PERFORMANCE ANALYSIS AND EFFICIENCY IMPROVEMENT OF COOLING TOWER AT MTPS-I
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This document discusses performance analysis and efficiency improvement of cooling towers at a thermal power station. It contains the following key points: 1. Cooling towers are used to reduce the temperature of hot water from condensers before it is circulated back through the power station. Various factors like wet/dry bulb temperatures and tower size affect cooling efficiency. 2. The document analyzes the design and components of induced draft cooling towers currently in use at the power station. Issues like algae growth and uneven temperatures reduce tower performance over time. 3. Covering the towers and preventing sunlight and nutrients from entering the water could help address the algae problem and improve long-term efficiency. The goal is to optimize parameters like
![International Research Journal of Engineering and Technology (IRJET) e-ISSN: 2395-0056
Volume: 09 Issue: 06 | June 2022 www.irjet.net p-ISSN: 2395-0072
© 2022, IRJET | Impact Factor value: 7.529 | ISO 9001:2008 Certified Journal | Page 382
To prevent spray nozzle blockage due to dust
particles forming on hot water basin.
6.2 MATERIAL PROPERTIES OF GI ROOF SHEET
Material : Galvanized Iron (GI)
Thickness of the sheet : 0.6 – 1.2 mm
Resistance : Corrosion Resistance
Tensile strength : 300 MPa
Yield Strength : 220 Mpa
Fig -9: Cooling Tower hot water basin without GI
roof sheet
Fig -10: Cooling Tower hot water basin with GI
roof sheet
7. COOLING TOWER CALCULATIONS
7.1 COOLING TOWER CALCULATIONS BEFORE GI
ROOF SHEET PROVIDED ON HOT WATER BASIN
Hot water temperature (thw) = 40°C
cold water temperature (tcw) = 30°C
Inlet air temperature = 32.5°
Outlet air temperature = 33.9°
Cold water basin temperature = 30°C
Wet bulb temperature = 24.5°C
Dry bulb temperature = 36.5°C
1) Cooling water range = (Hot water temperature) -
(Cold wate temperature)
= 40-30
= 10°C
2) Cooling water =(Water outlet temperature) -
Approach (Wet bulb temperature)
= 30-24.5
= 5.5°C
3) L/G Ratio = water flow in Kg /
Air flow in Kg
= 20794/7655
= 2.7164
4) Fan Air Flow Actual / = (Rated fan flow fan input) /
Cells (fan input speed rated )1.3
=(1945950 56.03 ) / (75)1.3
= 25.534 106 Nm3//hr
5) Air Mass Flow / Cell = flow density of air
= (1945950 56.03 ) / (75)1.3
= 25.534 106 m3/hr
6) Density ratio = actual air density / 0.0075
= 1.164 / 0.0075
= 15.52 Kg/m3
7) Fraction of water = mass of water evaporated /
mass of water
= 240.28 / 20794
= 0.0115
8) Enthalpy of inlet air (h1)=78.5 KJ/Kg[using psychometric
chart for wet bulb and dry bulb
temperature ]
9) Enthalpy of exit air (h2 )= h1 + ( L/G ratio range)
= 78.5 + ( 2.7164 10 )
= 105.66 KJ/Kg
10) Evaporation Loss = (Cooling water flow cooling
Tower Range ) / 675
= (20794 10) / 67
= 308.05 m3/hr
11) Make up water = Evaporation loss / (coc - 1)
consumption
= 308.05 / (1.45 – 1)
= 684.55 m3/hr
12) Drift loss = 0.2% of water supply
= (0.2 / 100) (20794)
= 41.588 m3/hr
13) Efficiency = [Range / (Range + approach)
100 ]
= [10/ (10 - 5.5) 100]
= 64.51%
7.1 COOLING TOWER CALCULATIONS AFTER GI
ROOF SHEET PROVIDED ON HOT WATER BASIN
Hot water temperature (thw) = 42°C
cold water temperature (tcw) = 30°C
Inlet air temperature = 32.5°
