This technical note summarizes research on the performance characteristics of Turgo and Pelton impulse turbines and their impact on pico-hydro installations. Laboratory tests were conducted on Turgo turbines to determine how efficiency is affected by variations in speed ratio and jet misalignment. The results show that under optimal conditions, Turgo turbine efficiency can exceed 80% at a speed ratio around 0.46. Both Turgo and Pelton turbines achieved peak efficiency at lower than theoretical ideal speed ratios, likely due to turbine inefficiencies. Jet misalignment caused efficiency to drop for Turgo turbines, demonstrating the importance of proper system design and installation for maximizing performance.
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Impulse (turgo and pelton) turbine performance characteristics and their impact on pico hydro installations
1. Technical note
Impulse (Turgo and Pelton) turbine performance characteristics and their impact
on pico-hydro installations
Bryan R. Cobb, Kendra V. Sharp*
School of Mechanical, Industrial & Manufacturing Engineering, 204 Rogers Hall, Oregon State University, Corvallis, OR 97331, USA
a r t i c l e i n f o
Article history:
Received 17 August 2011
Accepted 7 August 2012
Available online 20 September 2012
Keywords:
Hydropower
Turgo turbine
Pelton
Rural electrification
Pico-hydro
Micro-hydro
a b s t r a c t
Pico-hydropower is a viable technology that can be integrated into a decentralized, off-grid approach to
rural electrification in regions that currently have only limited access to electricity. The Turgo turbine is
classified as an impulse turbine, similar to the Pelton wheel, often used in pico-hydro systems. Both offer
high efficiency for a broad range of site conditions, but the primary difference is that the Turgo can
handle significantly higher water flow rates, allowing for efficient operation in lower head ranges and
thus potentially expanding the geographic viability. Published data on Turgo operating performance are
limited; despite the differences, discussion thereof in design manuals is generally lumped in with the
discussion of Pelton wheels. In this study, a laboratory-scale test fixture was constructed to test the
operating performance characteristics of impulse turbines. Tests were carried out to determine the effect
on turbine efficiency of variations in speed ratio and jet misalignment on two Turgo turbines. The results
were compared to similar tests in the same fixture on a Pelton turbine. Under the best conditions, the
Turgo turbine efficiency was observed to be over 80% at a speed ratio of approximately 0.46, which is
quite good for pico-hydro-scale turbines. Peak efficiencies for both the Pelton and the Turgo turbines
occurred at lower than theoretical ideal speed ratios based on a momentum balance; the reduction in
speed ratio at which peak efficiency occurs is likely caused by inefficiencies in the turbine. Tests of jet
misalignment showed that moving the jet to the inside or outside edge of the turbine blades caused
a drop in Turgo efficiency of 10e20% and reduced the optimal speed ratio by 0.03 (6.5%). Radial
misalignment had a significant adverse impact on both Turgo and Pelton turbines, however, angular
misalignment of the jet is more of a concern for the Turgo turbine. The results stress the importance of
proper system design and installation, and increase the knowledge base regarding Turgo turbine
performance that can lead to better practical implementation in pico-hydro systems.
Ó 2012 Elsevier Ltd. All rights reserved.
1. Introduction
Across the globe, 1.4e1.6 billion people have no access to elec-
tricity at all while another one billion are dependent on unreliable
electrical grids [1]. The United Nations (UN) has underscored the
importance of global access to electricity and other forms of energy
by setting a goal to achieve what it refers to as “universal access to
modern energy services” by 2030 [2]. Many of those lacking access
to modern energy live in rural areas, thus decentralized, off-grid
energy projects will play a vital role in achieving the UN’s energy
goal by 2030 [3].
Over the last 30 years, pico-hydropower (hydropower facilities
generating less than 5 kW [4])1
has been proven as a cost-effective,
clean, and reliable method of generating electricity and mechanical
power for off-grid applications and will play an important role in
rural electrification into the foreseeable future. In Nepal for
instance, 300 pico-hydro schemes constructed by Practical Action
are producing electricity, while 900 others are used for mechanical
power only [5]. Practical Action has also been involved with the
construction of another 70 installations in Sri Lanka and 15 in Peru
in recent years [5]. In the last decade, pico-hydro has become more
prevalent in Sub-Saharan Africa as well, where electrification
rates are some of the world’s lowest [6]. As of 2003, as many as
50 million households worldwide receive electricity from
* Corresponding author. Tel.: þ1 541 737 5246; fax: þ1 541 737 2600.
