Design and fabrication of mini cupola furnace and an atomizer for the production of powdered metal from waste aluminium cans

 

Table Of Contents


  • <p> </p><p>Cover Page<br>Title Page i<br>Certification ii<br>Dedication iii<br>Acknowledgements iv<br>Abstract v<br>Table of Contents vi<br>List of Tables xi<br>List of Figures xii<br>List of Plates xiii</p><p><strong>

Chapter ONE

INTRODUCTION

  • </strong></p><p>
  • 1.1Background of Study 1<br>
  • 1.2Aims and Objectives of the Study 3<br>
  • 1.3Problem Statement 4<br>
  • 1.4Scope of Research Project 5<br>
  • 1.5Relevance of Study 5<br>
  • 1.6Limitation of Study 5</p><p><strong>

Chapter TWO

LITERATURE REVIEW

  • </strong></p><p>
  • 2.1Introduction to Aluminium and Aluminium Recycling 7<br>
  • 2.2Introduction to Powder Metallurgy 8<br>2.2.1Historical Development 8<br>2.
  • 2.2Atomization Process 9<br>2.
  • 2.3Classification of Atomization process 10<br>2.
  • 2.4Uses of Powder Metals 10<br>2.
  • 2.5Some Common Metal Powder 11<br>
  • 2.3Introduction to Atomizer 12<br>2.
  • 3.1Classification of Atomizers 13<br>2.
  • 3.2Atomizer Requirement 14<br>
  • 2.4Introduction to Furnace 15<br>2.
  • 4.1Types of Furnaces 15<br>2.
  • 4.2Classification of Furnaces 16<br>2.
  • 4.3Introduction to Copula 17<br>2.
  • 4.4Parts of a Cupola Furnace 17<br>2.
  • 4.5Zones of Copula 19<br>2.
  • 4.6Cupola Operations 22<br>2.
  • 4.7Efficiency of Cupola Furnace 26<br>2.
  • 4.8Advantages and Limitations 27<br>2.
  • 4.9Limitations in Cupola Furnace 28<br>
  • 2.5Introduction to Refractory 28<br>2.
  • 5.1Refractory Definition 28<br>2.
  • 5.2Classification of Refractory 29<br>2.
  • 5.3Properties of Refractory 32<br>2.
  • 5.4Types of Refractory 36<br>2.
  • 5.5Selection of Refractory 39<br>2.
  • 5.6Manufacture of Refractory 39<br>2.
  • 5.7Functions and uses of Refractory 41<br>2.
  • 5.8Uses of Refractories 41<br>
  • 2.6Introduction to Coal 42<br>2.
  • 6.1Uses of Coal 43<br>2.
  • 6.2Refined Coal(Coke) 43<br>2.
  • 6.3Production of Coke 44<br>2.
  • 6.4Properties of Coke 44<br>2.
  • 6.5Uses of Coke 45<br>2.
  • 6.6Advantages of Coal over other Forms of Energy 45</p><p><strong>

Chapter THREE

RESEARCH METHODOLOGY

  • MATERIALS AND METHODOLOGY</strong></p><p>
  • 3.1Introduction 46<br>
  • 3.2The Design of Cupola Furnace 47<br>3.
  • 2.1Material Balance 47<br>3.
  • 2.2Reaction Mechanism 48<br>3.
  • 2.3Energy Balance 49<br>3.
  • 2.4Enthalpy Change 50<br>3.
  • 2.5Standard Heat of Reaction 51<br>
  • 3.3Energy Balance for the Furnace 52<br>3.
  • 3.1Combustion Chamber 52<br>3.
  • 3.2Enthalpy of the Reaction 53<br>3.
  • 3.3Standard Heat of Reaction 53<br>3.
  • 3.4Enthalpy of Flue Gases 54<br>3.
  • 3.5The Design of the Furnace 55<br>3.
  • 3.6Design of the Combustion Chamber 57<br>3.
  • 3.7Design of the down Section of the Furnace 58<br>
  • 3.4Design of an Atomizer 62<br>
  • 3.5Costing and Safety Measures 67<br>3.
  • 5.1Costing 67<br>3.
  • 5.2Safety Measures 69<br>
  • 3.6Materials of Constructions 70</p><p><strong>

