CSU-Carig
Anciado, John Christopher B., author.
Design, fabrication and testing of a portable pelletizer machine / - ©2024.
TITLE PAGE
ABSTRACT
DEDICATION
ACKNOWLEDGEMENT
TABLE OF CONTENTS
Chapter 1: THE PROBLEM AND ITS BACKGROUND
Introduction
Background of the Study
Objective of the study
Scope and Limitation
Conceptual Framework.
Significance of the Study
Definition of terms
Chapter 2: REVIEW OF RELATED LITERATURE
Related literature and studies
Chapter 3: RESEARCH METHODOLOGY
Research Design
Project Design
Electrical Wiring
Detailed Design
Procedure of Construction
Gannt Chart
Research Instruments
Project Development and Testing Procedure
Chapter 4: DISCUSSION OF RESULTS
Discussion of Results
Chapter 5: SUMMARY OF FINDINGS, CONCLUSION AND RECOMMENDATIONS
Summary
Conclusion
Recommendation
References
APPENDICES
Documentations
Manual
List of Tables
List of Figures
Curriculum Vitae
This study presents the design, development, and performance
evaluation of a portable pelletizer machine with a production capacity of 50-60 kg per hour. The machine is equipped with a 1 HP electric motor and features key components such as a 6-inch cylindrical tube, a 4 mm die for pellet formation, two pressing rollers, and a sophisticated control system.
The study investigates the machine's performance by testing twodifferent formulations, varying the die sizes (4 mm, 6 mm, and 8 mm), and analyzing the
You sent
resulting pellet shape and uniformity. The findings indicate that both formulations struggled to produce well-formed and uniform pellets, with the pellets being described as "Pulverized" or "Slightly form" with varying degrees of compactness.
The smaller die sizes (4 mm and 6 mm) showed slightly better results compared to the larger 8 mm die size, but overall, the pellets lacked the desired level of compactness and uniformity. This suggests that the formulations and processing conditions may require further optimization to improve the quality of the produced pellets.
The study concludes with recommendations for improving the performance of the portable pelletizer machine, including formulation optimization, process parameter optimization, machine design refinement, and comprehensive testing and validation. Implementing these recommendations can enhance the machine's ability to consistently produce high-quality pellets, making it more suitable for industrial applications.
Electrical 0002 / 2024 c.1
Design, fabrication and testing of a portable pelletizer machine / - ©2024.
TITLE PAGE
ABSTRACT
DEDICATION
ACKNOWLEDGEMENT
TABLE OF CONTENTS
Chapter 1: THE PROBLEM AND ITS BACKGROUND
Introduction
Background of the Study
Objective of the study
Scope and Limitation
Conceptual Framework.
Significance of the Study
Definition of terms
Chapter 2: REVIEW OF RELATED LITERATURE
Related literature and studies
Chapter 3: RESEARCH METHODOLOGY
Research Design
Project Design
Electrical Wiring
Detailed Design
Procedure of Construction
Gannt Chart
Research Instruments
Project Development and Testing Procedure
Chapter 4: DISCUSSION OF RESULTS
Discussion of Results
Chapter 5: SUMMARY OF FINDINGS, CONCLUSION AND RECOMMENDATIONS
Summary
Conclusion
Recommendation
References
APPENDICES
Documentations
Manual
List of Tables
List of Figures
Curriculum Vitae
This study presents the design, development, and performance
evaluation of a portable pelletizer machine with a production capacity of 50-60 kg per hour. The machine is equipped with a 1 HP electric motor and features key components such as a 6-inch cylindrical tube, a 4 mm die for pellet formation, two pressing rollers, and a sophisticated control system.
The study investigates the machine's performance by testing twodifferent formulations, varying the die sizes (4 mm, 6 mm, and 8 mm), and analyzing the
You sent
resulting pellet shape and uniformity. The findings indicate that both formulations struggled to produce well-formed and uniform pellets, with the pellets being described as "Pulverized" or "Slightly form" with varying degrees of compactness.
The smaller die sizes (4 mm and 6 mm) showed slightly better results compared to the larger 8 mm die size, but overall, the pellets lacked the desired level of compactness and uniformity. This suggests that the formulations and processing conditions may require further optimization to improve the quality of the produced pellets.
The study concludes with recommendations for improving the performance of the portable pelletizer machine, including formulation optimization, process parameter optimization, machine design refinement, and comprehensive testing and validation. Implementing these recommendations can enhance the machine's ability to consistently produce high-quality pellets, making it more suitable for industrial applications.
Electrical 0002 / 2024 c.1