Parameter Analysis And Life Cycle Cost Assessment Of A 12 Volt, 200AH, Lead Acid Battery.
ABSTRACT
This study examined the parameters and conduct life cycle cost assessment of a 12 volts lead acid battery. The objectives of the study were to determine and evaluate the cost components associated with the use of batteries, conduct replacement assessment on a 12volt lead acid battery and simulate battery parameters identified using Response Surface Methodology (RSM). The experiment was carried out using a 12volt lead acid battery with load of 120W and 185W. The data obtained were analyzed in response surface methodology in design expert software to statistically determine the analysis of variance and the regression model equations for each of the battery load. The Life Cycle Cost analysis of the battery was calculated. The result showed that the process parameters had significant effects on the battery attached with different load value. The values of the coefficient of determination (R) 0.9999, elaborated the significance of the regression models generated for the dependent variables. The LCC of the battery showed that the total cost for about 2years is #115,216.346 which can be more beneficial use home used compared to other source of electricity generation.
TABLE OF CONTENTS
Cover page
Declaration i
Certification ii
Dedication iii
Acknowledgment iv
Table of
contents v
List of tables vii
List of figures viii
Abstract ix
CHAPTER
ONE
INTRODUCTION
1.1
Background of Study 1
1.2 Statement of problem 2
1.3 Aim and Objectives of Study 2
1.4 Scope of the Study 2
1.5 Justification of Study 3
CHAPTER TWO
LITERATURE REVIEW
2.1 Conceptual Theory on Batteries 4
2.1.1 Types of battery 4
2.1.2 The Lead Acid Battery 5
2.2 Battery Parameters 6
2.2.1 State of Charge (SOC), and Depth of
Discharge (DOD) 6
2.2.2 State of Health (SOH), and End of Life (EOL) 7
2.2.3 C-rate 7
2.2.4 Cycle lifetime 8
2.2.5 Specific Power 8
2.2.5 Battery Efficiency 9
2.2.6 Cycle Lifetime 9
CHAPTER THREE
MATERIALS AND METHODS
3.1 Materials 10
3.2 Methods 10
3.2.1 Experimental
Setup 10
3.3 Governing
Equations / Mathematical Considerations 11
3.3.1 Life cycle cost model 11
3.3.2 Net Present Value (NPV) 12
3.3.1 Capitol
Recovery Factor (CRF) 13
CHAPTER FOUR
RESULTS AND DISCUSSION
4.1 Result for the battery with 120Watt load 14
4.1.1 ANOVA result for the energy delivered to the
120W load battery 15
4.1.2 ANOVA result for the efficiency to the 120W
load battery 17
4.1.3 ANOVA result for the charge stored in the
120W load battery 20
4.2 Result for the battery with 185 Watt load 22
4.2.1 ANOVA result for the energy delivered to the
185W load battery 23
4.2.2 ANOVA result for the efficiency to the 185W
load battery 25
4.2.3 ANOVA result for the charge stored in the
120W load battery 27
4.3 Economic Evaluation 29
CHAPTER FIVE
CONCLUSION AND RECOMMENDATION
5.1
Conclusion 30
5.2 Recommendation 30
REFERENCES
LIST OF TABLES
Tabl4
4.1 Experimental design for the
battery with 120Watt Load 14
Table 4.2: Analysis of Variance for the energy
delivered to the 120W load battery 16
Table 4.3: Analysis of Variance for the Efficiency
to the 120W load battery 18
Table 4.4: Analysis of Variance for the charge
stored in the 120W load battery 20
Tabl4
4.5 Experimental design for the
battery with 185Watt Load 22
Table 4.6: Analysis of Variance for the energy
delivered to the 185W load battery 24
Table 4.7: Analysis of Variance for the Efficiency
to the 185 W load battery 26
Table 4.8: Analysis of Variance for the charge
stored in the 185W load battery 28
LIST OF FIGURES
Figure 4.1: Effect
of the process parameters on the energy delivered to the 120watt load battery 17
Figure 4.2:
Effect of the process parameters on the efficiency to the 120watt load battery 19
Figure 4.3:
Effect of the process parameters on the charge stored in the 120watt load
battery 21
Figure 4.4:
Effect of the process parameters on the energy delivered to the 185 watt load
battery 25
Figure 4.5:
Effect of the process parameters on the efficiency to the 185 watt load battery 27
Figure 4.6:
Effect of the process parameters on the charge stored in the 185 watt load
battery 29
0.0
LEKWAUWA, C (2023). Parameter Analysis And Life Cycle Cost Assessment Of A 12 Volt, 200AH, Lead Acid Battery.. Repository.mouau.edu.ng: Retrieved Apr 27, 2024, from https://repository.mouau.edu.ng/work/view/parameter-analysis-and-life-cycle-cost-assessment-of-a-12-volt-200ah-lead-acid-battery-7-2
CHUKWUEBUKA, LEKWAUWA. "Parameter Analysis And Life Cycle Cost Assessment Of A 12 Volt, 200AH, Lead Acid Battery." Repository.mouau.edu.ng. Repository.mouau.edu.ng, 15 Aug. 2023, https://repository.mouau.edu.ng/work/view/parameter-analysis-and-life-cycle-cost-assessment-of-a-12-volt-200ah-lead-acid-battery-7-2. Accessed 27 Apr. 2024.
CHUKWUEBUKA, LEKWAUWA. "Parameter Analysis And Life Cycle Cost Assessment Of A 12 Volt, 200AH, Lead Acid Battery.". Repository.mouau.edu.ng, Repository.mouau.edu.ng, 15 Aug. 2023. Web. 27 Apr. 2024. < https://repository.mouau.edu.ng/work/view/parameter-analysis-and-life-cycle-cost-assessment-of-a-12-volt-200ah-lead-acid-battery-7-2 >.
CHUKWUEBUKA, LEKWAUWA. "Parameter Analysis And Life Cycle Cost Assessment Of A 12 Volt, 200AH, Lead Acid Battery." Repository.mouau.edu.ng (2023). Accessed 27 Apr. 2024. https://repository.mouau.edu.ng/work/view/parameter-analysis-and-life-cycle-cost-assessment-of-a-12-volt-200ah-lead-acid-battery-7-2