Modification And Testing Of Biomass Dryer
The title “Modification and Testing of Biomass Dryer” encapsulates a comprehensive exploration of refining and evaluating a biomass dryer system. This process involves enhancing the existing functionality of the dryer to optimize its performance and efficiency. The intricate modifications may include adjustments to the heating mechanisms, airflow dynamics, or moisture control systems. Subsequently, rigorous testing is conducted to validate the efficacy of these modifications under various operational conditions. The assessment encompasses factors such as drying time, energy consumption, and the quality of the dried biomass. The endeavor seeks to innovate and fine-tune the biomass drying process, aligning it with contemporary standards of sustainability and resource efficiency. Through a methodical approach, this study contributes to the ongoing evolution of biomass drying technologies, ensuring their relevance in the context of environmental conservation and renewable energy practices.
Drying is out of the major problem in post harvest operation. The traditional method of Drying (Sun drying) is weather dependent and unhygienic which affect food storage most especially in developing countries like India where more than 3300 to 3700 hours of bright sunshine per year available in North- West and West coastal region. The dryer consist of the following operating component parts: a cabinet, blower, trays, temperature controller, copper wire and light emitting Diode (LED) screen and switch. The factors considered in the study were turmeric of 2000g weight, temperature (500C, 600C and 800C) and each were replicated 3 times. The testing was carried out in term of drying rate, amount of moisture loss and applied temperature. Temperature of 600C and 700C favours the drying of the three weight that temperature of 400C. the time taken for each figure sample at different weight and temperature differs. Hence, the higher the temperature the lesser the time taken for the turmeric to dry, the higher the weight the higher the time taken for turmeric to dry, the statistical analysis (ANOVA) shows that there is high significance difference at 5% in the mean value of the drying rate as affected by temperature 400C and there high significance difference at 1% and 5% in the mean value of the drying rate. The efficiency of the battery operated biomass dryer on the modification to the biomass dryer was evaluated to be N 223,250.00.
Cover Page
Title Page
Certification
Dedication
Acknowledgements
Abstract
Table of Contents
List of Tables
List of Figures
List of Plates
CHAPTER ONE:
INTRODUCTION
1.1 Background to the Study 1
1.2 Problem Statement 2
1.3 Aim and Objectives 2
1.4 Justification 3
1.5 Scope of the Project 3
CHAPTER TWO:
LITERATURE REVIEW
2.1 Drying as an Element of Post Harvest 4
2.1.1 Types of Losses 5
2.1.1.1 Moisture Content 6
2.1.1.2 Damage 6
2.1.1.3 Direct and Indirect Losses 6
2.1.1.4 Weight Loss 6
2.1.1.5 Quality Loss 6
2.1.1.6 Food Loss 7
2.1.1.7 Seed Viability Loss 7
2.1.1.8 Commercial Loss 7
2.2 Methods of Drying 8
2.2.1 Traditional method of drying 8
2.2.2 Modern Methods of Drying 8
2.3 Mechanisms of Drying 9
2.4 Basic Theory of Drying 10
2.4.1 Thin Layer Drying 11
2.4.2 Deep Bed Drying 14
2.5 Factors affecting rate of drying 15
2.5.1 Crop Parameters 15
2.5.2 Air Parameters 16
2.5.3 Dryer Parameters 17
2.6 Review of Dryers 17
2.7 Drying Process 18
2.8 Agronomy of Turmeric 19
2.8.1 Benefit of Turmeric 19
2.9 Sources of Energy for Drying 20
2.9.1 Briquette as a Source of Energy 20
2.9.2 Solar as a Source of Energy 21
2.9.3 The Fossil Fuels 21
2.9.4 Electricity 21
2.9.5 Nuclear Power 21
2.9.6 Hydro Power 22
2.9.7 Geothermal Energy 22
2.9.8 Wind Power 22
CHAPTER THREE:
MATERIALS AND METHOD
3.1 Modified Areas on the Biomass Dryer 23
3.2 Materials 23
3.2.1 Charcoal 23
3.2.2 Digital Weighing Scale 24
3.2.3 Temperature Monitor and Controller 24
3.2.4 Biomass Dryer 25
3.2.5 Digital Venier Caliper 25
3.2 Description of the Machine 26
3.3 Component Parts of the Biomass Dryer 26
3.3.1 Chimney 27
3.3.2 Drying Tray 27
3.3.3 Drying Chamber 27
3.3.4 Solar Panel 27
3.3.5 Battery 28
3.3.6 Ash Port 28
3.3.7 Temperature Controller 28
3.3.8 Centrifugal Fan (Blower) 28
