Parametric Modeling of Single-stage Double-suction
Centrifugal Pump Impeller
L J Du
1
, H L Chen
1
, W Liu
2
, Y H Wang
1
, X R Chu
1
and J Gao
1,*
1
School of Mechanical, Electrical&Information Engineering, Shandong University,
Weihai, Weihai 264209, Shandong, China;
2
Shandong Shuanglun Co., Ltd., Weihai 264203, China
Corresponding author and e-mail: J Gao, shdgj@sdu.edu.cn
Abstract. Aiming at the parametric modelling design of the single-stage double-suction
centrifugal impeller, C# was used for secondary development with software SolidWorks.
Based on the created parametric driving model, the impeller with different design parameters
can be obtained quickly. The boolean operation was performed on the parameterized impeller
structure model to obtain the water body model. And the fluid numerical simulation of
hydraulic performance of the impeller can be obtained through ANSYS, which saves a great
work of the impeller design and improve work efficiency.
1. Introduction
A single-stage double-suction centrifugal pump is a typical centrifugal pump with an impeller, two
suction inlets and one discharge outlet, and adopts a mid-open structure. Due to its advantages of
simple structure, easy maintenance, high reliability, high flow rate, high efficiency, and small
cavitation loss, single-stage double-suction centrifugal pumps have a wide range of applications in
various fields of production and life [1].
The impeller is the core component of the single-stage double-suction centrifugal pump and it
determines the hydraulic performance of the pump. Therefore, the design of the impeller is the most
important task of the pump design. At present, modeling software has been widely used in the
process of impeller design, and the model is simulated by computer to get the impeller products that
meet the requirements of the design. However, because of the complex geometry of impeller, the 3D
modeling process is rather cumbersome. The manual modeling method is time-consuming and
laborious. In the process of designing an impeller, the parameters of the impeller need to be modified
many times for the optimized simulation results, which causes the designers a lot of work and affect
the design efficiency [2-3]. The impeller is a typical serialized product. The same type of impeller
has a similar structure and different sizes. The modeling process and the modeling method are
basically the same. Therefore, the parametric modeling method can be adopted. Based on the created
parametric driving impeller model, with the input modeling parameters, the preset process
automatically completes the modeling of the impeller, improving design efficiency and shortening
the design cycle.
In order to realize the parametric modeling of the single-stage double-suction centrifugal pump
impeller, C# language was used to carry out the secondary development of SolidWorks software, and
250
Du, L., Chen, H., Liu, W., Wang, Y., Chu, X. and Gao, J.
Parametric Modeling of Single-stage Double-suction Centrifugal Pump Impeller.
In Proceedings of the International Workshop on Materials, Chemistry and Engineering (IWMCE 2018), pages 250-256
ISBN: 978-989-758-346-9
Copyright © 2018 by SCITEPRESS – Science and Technology Publications, Lda. All rights reserved
created the pump impeller parametric modeling procedure. The created model was imported into
ANSYS to carry out the hydraulic simulation to verify the effectiveness of the developed program.
2. Centrifugal pump impeller modeling method
Considering the general applicability of the program and the difficulty of development, SolidWorks
software was selected as the supporting platform. Based on the manual modeling process, a
parametric modeling process for a single-stage double-suction centrifugal pump impeller for a closed
impeller was designed as follows:
(1) According to the three-dimensional coordinates of the intersection point of the wood pattern
cutting line and the axial plane intercept line, the "XYZ point curve" function is used to obtain the
wood pattern cut lines of all the blades. Use the “Slope” function to get the working surface and the
back of the blade, respectively.
(2) Use the "extended surface" function to extend the working face and back face of the blade
toward the direction of the impeller outlet and the direction of the rear cover plate by a certain
distance.
(3) Using the “Slope” feature to obtain the four sides of the blade, using the “Surface Suture”
function to stitch all the surfaces of the blade into one entity. The "cut-out" function is used to
remove the blade solids to ensure that the blades do not extend beyond the impeller, so that the
blades do not interfere with the front and rear cover plates after cutting.
(4) Use the "array" function to get all the blades.
(5) Draw the sketches of the front and rear cover plates, and use the “rotary boss/substrate”
function to obtain the front and rear cover plates.
(6) Use the "mirror" function to get a complete impeller model.
3. Parametric modeling program procedure
3.1. Selection and processing of parameters
Using program-driven method, it is necessary to provide the required parameters for each step
according to the already determined parametric modeling process. Some parameters can be obtained
through the operation of other parameters. Therefore, a set of modeling parameters that require
designers to input must be determined. The model parameters of the blade and the cover are
relatively independent, so they are explained separately.