Outlet air temperature = 33.9°](https://image.slidesharecdn.com/irjet-v9i663-221007113522-bc296010/85/PERFORMANCE-ANALYSIS-AND-EFFICIENCY-IMPROVEMENT-OF-COOLING-TOWER-AT-MTPS-I-5-320.jpg)
![International Research Journal of Engineering and Technology (IRJET) e-ISSN: 2395-0056
Volume: 09 Issue: 06 | June 2022 www.irjet.net p-ISSN: 2395-0072
© 2022, IRJET | Impact Factor value: 7.529 | ISO 9001:2008 Certified Journal | Page 383
Cold water basin temperature = 30°C
Wet bulb temperature = 24.5°C
Dry bulb temperature = 36.5°C
1) Cooling water range = (Hot water temperature) -
(Cold wate temperature)
= 42-30
= 12°C
2) Cooling water =(Water outlet temperature) -
Approach (Wet bulb temperature)
= 30-24.5
= 5.5°C
3) L/G Ratio = water flow in Kg /
Air flow in Kg
= 20794/7655
= 2.7164
5) Air Mass Flow / Cell = flow density of air
= (1945950 56.03 ) / (75)1.3
= 25.534 106 m3/hr
6) Density ratio = actual air density / 0.0075
= 1.164 / 0.0075
= 15.52 Kg/m3
7) Fraction of water = mass of water evaporated /
mass of water
= 240.28 / 20794
= 0.0115
10) Evaporation Loss = (Cooling water flow cooling
Tower Range ) / 675
= (20794 12) / 675
= 369.67 m3/hr
11) Make up water = Evaporation loss / (coc - 1)
consumption
= 369.67 / (1.45 – 1)
= 821.4 m3/hr
12) Drift loss = 0.2% of water supply
= (0.2 / 100) (20794)
= 41.588 m3/hr
13) Efficiency = [Range / (Range + approach)
100 ]
= [12/ (12 - 5.5) 100]
= 68.57 %
8. PERFORMANCE GRAPH
8.1 RANGE vs EFFICIENCY
Graph is plotted between the range of the cooling tower
and corresponding efficiency of the cooling tower
Fig -11: Range vs Efficiency Graph
8.2 INPUT vs EFFICIENCY
Graph is plotted between the input temperature of hot
water and corresponding efficiency of the cooling tower.
Fig -12: Input vs Efficiency Graph
9. CONCLUSION
After theoretical analysis, it works found the efficiency of
cooling tower-I was 64.1% which islowerthanthedesigned
value at 70.97% which is due to atmospheric temperature.
Because of frequent and periodic maintenance of fans. gear
box, drive shaft, hot water basin, flow control valves, hot
water pipe lines, and nozzles. It will attain stable efficiency.
Due to scheduled maintenance. There is no algae formation
in the hot water basin and so the cooling tower is still in
better condition and also improvement inthecoolingtower-
I by providing Gl sheet on the hot water basin cell top to
reduce the algae growth and cold-water temperature
reduced up to 68.57% (-4°c). It also to improve the cooling
tower and generation.
ACKNOWLEDGEMENT
We wish to express our sincere thanks to our honorable
chairman Thiru. JANSONS.T.S.NATARAJAN, Sengunthar
Institutions, Tiruchengode for providing opportunity to do](https://image.slidesharecdn.com/irjet-v9i663-221007113522-bc296010/85/PERFORMANCE-ANALYSIS-AND-EFFICIENCY-IMPROVEMENT-OF-COOLING-TOWER-AT-MTPS-I-6-320.jpg)
![International Research Journal of Engineering and Technology (IRJET) e-ISSN: 2395-0056
Volume: 09 Issue: 06 | June 2022 www.irjet.net p-ISSN: 2395-0072
© 2022, IRJET | Impact Factor value: 7.529 | ISO 9001:2008 Certified Journal | Page 384
this project. We wish to extend our heartfelt thanks to our
honorable Secretary and Correspondent Prof.
A.BALADHANDAPANI, M.A., M.Phil., and other respected
Trust members for providing us with all the facilities to
develop the project successfully.