3.3.9 LED Screen 28
3.3.10 Charge Controller 28
3.3.11 Copper Pipe 29
3.4 Design Consideration for the Biomass Dryer 29
3.4.1 Air Temperature 29
3.4.2 Air Relative Humidity 29
3.4.3 Air Flow Rate 30
3.5 Material Selection 30
3.6 Operation of the Biomass Dryer 31
3.7 Design Analysis/Design Calculation 31
3.7.1 Design for the Volume/Capacity of Drying Tray 31
3.7.2 Design of Area of the Temperature Controller 31
3.7.3 Design of Area of Copper Pipe 32
3.7.4 Design of Area for the Burning Chamber 32
3.7.5 The Amount of Moisture to be Removed from Agricultural Produce 32
3.7.6 Design for Solar Panel Capacity 33
3.7.7 Drying Rate 33
3.7.8 Design Calculation and Analysis 33
3.8 Bill of Engineering Measurement and Evaluation (BEME) 35
3.10.1 Sourcing of Raw Material 37
3.10.2 Sample Preparation 37
3.10.3 Experimental Design and Layout 37
3.10.4 Experimental Procedure 38
3.10.5 Output Parameter 38
3.10.5.1 Measurement for Drying Rate 38
3.10.5.2 Determination of Water Loss 38
CHAPTER FOUR:
RESULTS AND DISCUSSIONS
4.1 Results 40
4.2 Discussion 44
4.2.1 Effect of Drying Rate on Turmeric at 500C 44
CHAPTER FIVE:
CONCLUSIONS AND RECOMMENDATIONS 48
5.1 Conclusions 48
5.2 Recommendations 48
Reference 50
Appendix A 54
Appendix B 56
Appendix C 58
AppendiX D 60
INTRODUCTION
1.1 Background to the Study
Drying is the dehydration process used to remove the moisture present in food products by the application of heat. The heat may be supplied either by hot air or from the biomass energy. Drying process is used to preserve the food products for future usage. Drying prevents the growth of bacteria and yeast formation. Drying can be achieved by using open air and biomass dryers. (Atulet al, 2014). Drying has a vital role in post harvest processing. It has always been of great importance for conserving agricultural products and for extending the food shelflife. (Doymaz 2007).
Drying crops by biomass energy is of great economic importance, especially in Nigeria where most of crops and grain harvests are lost to fungal and microbial attack. These wastage could be easily prevented by proper drying which enhance storage of crops and grains over long period of time. The biomass energy can easily be harnessed by a proper design of biomass dryer for crop drying. This method of drying requires the transfer of both heat and water vapor (Forsonet al, 2007). Biomass drying is a process of using biomass energy to heat air and the product so as to achieve drying of agricultural products (Ajay et al, 2009). Biomass air heaters are simple devices to heat air by utilizing biomass energy and employed rate temperature between 800C such as crop drying and space heating (Bukola and Ayoola, 2008).
Biomass can be define as all renewable or organic matter including plant materials, animal products, and forestry by products and urban wastes etc with highly different properties to be used as fuels. Energy obtained from biomass is not site specific, thus can be established at any place where plant and animal waste is available. The biomass backup burner helps the small scale farmers to dry their product in a more efficient manner. It is also able to reduce the drying time as compared to direct sun drying (Paistet al, 2005).
The biomass dryer is one of the dryers which has achieved some level of acceptance. One of the important disadvantages of the dryer is that it cannot be used without any backup heater during night times and cloudy days. Introducing biomass makes the dryer operational even beyond sunshine hours (IEA, 2011).
1.2 Problem Statement
Majority of the rural farmers do not have access to sustainable electricity supply. Therefore, the biomass dryer are used to operate during raining season at harvest time, the biomass dryer must also be able to continue drying during this period in order to achieve effective drying. It must be able to continue drying until late evening to shorten the drying period (Akhraniet al, 2013). With the price of energy constantly rising, the use of biomass presents air option for decreasing energy dependency. There is also an account locally produced biomass contributes to self-sufficiency and a low dependency on the energy market and on other region (Hutla and Mazancova, 2004).
