TABLE OF CONTENTS
Title Page
Abstract
CHAPTER ONE
INTRODUCTION
1.1 Background
1.2 Problem Statement
1.3 Aim and Objectives
1.4 Justification
1.5 Scope
CHAPTER TWO
LITERATURE REVIEW
2.1 Introduction
2.2 Historical Development of Gasification
2.3 Biomass Reserve in Nigeria
2.4 Biomass Material
2.5 Components of Biomass
2.5.1 Cellulose
2.5.2 Hemicellulose
2.5.3 Lignin
2.6 Biomass Characterization
2.6.1 Proximate analysis
2.6.2 Ultimate analysis
2.7 Biomass Heating Value
2.7.1 Higher heating value
2.7.2 Lower heating value
2.7.3 Estimation of biomass heating values
2.8 Biomass Beneficiation
2.8.1 Size reduction
2.8.2 Pre-drying
2.9 Biomass Conversion Process
2.9.1 Thermochemical conversion
2.9.2 Biochemical conversion
2.10 Gasification Process
2.10.1 Drying
2.10.2 Pyrolysis
2.10.3 Combustion
2.10.4 Reduction
2.11 Gasifier Design
2.11.1 Fixed bed design
2.11.2 Fluidize bed gasifier
2.12 Gasification Operating Parameters
2.12.1 Equivalence ratio
2.12.2 Temperature
2.12.3 Gasification medium
2.12.4 Moisture content
2.12.5 Superficial velocity
2.13 Product Gas Treatment
2.13.1 Tar removal
2.13.2 Particulate removal
2.13.3 Gas conditioning
2.14 Synthesis Gas Application
2.14.1 Thermal energy
2.14.2 Power generation
2.14.3 Transportation fuels
2.14.4 Methanol production
2.15 Gasification Safety Consideration
2.15.1 Gas toxic hazard
CHAPTER THREE
MATERIALS AND METHODS
3.1 Materials and Equipment
3.2 Sawdust Characterization
3.3 Experimental Setup
3.4 Experimental Measurement
3.5 Gasification Performance Evaluation
3.6 Thermodynamic Equilibrium Model
3.6.1 Model assumptions
3.6.2 MATLAB Simulation Algorithm
3.7 Root Mean Square Error
CHAPTER FOUR
RESULTS AND DISCUSSION
4.1 Proximate Analysis Result
4.1.2 Ultimate analysis result
4.2 Gasification Using Air Medium
4.2.1 Effect of air flow rate on equivalence ratio and temperature
4.2.2 Effect of air flow rates on product gas composition
4.3 Gasification Using Oxygen Enriched Air
4.3.1 Effect of oxygen enrichment on equivalence ratio and temperature
4.3.2 Effect of oxygen enrichment on gasification performance parameter
4.3.3 Effect of oxygen enrichment on product gas composition
4.3.4 Effect of oxygen enrichment on H2/CO and CO/CO2 ratio
4.4 Model Validation
4.4.1 Model validation with literature data
4.4.2 Model validation with present experimental data
CHAPTER FIVE
CONCLUSIONS AND RECOMMENDATIONS
5.1 Conclusions
5.2 Recommendations
APPENDIX
Abstract
This research work investigates the effect of gasification operating parameters, namely: equivalence ratio (ER), gasification agent, reaction zone temperature, and residence time on quality of syngas produced using sawdust.The research experiments were conducted using a pilot scale downdraft gasifier with constricted throat and a rotating grate. Temperatures at reaction zone of the gasifier were monitored directly using a digital thermometer whereas an online gas analyzer capable of detecting percentage composition and calorific value was employed to monitor quality of the syngas.Two sets of experiments were carried out separately; one using air and the other using oxygen-enriched air as gasifying agents. With air, flow rates at 6.4, 1.9 and 0.7 litre per minute (LPM) were used for the study. The results obtained shows that the higher air flow level favours better quality of syngas. Air flow rate at 0.64LPM generated the best quality of syngas containing 13.55 and 2.59% of CO and H2, respectively. Syngas maximum caloric value of nearly 3MJ/Nm3 at a temperature of 550°C was observed. Using oxygen enriched-air on the other hand, flow rate was maintained at 10LPM while varying the percentage oxygen at 21, 30, 40, 50, 60 and 80%.It was found that 40% oxygen enrichment generated the best quality of syngas containing29.57 and 14.29% of CO and H2 respectively.Syngas calorific value was observed to rise consistently from 2.08 to a maximum of 6.69MJ/Nm3 as percentage oxygen in the gasifying agent was increased from 21 to 40%. Gasification performance shows that both cold gas efficiency (CGE) and carbon conversion efficiency(CCE) reaches peak value of 46.81 and 82.04% respectively at ER value of 0.2953 which also corresponds to the 40% oxygen level in gasifying agent.
CHAPTER ONE
INTRODUCTION
1.1 Background
The alarming rate of global warmingas a result of harmful gases released into the atmosphere combined with continual depletion of fossil fuel resources at unprecedented rate led researchers to devote effort in developing alternative energy technologies from agricultural wastes like sawdust, rice husk andsugar cane bagasse to meet up future energy demand (Christus et al., 2014).
Although it is not known how much fossil fuel is still available, it is generally accepted that it is being depleted and is non-renewable. With these challenging circumstances, search for other alternative renewable forms of energy sources becomes imperative. Other consequences associated with fossil fuel use include the release of the trapped carbon in the fossil fuels to the atmosphere in the form of carbon dioxide which has led to increased concerns about global warming. Also, fossil fuel resources are not distributed evenly around the globe which makes many countries heavily dependent on imports (Ajay et al.,
2009).Evidence suggests that conventional oil production has a limited capacity to meet growing demand, and most additional demand will have to be met by unconventional sources. Since the globe is turning towards the sustainable development, renewable energy technologies are getting more attention all over the world (Bergerson and Keith, 2006).
The combustion of biomass of different varieties has gaindramatic applications ranging from woodstove for domestic usage to industrial power generation. However more extensive applications lie ahead from effective technology for conversion of the biomass....
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