We would like to express oursinceregratitudetoourbeloved
Principal Dr.K.UMADEVI.ME., Ph.D., for having rendered us
moral support in our endeavor
We feel elated by the encouragement of Mr. N.THIRU
SENTHIL ADHIBAN,M.E., Head of the Department of
Mechanical Engineering for motivating us throughout the
completion of this project
REFERENCES
[1] R. Ramkumar A. Ragupathy. Thermal Performance of
Forced Draft Counter Flow Wet Cooling Tower with
Expanded Wire Mesh Packing International Journal on
Technical and Physical Problems of Engineering"
(IJTPE), Issue. 6, Vol. 3, No. 1, Mar. 2011
[2] Ronak Shah, TruptiRathod, Thermal Design Of Cooling
Tower, International Journal of Advanced Engineering
Research and Studies E-ISSN2249-8974
[3] Xiaoni Qi. Yongqi Liu Zhenyan Liu Exergy Based
Performance Analysis of a Shower Cooling Tower
Strojniš kivestnik- Journal of Mechanical Engineering
59(2013)4, 251-259
[4] Ding Feng, Xing Ke-jia, Li Shi-Bei, Bai Jun-hong,
Sensitivity Analysis of Plume RisingHeightfromCooling
Tower, Procedia Environmental Sciences2(2010)1374-
1379.
[5] Y.A. Li and M.Z. Yu, F.W. Shang, P. Xie, The Development
of A Mathematical Model With An Analytical Solution Of
The Counter flow Closed Circuit Cooling Tower,
International Journal on Architectural Science, Volume
1, Number 3, p.120-122, 2000.
[6] L. Lu, W. Cai, A Universal Engineering Model ForCooling
Towers, (2002). International Refrigeration and Air
Conditioning Conference. Paper 625.](https://image.slidesharecdn.com/irjet-v9i663-221007113522-bc296010/85/PERFORMANCE-ANALYSIS-AND-EFFICIENCY-IMPROVEMENT-OF-COOLING-TOWER-AT-MTPS-I-7-320.jpg)
PERFORMANCE ANALYSIS AND EFFICIENCY IMPROVEMENT OF COOLING TOWER AT MTPS-I
- 1. © 2022, IRJET | Impact Factor value: 7.529 | ISO 9001:2008 Certified Journal | Page 378 PERFORMANCE ANALYSIS AND EFFICIENCY IMPROVEMENT OF COOLING TOWER AT MTPS-I Mr. N.THIRU SENTHIL ADHIBAN1, M.SUKEL AHAMED2, S.SUGUMAR3, P.NETHAJI4 1Head of the Department, 2,3,4 UG Scholar 1,2,3,4 Department of Mechanical Engineering, Sengunthar Engineering College (Autonomus), Tiruchengode, Namakkal, India. ---------------------------------------------------------------------***--------------------------------------------------------------------- Abstract - In thermal power station one of the main part is condenser which cools the hot water. When cooling the hot water, it becomes cold water. The how water temperature is reduced by the cooling tower. When hot water enters into the cross flow induced draft cooling tower and sprayed by the nozzle, so that hot water is converted into cold water. The effective cooling water is depends upon wet bulbtemperature, dry bulb temperature, size and height. This project deals with analysis of cooling tower which is one of the deciding factors used for the power plant efficiency. Key Words: Wet bulb temperature, dry bulb temperature, cooling water range, cooling water approach, inlet air and water temperature, outlet air and water temperature etc. 1.INTRODUCTION The Mettur thermal power station is the Tamilnadu electrical board's inland thermal power facility. Industrial development is critical to the country's economic success. The facility is on Stanley reservoir's left edge, on the Ellis Surplus route. The major goal ofthe840MWMetturThermal Electricity Station is to meet the power needs of the state of Tamilnadu's industrial centers. Work onthe projectbeganin 1981, and the first unit was commissioned in 1987. The last three units were put into service in 1987, 1989, and 1990, respectively. 1.1 SCOPE OF THE PROJECT The scope of the project is to find the energy conservation opportunities in Mettur Thermal Power Stationbyfollowing methods: To find the various opportunities in cooling tower casing, fan blade material and fan blade angle. Through replacement of motors to reduce the current and horse power. To optimize the blow down rate. To restrict flows through the large loads to design values. To increase the cooling tower efficiency. 