Energy saving in cooling towers by using variable frequency drives

Proceedings of the 2nd International Conference on Current Trends in Engineering and Management ICCTEM -2014
INTERNATIONAL JOURNAL OF ELECTRICAL ENGINEERING &
17 – 19, July 2014, Mysore, Karnataka, India
TECHNOLOGY (IJEET)
ISSN 0976 – 6545(Print)
ISSN 0976 – 6553(Online)
Volume 5, Issue 8, August (2014), pp. 148-160
© IAEME: www.iaeme.com/IJEET.asp
Journal Impact Factor (2014): 6.8310 (Calculated by GISI)
www.jifactor.com
IJEET
© I A E M E
ENERGY SAVING IN COOLING TOWERS BY USING VARIABLE
FREQUENCY DRIVES
Sowmya G1, S.Nagendra prasad2, N.Kumar3
1(E & E Department, VVIET, Mysore, Karnataka, India)
2, 3(E & E Department, NIE, Mysore, Karnataka, India)
148
ABSTRACT
This paper deals with energy savings in cooling towers by using variable frequency drives.
An economic evaluation has been performed to determine the potential annual savings of 25% is
achieved by using adjustable-speed AC drives on cooling tower fans to track water temperature
throughout the year. PWM was found to be the optimum solution for efficiency, harmonic distortion
feedback, and power-factor considerations. The digital drive also offered the control options
necessary to successfully operate with two fans in parallel on one drive. These options included the
capability for bypass starters, automatic transfer, and selectable fault condition responses. In addition
to the energy savings offered by the digital drives, being able to adjust the speed of the fans would
result in smoother plant operations due to constant water temperatures. The adjustable-speed drives
also enable the fans to be soft started.
Closed loop PWM controlled Inverter fed 3 phase Induction Motor model is developed
followed by simulation results using Matlab/Simulink. The control block diagram of the proposed
system is given in this paper.
Keywords: Cooling Tower, Model Simulation, Variable operating conditions, Variable Frequency
Drive.
I. INTRODUCTION
The manufacturing industry can be classified as the process industry and discrete
manufacturing. The process industry transforms the inputs, through various conversion methods, into
a new product with significantly different physical and chemical properties from the unprocessed
substance. It can be further categorized into various market segments including food and beverages,
chemicals, petrochemicals, paper, pesticides, fertilizers, dyes and pigments and drugs and

pharmaceuticals. The end products usually act as inputs for the discrete manufacturing industry,
which includes electronic, power equipment, automobiles and a range of consumer goods.
To sustain in the increasingly competitive environment, the process industry needs to reduce
its operational costs without impacting profitability and product quality. This multiproduct industry
is energy intensive and provides a major opportunity to implement energy efficiency solutions.
Through strategic investments in energy efficiency initiatives, the process industry can reap the
benefits of reduced energy consumption- lower energy and operation and maintenance costs. In
addition, these initiatives have a positive impact in terms of reduced dependence on fossil fuels and
lower carbon emissions.
149
Solutions for achieving energy efficiency
Every plant has a unique configuration for process equipment, input supply pattern, a power
generation and distribution system and grid power supply pattern. Therefore, the energy saving
solution needs to be customized for each facility.
The equipment and systems used in process industries are usually old and inefficient. Since
energy consumption is barely monitored in these industries, the management, in most cases, is not
aware of the energy inefficiency in the systems. Thus, the first step towards adopting an energy
efficiency solution is measuring both electrical and thermal energy consumption through regular
audits. Following this, the organization needs to prepare a road map highlighting future energy
efficiency projects, the requisite investments in these projects, and the payback period.
Process industries can also adopt specific and generic energy efficiency improvement
solutions. The specific solutions are related to process improvement, process integration and control,
combined heat and power methods, load distribution and optimization and process automation.
Generic energy efficiency improvement solutions are related to the replacement, modification
and installation of heaters, furnaces, motors, pipes, lights, turbines, boilers, cooling towers and other
components used in the process industry. These solutions typically do not entail significant
investments. For instance, the installation of variable frequency drives (VFDs) in motors offers
significant energy savings. The operating speed of a motor connected to a VFD is changed by
varying the frequency of motor supply voltage, which allows continuous process speed control.
Another generic low investment measure includes the replacement of metallic blades with
fibre- reinforced plastic (FRP) blades in the cooling towers. Metallic blades are heavy and consume
more power. Replacing them with the lightweight FRP blades helps in reducing power consumption
by 20-40 percent. Similarly, the replacement of shell and tube heat exchangers increases the rate of
heat transfer, leading to thermal energy savings. Further, the replacement of exhaust fans with
natural air draft turbo ventilators reduces the power requirement. The ventilators run on wind while
the exhaust fans use electrical energy to operate the motor.
The other cost effective measures include the replacement of sodium vapour lamps with
compact fluorescent lamps, switching off equipment when not in use, installation of a centralized air
conditioner (AC) in place of separate ACs, and the use of fiberglass sheets on rooftops for better
lighting on plants premises during daytime. In addition, process industries can deploy renewable
energy-based power systems to reduce their dependence on the grid supply. For instance, solar water
heaters can be installed to meet hot water requirements.
II. BACKGROUND INFORMATION
The purpose of a cooling tower is to provide process cooling water within a specified
temperature range, usually between 28-29ºC. Since the cooling tower will operate most of the time at
less than design capability, an economic evaluation was performed to determine the potential annual
savings achieved by using adjustable speed AC drives on the cooling tower fans. The outcome of this
evaluation had to not only justify the increased capital expenditure for the adjustable speed drives,