The parameters of the blade modeling section are the number of blade woodcut lines and
corresponding angles, the number of axial plane intercept lines and the axial coordinates, the radial
coordinates of the intersection point of the woodcut line and the axial line or the boundary line, and
the blade boundary line parameters shown in Figure 1. This paper only analyzes the blades with a
single arc boundary line and double arc boundary line. For the blades with other types of boundary
lines, similar processing can be performed with reference to this method.
With the function “through the XYZ point curve” to draw the cut line of the wood pattern, and
after the wood pattern cut line undergoes laid out, extended, and stitched, the blade model was
obtained by the array function. The three-dimensional rectangular coordinate system was established
with the rotation axis of the impeller as the Z axis and the mirror surface as the XY plane. The XY
coordinate of the intersection point of the wood pattern cutting line and the axial plane intercept line
or the boundary line can be obtained by multiplying the radial coordinate of the intersection point and
the sine and the cosine of the section angle of the wood pattern cutting line corresponding to the point.
The Z coordinate of the intersection point of the wood mold cutting line and the axial surface section
line is the same as the axial coordinate of the axial surface section line corresponding to this point.
The Z coordinate of the intersection point between the wood mold cut line and the boundary line is
more complex and related to the type of the boundary line. It needs to be calculated according to the
Parametric Modeling of Single-stage Double-suction Centrifugal Pump Impeller
251
geometric relationship. In this paper, the single-arc boundary line blade is taken as an example to
illustrate wooden cutting line and the boundary point Z coordinate calculation process. The
double-arc boundary line blade and other types of boundary line blade can be similarly calculated
with reference to this process.
Figure 1. Parameters of blade boundary line a) Single Arc. b) Double arc.
For the intersection point on the boundary of the single arc front cover, the following formula can
be obtained according to the geometric relationship:
1
tan sin
2
IR
α
α
×=×
(1)
21
1
tan
tan 2
DD
HR
α
α
×
−
=+
(2)
When the
90
α
≠°
,
2
111
((ZHc R RD
ρ
=+− −+−))
,
11
( D < I+D )
ρ
≤
(3)
2
tan
D
Z
c
ρ
α
−
=+
,
12
()ID D
ρ
+<<
(4)
When the
=90
α
°
,
22
1101
()ZRc R R D
ρ
=+− − +−
,
11
( D < I+D )
ρ
≤
(5)
Z = c
,
12
()
I
DD
ρ
+<<
(6)
For the intersection point on the borderline of the single arc rear cover, the following formula can
be obtained according to the geometric relation:
2
tan sin
2
IR
β
β
=× ×
(7)
20
2
tan
tan 2
DD
HR
β
β
−
=+×
(8)
When the
90
β
≠°
,
22
220
(-ZH R R D
ρ
=− − + )
,
00
( D < I+D )
ρ
≤
(9)
IWMCE 2018 - International Workshop on Materials, Chemistry and Engineering
252
2
tan
D
Z
ρ
β
−
=
,
0
()ID
ρ
+<
(10)
When the
90
β
=°
,
22
2220
()ZR R R D
ρ
=− − +−
,
00
( D < I+D )
ρ
≤
(11)
0Z =
,
0
()ID
ρ
+<
(12)
After obtaining all the three-dimensional coordinates of the insection point of the wood mold and
the axial line or the boundary line, the blade part modeling can be completed according to the
determined parametric modeling process.
The cover plate model is obtained by the function of "rotary convex platform/matrix". Therefore,
the key to the modeling of the cover plate is to determine the coordinate of each parameter point
needed in the sketching command. Taking into account the actual drawing of the project, reduce the
designer's calculation of the parameters as much as possible, the modeling parameters selected in this
paper can be obtained directly from the engineering drawings. This article only takes one structural
type cover plate as an example, and other types of cover plate parameter selection can refer to this
process. All the parameters required in the modeling of the cover plate are shown in Figure 2.
According to the geometric relationship between each parameter point, the equations between the
coordinates of each parameter point and the modeling parameters can be established, and the
coordinates of each parameter point can be obtained through calculation. In this way, using the
drawing function of SolidWorks to insert straight lines, arcs and chamfers, completing the sketching
of the front and rear cover plates, and finally using the “rotary convex platform/matrix” function to
obtain the front and rear cover solid models.
Figure 2. Parameters for the cover.
3.2. Program design
The main API functions are as follows:
Insertion Point: ModelDoc2.InsertCurveFilePoint
Surface Loft: ModelDoc2.InsertLoftRefSurface2
Surface extension: ModelDoc2.InsertExtendSurface
Surface Suture: FeatureManager.InsertSewRefSurface
Parametric Modeling of Single-stage Double-suction Centrifugal Pump Impeller
253
Cut: ModelDoc2.InsertCutSurface
Array: FeatureManager.FeatureCircularPattern4
Sketch: SketchManager.CreateLine, SketchManager.CreateArc
Rotary Boss / Base: FeatureManager.FeatureRevolve2
Mirror: FeatureManager.InsertMirrorFeature
The impeller modeling is divided into two parts, blade modeling and cover plate modeling. Each
part is divided into two major steps, modeling parameter coordinate calculation and
three-dimensional modeling. In this way, the designer inputs the modeling parameters through the
user interaction interface, the program automatically completes the parameter calculation, and calls
the SolidWorks API function to perform the modeling operation in a predetermined sequence to
complete the modeling of the impeller.
