Jtam-A4.dvi


JOURNAL OF THEORETICAL

AND APPLIED MECHANICS

51, 2, pp. 363-373, Warsaw 2013

STUDY OF TOPOLOGY AND VORTEX STRUCTURE IN TURBINE

CASCADES WITH TIP CLEARANCE UNDER DIFFERENT

INCIDENCE ANGLES

Pei-Gang Yan

Harbin Institute of Technology, School of Energy Science and Engineering, Harbin, China

Xiao-Qing Qiang, Jin-Fang Teng

Shanghai Jiao Tong University, School of Aeronautics and Astronautics, Shanghai, China

e-mail: qiangxiaoqing@sjtu.edu.cn

Wan-Jin Han

Harbin Institute of Technology, School of Energy Science and Engineering, Harbin, China

Three sets of conventional straight, positive curved and negative curved turbine cascades
with tip clearance were tested with experimental measurement. The impact of incidence
angles and blade bending on the tip leakage was studied under larger clearance (0.036 of
span). An ink trace visualization of the wall flow and topology theorywas adopted and thus
the topological structures of the blade surface, the upper and lower end wall were analyzed
in this paper. It was found that, compared with the same cascade under the zero incidence
angle, the saddle points allmove to the upstream, the scope of the separation expands along
the flow and span direction, and the separation line of the upper and lower passage vortex
climb to the middle span of the blade when the flow incidence angle increased from zero
to 20◦. Under the condition of zero and 20◦ incidence angle, the positive curved blade will
eliminate the upper passage vortex. The numbers of singular points are reduced and the
interaction loss between the passage vortex and the leakage vortex is greatly reduced too.
On the other hand, it also strengthens the blocking effect of the end wall cross flow on the
leakage flow, thereby reduces the relative leakage flow rate.

Key words: turbine cascade, tip clearance, topological rules, experimental study

1. Introduction

In modern high-performance turbo engines, the leakage losses generated from the rotor tip
clearance flow (including the relative leakage flow rate and leakage flow loss) accounts for a
sizeable proportion of the total losses in a turbine stage. For a long time, in order to reduce
these losses, researchers havemade painstaking efforts to explore a number of effectivemethods,
and many of them have been applied to engineering practice. Among them, the curved and
twisted blade technique has been proved to be an effective method. The mechanism of curved
and twisted blade to reduce flow loss has been revealed in a turbine stator without clearance
(Williams et al., 2008; Liu T. and Woodiga, 2010). However, the mechanism of leakage losses
under a different gap size and flow incidence angle is not identical. Themechanism of the curved
blade to reduce leakage losses is not exactly the same.
Topological analysis is a theoretical tool to obtain the flow structure information from flow

visualization pictures. It has been widely and successfully applied to the outflow research (Li-
ghthill, 1963; Tobak and Peake, 1982; Liu M., 1987; Dellery, 1991; Bringhenti and Barbosa,
2008). Wang Zhongqi and his research group (Song, 1997; Su and Wang, 1992; Huang, 1997;
Kang, 1990; Zhang, 2007; Yang, 2006) introduced the topology method to analyze the flow in
turbo-machinery, derived the topology rules of annular rotor and stator both of the wall and



364 P.-G. Yan et al.

cross-section flow. Detailed analysis of wall and cross-section flow pictures in an annular com-
pressor cascadewith tip clearancewasperformedandprovided the topology andvortex structure
of this type of cascade. It pointed out that the concentrated shedding vortex plays a dominant
role in the generation of flow losses.

On this basis, in this paper, the ink flow visualization method is adopted to study the flow
patterns on both the blade surface and end wall in a turbine cascade with a gap of 0.036 span
heights. By topology analysis, the topology andvortex structure under different incidence angles
of the tested cascade is achieved, and then, the similarities and differences of the flow structure
of incidence angle and stack line are discussed to reveal themechanism of energy loss generation
and the curved blade to reduce losses (especially leakage loss) in a turbine cascade with tip
clearance.