Chapter FOUR

DATA PRESENTATION AND ANALYSIS

  • RESULTS, OBSERVATION AND DISCUSSION</strong></p><p>
  • 4.1Results 79<br>
  • 4.2Observations and Discussion 80<br>
  • 4.3The Size of the Metal Powder produced 81<br>
  • 4.4The Shape of Aluminum metal powder produced 81</p><p><strong>

Chapter FIVE

SUMMARY, CONCLUSION AND RECOMMENDATIONS

  • AND RECOMMENDATIONS</strong></p><p>
  • 5.1Conclusion 83<br>
  • 5.2Recommendations 83<br>REFERENCES 85<br>APPENDIX A 88<br>APPENDIX B 94<br>APPENDIX C 97</p><p><strong>LIST OF TABLES</strong><br>Table
  • 2.1Melting point Chart of pure Compounds 33<br>Table
  • 2.3Classes of Fire Clay Brick 38<br>Table
  • 3.1Material Balance Table 49<br>Table
  • 3.2Specification Sheet for the Designed Atomizer 67<br>Table
  • 3.3Cost of Materials 68<br>Table
  • 3.4Fabrication cost 68<br>Table
  • 3.5Additional Expenses 69<br>Table
  • 4.1Results from the Cupola Furnace 79</p><p><strong>LIST OF FIGURES</strong><br>Figure
  • 2.1Broad Classification of Furnace 19<br>Figure2.2 Copula Furnace 21<br>Figure
  • 3.1The Combustion Chamber (Materials) 48<br>Figure
  • 3.2Balance Around the combustion Chamber 52<br>Figure
  • 3.3Balance around the Furnace 55<br>Figure
  • 3.4Internal and External diameters 58<br>Figure
  • 3.52D And 3D views of the cupola Furnace 59<br>Figure
  • 3.63D View of the Cupola Furnace Sections 60<br>Figure
  • 3.7Front View of the Cupola Furnace 61<br>Figure
  • 3.82D Sectioned view of the Lower Section of the Atomizer 63<br>Figure
  • 3.92D Sectioned view of the Middle Section of the Atomizer 64<br>Figure
  • 3.102D View of the Lower Section of the Atomizer 65<br>Figure
  • 3.113-D Section view of the Atomizer 66</p><p><strong>LIST OF PLATES</strong><br>PLATE 1 ALIEN KEY<br>PLATE 2 VERNIER CALIPER<br>PLATE 3 HAND FILES<br>PLATE 4 TAP WRENCH<br>PLATE 5 TWO WAY GRINDING MACHINE<br>PLATE 6 LATHE MACHINE<br>PLATE 7 DRILL BIT</p> <br><p></p>

Project Abstract

<p> This research is centered on the design and fabrication of cupola furnace and atomizer for the production aluminium powder metal with the available material.0.4kg of refined coke was chosen as the basis for material and energy balance calculations and the design calculations performed from whose values are used to produce the design drawings. Mild steel was used for the internal linings of the furnace casing while other material were selected based on functionality ,durability ,cost and local availability. The furnace and atomizer were assembled and the furnace inner wall of the casing was lined with refractory bricks made from heated mixture of kaolin, clay, sawdust and water after which the cylindrical shell was positioned .Testing was subsequently performed to evaluate the performance of the furnace and the atomizer by first gathering of the aluminium cans .The furnace was heated to 8700c and it was observe that the furnace has 36.9% efficiency which is within the acceptable value for furnace efficiencies. Atomizer produced various sizes of powder metal depending on the type of mesh used and the shape obtained was irregular in shape. <br></p>

