maximum efficiency of pump that is inlet angle 24.42° and outlet angle 36.32°. Here we can take the only efficiency for the design point of view.
REFERENCES
-
Igor J. Karassik, J. P. (2001). pump handbook. TATA MCGRAW- HILL PUBLICATION.
-
etd.lib.metu.edu.tr/upload/2/12608093/index.pdf
-
idmeb. engineering science data unit(2003) /80030b_15_23.pdf
-
Manivannan, A. (2010). Computational fluid dynamics analysis of a mixed flow pump impeller. International Journal of Engineering, Science and Technology , 200-206.
-
Arunangsu Das, A. K. (2013). Design and Stress Analysis of a Mixed Flow pump impeller. International Journal of Mechanical Engineering and Computer Applications.
-
Sambhrant Srivastava, A. K. (2014). Design of a mixed flow pump impeller blade and its validation using stress analysis. procedia material science , 417-424.
-
m. j. van os, j. g. (1997). a parametric study of the cavitation inception behavior of a mixed-flow pump impeller using a three-dimensional potential flow model. Department of Mechanical Engineering university of twente.
-
miner, s. m. (2001). 3-d viscous flow analysis of a mixed flow pump impeller. international journal of rotating machinery , 53-63.
-
Myles, D.J., A design method for mixed flow fans and pumps, Report No. 117, National Engg. Laboratory, 1965.
-
Stepanoff, A.J., Centrifugal and Axial flow pumps, 1957, John Wiley and sons 2nd Edition, New York.