2.COOLING TOWER The cooling system conjointly includes any machinery accustomed operatethe tower andanytanks,pipesorvalves. A cooling is instrumentality accustomed cut back the temperature of the water by extracting heat from water and emitting to the atmosphere. cooling build use to evaporation wherever by a number of the water is gaseous into a moving air stream and afterward discharged into the atmosphere.As a results the reminder of the water is cooled down considerably. coolingsquaremeasureabletolowerthewater temperatureover devicesthatusesolelyairtorejectheatjust like the radiator within the automobile and square measure thus most value effective and energy economical. cooling square measureemployed in air con system forrefrigeration or to cool down materials in industrial processes. cooling square measuredevices thatusecloseairtocooldownwater. A cooling system mightcontain oneoralotofcoolingthatuse identical recirculating water. 2.1 HOW DOES A COOLING TOWER WORKS? In a cooling tower system, the fan pushes or attractsairfrom the atmosphere into the tower to cool down recirculating water. Warm water, that has removed heat from associate air-con, refrigeration or process, enters the highest of the tower. because the water falls throughthetowerrecentairis forced through it. This recent air cools the water. The cooled water then falls to a storage basin before being recirculates through system once more. 2.2 TYPES OF COOLING TOWER The section describes about the types of cooling tower they are: Types of draft in cooling tower Natural draft cooling tower Mechanical draft cooling tower 1. Forced draft cooling tower 2. Induced draft cooling tower Types of water and air flow in cooling tower Cross flow Counter Flow International Research Journal of Engineering and Technology (IRJET) e-ISSN: 2395-0056 Volume: 09 Issue: 06 | June 2022 www.irjet.net p-ISSN: 2395-0072
- 2. International Research Journal of Engineering and Technology (IRJET) e-ISSN: 2395-0056 Volume: 09 Issue: 06 | June 2022 www.irjet.net p-ISSN: 2395-0072 © 2022, IRJET | Impact Factor value: 7.529 | ISO 9001:2008 Certified Journal | Page 379 2.3 NATURAL DRAFT COOLING TOWER This type of tower is incredibly common. It are often known by the fan at the highest of the tower. The fan pulls air up through the tower within the wrong way to that the water is falling. The air sometimes enters the tower through body of water louvers on the perimeters of the tower. This type of tower as shown in Fig. -1. Fig -1: Natural Draft Cooling Tower 2.4 MECHANICAL DRAFT COOLING TOWERS Mechanical draft cooling towers have giant fans to force or draw air through circulated water. The water falls downward over fill surface that facilitate increase the contact time between the water and therefore the air this helps maximize heat transfer between the 2 cooling rates of mechanical draft towers rely upon numerous parameters like fan diameter and speed of operation, fill for system resistance etc. 2.4.1 COUNTER FLOW TOWERS Counter flow cooling tower air is drawn through the falling water and the fill thereforelocatedinsidethetoweralthough design depends on specific site conditions. 2.4.2 CROSS FLOW TOWERS Cross flow tower air is drawn the falling water and the fill is located outside the water. 2.5 INDUCED DRAFT COOLING TOWER Type of mechanical draft cooling tower with a fan at the discharge (at the top) which pulls air up through the tower. The fan induces hot moist air out the discharge 2.5.1 INDUCED DRAFT COUNTER FLOW COOLING TOWER This is a relatively popular form of tower. The fan at the top of the tower can be used to identify it. In the opposite direction from where the water is falling,thefandrawsairup through the tower. Normally, air enters the tower through intake louvers on the tower's sides. This type of tower as shown in Fig. -2. Fig -2: Induced Draft Counter Flow Cooling Tower 2.5.2 INDUCED DRAFT CROSS FLOW COOLING TOWER The fan is also mounted on the top of a cross flow cooling tower with induced draught. In this type of tower, the fan, on the other hand, pulls or induces atmospheric air over the water falling from the top of the tower to the basin This type of tower as shown in Fig. -3. Fig -3: Induced Draft Cross Flow Cooling Tower
