DEVELOPMENT AND PERFORMANCE EVALUATION OF HYDRAULIC PISTON PRESS BIOMASS HOOLOW BRIQUETTE MAKING MACHINE

 

Table Of Contents


  • <p>       <b>&nbsp;TABLE OF CONTENTS&nbsp;</b></p><p>TITLE PAGE ..................................................................................................................................iii&nbsp;</p><p>DECLARATION.............................................................................................................................iv&nbsp;</p><p>CERTIFICATION............................................................................................................................v&nbsp;</p><p>DEDICATION ................................................................................................................................vi&nbsp;</p><p>ACKNOWLEDGEMENT..............................................................................................................vii&nbsp;</p><p>ABSTRACT..................................................................................................................................viii&nbsp;</p><p>TABLE OF CONTENTS ................................................................................................................ix&nbsp;</p><p>LIST OF TABLES .........................................................................................................................xii&nbsp;</p><p>LIST OF FIGURES........................................................................................................................xv&nbsp;</p><p>LIST OF PLATE...........................................................................................................................xvi&nbsp;</p><p>LIST OF APPENDICES ..............................................................................................................xvii</p><p>&nbsp;LIST OF ABBREVIATIONS .....................................................................................................xviii&nbsp;</p><p>
  • 1.0INTRODUCTION................................................................................................................1&nbsp;</p><p>
  • 1.1General Background ..............................................................................................................1&nbsp;</p><p>
  • 1.2Statement of Problems........................................................................................................3&nbsp;</p><p>
  • 1.3Aim and Objectives of Study ..............................................................................................4&nbsp;</p><p>
  • 1.4Justification of Study...........................................................................................................4&nbsp;</p><p>
  • 1.5Scope and Limitation of the Study.....................................................................................6&nbsp;</p><p>
  • 2.0LITERATURE REVIEW.....................................................................................................7&nbsp;</p><p>
  • 2.1Background.............................................................................................................................7&nbsp;</p><p>
  • 2.2Briquetting Technologies.......................................................................................................7&nbsp;</p><p>2.
  • 2.1Screw press technology ............................................................................................7&nbsp;</p><p>2.
  • 2.2Piston press technology ............................................................................................8&nbsp;</p><p>2.
  • 2.3Roller press.............................................................................................................10&nbsp;</p><p>2.
  • 2.4Pellet press..............................................................................................................10&nbsp;</p><p>2.
  • 2.5Manual presses (Low-pressure briquetting) ...........................................................11&nbsp;</p><p>
  • 2.3Existing Briquetting Machines.........................................................................................12&nbsp;</p><p>
  • 2.4Materials for the Production of Briquettes......................................................................14&nbsp;</p><p>
  • 2.5Factors Affecting Briquette Production ...........................................................................16&nbsp;</p><p>2.
  • 5.1Biomass particle size and shape .............................................................................16&nbsp;</p><p>2.
  • 5.2Biomass moisture content.......................................................................................17&nbsp;</p><p>2.
  • 5.3Biomass temperature ..............................................................................................17&nbsp;</p><p>2.
  • 5.4Die temperature ......................................................................................................18&nbsp;</p><p>2.
  • 5.5External additives and binders................................................................................18&nbsp;</p><p>
  • 2.6Briquettes’ Performance Characteristics.........................................................................19&nbsp;</p><p>2.
  • 6.1Physical properties..................................................................................................19&nbsp;</p><p>2.
  • 6.2Thermal properties..................................................................................................21&nbsp;</p><p>2.
  • 6.3Mechanical property...............................................................................................23&nbsp;</p><p>
  • 2.7Research Gap........................................................................................................................24&nbsp;</p><p>
  • 3.0MATERIALS AND METHODS .......................................................................................25&nbsp;</p><p>
  • 3.1Materials Selection ...............................................................................................................25&nbsp;</p><p>3.
  • 1.1Material selection for the construction of briquette making machine ....................25&nbsp;</p><p>3.
  • 1.2Material selection for the evaluation of briquette making machine .......................25&nbsp;</p><p>
  • 3.2Equipments ........................................................................................................................26&nbsp;</p><p>
  • 3.3Design Considerations.......................................................................................................26&nbsp;</p><p>
  • 3.4Machine Design..................................................................................................................27</p><p>&nbsp;3.
  • 4.1Briquette size ..........................................................................................................27&nbsp;</p><p>3.
  • 4.2Determination of allowable tensile stress...............................................................27&nbsp;</p><p>3.
  • 4.3Determination of thickness of cylinder ..................................................................28&nbsp;</p><p>3.