E-mail addresses: cobb.bryan@gmail.com (B.R. Cobb), kendra.sharp@
oregonstate.edu (K.V. Sharp).
1
Hydropower is commonly classified by power output as large (>10 MW), small
(<10 MW), mini (<1 MW), micro (<100 kW), and pico (<5 kW).
Contents lists available at SciVerse ScienceDirect
Renewable Energy
journal homepage: www.elsevier.com/locate/renene
0960-1481/$ e see front matter Ó 2012 Elsevier Ltd. All rights reserved.
http://dx.doi.org/10.1016/j.renene.2012.08.010
Renewable Energy 50 (2013) 959e964
2. hydropower on mini-grids, with several hundred thousand units
installed [7].
While pico-hydro presents significant advantages, including
cost, over other types of electricity generation, implementation can
present a challenge [8], including a heavy dependence on site-
specific conditions for scheme design [9]. Off-the-shelf systems
have been designed to reduce the site-specific design but this does
not completely eliminate the need for technical expertise [10]; in
order to ensure long term success of projects, proper design and
installation are important, as is community cooperation for day-to-
day management, though maintenance is not typically overly
difficult or time consuming.
1.1. Motivation
For implementation of pico-hydropower in developing coun-
tries, it is necessary to ensure that (1) appropriate technology exists
and (2) understanding and awareness of such technology exists
[8,10]. One area of appropriate technology for pico-hydro that has
lacked adequate attention up to this point is the use of Turgo
turbines. While Turgo turbines offer many of the same advantages
of Pelton turbines, such as high efficiency for a broad range of site
conditions, there are differences that are worth noting. Fig. 1 shows
photos of both a Turgo and a Pelton turbine. Currently, pumps-as-
turbines (PATs), a type of reaction turbine, are commonly used for
medium head schemes; however Turgo turbines are also a viable
solution in this range. A chart showing the applicable head ranges
for different turbine types is provided in Table 1.
Turgo turbines have been in use for hydropower since 1919 [11],
yet published work in typical design manuals [12,13] about their
operating performance is limited. Oftentimes, despite their differ-
ences, the discussion of Turgo turbines is lumped in with a discus-
sion of Pelton wheels. The most important difference is that the
Turgo can handle significantly higher water flow rates, allowing for
efficient operation in lower head ranges (than a Pelton wheel) and
potentially expanding the geographic viability of pico-hydro.
Several off-the-shelf turbine-generator sets are available with
Turgo turbines in North America [14e16] though performance
specifications are only provided as water-to-wire efficiencies
leaving specific turbine efficiency ill-defined. In and of itself, the lack
of access to off-the-shelf turbine-generator sets in developing
countries is not prohibitive for installation; many installations start
with individual components, and manufacturing (e.g. casting and
machining) of a Turgo turbine and Pelton wheel are comparable. A
number of documented installations of Turgo turbines [17] show
low operating efficiencies (20e30% rather than 50e60%) [15] sug-
gesting room for improvement on the design and installation of the
systems.
This study aims to demonstrate how parameters such as speed
ratio (ratio of tangential turbine velocity and jet velocity), system
design, and installation impact turbine efficiency, thereby
increasing the knowledge base in this area and improving Turgo
turbine implementation.
1.2. Objectives
This study seeks to experimentally validate the following
hypotheses: 1) Turgo turbine efficiency has a dependence on speed
ratio similar to the dependence observed with Pelton turbines; and
2) jet misalignment must be minimized in order to maximize
energy transfer from the water jet to an impulse turbine. Several
potential pitfalls of poorly-managed pico-hydro installations are
also investigated. While Turgo turbine use is emphasized herein,
based on our concurrent Pelton wheel testing [18], the findings are
broadly applicable to both turbine types.
2. Materials & methods
A laboratory test set up (Fig. 2), constructed to simulate a typical
pico-hydro scheme, consists of a vertical axis impulse turbine
directly coupled with a WindBlue Power DC-540 permanent
magnet alternator (PMA) and a 2-hp MP Pumps centrifugal pump
driving the flow of water to create a water jet that turns the turbine.
A 100-mm PCD brass ABS Alaskan Harris Pelton turbine, a 131-mm
PCD plastic Turgo turbine, and a 169-mm PCD plastic Hartvigsen-
Hydro Turgo turbine were tested. The generator (and associatedFig. 1. Photos of (a) a Turgo turbine and (b) a Pelton turbine.
Table 1
Classification of turbines used for pico-hydro based on hydraulic head and type
(adapted from Paish [21]).