- 3. International Research Journal of Engineering and Technology (IRJET) e-ISSN: 2395-0056 Volume: 09 Issue: 06 | June 2022 www.irjet.net p-ISSN: 2395-0072 © 2022, IRJET | Impact Factor value: 7.529 | ISO 9001:2008 Certified Journal | Page 380 2.6 FORCED DRAFT COOLING TOWER Type of mechanical draft tower in which one or more fans located at the air inlet to force air into the cooling tower. 2.6.1 FORCED DRAFT COUNETER FLOW COOLING TOWER The water in a forced draught counter flow cooling tower is cooled by air driven through the top of the water and into the falling water. This type of tower as shown in Fig. -4 Fig -4: Forced Draft Counter Flow Cooling Tower 2.6.2 FORCED DRAFT CROSS FLOW COOLING TOWER The fan is mounted on one or double side of the tower in a forced draught cross flow cooling tower. This fan forces atmospheric air to the fill. This fan is horizontally across the tower, passing through the water dropping from the top of the forced draft cooling tower's top to the basin through the fill. This type of tower as shown in Fig. -5. Fig -5: Forced Draft Cross Flow Cooling Tower 3. DESIGN OF INDUCED DRAFT COOLING TOWER IDCT FAN : 11 No per unit Totally 22 No for stage (unit I & II) Flow control valves : 22 N per unit Totally 44 No for stage (unit I & II) Total height of cooling : 20.13m tower Depth of cooling tower : 2.88m sump Height from ground level: (11.45+5.8) =17.25m Fan stack height : 5.80m Height from ground level to top : 11.45m Fig -6: Design of Induced Draft Cooling Tower 3.1. COMPONENTS OF COOLING TOWER Basic components of cooling tower is given below Frame and casing Fills Hot warer basin Cold water basin Drift eliminator Louvers Nozzles Fans Fig -7: Cooling Tower Basins
- 4. International Research Journal of Engineering and Technology (IRJET) e-ISSN: 2395-0056 Volume: 09 Issue: 06 | June 2022 www.irjet.net p-ISSN: 2395-0072 © 2022, IRJET | Impact Factor value: 7.529 | ISO 9001:2008 Certified Journal | Page 381 3.2 PERFORMANCE OF COOLING TOWER During the performance evaluation, portable monitoring instruments are used to measure the following parameters. Wet bulb temperature Dry bulb temperature Cooling tower inlet water temperature Cooling water outlet temperature Inlet and Exhaust air temperature Range and Approach Air and water flow rate 4. PROBLEM IDENTIFICATION IN INDUCED DRAFT COOLING TOWER The cooling towers efficiency and performance is reduced due to these problems they are given below Algae grows fastly due to sunlight falling on cooling tower hot water basin. Algae blocks the cooling tower nozzle.Ifalgae growscontionously these leads to stop the water flow to the cooling tower. The temperature of the hot water doesn’t maintain evenly on all cells of the cooling tower. Uneven temperature cause efficiency drop Dust and garbages are blocks the cooling tower nozzle. To solve these problems cover the cooting tower by using GI roof sheets. 4.1 FACTORS AFFECTING THE COOLING TOWER Capacity Range Head load Algae growth. 5. ALGAE GROWTH IN COOLING TOWER 5.1 HOW ALGAE IS FORMED IN COOLING TOWER Moisture, sunshine, and nutrients are required for algae to flourish. Because cooling towers are exposed to the outside air, they frequently enable outside bacteria (algal nutrients) and sunlight to enter the water. As a result, if left untreated, algae may soon grow out of control. 