  • 4.4Determination of the Capacity of Compressing Device (Hydraulic Jack) .............29&nbsp;</p><p>3.
  • 4.4Summary of Design Calculation.............................................................................34&nbsp;</p><p>
  • 3.5Fabrication procedure of briquetting machine................................................................35&nbsp;</p><p>3.
  • 5.1Fabrication of the upper compression plate............................................................35&nbsp;</p><p>3.
  • 5.2Fabrication of the Mould ........................................................................................36&nbsp;</p><p>3.
  • 5.3Fabrication of the piston and lower compression plate ..........................................37&nbsp;</p><p>3.
  • 5.4Fabrication of the machine stand (support)............................................................38&nbsp;</p><p>
  • 3.6Cost of Materials................................................................................................................39&nbsp;</p><p>
  • 3.7Evaluation Procedures......................................................................................................40&nbsp;</p><p>3.
  • 7.1Biomass collection and preparation........................................................................40</p><p>&nbsp;3.
  • 7.2Starch binder preparation .......................................................................................40&nbsp;</p><p>3.
  • 7.3Determination of moisture content of the prepared samples..................................40&nbsp;</p><p>
  • 3.8Machine Evaluation...........................................................................................................41&nbsp;</p><p>3.
  • 8.1Determination of physical properties .....................................................................41&nbsp;</p><p>3.
  • 8.2Determination of thermal properties.......................................................................43&nbsp;</p><p>3.
  • 8.3Machine output capacity.........................................................................................46&nbsp;</p><p>
  • 3.9Experimental Procedures .................................................................................................47&nbsp;</p><p>3.
  • 9.1Briquetting production (Machine operation)..........................................................47&nbsp;</p><p>3.
  • 9.2Experimental Design and Layout ...........................................................................47&nbsp;</p><p>
  • 4.0RESULTS AND DISCUSSION.........................................................................................49&nbsp;</p><p>
  • 4.1The Developed Hydraulic Piston Press Biomass Hollow Briquette Making Machine ...49&nbsp;</p><p>4.
  • 1.1Upper compression plate ........................................................................................50&nbsp;</p><p>4.
  • 1.2Machine mould.......................................................................................................51&nbsp;</p><p>4.
  • 1.3Machine pistons......................................................................................................51&nbsp;</p><p>4.
  • 1.4Lower compression plate........................................................................................51&nbsp;</p><p>4.
  • 1.5Machine stand (support).........................................................................................51</p><p>&nbsp;
  • 4.2Effect of Particle Size and Binder Ratio on Sorghum-Stalk Briquette Quality Parameters. ........................52&nbsp;</p><p>4.
  • 2.1Compressed density of sorghum-stalk briquette.....................................................52&nbsp;</p><p>4.
  • 2.2Relaxed density of sorghum-stalk briquette ...........................................................55&nbsp;</p><p>4.
  • 2.3Relaxation ratio of sorghum-stalk briquette ...........................................................59&nbsp;</p><p>4.
  • 2.4Shattered index of sorghum-stalk briquette............................................................61&nbsp;</p><p>4.
  • 2.5High calorific value of sorghum-stalk briquette.....................................................63&nbsp;</p><p>4.
  • 2.6Ash content of sorghum-stalk briquette..................................................................66&nbsp;</p><p>4.
  • 2.7Volatile matter of sorghum-stalk briquette.............................................................68&nbsp;</p><p>4.
  • 2.8Fixed carbon of sorghum-stalk briquette................................................................71&nbsp;</p><p>4.
  • 2.9Thermal fuel efficiency of sorghum-stalk briquette ...............................................74&nbsp;</p><p>
  • 4.3Effect of Particle Size and Binder Ratio on Millet-Briquette Quality Parameters. .......75&nbsp;</p><p>4.
  • 3.1Compressed density of millet-stalk briquette .........................................................75&nbsp;</p><p>4.
  • 3.2Relaxed density of millet-stalk briquette................................................................77&nbsp;</p><p>4.
  • 3.3Relaxation ratio of millet-stalk briquette................................................................79&nbsp;</p><p>4.
  • 3.4Shattered index of millet-stalk briquette ................................................................81&nbsp;</p><p>4.
  • 3.5High calorific value of millet-stalk briquette .........................................................83&nbsp;</p><p>4.
  • 3.6Ash content of millet-stalk briquette ......................................................................85&nbsp;</p><p>4.
  • 3.7Volatile matter of millet-stalk briquette .................................................................88&nbsp;</p><p>4.
  • 3.8Fixed carbon of millet-stalk briquette ....................................................................91&nbsp;</p><p>4.
  • 3.9Thermal fuel efficiency of millet stalk briquette ....................................................93&nbsp;</p><p>
  • 4.4Machine Output Capacity ...................................................................................................94&nbsp;</p><p>4.
  • 4.1Mass of Ejected Briquettes.....................................................................................94&nbsp;</p><p>4.
  • 4.2Briquette Production time.......................................................................................96&nbsp;</p><p>4.
  • 4.3Output Capacity of the Machine.............................................................................96&nbsp;</p><p>
  • 5.0CONCLUSION AND RECOMMENDATION .................................................................98&nbsp;</p><p>
  • 5.1Conclusion.............................................................................................................................98&nbsp;</p><p>
  • 5.2Recommendations.................................................................................................................99</p><p>&nbsp;REFERENCE...............................................................................................................................101&nbsp;</p><p>APPENDICES..............................................................................................................................106 <br></p><p><br></p>