2. Test models

A five-hole probe is used to measure the flow field parameters both in rectangular cascades
and in tip clearance. The ink visualization is performed on the blade surface and end wall. The
experiment is conducted by the low-speed cascadewind tunnel ofHarbin Institute of Technology
(shown in Fig. 1a). The air flow comes from a 75kW centrifugal fan. The airflow is compressed
by the centrifugal fan into a 3m long regulator tube, the honeycomb, convergence tube, inlet
part, side plate, tested cascade and tailgate in turn. With the stepper motor and coordinate
frame of the test system, the probes canmove in three directions (x,y,z) and rotate around its
own axis, which canmeasure the cascade along the axial, spanwise and pitchwise direction.

Fig. 1. Schematic of the low speed wind tunnel and tested cascademodels; (a) low-speed cascade wind
tunnel (1 – regulator tube, 2 – honeycomb, 3 – convergence tube, 4 – inlet part, 5 – side plate,

6 – rotating disc, 7 – tested cascade, 8 – tailgate), (b) tested cascades

The testmodels contain three sets of gas turbine rectangular cascades: conventional straight
cascade; the 20◦ positive curved cascade; and the −20◦ negative curved cascade (shown in
Fig. 1). The cascade parameters are shown in Table 1. In this paper, the ink display method is
used to reveal the flow pattern through the topological vortex structure, and therefore, there is
no further discussion on flow field measurement results.

In this study, the ink display method is used to show that the flow patterns both on the
blade and end wall. First, we need to drop some ink droplets in the appropriate position of the
blade surface. When the fan works properly, the air flow channel gate is opened to control the
airflow flow rate. The ink droplets move along the blade surface and end wall with a certain
speed of the airflow and drags a track which can be identified as the limiting streamlines on the
surface. Through a combination of the flow parameters measured by probes and the topological
analysis, we can get the detailed flow structure of the cascade flow.



Study of topology and vortex structure in turbine cascades... 365

Table 1.Geometry data of the tested cascades

Blade chord b=120.5mm Outlet metal angle α2p =−63
◦

Span h=110mm Camber angle ∆α=113◦

Pitch t=90mm Blade counts N =6

Relative chord length t/b=0.763 Tip clearance τ =4mm

Axial chord B=118.5mm Relative tip clearance τ = τ/h=0.036

Aspect ratio h/b=0.913 Total pressure at inlet P∗0 =10730Pa

Leading edge radius R1 =6.75mm M at outlet mid-span M =0.3

Trailing edge radius R2 =3.37mm Re (based on chord) Re=8.3 ·10
5

Inlet metal angle α1p =50
◦ Inlet boundary layer thickness δ=14mm

3. Topology rules

The surfaces of a cascade with tip clearance can be decomposed into two unconnected surfaces:
casing and rotor surface. In which, the rotor surface contains of the blade surface and hub. The
friction lines are surrounded with many odd points on these surfaces.
Onthe surface, the three-dimensional separationof theLighthillmodelgives the total number

of nodes, and the saddle points should satisfy the relationship below

∑
N −

∑
S=2(2−n) (3.1)

Among them, n is the number of connected domains and N and S, respectively, for the number
of nodes and saddle points. For the annular cascade with tip clearance, the blade surface and
the inner ring form a connected domain while the outer ring forms another one. Thus, the odd
points on the blade surface and hub wall should follow the following equation

∑
Nbh−

∑
Sbh =0 (3.2)

where
∑
Nbh and

∑
Sbh represents the total number of nodes and saddle points on the blade

surface and hub wall.
The flow on the shroud wall is governed by the same topological rules

∑
Nc−

∑
Sc =0 (3.3)

where
∑
Nc and

∑
Sc represents the total number of nodes and saddle points on the shroud

wall.
The flow patterns around the solid cascade surface with tip clearance, on the whole, have

the same numbers of node and saddle points. The topologies of rectangular cascades with tip
clearance equivalents to that of annular cascades and follow the topological rules above.

