Design of forced convection heat transfer rig
Table Of Contents
<p> </p><p>Cover Page<br>Title page<br>Certification page<br>Dedication<br>Acknowledgement<br>Abstract<br>List of figures<br>List of Tables<br>List of graph<br><strong>
Chapter ONE
</strong><br>1.0 Introduction<br>1.1 Modes of heat Transfer<br>1.2 Aims and Objectives<br>1.3 Application and uses<br><strong>Chapter TWO
</strong><br><strong>LITERATURE REVIEW</strong><br>2.0 Previous works on forced convection studies<br>2.1 Purposes of the study<br>2.2 Basic laws Governing Heat Transfers<br>2.3 Heat Transfer by Convection<br>2.4 Determination of Coefficient of Heat Transfer by convection<br><strong>Chapter THREE
</strong><br>3.0 Analysis of Design<br>3.1 Description of Design<br>3.1.1 Methodology<br>3.2. Steps Considered for the Designing of forced convective heat transfer rig<br><strong>Chapter FOUR
</strong><br>4.0 Experimental procedure<br>4.1 Material Methods<br>4.1.1 Consideration for Material Selection<br>4.1.2 Selecting materials for the test rig<br>4.2 Forced convection Data and Calculations<br><strong>Chapter FIVE
</strong><br>5.0 Analysis Of Result<br>5.1 Fourier’s Laws of heat Conduction<br>5.2 Thermal Conductivity of Material<br>5.3 Determination of Quality of Heat Entering the Hot Pipe<br>5.4 Determination of Temperature<br><strong>CHAPTER SIX</strong><br>6.0 Observation<br>6.1 Suggestion for improvement<br>6.2 Challenges Encountered<br>6.3 Recommendation<br><strong>CHAPTER SEVEN</strong><br>7.0 Conclusion</p><p><strong>Reference</strong></p><p>List of Figure Pages<br>Figure 1<br>Figure 2<br>Figure 3<br>Figure 4<br>Figure 5</p><p>List of table pages<br>Table 1<br>Table 2<br>Table 3<br>Table 4</p><p>List of graphs pages<br>Graph 1<br>Graph 2</p> <br><p></p>Thesis Abstract
<p> </p><p>This project report contains experimental illustration of forced convective heat transfer rig, which consist of a tube, through which air is sent in by a blower. The test section consists of a long electrical surface heater on the tube which serves as a constant heat flux source on the flowing medium. The inlet and outlet temperature of the flowing medium are measured by thermocouple and also the temperature at several locations along the surface heater from which an average temperature can be obtained. An orifice meter is used to measure the airflow rate with a ‘U’ tube water manometer. An ammeter and voltmeter are provided to measure the power input to the heater. A power regulator is provided to vary the power input to heater. A valve is provided to regulate the flow rate of air. The air being generated by the blower is being passed through a hose connected to a mild steel pipe. The total heat input rate to the air is calculated using = MCPΔt</p><p>Where;</p><p>M = Mass flow rate</p><p>Cp = Specific heat</p><p>Δt = Temperature change of the air across the heating section</p><p>Hence, the forced convection heat transfer coefficient is obtained using qt = h.AΔT</p><p>Where;</p><p>ΔT = log mean temperature across the heating section</p><p>The result of the convective heat transfer of h = 0.05 W/m2k was obtained</p> <br><p></p>Thesis Overview
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