Project Abstract

<p>&nbsp;                  <b>ABSTRACT&nbsp;</b></p><p>In this study, a simple four-mould hydraulic piston press biomass hollow briquette making machine, suitable for household and small-scale production of circular briquettes with a centre hole was developed. The briquetting machine was operated using a 4-tons hydraulic jack. Other members of the machine include the mould, pistons, lower and upper compression plates, jack head and jack seat plates, and the machine stand. The performance evaluation of the machine was carried out using sorghum and millet stalk at moisture content of 8% and 6 % respectively. The biomass material was milled using hammer mill with sieve sizes 7mm (P1), 5mm (P2), and 3mm (P3). Briquettes were produced from mixture of biomass at these three particle sizes P1, P2 and P3 and cassava starch binder at three binder ratios of 20% (B1), 30% (B2) and 40% (B3) by weight of biomass material. Four physical properties namely – compressed density, relaxed density, relaxation ratio, and shattered index of the briquettes; and five thermal properties namely – heat calorific value, ash content, volatile matter, fixed carbon content and thermal efficiency of briquetting materials were determined. The machine evaluation was based on Complete Randomized Design (CRD). The data obtained was statistically analyzed using Statistical Analysis System (SAS 9.1) software. Biomass particle size was found to be significant at 1% probability level on physical properties forsorghum-stalk briquette except on relaxation ratio, which was significant only at 5% probability level. The physical properties of sorghum-stalk briquettes improved with decrease in particle size. Mean values of 727.67kg/m3 , 222.35kg/m3 , 89.57% and 3.28 were recorded for compressed density, relaxed density, shattered index and relaxation ratio, respectively at sorghum-stalk particle size P1(3mm). Binder ratio B2 was found to have the best effect on the compressed density and relaxed density of sorghum-stalk briquettes while relaxation ratio and shattered index of sorghum-stalk briquettes improved with increase in binder ratio to B3. Particle sizes and binder ratio were found to be significant at 1% probability level on the thermal properties of sorghum-stalk briquettes, with optimum mean values of 17.726 MJ/kg, 1.6%, 24.60 % and 24.66% for calorific value, ash content, volatile matter and thermal efficiency respectively at P3. The thermal properties of sorghum-stalk briquette and Millet-stalk briquette were found to improve with decrease in binder ratio. However, starch binder was found to have no significant difference on the physical properties of millet-stalk briquettes. The physical properties of millet-stalk briquettes increased with decrease in particle size. Mean values of 814.41kg/m3 , 225.34kg/m3 and 99.49% was obtained for compressed density, relaxed density and shattered index, respectively for millet-stalk briquette at particle size P1(3mm). While particle size has no significant difference on the relaxation ratio of millet-stalk briquettes. On the other hand, particle size P2 gave optimum mean thermal property values of 16.692 MJ/kg, 2.9%, 26.20 % and 28.15% for calorific value, ash content, volatile matter and thermal fuel efficiency respectively. Generally, the constructed briquetting machine is capable of producing quality briquettes from sorghum and millet stalk biomass at particle sizes 3mm (P3) and 5mm (P2) respectively. The developed prototype briquetting machine has a production capacity range of 4.64 kg/hr – 5.26 kg/hr depending on the material used in producing the briquette. <br></p>

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