4. Topology and vortex structure under zero incidence angle

4.1. Topology analysis of straight cascades shroud with tip clearance

Figures 2a-c illustrates the ink visualizations on the shroud wall of the straight, positive
curved and negative curved cascades. Figure 2d gives out the topology structures. The figures
show that the characteristics flow patterns at the shroud wall contains a double saddle point
near the tip leading edge, the separation line Ls and the reattachment line Lr.Within onepitch
on the shroud wall there are two areas, one is the tip clearance area, and another area is the



366 P.-G. Yan et al.

flow area. If it is bounded by the tip suction side, the transverse pressure gradient is opposite at
these two sides. The endwall boundary layers clustered near the tip suction and pressure side or
even separated under the effects of the pressure gradient and formed a separation line Ls and
a reattachment line Lr. Along the pitchwise direction, the static pressure on Ls are minimum,
the limiting streamlines asymptotic to it on both sides, the separation line starting from Ls and
flows into the far field. The static pressure on Lr aremaximum, the limiting streamlines depart
from it on both sides, which means that the far field flows toward the end wall.

Fig. 2. Flow visualization on the tip wall (incidence 0◦); (a) straight cascades, (b) positive curved
cascades, (c) negative curved cascades, (d) topology structure at clearance

The transverse pressure gradient within the flow and gap will affect the circumferential
distribution of static pressure in the upper region of the leading edge. The kind of topological
structure on the leading edge end wall is closely related to the circumferential distribution of
local static pressure.
At the sidewithout clearance, the transverse pressure gradient only has one directionwithin

one pitch. In this casing, it forms a single saddle point separation. At the side with clearance,
affected by the transverse pressure gradients which have the opposite direction in the flow
passage and tip clearance, there occur two areas with the opposite pressure gradient in front
of the leading edge. Under the action of the opposite direction pressure gradient within the
end wall boundary layer, there forms a special flow pattern with two saddle points (Sh,Sl)
and two nodes (Nh,Nl) on the suction side and pressure side of the leading edge. As Fig. 2d
shows, the friction lines through the saddle point Sh on the suction side of the leading edge
have two branches. It indicates that if there is a tip clearance, partial flow of the inlet end
wall boundary layer forms the suction side horseshoe vortex in front of the leading edge. Among
them, the suction side branches around the leading edge enter into the suction side of the shroud
corner under transverse pressure gradient and join with the leakage vortex separation line Ls
at about 0.05 axial chord locations. The pressure side branches flow downstream and enter
into the tip clearance. Under the same transverse pressure gradient, it slants through the tip
and merges with the leakage vortex separation line Ls at about 0.25 axial chord locations. In



Study of topology and vortex structure in turbine cascades... 367

area B, where these two branches surrounded, the limiting streamlines gradually move closer
to these two branches and form an attached node pointNh at the downstream of Sh. This flow
phenomenon also occurs on the pressure side. Another part of the inlet endwall boundary layer
separates from the saddle point Sl and forms the pressure side of the horseshoe vortex. The
suction side branches flow downstream and meet with the pressure side separation lines of the
suction side horseshoe vortex. The pressure side branches slant through the flow passage and
converge to the separation line Ls under the transverse pressure gradient and form an attached
node point Nl at the downstream of Sl. As the separation line Ls and the reattached line Lr
stretch downstream, these two lines intersect at about 1/3 axial chord beyond the trailing edge
and form a saddle point Sw. One of the separation lines started from Sw extends further to the
downstream, and the other onemoves upstream into the spiral point Nsw.

On the whole, there are three saddle points, two reattached node points and one separation
spiral point on the shroud wall with tip clearance. Total number of singular points follows the
topology rules shown in Eq. (3.2).