Thus, there is the need to design and fabricate a biomass dryer that would solve the above mentioned problems for the farmers.
1.3 Aim and Objectives
This aim of this project is tomodified a biomass dryer in order to reduce the moisture content of agricultural crop so as to prolong their shelflife using biomass as a source of heat generation.
The specific objectives of this project are:-
i. To extend the condenser in the drying chamber for easy conveyance of the heated air
ii. To redesign briquette chamber to avoid heat loss and for easy loading of briquette
iii. To introduce copper pipe for easy transfer of heat into the drying trays
iv. To carryout performance evaluation on the biomass dryer in term of weight loss, temperature and time
1.4 Justification
The open sun drying process is a slow process, dried products will be of low quality due to contamination of dust particle, damages due to rain and moisture present in the air. Also there is a loss of food products due to insects, birds and animals. Thus there is need to design an integrated biomass dryer that helps to achieve above mentioned and also to reduce the effect of atmospheric pollution on the product because it is carried out in a closed environment (Atul Petal, 2014).
1.5 Scope of the Project
Turmeric (Curcuma Longa L.) is one of the essential of the Indian recipes. Besides the taste and aroma, it is also being used for material value since ancient times. (Jacob 2005). Turmeric is a specie derived from the rhizomes of Curcuma Longa, which is a member of the ginger family Zingiberaceae. The bright yellow colour of turmeric comes mainly from polyphonic pigment curcuminoids (Aggarwalet al., 2007).
Preservation of turmeric cannot be over emphasized in order to reduce post harvest loss of agricultural produce.
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Modification And Testing Of Biomass Dryer:
Modifying and testing a biomass dryer involves making improvements to its design, functionality, or efficiency, and then conducting experiments to ensure that the modifications meet the desired objectives. Here’s a general guide on how you might approach this process:
Modification of Biomass Dryer:
- Identify Goals:
- Determine the specific objectives of the modification (e.g., improving drying efficiency, reducing energy consumption, enhancing safety).
- Review Existing Design:
- Understand the current design and components of the biomass dryer.
- Design Changes:
- Collaborate with engineers or experts to develop modifications that align with your goals.
- Consider improvements in insulation, airflow, heat transfer mechanisms, or control systems.
- Materials and Components:
- Select appropriate materials and components for the modifications, ensuring they are compatible with biomass drying conditions.
- Safety Considerations:
- If applicable, ensure that any modifications comply with safety standards and regulations.
- Cost-Benefit Analysis:
- Evaluate the cost-effectiveness of the proposed modifications.
- Implementation:
- Carry out the modifications following the design specifications.
- Document the changes made to the dryer.
Testing of Modified Biomass Dryer:
- Preparation:
- Conduct a thorough inspection of the modified dryer to ensure all components are installed correctly.
- Instrumentation:
- Install sensors and measurement devices to monitor key parameters such as temperature, airflow, and moisture content during the drying process.
- Baseline Testing:
- Run tests on the unmodified dryer to establish baseline performance metrics for comparison.
- Test Plan:
- Develop a comprehensive test plan outlining the parameters to be tested, the duration of tests, and the expected outcomes.
- Performance Testing:
- Run the modified biomass dryer under various conditions to evaluate its performance.
- Monitor and record data at regular intervals.
- Data Analysis:
- Analyze the collected data to assess improvements in efficiency, energy consumption, and other relevant parameters.
- Comparative Analysis:
- Compare the results of the modified dryer with the baseline data to quantify the effectiveness of the modifications.
- Iterative Testing:
- If necessary, make further adjustments and conduct additional tests until the desired performance is achieved.
- Documentation:
- Document the results of the tests, including any challenges encountered, and create a report summarizing the modifications and their impact.
- Feedback and Validation:
- Seek feedback from relevant stakeholders and validate the modifications against the initial goals.
Remember to approach modification and testing systematically, and involve relevant experts to ensure the success of the project. Additionally, it’s essential to consider environmental and safety factors throughout the process.