Turbine type Low (<10 m) Medium (10e50 m) High (>50 m)
Impulse Crossflow Crossflow
Turgo
Pelton
Turgo
Pelton
Reaction Francis
Propeller
Kaplan
Francis
B.R. Cobb, K.V. Sharp / Renewable Energy 50 (2013) 959e964960
3. bearing) is mounted atop an inverted catch basin containing the
turbine and nozzle, and the mount allows the generator to spin
freely about the shaft. Isolation and flow control valves are located
in the Polyvinyl chloride (PVC) pipe flow loop.
Various instruments were installed throughout the system in
order to characterize the performance of the principle components,
the nozzles, turbine and PMA. An FP-7001A paddle wheel flow
sensor (range of 0e50 gpm) measures the volumetric flow rate of
water through the flow loop. An Omega PX309-050 GV pressure
transducer (range of 0e50 psig) is used to monitor pressure in the
loop. A Fluke 189 and a Sears Model 982015 digital multimeter are
used to measure voltage and current produced by the PMA. Shaft
speed, urev, is measured using an Extech Instruments Model 461920
laser tachometer.
3. Calculations
As in a typical pico-hydro scheme, hydraulic head H can be
calculated at any location where elevation z, pressure p, and
velocity v are known using
H ¼ z þ
p
rg
þ
v2
2g
: (1)
where r is the density of the fluid and g is gravity. In this experi-
ment, the flow meter and pressure transducer were used to directly
determine net head, Hn, located upstream of the nozzle. Jet head Hj
and jet velocity vj, the head and velocity downstream of the nozzle,
are related to Hn via the nozzle’s velocity coefficient Cv as follows:
Hj ¼ C2
v Hn (2)
vj ¼ Cv
ffiffiffiffiffiffiffiffiffiffiffi
2gHn
p
: (3)
Over the range of jet velocities investigated here, the velocity
coefficient depends primarily on nozzle geometry. For a 60
rounded nozzle Cv¼0.97 and for a 14 tapered nozzle Cv ¼ 0.98 [12].
The brass nozzles used for this study all fall between these two
geometries so Cv ¼ 0.975 was assumed.
The power in the jet, shaft and electrical output are found using
flow rate, Q, which was directly measured, and the calculated jet
head.,
_Wj ¼ rgQHj: (4)
The power transferred to the turbine/shaft is found by relating
the shaft speed u (rpm) and torque T:
_Ws ¼
2pTu
60
: (5)
Shaft power is then converted to DC electrical power by the
generator:
_Welec ¼ IV; (6)
where I is the current through the circuit and V is the voltage across
the alternator terminals.
The efficiencies of the turbine and generator are calculated
based on the ratio of power at the various points within the system
respectively:
ht ¼
_Ws
_Wj
; (7)
hgen ¼
_We
_Ws
: (8)
In the case of Turgo and Pelton Turbines, speed ratio, x, the ratio
of the turbine speed to jet velocity, is important to identifying the
best operating point and is defined as
x ¼
NpðPCDÞ
60vj
; (9)
where N is the turbine (or shaft) speed in revolutions per minute
(rpm) and PCD is pitch-circle-diameter. Best efficiency is achieved
with a speed ratio of about 0.45e0.50 for Pelton turbines [8,12].
Specific speed is another non-dimensional parameter that
enables comparison of different turbines and operating conditions
and is thus useful for scaling turbines and flow conditions. In
practice, the most common form is dimensional:
Ns ¼
N
_Wt
1=
2
ðHnÞ
5=
4
; (10)
where units are ðrpmÞðkWÞ
1=
2
=ðmÞ
5=
4
:
Fig. 2. (a) Schematic of laboratory-scaled test fixture and (b) photo of the text fixture.
B.R. Cobb, K.V. Sharp / Renewable Energy 50 (2013) 959e964 961
4. 4. Results discussion
4.1. Effects of speed ratio
Given that turbine efficiency is heavily influenced by speed
ratio, it is an important parameter to consider in selecting the
proper turbine speed for a given jet velocity. A momentum balance
on a Turgo turbine dictates that the theoretical speed ratio should
be set at 0.53 for a jet angle of 20, whereas experimental studies
put the actual value between about 0.46 and 0.48. Near peak effi-
ciency, small changes in speed ratio have a limited impact on effi-
ciency; losses increase more rapidly the further the deviation from
its ideal (peak efficiency) speed ratio. Changing the speed ratio after
installation may not be practical; therefore, accurately approxi-
mating speed ratio in the design stage is essential.