4.2. Topology analysis of straight cascades blade and hub with tip clearance

Figure 3 shows the ink track and topological structure on the blade surface and the endwall
of the straight cascades. During the ink trace test, the development of the ink trace is recorded
instantly to describe the specific topological disciplines. It can be seen that the reattachment line
started from the attached node point Nam near the leading edge middle span climbs towards
upper blade span and gets into the tip clearance with leakage flow. The reattachment line
diagonally crosses the blade tip and intersects the blade tip suction side at about 30% axial
chord length. And then it enters the extension below the suction side and inclined slightly to
form a saddle point Sc. From the saddle point, there are two separation lines. One of them
develops along the tip suction side to the downstream and ends in the separation point Nst
near the trailing edge. Another one extends into the bottom of the suction side and gets into
the separation point Nsu at 1/3 span height away from the tip. The attached node point Nc is
formed at downstream of Sc. There are two reattachment lines from Nc. One of them reversely
flows upstream Sc, and the other one flows downstream and meets the trailing edge at about
1/5 span fromthe tip and forms the saddle point Su. In thepicture,we also could find separation
in the tip clearance flow. There are two separation lines from the saddle point Sd at about 35%
axial chord. One of them meets the separation branches of Sc along the blade tip suction side,
and another one overlaps with the edge of blade tip pressure side and ends on the pressure
side trailing edge separation node Npt. At the downstream of Sd, there forms an attached node
point Nd.

Fig. 3. Ink track and topological structure on the blade surface and the end wall of straight cascades
(incidence 0◦)



368 P.-G. Yan et al.

The similar flow conditions occurs in the lower end wall and suction surface comparing to
the flow within no-gap cascade. The end wall boundary layer meets the cylindrical inlet edge
and forms a separation saddle point Sa and two horseshoe vortex branches.The pressurebranch
diagonally crosses the flow channel and meets the horseshoe vortex suction side branch of the
adjacent blade passage and forms the saddle point Sb. One of the separation lines ends in the
separation node point NSl, and another one ends in Nsw. There is a saddle point Sw. One of
the two separation lines ends in Nsw, and the other flows downstream. The reattachment lines
from Nb also end in Sh.

The tip clearance leakage flow starts from the pressure side to the suction side and the cross
flow at the bottom end wall is also from the pressure side to the suction side. Therefore, the
limiting streamlines of the pressure surface extend to both end walls form the middle span. It
forms a reattached line from Nam which ends in Smp.

In the conventional straight cascade, there have nine saddle points, four attached points,
four separation points and a separation spiral point. The total number of singular points follows
Eq. (3.3).

4.3. Impact of curved blade on topology and vortex structure

Figures 4a,b show the ink track of positively andnegatively curved cascades. Comparedwith
the straight cascades, the topological and vortex structure of negative curved cascades is similar
to it, while the positive curved cascades are different. The negative curved cascades only change
the position of singular points, while remain its type and numbers unchanged. As the ink track
shows, the positive curved cascades eliminate the separation line of the upper passage vortex
and the numbers of singular points thus is reduced from 24 (total number of Fig. 2d and Fig. 4)
to 20 (total number of Fig. 2d and Fig. 6).

Fig. 4. Ink track and topological structure on the blade surface and the end wall of positive and
negative curved cascades (incidence 0◦); (a) ink track visualization (left – straight cascades,
right – positive curved cascades), (b) topology structure (left – positively curved cascades,

right – negatively curved cascades



Study of topology and vortex structure in turbine cascades... 369

The positive curved cascades change the topology structure and improve the aerodynamic
characteristics of the cascade are because:

1) the positive curved cascades reduce the singular and semi-odd points and also reduce the
viscous shear effects and entropy increase;

2) it eliminates the upper passage vortex and prevents the cross flow to be pushed to the
middle span but attaches to the upper end wall and enhances the block of leak flow;

3) positive curved cascades reduce the pressure difference between the tip pressure side and
suction side, weaken the driving force of the leakage flow.

As for the negative curved cascades, the impact on leakage flow rate is just opposite. The
anti-C-type of pressure contours pushes the upper passage vortex to the tip region and enhances
theblock of leakage flow.The enhancedpressuredifferencebetween thepressure side and suction
side strengthens the driving force of the leakage flow. Compared with the straight cascades, the
increase or decrease of leakage flow rate depends on which aspect is dominant. While the tip
clearance is 0.036, the pressure difference plays the main role and thus the leakage flow rate in
negative curved cascades is larger.