Project Overview

<p> </p><p><strong>INTRODUCTION</strong></p><p><strong>Background of Study</strong></p><p>Powder metallurgy is a technique concerned with the production of metal powders and converting them into useful shapes. It is a material processing technique in which particulate materials are consolidated to semi-finished and finished products. Metal powder production techniques are used to manufacture a wide spectrum of Metal powders designed to meet the requirements of a large variety of applications. Various powder production processes allow precise control of the chemical and physical characteristics of powders and permit the development of specific attributes for the desired applications. Powder production processes are constantly being improved to meet the quality, cost and performance requirements of all types of applications. Metal powders are produced by mechanical or chemical methods.</p><p>The most commonly used methods include water and gas atomization, milling, mechanical alloying, electrolysis, and chemical reduction of oxides.</p><p>The type of powder production process applied depends on the required production rate, the desired powder properties and the properties desired in the final part. Chemical and electrolytic methods are used to produce high purity powders while Mechanical milling is widely used for the production of hard metals and oxides. Atomization is the most versatile method for producing metal powders.</p><p>It is the dominant method for producing metal and pre-alloyed powders from aluminium, brass, iron, low alloy steel, stainless steel, tool steel, super alloy, titanium alloy and other alloys.</p><p>Atomization [Mehrotra 1984] is a process in which a liquid stream disintegrated into a large number of droplets of various sizes. Basically atomization consists of mechanically disintegrating a stream of molten metal into the fine particles by means of a jet of compressed gases or liquids. It is an important process which finds wide applications such diverse field as spraying for insecticidal use, fuel injection in internal combustion engines, liquid spray drying, and liquid dispersion in numerous liquid–gas contact operations such as distillation, humidification, and spray crystallization.</p><p>The technique of atomizing a metal melt, with fluid was connected with the production of metal powders. The basic principle involved in atomization of liquid consists in increasing the surface area of the liquid stream until it becomes unstable disintegrated. The energy required for disintegration can be imparted in several ways depending on the mode in which the energy is supplied. The atomization process [Mehrotra 1984] can be classified into three main categories:</p><p>Pressure atomization.</p><ol><li>Mechanical</li><li>Chemical or centrifugal atomization.</li><li>Fluid atomization.</li></ol><p>The present work concentrated on the third type of atomization. The kinetic energy of a second fluid stream, being ejected from a nozzle is used for disintegrating of the liquid. The stream in a free fall is impacted by a high pressure jet of second fluid which is usually gas or water emerges either tangentially or at angle from nozzle. So that molten which in general, have high surface tension can be atomized by the fluid atomization technique.</p><p><strong>1.2 &nbsp; Aim and Objectives of the Study</strong></p><p><strong>1.2.1 &nbsp; Aim of Study</strong></p><p>The aim of this study is to design and fabrication a mini cupola furnace and an atomizer for the production of powdered metal from waste aluminium cans.</p><p><strong>1.2.2 &nbsp; Objectives of Study</strong></p><p>The objectives of the study include the following</p><ol><li>Determination of the volume of a single aluminium can using a weighing balance.</li><li>Carrying out a material and energy balance to determine the mass aluminium to be melted, amount of fuel required and the required capacity of the furnace.</li><li>Carrying out mechanical design of the mini-cupola furnace required to melt the waste aluminium can,</li><li>Fabrication of the proposed designed mini-cupola furnace plant.</li><li>Design of the atomizer for metal powder production.</li><li>Fabrication of the designed atomizer</li><li>Analysis of the obtained aluminium powder metal.</li></ol><p><strong>1.3 &nbsp; Problem Statement</strong></p><p>Wide-spread application and high demand of powder metal in industrial and domestic processing activities and the littering- rate of aluminium cans all over the country which poses a serious adverse environmental condition, have grown at an alarming rate over the years. Therefore, the purpose of this project is to design and fabricate a mini-copula furnace and an atomizer for the production of powder metal from waste aluminium cans which can be used for various domestic and industrial applications and also serves as a good environmental pollution control for the aforementioned waste.</p><p><strong>1.4 &nbsp; Scope of the Research Project</strong></p><p>This research project focuses on the design and fabrication of a mini-copula furnace and an atomizer for the production of powder metal from waste aluminium cans through process atomization.</p><p><strong>1.5 &nbsp; &nbsp; Relevance of the Study</strong></p><p>The importance of this study includes the following:</p><ol><li>To reduce the rate of environmental pollution (air, soil and water pollution) caused by littering waste aluminium cans.</li><li>Meet up with the ever-growing demand for powder aluminium metal in the automobile industry</li></ol><ul><li>To save energy and raw materials for the future industries.</li></ul><ol><li>To provide raw material for metal matrix composites and wide applications in paint industries.</li><li>To encourage researchers think of ways of harnessing other waste materials.</li><li>To increase the availability of solid fuels for rockets.</li></ol><ul><li>It also serves as a reference material to any researcher on this field.</li></ul><p><strong>1.6</strong>&nbsp; &nbsp;<strong>Limitation of the Study</strong></p><p>The factors hindering effective execution of this study are:</p><ol><li>Inadequate power supply for the operation of the fabricating machines.</li><li>Inadequate fund</li></ol><ul><li>Time limit towards successful completion of the project</li></ul><ol><li>Use of readily available air as the atomizing fluid instead of costly pure nitrogen.</li></ol> <br><p></p>

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