but also had to maintain a very high level of reliability due to the critical nature of the cooling tower.
This paper reviews the key points of the economic evaluation, and then discusses the application of
adjustable speed drives to cooling tower fans.
150
The cooling Water System
The cooling tower [1],[2] is used to provide process cooling water to heat exchangers for five
separate production plants. Loss of this system would create a process upset in these plants. The
cooling tower had to be designed with the highest degree of reliability possible to insure the integrity
of the cooling water system.
COOLING TOWER PAHARPUR MODEL NO --23204 T--0
SERIAL NO---004--20--0025
GEAR BOX MODLE---22.2
NOZZLE SET----1.
DRIVE SET--------1
DRIVE SOFT SET --1.
6 Q BUSH---8 NOS
HOT WATER BASIN SET---1.
MOTOR DETAILS FRAME NO—200L, H P---20,
KW-15, RPM—1765, DUTY---S1.
PUMP BEARING 6307 --2z- &- 6308--2z.
COOLING TOWER PUMP IMPELLER - KDS 2050
PUMP DETAILS TYPE K D S 2050
SIZE 100X80, IMP DIA 197. 0
R P M 2915
HEAD RANGE--M----30--46.0
CAPACITY RANGE lps ---29--16.
KW/HP----15/20.
COOLING TOWER WATER TREATMENT CHEMICAL
SISIL--CT--104 8 LTRS PER DAY.
SISIL--CT--101 3 LTRS PER DAY
QUENCH OIL HEAT EXCHANGER PLATES TYPE M6 - M D F
GEAR BOX BEARING 34306, 34500 (CUP)
Electrical System
Incoming power at the 66 kV level is provided by means of overhead distribution from two
separate busses in a powerhouse. Each of the two feeders is capable of carrying the entire load
individually. 5 MVA transformer steps down this voltage to a level of 11kV and 5 distribution
transformers step down 11kV to 415 volt level. A secondary three breaker transfer scheme with a
normally open tie breaker is used to switch between the feeders in the event of an outage on one of
them. This system will provide high electrical reliability for the tower to reduce the possibility of a
power interruption due to the loss of one feeder.