5. Topology and vortex structure under 20◦ incidence angle

Figure 5 shows the ink track of these three sets of cascades at 20◦ incidence angle. Compared
with Fig. 2, in addition to the location of the singular points and separation range, these three
sets of cascades have the same number and type of singular points. At 20◦ incidence angle, the

Fig. 5. Flow visualization on the tip wall (incidence 20◦); (a) straight cascades, (b) positive curved
cascades, (c) negative curved cascades, (d) topology structure at clearance

saddle points Sl and Sh move to the upstream andmiddle passage. The region surrounded by
the two branches of the horseshoe vortex extends along the flow direction. Themeeting location
of these two separation lines with Ls moves upstream. The limiting streamlines tend to be



370 P.-G. Yan et al.

perpendicular to the pressure and suction sides. The changes of upper end wall topology are all
because the leading edge blunting and cross pressure gradient increase with the increase of the
flow attack angle.
Figures 6 and 7 illustrate the ink visualizations on the shroud wall of the straight, positive

curved and negative curved cascades at 20◦ incidence angle and 0.036 relative tip clearances.
Compared to Fig. 2, themain changes are: first, Sa, the saddle of the leading edge at the lower
endwall of the blade moves to the upstream and the middle passage of the cascade. Sb, Sc
and Sα, which represent the saddle point near the suction side at the lower endwall, the saddle
point near the suction side, and the saddle point on the blade tip, also move upstream. This
shows that the horseshoe vortex of lower end wall, the upper and lower passage vortex, the
suction side corner vortex, the tip separation vortex and the secondary vortexes occurred in the
more upstream location, the vortex intensity are increased at the same axial chord position.
Secondly, the separation lines of the lower and upper passage vortex meet at about 75% of
the axial chord from the leading edge, these two contrary rotated passage vortexes converge at
this location and exhibit intense interaction, and the eddy dissipation loss rapidly increases. It
can be inferred that within the straight cascade flow loss, the passage vortex and tip leakage
vortex interaction loss accounts for amajor proportion at the zero attack angle while the lower
and upper passage vortex convergence loss accounts for the main part at 20◦ incidence angle.
Thirdly, because the separation lines of the upper and lower passage vortex meet together, the
total number of singular points of the straight cascade reduce from18 to 16, including one saddle
point and one separation node.

Fig. 6. Flow visualization on the end wall and blade surface of the three cascades (incidence 20◦);
(a) straight cascades, (b) positive curved cascades, (c) negative curved cascades

The number and type of singular points on the blade surface and the lower end wall of
positive curved cascades are the same both at zero and 20◦ incidence angles. The saddle point
Sa and Sb locate in the most upstream position as well as the horseshoe vortex and lower
passage vortex. The lower passage vortex climbs up to the middle span at about 30% of the
axial chord and moves downstream. As decried above, the positive curved cascade eliminates
the upper passage vortex, there does not exist a counter rotating vortex at the middle span.



Study of topology and vortex structure in turbine cascades... 371

Fig. 7. Topology and vortex structure on the end wall and blade surface of the three cascades
(incidence 20◦); (a) straight cascades, (b) positive curved cascades, (c) negative curved cascades

Compared to that at zero incidence angles, the positive incidence angle does not bring a greater
loss. Itmeans that the positive curved cascades reduce the flow lossmore significantly than zero
incidence situations.

The number and type of the singular point on the blade surface and lower end wall of
negative curved cascades are the same both at the zero and 20◦ incidence angle, only the
locations change. The four saddle points (Sa, Sb, Sc and Sα) locate more upstream than the
zero incidence situations and more downstream than 20◦ incidence angle situations of straight
cascades. The lower andupperpassage vortexesmeetwith each other at the upstreamof trailing
edge.