Plotting the measured turbine efficiency vs. non-dimensional
speed ratio collapses the curves from multiple experiments onto
one curve, with a peak efficiency occurring around a speed ratio of
0.45 (Fig. 3). Other tests on the two Turgo turbines used for this
work showed that peak efficiency consistently fell in the speed
ratio range of 0.45e0.50 (The tested Pelton wheel showed peak
efficiency at speed ratios of 0.40e0.42, lower than the Pelton
theoretical ideal value of 0.5.).
One potential explanation for the deviation from the ideal Turgo
speed ratio of 0.53 may be a result of non-ideal flow conditions in
the cups (e.g. losses introduced by flow inside the cups that reduce
the velocity of the stream leaving the turbine). Peak efficiency for
the 169-mm Turgo turbine was measured at over 85% while the
best efficiency for the 133-mm model was just over 81%. Compared
to Pelton turbines tested in the same power range, the Turgo
turbines performed quite well. Typical Pelton turbines in pico-
hydro tend to operate in the 75e85% peak turbine efficiency
range [12] while other Turgo turbine designs have been found to
operate at over 70% efficiency [8]. (The highest efficiency measured
for a Pelton turbine using this test fixture was 73%.) Gilkes [19],
a hydropower company in the UK, reports peak turbine efficiencies
around 85% for their Turgo turbines used in applications with
power outputs ranging from 20 kW to 10 MW.
Another noteworthy finding from these tests is the sensitivity of
the turbine efficiency to changes in speed ratio. As Fig. 3 shows,
from a speed ratio of about 0.40e0.55, efficiency only changes by
about 3 percentage points but outside that range turbine
efficiency drops off significantly. Similar trends in terms of
efficiency drop-off were observed with the tested Pelton turbine
[18].
4.2. Effects of jet misalignment
A number of tests were conducted to determine the signifi-
cance of the effects of poor jet alignment. Radial misalignment of
the incoming jet with the tested Pelton turbine by half a cup
width caused a drop of 15e20 percentage points in efficiency.
Like the Pelton turbine, the Turgo turbines can be heavily
impacted by improper radial jet alignment. The drop in peak
turbine efficiency can be as much as 15 percentage points for the
outside misalignment with a smaller reduction for the inside
misalignment (Fig. 4). Fig. 4 also clearly shows a reduction in the
speed ratio at peak turbine efficiency for the outside case and an
increase for the inside case. The shift in speed ratio, nearly 20% for
the outside misalignment, is due to the effective change in pitch
circle diameter (PCD) of the turbine caused by a change in loca-
tion at which the jet hits the turbine blades. There may also be
added energy losses in the turbine from the altered flow pattern
in the blades. For misalignment to the outside, it may be more
likely that water from the jet will miss the turbine altogether;
whereas on the inside, all the water should still hit the turbine.
The most important point to take is that a modest radial
misalignment can have a noticeable negative impact on turbine
performance by reducing the peak efficiency by over 20% and
Fig. 3. Turbine efficiency vs. speed ratio for a 169-mm Turgo turbine with a 9.53-mm
nozzle and three different jet velocities.
Fig. 4. Turbine efficiency vs. speed ratio for a 169-mm Turgo turbine with an 11.11-mm nozzle for three radial jet positions. Error bars are shown for speed ratio (horizontal) and
turbine efficiency (vertical).
B.R. Cobb, K.V. Sharp / Renewable Energy 50 (2013) 959e964962
5. shifting the speed ratio at which peak efficiency occurs by up
to 20%.
Angular misalignment is more of a concern for Turgo turbines
than it is for Pelton turbines for the simple reason that the installed
jet angle is intended to be around 20 (i.e. not 0). Reducing the jet
angle from the commonly used angle 20 [20] to 18 appears to
reduce efficiency by a little less than 5 percentage points, and by
close to a 10-point reduction for 14 and 24 jet angles. For the jet
angle above 20, peak efficiency appears to occur at a higher speed
ratio. This latter effect is caused by the jet striking the turbine closer
to the inside of the blades for the 24 test, resulting in a smaller
effective PCD. For the tested Pelton wheel, the experiments indeed
reflected the expected smaller sensitivity to angular misalignment;
the efficiency drop was less than 5 percentage points for a 10
misalignment.