151
The Control System
The cooling tower controlled by means of a star/delta starter and the cooling tower fan
operates at the same speed throughout the day irrespective of the weather condition. Cooling tower
fans gain a special advantage from the Variable Speed AC Drive. The cooling tower is outdoors
exposed to sun, wind, rain, sleet, and all kinds of other things. It is expected to dispose of a variable
amount of heat in a variable environment. The amount of forced air cooling required can be easily
controlled, it is not necessary to run the fan at 100% when the load is much lower due to a cool rainy
day. If the installation is in a northern climate, or in the mountains, the Variable Speed AC Drive
provides an easy way to reverse the fan, and dispose of any build up of ice.
III. VARIABLE FREQUENCY DRIVE
variable-frequency drive (VFD) (also termed adjustable-frequency drive, variable-speed
drive, AC drive, micro drive or inverter drive) is a type of adjustable-speed drive used in electro-mechanical
drive systems to control AC motor speed and torque by varying motor input frequency
and voltage.
VFDs are used in applications ranging from small appliances to the largest of mine mill
drives and compressors. However, about a third of the world's electrical energy is consumed by
electric motors in fixed-speed centrifugal pump, fan and compressor applications and VFDs' global
market penetration for all applications is still relatively small. This highlights especially significant
energy efficiency improvement opportunities for retrofitted and new VFD installations.
Over the last four decades, power electronics technology has reduced VFD cost and size and
improved performance through advances in semiconductor switching devices, drive topologies,
simulation and control techniques, and control hardware and software.
Although space vector pulse-width modulation (SVPWM) is becoming increasingly popular,]
sinusoidal PWM (SPWM) is the most straightforward method used to vary drives' motor voltage (or
current) and frequency. With SPWM control quasi-sinusoidal, variable-pulse-width output is
constructed from intersections of a saw-toothed carrier frequency signal with a modulating sinusoidal
signal which is variable in operating frequency as well as in voltage (or current).
An embedded microprocessor governs the overall operation of the VFD controller. Basic
programming of the microprocessor is provided as user inaccessible firmware. User programming of
display, variable and function block parameters is provided to control, protect and monitor the VFD,
motor and driven equipment.
Powerflex 400
PowerFlex 400 AC Drives are optimized for control of commercial and industrial fans and
pumps. Built-in features such as purge and damper input provide a cost-effective solution for speed
control in a broad range of variable torque fan and pump applications. An available packaged
PowerFlex 400 Fan and Pump drive provides additional control, power, and enclosure options in
standardized designs for a cost-effective solution for speed control in variable torque fan and pump
applications.
Operator interface
The operator interface provides a means for an operator to start and stop the motor and adjust
the operating speed. Additional operator control functions might include reversing, and switching
between manual speed adjustment and automatic control from an external process control signal. The
operator interface often includes an alphanumeric display and/or indication lights and meters to
provide information about the operation of the drive. An operator interface keypad and display unit is
often provided on the front of the VFD controller. The keypad display can often be cable-connected
and mounted a short distance from the VFD controller. Most are also provided with input and output

(I/O) terminals for connecting pushbuttons, switches and other operator interface devices or control
signals.
152
IV. ANALYSIS AND DISCUSSION
On studying the meteorological data of Mysore, it was observed that the variation of weather
conditions between day & night & also seasonal variation was quite substantial. A rough idea about
the same can be made in table below.
Table 1: Meteorological data of Mysore city & temperature distribution in Primary and
Secondary circuit of cooling system
Month Wet Bulb Temp
(ºC)
CTW- Cold water
return temp (ºC)
Secondary Coolant Cold
Water return temp (ºC)
Max Min Max Min Max Min Desired
Temp
Jan 21.5 16.0 22.6 17.4 25.8 17.8 31.0
Feb 20.0 18.5 23.2 19.2 27.0 22.8 31.0
Mar 21.0 17.0 26.8 20.5 27.3 24.0 31.0
Apr 25.5 21.0 30.6 22.2 28.0 24.4 31.0
May 24.5 19.5 24.6 21.8 28.4 25.2 31.0
Jun 24.5 21.5 26.5 22.2 29.7 25.3 31.0
Jul 24.0 21.0 29.3 22.3 29.4 24.3 31.0
Aug 23.5 21.0 21.8 21.2 27.0 23.4 31.0
Sep 22.5 19.5 21.8 21.8 27.6 24.7 31.0
Oct 22.5 20.5 25.5 21.8 28.2 24.3 31.0
Nov 21.0 16.5 24.0 23.0 26.6 25.0 31.0
Dec 21.5 16.0 23.6 19.3 25.8 18.6 31.0
The design cold water inlet temperature in the secondary circuit of the cooling system, to
various systems is approx. between 31-32 ºC and the maintenance of this design temperature was
very important from the point of view of process performance. However, due to the wide fluctuation
of weather conditions & also due to the partial loading of cooling tower, it had virtually become
impossible to maintain optimum cooling tower cold water return temperature i.e. 28-29 ºC and
operating cold water inlet temperature to various system i.e. 31-32 ºC. A rough idea about the extent
of variations that has been taking place can be made from the following table below.
From table 1 & the graph shown, it can be due to the partial loading of the cooling tower and
also due to seasonal fluctuation of weather conditions frequently, it is not able to maintain the

optimum cooling tower cold water return temperature. So, the main objective was to take some
measures in order to achieve optimum cooling tower cold water return temperature.
By using VFD, the fan speed & the quantity of air being supplied to the cooling tower can be
varied in the entire range from zero speed to maximum fan speed & from zero air supply to
maximum air supply as per the requirement of the process. By varying the frequency of the supply
power with the help of VDF, the speed of motor can be varied.
For achieving the optimum CTW return temperature, it was necessary to operate the cooling
tower at zero fan speed & at full fan speed in order to see the extent the temperature control possible
with the installation of a VFD. The result of the experiment is described in the Table below.
Table 2: Variation cooling system temp with respect full speed & zero speed of cooling tower
fan
Fan Speed CTW return
temperature(ºC)