6. Conclusions

Through ink visualizations and topology analysis of the flow in different cascades, this article
establishes the topology and vortex structures in a bent cascade with large tip clearance. From
the point of view of identification of the fine structure of the flow field, it has been revealed that
the blade bent led to a relative increase or decrease in the amount of the leakage flow rate and
loss mechanism. It comes to the following conclusions:

• The positive curved blade cascade with tip clearance leads to significant changing of the
topology and vortex structure under zero incidences. One is to reduce the number of
singular points and half ones, and reduces the entropy increase of flow around the cascades
aswell as the viscous shearwall effects; the second is to eliminate the upper passage vortex
and reinforce leakage flow cross-blocking force caused by the end wall cross flows. The
negative curved blade cascade only changes the location of singular points and remains
the type and numbers unchanged. The improvements of aerodynamic performance by the
negative curved cascade are lower than those of positive ones.



372 P.-G. Yan et al.

• The total number of singular points on thewall surface of straight cascades decrease when
the flow incidence angle increases from 0◦ to 20◦. Comparedwith the zero incidence cases,
the saddle points of the three sets of cascades move forward, the scope of the separation
region expands along the flow and vertical direction and the separation lines of the lower
and upper passage vortex climbs to the middle span. In the straight cascade, these two
separation lines meet at about 75% of the relative chord at the middle span. The lower
and upper passage vortexes with the opposite rotary direction mix and increase the flow
loss. The positive curved cascade also eliminates the upper passage vortex and reduces the
extra loss caused by the lower and upper passage vortex mixing. The separation lines of
the lower and upper passage vortex in the negative curved cascade meet later along the
flow direction than that in the straight cascade.

Acknowledgements

This work was supported by the National Natural Science Founding of PR China under Grant

No. 51121004.

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7. Liu T., Woodiga S.A., 2010, Experimental examination of skin friction topology in separated
flows, 48th AIAA Aerospace Sciences Meeting, AIAA-2010-0045

8. SongY., 1997,AnExperimental Investigation into the Influence of the Blade Curving on the Flow
Field Structure and Performance in an Annular Turbine Cascade, Doctoral dissertation of Harbin
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9. Su J., Wang Z., 1992, Profiling of simultaneously vaulted and twisted blades-theory, experiment,
design and application,Power Engineering, 12, 6, 1-6

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of Fluid Mechanics, 14, 1, 61-85

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Study of topology and vortex structure in turbine cascades... 373

Badania topologii i struktury wirów palisady turbiny z luzem wierzchołkowym przy

różnych kątach natarcia

Streszczenie

W pracy zaprezentowano wyniki pomiarów eksperymentalnych trzech zestawów konwencjonalnych
palisad turbin o prostym, dodatnio i ujemnie zakrzywionym profilu. Zbadano wpływ kąta natarcia oraz
efekt zginania łopatek na stratywskutek upływu przy luzie wierzchołkowymsięgającym3.6% rozpiętości
łopatek. Do analizy zastosowano wizualizację śladów pozostawianych barwnikiem oraz teorię topologii,
tj. struktur topologicznych reprezentujących powierzchnię łopatki oraz górnej i dolnej ściany krańcowej.
Zaobserwowano, że w porównaniu do analogicznej palisady o zerowym kącie natarcia wszystkie punkty
siodłowe przesuwają się w górę przepływu, a obszar oderwania strugi rozszerza się wzdłuż promienia ło-
patki. Jednocześnie granica oderwania górnego i dolnego wiru przemieszcza się ku środkowi łopatki, gdy
kąt natarcia narasta od zera do 20◦. Przy tych granicznychwartościach kąta natarcia łopatki o dodatniej
krzywiźnie profilu eliminują górny wir podczas przejścia. Ponadto okazało się, że liczba punktów osobli-
wych zmniejszyła się podobnie, jak osłabiła się interakcja pomiędzy wirami przejścia i wirami upływu.
Stwierdzono, że wzmacnia to efekt blokowania upływu poprzecznym przepływem na krańcowej ścianie
łopatki, co ostatecznie redukuje straty indukowane upływem.

Manuscript received May 8, 2012; accepted for print June 24, 2012