4. Examples and discussion
A typical single-stage double-suction centrifugal pump impeller was used as an example to verify the
correctness of the impeller model established by this SolidWorks secondary development program,
and the numerical simulation of its hydraulic performance was performed using ANSYS software.
4.1. The establishment of an impeller model
The single-stage double-suction centrifugal pump impeller is selected as an example. The type of the
boundary line is a single arc boundary line. By entering the following parameters of the blade: the
number of wood mold cutting lines and the corresponding angle, the number of axial plane intercept
lines and the axial coordinate, the radial coordinates of the wooden cutting line between the axial
plane or border line, and blade number, the blades can be generated. Enter the modeling parameters
of the cover plate, click the function button to complete the cut off, front cover modeling, rear cover
plate modeling and impeller mirror functions, the generated impeller model is shown in Figure 3.
4.2. Meshing and numerical calculation
The structure of the double-suction mid-open pump is complex and there are rotating and stationary
areas. The design parameters are: revolving speed 990 r/min, flow rate 3200
/ℎ, head of delivery
22m, efficiency 88%, water density 997kg/
. First, the parameterized impeller model is used to
perform Boolean operation to obtain the impeller water model. Then, the impeller water model and
its associated shell water calculation model are imported into ICEM in the Parasolid format for
boundary and entity definition, and then the grid division function is used to generate the mesh, and
imported for the numerical simulation of internal flow. The walls adopt triangular meshes, and the
unstructured tetrahedral meshes are used in the solid part to facilitate the convergence of calculations
and obtain more accurate simulation values. The water flows in the pump as incompressible flow, and
there is no heat exchange between the water flow and the outside [4-5]. Therefore, the numerical
model does not include the energy equation model. Speed condition is selected as the inlet boundary,
and outflow condition is selected as the outlet boundary. The adopted mesh model is shown in Figure
4.
Figure 3. Impeller model.
Fi
g
ure 4. Im
p
eller water
g
rid dia
g
ra
m
.
IWMCE 2018 - International Workshop on Materials, Chemistry and Engineering
254
4.3. Simulation results and analysis
The simulation results of the design condition is shown in Figure 5 and Figure 6.Figure 5 shows the
total pressure distribution of the impeller. The total pressure is the sum of the static pressure and the
dynamic pressure, representing the energy of a unit volume fluid. It can be seen that as the impeller
rotates at high speed, the fluid energy gradually increases along the impeller flow path under
centrifugal force. From a physical point of view, the maximum flow velocity in the impeller's internal
flow field should be located at the impeller outlet, and the minimum flow velocity at the impeller
inlet. As shown in Figure 6, the flow of fluid entering the impeller is relatively uniform, the flow of
fluid in the pressure chamber is relatively smooth, and the speed gradient change is small, which is is
consistent with the theoretical analysis results [6]. The working medium is thrown from the impeller
to the pressure chamber outlet, the flow velocity gradually decreases along the flow direction and
reaches a minimum value near the outlet of the pressure chamber, and there is no obvious sudden
change. This is consistent with the design principle of the pressure chamber. From the overall flow
field distribution, it can be seen that the overall flow trend simulated by the commercial software
ANSYS is consistent with the design theory of the impeller and the pressure chamber. And the
simulation results show that the pump's analysis efficiency is 89.1%, which has exceeded the design
efficiency of 88%, proving that the performance of the calculation model meets the design
requirements.
Figure 5. Impeller total pressure distribution.
Figure 6. Overall flow field distribution.
Parametric Modeling of Single-stage Double-suction Centrifugal Pump Impeller
255
5. Conclusions
1) Establishing a single-stage double-suction centrifugal pump parametric modeling system using
SolidWorks secondary development is feasible;
2) The impeller model generated by this method is the same as the model obtained by manual
modeling. It can generate impeller models with multiple blade types, and more types of
impellers can be added as needed to meet the actual design needs.
3) The impeller model generated using this method can meet the requirements of the model for the
hydraulic analysis of the impeller.
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[3] Higbee R W, Giacomelli J J and Wyczalkowski W R 2013 J. Advanced impeller design:
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[4] Liu B, Zhang Y, Zheng Y, Huang B, Chen X and Jin Z 2016 J. Micromixing simulation of
novel large-double-blade impeller Journal of the Taiwan Institute of Chemical
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[5] Zhao X, Xiao Y, Wang Z, Luo H, Soo-Hwang A, Yao Y and et al 2017 J. Numerical analysis
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