% $#

%#
153
Secondary Coolant Cold
Water return temp (ºC)
FULL 22.5 28
ZERO 32 37
So, from table.2, it is clear that the extent temperature control possible, by varying the speed
of the fan full speed to zero speed is approx, 9-10ºC the same fulfills the requirements.
On the basis of above study, to operate the cooling tower fans at variable speed SPWM drive
were installed. The VFD device has the facility to operate both in fixed drive (FD) mode. So,
depending upon the requirements, the VDF device can be operated at full speed in FD mode or at
variable speed in VD mode between 6Hz to 60Hz to fulfill the temperature requirement.

!

#$

!
Fig 1: Graph Showing Monthly Distribution of Coolant Temperature

Table 3: Seasonal variations of fan speed over a period of 1-year and cooling tower return
temperature
154
Months Period
(Months)
Fan Speed (Hz) CTW
return
Temp.
Secondary ckt.
Inlet Temp.
Day Night Avg ºC
ºC
Mar Apr
May June
4 40-50 35-40 40 26-29 29-31
July Aug
Sep Oct
4 30-35 25-30 35 26-29 29-31
Nov Dec
Jan Feb
4 35-40 20-30 30 26-29 29-31
Considering fluctuation of weather conditions also the partial loading of cooling
tower(depending on the Production), it is decided to run the Cooling tower fan at the following
frequencies in order to have the CTW return temperature approximately equal to the design
temperature.
So, from the above table, it is concluded that the regulation of cooling tower fan speed and
air flow using a VFD -device helps in maintaining optimum cooling tower return temperature even in
the circumstances when cooling tower is partially loaded and also weather climatic condition
fluctuation is substantial.
V. MATLAB/SIMULINK MODEL
SPWM Control of an induction motor
In Sinusoidal PWM three phase reference modulation signals are compared against a
common triangular carrier wave to generate the PWM signals for the three phases. Fig:3 represents
the closed loop speed control of 3 phase IM (represents the fan of the Cooling Tower). To have
closed loop control temperature sensor is used to sense the temperature of the inlet water to the
cooling tower and the feedback is given to VFD to accordingly set the speed (frequency settings) of
the IM to get the constant water outlet from the Cooling Tower.
To get the constant water outlet from the Cooling Tower, model consists of a dynamic lookup
table. The dynamic parameters of the lookup table are Temperature and the corresponding Frequency
at which the 3 phase IM has to run. From the detailed analysis and discussion made in the previous
chapter, lookup table has been derived. The inlet water temperature of the Cooling Tower varies
between 40 ºC to 55 ºC and the corresponding frequency at which the motor has to run to get the
constant water outlet temperature of 28 ºC to 29 ºC has been arrived by running motor at full speed
and zero speed. Table below gives the temperature and the corresponding frequency.
The machine's rotor is short-circuited, and the stator is fed by a PWM inverter, built with
Simulink blocks and interfaced to the Asynchronous Machine block through the Controlled Voltage
Source block.
The inverter uses sinusoidal pulse-width modulation. The base frequency of the sinusoidal
reference wave is set at 50 Hz and the triangular carrier wave's frequency is set at 1980 Hz.

The Simulink input of the block is the mechanical torque at the machine's shaft. When the
input is a positive Simulink signal, the asynchronous machine behaves as a motor. When the input is
a negative signal, the asynchronous machine behaves as a generator. Here the 20 HP machine is
connected to a constant load of nominal value (11.9 N.m).
RelayA
RelayB
+
-
vab
+ -
+ -
2*pi/3*[ 0,-1,1 ]
Math
Function Look-Up
Demux
Fourier
Mag
Feedback from
Temperature sensor
Constant1
20 HP - 400 V
50 Hz - 1460 rpm
Tm
Fig 2: Simulink model of a PWM Controlled Inverter fed 3Phase Induction motor
155
vab (V)
v
-K-rpm
-K-pu2radpersec
Discrete,
Ts = 2e-006 s.
powergui
-K-peak2rms
ir,is (A)
s
Vbc
s
Vab
sin
x
xdat
ydat
y
Temperature v/s
Frequency
Lookup Table
-C-Temperature
Te (N.m)
RelayC
1460
Rated speed
RMS Vab voltage
Product
N (rpm)
rem
Table
Fourier
Phase
50
Divide
Demux
-C-Corresponding
Frequency
1/1980
11.9
29.19
Constant
Clock
m
A
B
C
Rotor current ir_a (A)
Stator current is_a (A)
Rotor speed (wm)
Electromagnetic torque Te (N*m)