5.2 PROBLEM OF ALGAE GROWTH IN COOLING TOWER If algae are growing continuously, they block the cooling tower spray nozzle and reduces the water flow They make more maintenance cost then regular maintenance. This makes more water loss. 5.3 REDUCTION OF ALGAE GROWTH IN COOLING TOWER To control the algae growth, preventsunlightfalling on hot water basin of the cooling tower by using GI roof sheets. Periodic water chemical dosing reduces the water nutrients and algae growth Periodic maintenance and cleaning excess algae improves the cooling tower performance. Fig -8: Algae Growth Cooling Tower 6. PROVIDING GI ROOFSHEETONCOOLINGTOWER HOT WATER BASIN 6.1 PURPOSE OF PROVIDINGGISHEETONCOOLING TOWER HOT WATER BASIN To reduce algae growth in cooling tower To maintain hot water temperature evenly on all cells of the cooling tower
- 5. International Research Journal of Engineering and Technology (IRJET) e-ISSN: 2395-0056 Volume: 09 Issue: 06 | June 2022 www.irjet.net p-ISSN: 2395-0072 © 2022, IRJET | Impact Factor value: 7.529 | ISO 9001:2008 Certified Journal | Page 382 To prevent spray nozzle blockage due to dust particles forming on hot water basin. 6.2 MATERIAL PROPERTIES OF GI ROOF SHEET Material : Galvanized Iron (GI) Thickness of the sheet : 0.6 – 1.2 mm Resistance : Corrosion Resistance Tensile strength : 300 MPa Yield Strength : 220 Mpa Fig -9: Cooling Tower hot water basin without GI roof sheet Fig -10: Cooling Tower hot water basin with GI roof sheet 7. COOLING TOWER CALCULATIONS 7.1 COOLING TOWER CALCULATIONS BEFORE GI ROOF SHEET PROVIDED ON HOT WATER BASIN Hot water temperature (thw) = 40°C cold water temperature (tcw) = 30°C Inlet air temperature = 32.5° Outlet air temperature = 33.9° Cold water basin temperature = 30°C Wet bulb temperature = 24.5°C Dry bulb temperature = 36.5°C 1) Cooling water range = (Hot water temperature) - (Cold wate temperature) = 40-30 = 10°C 2) Cooling water =(Water outlet temperature) - Approach (Wet bulb temperature) = 30-24.5 = 5.5°C 3) L/G Ratio = water flow in Kg / Air flow in Kg = 20794/7655 = 2.7164 4) Fan Air Flow Actual / = (Rated fan flow fan input) / Cells (fan input speed rated )1.3 =(1945950 56.03 ) / (75)1.3 = 25.534 106 Nm3//hr 5) Air Mass Flow / Cell = flow density of air = (1945950 56.03 ) / (75)1.3 = 25.534 106 m3/hr 6) Density ratio = actual air density / 0.0075 = 1.164 / 0.0075 = 15.52 Kg/m3 7) Fraction of water = mass of water evaporated / mass of water = 240.28 / 20794 = 0.0115 8) Enthalpy of inlet air (h1)=78.5 KJ/Kg[using psychometric chart for wet bulb and dry bulb temperature ] 9) Enthalpy of exit air (h2 )= h1 + ( L/G ratio range) = 78.5 + ( 2.7164 10 ) = 105.66 KJ/Kg 10) Evaporation Loss = (Cooling water flow cooling Tower Range ) / 675 = (20794 10) / 67 = 308.05 m3/hr 11) Make up water = Evaporation loss / (coc - 1) consumption = 308.05 / (1.45 – 1) = 684.55 m3/hr 12) Drift loss = 0.2% of water supply = (0.2 / 100) (20794) = 41.588 m3/hr 13) Efficiency = [Range / (Range + approach) 100 ] = [10/ (10 - 5.5) 100] = 64.51% 7.1 COOLING TOWER CALCULATIONS AFTER GI ROOF SHEET PROVIDED ON HOT WATER BASIN Hot water temperature (thw) = 42°C cold water temperature (tcw) = 30°C Inlet air temperature = 32.5° Outlet air temperature = 33.9°
- 6. International Research Journal of Engineering and Technology (IRJET) e-ISSN: 2395-0056 Volume: 09 Issue: 06 | June 2022 www.irjet.net p-ISSN: 2395-0072 © 2022, IRJET | Impact Factor value: 7.529 | ISO 9001:2008 Certified Journal | Page 383 Cold water basin temperature = 30°C Wet bulb temperature = 24.5°C Dry bulb temperature = 36.5°C 1) Cooling water range = (Hot water temperature) - (Cold wate temperature) = 42-30 = 12°C 2) Cooling water =(Water outlet temperature) - Approach (Wet bulb temperature) = 30-24.5 = 5.5°C 3) L/G Ratio = water flow in Kg / Air flow in Kg = 20794/7655 = 2.7164 5) Air Mass Flow / Cell = flow density of air = (1945950 56.03 ) / (75)1.3 = 25.534 106 m3/hr 6) Density ratio = actual air density / 0.0075 = 1.164 / 0.0075 = 15.52 Kg/m3 7) Fraction of water = mass of water evaporated / mass of water = 240.28 / 20794 = 0.0115 10) Evaporation Loss = (Cooling water flow cooling Tower Range ) / 675 = (20794 12) / 675 = 369.67 m3/hr 11) Make up water = Evaporation loss / (coc - 1) consumption = 369.67 / (1.45 – 1) = 821.4 m3/hr 12) Drift loss = 0.2% of water supply = (0.2 / 100) (20794) = 41.588 m3/hr 13) Efficiency = [Range / (Range + approach) 100 ] = [12/ (12 - 5.5) 100] = 68.57 % 8. PERFORMANCE GRAPH 8.1 RANGE vs EFFICIENCY Graph is plotted between the range of the cooling tower and corresponding efficiency of the cooling tower Fig -11: Range vs Efficiency Graph 8.2 INPUT vs EFFICIENCY Graph is plotted between the input temperature of hot water and corresponding efficiency of the cooling tower. Fig -12: Input vs Efficiency Graph 9. CONCLUSION After theoretical analysis, it works found the efficiency of cooling tower-I was 64.1% which islowerthanthedesigned value at 70.97% which is due to atmospheric temperature. Because of frequent and periodic maintenance of fans. gear box, drive shaft, hot water basin, flow control valves, hot water pipe lines, and nozzles. It will attain stable efficiency. Due to scheduled maintenance. There is no algae formation in the hot water basin and so the cooling tower is still in better condition and also improvement inthecoolingtower- I by providing Gl sheet on the hot water basin cell top to reduce the algae growth and cold-water temperature reduced up to 68.57% (-4°c). It also to improve the cooling tower and generation. ACKNOWLEDGEMENT We wish to express our sincere thanks to our honorable chairman Thiru. JANSONS.T.S.NATARAJAN, Sengunthar Institutions, Tiruchengode for providing opportunity to do
- 7. International Research Journal of Engineering and Technology (IRJET) e-ISSN: 2395-0056 Volume: 09 Issue: 06 | June 2022 www.irjet.net p-ISSN: 2395-0072 © 2022, IRJET | Impact Factor value: 7.529 | ISO 9001:2008 Certified Journal | Page 384 this project. We wish to extend our heartfelt thanks to our honorable Secretary and Correspondent Prof. A.BALADHANDAPANI, M.A., M.Phil., and other respected Trust members for providing us with all the facilities to develop the project successfully. We would like to express oursinceregratitudetoourbeloved Principal Dr.K.UMADEVI.ME., Ph.D., for having rendered us moral support in our endeavor We feel elated by the encouragement of Mr. N.THIRU SENTHIL ADHIBAN,M.E., Head of the Department of Mechanical Engineering for motivating us throughout the completion of this project REFERENCES [1] R. Ramkumar A. Ragupathy. Thermal Performance of Forced Draft Counter Flow Wet Cooling Tower with Expanded Wire Mesh Packing International Journal on Technical and Physical Problems of Engineering" (IJTPE), Issue. 6, Vol. 3, No. 1, Mar. 2011 [2] Ronak Shah, TruptiRathod, Thermal Design Of Cooling Tower, International Journal of Advanced Engineering Research and Studies E-ISSN2249-8974 [3] Xiaoni Qi. Yongqi Liu Zhenyan Liu Exergy Based Performance Analysis of a Shower Cooling Tower Strojniš kivestnik- Journal of Mechanical Engineering 59(2013)4, 251-259 [4] Ding Feng, Xing Ke-jia, Li Shi-Bei, Bai Jun-hong, Sensitivity Analysis of Plume RisingHeightfromCooling Tower, Procedia Environmental Sciences2(2010)1374- 1379. [5] Y.A. Li and M.Z. Yu, F.W. Shang, P. Xie, The Development of A Mathematical Model With An Analytical Solution Of The Counter flow Closed Circuit Cooling Tower, International Journal on Architectural Science, Volume 1, Number 3, p.120-122, 2000. [6] L. Lu, W. Cai, A Universal Engineering Model ForCooling Towers, (2002). International Refrigeration and Air Conditioning Conference. Paper 625.