Experimental investigation of the terracotta tubes based direct evaporative cooling system (Softcopy is also available)
Priyadarshi, Sahil (PT500716)
Experimental investigation of the terracotta tubes based direct evaporative cooling system (Softcopy is also available) - 2018 - xi,42p.
Content
List of Abbreviations x
Definitions of Terminology xi
1 Introduction - 1 -
Background - 1 -
1.1.1 Purpose of installation - 1 -
1.1.2 Cool AnT System Description & Working Principle - 1 -
1.1.3 System Limitation - 2 -
1.1.4 Need for the study - 2 -
Research Question - 2 –
1.2.1 Research objectives - 2 -
Significance of the study - 3 -
2 Literature Review - 3 -
Introduction - 3 -
Material Relevance - 3 -
Summary of literature review - 7 -
3 Research Methodology - 8 -
Overview - 8 -
Experimental Set-up - 8 -
3.2.1 Fabrication - 8 -
Measurements - 10 -
3.3.1 Measured Parameters - 10 -
3.3.2 Measuring Instruments & Equipment Specifications - 10 -
3.3.3 Measurement Methodology - 11 -
Experimentation Methodology - 12 -
3.4.1 Fully saturated pots without water flow at different air flow rates - 12 -
3.4.2 Dry pots with water flow at different air flow rates - 13 -
3.4.3 Dry pots at different water flow rates - 13 -
3.4.4 Geometrical Variation - 13 -
Data Gathering Process - 13 -
Data Analysis - 14 -
Experimentation Guidelines - 14 -
3.7.1 Experimental Set-up - 14 -
3.7.2 Water System - 15 -
3.7.3 Electrical Systems - 15 -
3.7.4 Market Research - 15
3.7.5 Measurements - 15 -
3.7.6 Management & Co-ordination - 16 -
4 Results & Analysis - 16 -
Fully saturated pots without water flow at different air flow rates - 16 -
4.1.1 Outlet air temperature (°C) & RH (%) with respect to inlet air temperature (°C) & RH (%): - 16
4.1.2 Temperature drop (°C) at different air flow rates - 18 -
4.1.3 Wet-bulb efficiency (%) with respect to air flow rate (cfm) - 19 -
Dry pots with water flow at different air flow rates - 20 -
4.2.1 Outlet air temperature (°C) & RH (%) with respect to inlet air temperature (°C) & RH (%) - 20 -
4.2.2 Temperature drop (°C) at different air flow rates - 20 -
4.2.3 Wet-bulb efficiency (%) with respect to air flow rate (cfm) - 21 -
4.2.4 Water consumption (L) - 22 -
4.2.5 True power (W) consumption - 22 -
4.2.6 Coefficient of Performance (COP) - 23 -
Pots at different water flow rates - 23 -
4.3.1 Temperature drop (°C) at different water flow rates - 24 -
4.3.2 Wet-bulb efficiency (%) with respect to air flow rate (cfm) - 24 -
Geometrical Variation - 25 -
4.4.1 Outlet air temperature (°C) & RH (%) with respect to inlet air temperature (°C) & RH (%) - 25 -
4.4.2 Temperature drop (°C) - 26 -
4.4.3 Wet-bulb efficiency (%) with respect to air flow rate (cfm) - 26 -
4.4.1 Water consumption (L) - 27 -
4.4.2 True power (W) consumption - 27 -
Advantages and Application of the System - 28 -
Comparison with Different Evaporative Cooling Systems - 28 -
5 Conclusion - 30 -
References - 31 -
MBEP TH-0011 / PRI
Experimental investigation of the terracotta tubes based direct evaporative cooling system (Softcopy is also available) - 2018 - xi,42p.
Content
List of Abbreviations x
Definitions of Terminology xi
1 Introduction - 1 -
Background - 1 -
1.1.1 Purpose of installation - 1 -
1.1.2 Cool AnT System Description & Working Principle - 1 -
1.1.3 System Limitation - 2 -
1.1.4 Need for the study - 2 -
Research Question - 2 –
1.2.1 Research objectives - 2 -
Significance of the study - 3 -
2 Literature Review - 3 -
Introduction - 3 -
Material Relevance - 3 -
Summary of literature review - 7 -
3 Research Methodology - 8 -
Overview - 8 -
Experimental Set-up - 8 -
3.2.1 Fabrication - 8 -
Measurements - 10 -
3.3.1 Measured Parameters - 10 -
3.3.2 Measuring Instruments & Equipment Specifications - 10 -
3.3.3 Measurement Methodology - 11 -
Experimentation Methodology - 12 -
3.4.1 Fully saturated pots without water flow at different air flow rates - 12 -
3.4.2 Dry pots with water flow at different air flow rates - 13 -
3.4.3 Dry pots at different water flow rates - 13 -
3.4.4 Geometrical Variation - 13 -
Data Gathering Process - 13 -
Data Analysis - 14 -
Experimentation Guidelines - 14 -
3.7.1 Experimental Set-up - 14 -
3.7.2 Water System - 15 -
3.7.3 Electrical Systems - 15 -
3.7.4 Market Research - 15
3.7.5 Measurements - 15 -
3.7.6 Management & Co-ordination - 16 -
4 Results & Analysis - 16 -
Fully saturated pots without water flow at different air flow rates - 16 -
4.1.1 Outlet air temperature (°C) & RH (%) with respect to inlet air temperature (°C) & RH (%): - 16
4.1.2 Temperature drop (°C) at different air flow rates - 18 -
4.1.3 Wet-bulb efficiency (%) with respect to air flow rate (cfm) - 19 -
Dry pots with water flow at different air flow rates - 20 -
4.2.1 Outlet air temperature (°C) & RH (%) with respect to inlet air temperature (°C) & RH (%) - 20 -
4.2.2 Temperature drop (°C) at different air flow rates - 20 -
4.2.3 Wet-bulb efficiency (%) with respect to air flow rate (cfm) - 21 -
4.2.4 Water consumption (L) - 22 -
4.2.5 True power (W) consumption - 22 -
4.2.6 Coefficient of Performance (COP) - 23 -
Pots at different water flow rates - 23 -
4.3.1 Temperature drop (°C) at different water flow rates - 24 -
4.3.2 Wet-bulb efficiency (%) with respect to air flow rate (cfm) - 24 -
Geometrical Variation - 25 -
4.4.1 Outlet air temperature (°C) & RH (%) with respect to inlet air temperature (°C) & RH (%) - 25 -
4.4.2 Temperature drop (°C) - 26 -
4.4.3 Wet-bulb efficiency (%) with respect to air flow rate (cfm) - 26 -
4.4.1 Water consumption (L) - 27 -
4.4.2 True power (W) consumption - 27 -
Advantages and Application of the System - 28 -
Comparison with Different Evaporative Cooling Systems - 28 -
5 Conclusion - 30 -
References - 31 -
MBEP TH-0011 / PRI