Table 4: Temperature and corresponding frequency of dynamic lookup table
156
Temperature in
ºC
Frequency in Hz Speed in rpm Outlet water
Temperature in
ºC
40 20 584 28-29 ºC
41 22 642 28-29 ºC
42 24 700 28-29 ºC
43 26 759 28-29 ºC
44 28 817 28-29 ºC
45 30 876 28-29 ºC
46 32 934 28-29 ºC
47 34 992 28-29 ºC
48 36 1050 28-29 ºC
49 38 1110 28-29 ºC
50 40 1168 28-29 ºC
51 42 1225 28-29 ºC
52 44 1284 28-29 ºC
53 46 1342 28-29 ºC
54 48 1400 28-29 ºC
55 50 1459 28-29 ºC
IV. SIMULATION AND EXPERIMENTAL RESULTS
The modeling of a PWM Controlled Inverter fed 3Phase Induction motor is done. The results
of the simulation are as shown below.
Simulation results show better speed response of three phase induction motor (representing
cooling tower fan) with the change in temperature. The model also provides the better torque
response.The various currents, voltage response is obtained from the simulation results are as
follows.
Fig:4 shows the machine's speed going from 0 to 800 rpm at certain temperature and as the
temperature increases the speed increases automatically. Fig:5 shows the electromagnetic torque
developed by the machine for the same temperature change. Because the stator is fed by a PWM
inverter, a noisy torque is observed.

Fig 3: Output voltage of the SPWM Controlled Inverter
Fig 4: Speed Response of SPWM Controlled Inverter Fed I.M
157

Fig 5: Torque Response of SPWM Controlled Inverter Fed I.M
Fig 6: Rotor Current of SPWM Controlled Inverter fed I.M
However, this noise is not visible in the speed because it is filtered out by the machine's
inertia, but it can also be seen in the stator and rotor currents, which are observed next.
158

Fig 7: Stator Current of SPWM Controlled Inverter Fed I.M
Fig 6 and 7 shows the Rotor and Stator Line current response coming out from SPWM
controlled Inverter fed I.M for the different temperatures. We observe that initially variations occur
in the line currents and later it reaches the steady state within 0.1s. Initially Induction motor is at
rest, so it draws more current at the beginning.
159
VI. CONCLUSION
The Third Law of Affinity for fans states the ratio of the horse power for two operating
conditions is equal to the cube of the ratio of the flow rate at those conditions. Since flow rate is
proportional to speed and horse power is proportional to power (kVA), then the power used is
proportional to the cube of the speed. Therefore, reducing the fan speed by one-half requires only
one-eighth of the power.
Using any adjustable speed drive technology to track the wet bulb temperature throughout the
year will result in an annual energy savings of 25% when compared with running the fan at full-speed
all the time. This factor alone justified the additional capital expenditure for the drives.
However, due to the critical nature of the cooling tower other factors had to be weighed. In addition
to the tremendous annual energy savings offered by the drives, other operating criteria dictated the
necessity of using adjustable speed drives. Being able to adjust the speed of the fans would result in
smoother plant operations due to constant water temperatures.
Modeling and simulation of SPWM controlled Inverter fed 3 phase I.M drive has been done
by using MATLABSIMULINK. Simulation and experimental results presented are in agreement
with the theoretical analysis.
VII. REFERENCE
[1] The energy-saving benefit and economic evaluation analysis of cooling tower with flue gas
injection by Han, Q. ; Liu, D.Y. ; Chen, F.S. ; Yang, Z.
[2] DIII-D water-cooling system upgrades through modeling and power saving projects by Yip,
H.H. ; Mauzey, P.S. ; Anderson, P.M. ; Le, T. ; Hegstad, T. ; Thomas, A.; Leung, D.

Energy saving in cooling towers by using variable frequency drives

More Related Content

What's hot (11)

Viewers also liked (16)

Similar to Energy saving in cooling towers by using variable frequency drives (20)

More from IAEME Publication (20)

Recently uploaded (20)

Energy saving in cooling towers by using variable frequency drives