4.3. Scaling of results
To verify that results from this research would be applicable to
flow and head conditions outside of those tested, the impact of
changes in head, specific speed, and flow rate were investigated for
both Pelton and Turgo turbines. For medium head applications,
where Turgo turbines are most likely to be used, head is below 50 m
[21]. The system used in this study is capable of producing heads up
to about 30 m, thus covering a meaningful range for Turgo turbine
use in practice [19]. For the lower power applications encountered
with pico-hydro (5 kW), the impulse turbines used are generally
not much larger than those used in this study, so changes in turbine
size were not investigated.
Over the variable range of hydraulic head tested here (13e
28 m), experiments confirmed effectively no difference in Turgo
efficiency or the speed ratio at which peak efficiency occurred from
one head to another (holding nozzle diameter, and thus specific
speed constant). A second evaluation of the impact in a change in
head was conducted; this time, however, the change in head was
accomplished by a change in nozzle diameter. Since a centrifugal
pump was driving the flow in the experimental set-up, a change in
nozzle size resulted in a higher flow rate and lower head due to
a change in pump efficiency corresponding to the pump perfor-
mance curve. These experiments showed that even when specific
speed is not held constant, changes in head have no noticeable
impact on peak efficiency for Turgo turbines within the range of
parameters tested.
Under more extreme operating conditions, such as very low or
high head, other factors could have a significant impact. Factors
such as bearing or windage losses should be considered for such
extreme cases, as they can affect efficiency at high turbine or shaft
speeds. For medium head, between 10 and 50 m, these other factors
are not expected to have a major influence on turbine performance.
Another potentially important consideration is nozzle size. Guide-
lines for maximum nozzle diameter for a particular turbine are not
widely available, though above some point turbine efficiency will
most certainly be negatively impacted. For this study, the
maximum nozzle diameter used was 1/2” corresponding to roughly
10% of PCD and 33% of the cup width with no apparent impact on
turbine efficiency.
5. Summary conclusion
Pico-hydropower is a viable technology for rural electrification
in some of the most distant, impoverished regions of the world.
Provided adequate consideration is given to site-specific condi-
tions and installation [9], pico-hydro can be a very economical
solution. As shown by the experiments in this study, proper
equipment selection and installation are key components to
achieving reasonable system efficiencies, and thereby raise power
output.
For impulse turbines, proper speed ratios (ratios of about
0.4e0.5) are essential for efficient energy transfer from the water
jet to the generator shaft. Theoretically, the peak efficiency point
for the Turgo turbine should occur at approximately x ¼ 0.53 for
a jet angle of 20. Experimentally, peak efficiency occurs at
a slightly lower speed ratio, approximately 0.46e0.48. Simi-
larly, the theoretical peak efficiency point for the Pelton is at
a speed ratio of 0.50, but experimentally it occurs closer to 0.41.
A second consideration pertaining to speed ratio is the shift in
peak efficiency point for systems with low turbine efficiency. For
example, if jet misalignments and frictional losses within the
turbine lower turbine efficiency, the speed ratio at which peak
efficiency occurs is also lowered. Correctly accounting for the
shift in speed ratio can prevent a 5e10 percentage point loss in
turbine efficiency. The effect that the speed ratio can have on
turbine efficiency also means it is important to accurately
determine the net head prior to installation, since it is required
for determining jet velocity.
Proper jet alignment is another essential consideration. Even
small misalignments (a few centimeters or degrees) can have
significant negative effects on turbine efficiency. Care must be
taken in the installation process to make certain the jet strikes the
turbine in such a way that an efficient transfer of energy can
occur. Results from this study demonstrate that visual adjust-
ments are not adequate for achieving the highest turbine effi-
ciency. A standardized turbine housing with built in nozzle
mounts would simplify alignment. The housing would need to
allow for large scale adjustments to accommodate different
turbine sizes, as well as for fine adjustments to optimize the
position during testing.
There are several areas for future work on this project that
have the potential to improve pico-hydro. The flow limitations
for Turgo turbines need to be established in relation to PCD
and/or cup size (similar to the way it has been established for
Pelton turbines). A Turgo turbine and turbine-generator set that
can be easily built using basic manufacturing techniques should
be identified. Most importantly, a general awareness and tech-
nical understanding of successful pico-hydro technology needs
to be developed and fostered at the local and regional levels
so that rural electrification projects can be implemented
effectively.
Acknowledgments
The authors wish to acknowledge the capstone design team
(Alan Cassler, Joe Codichini, Jennifer DiBello, and Ruomeng Pang) at
Pennsylvania State University for their initial work on the design
concept of a test fixture; Dr. J. Garth Thompson for discussions;
Caleb Calkins for assistance at Oregon State University; and Oregon
State University for partial support of Bryan Cobb.
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