Performance of microwave activated adsorption cycle theory and experiments

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Performance of microwave activated adsorption cycle theory and experiments

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PERFORMANCE OF MICROWAVE-ACTIVATED ADSORPTION CYCLE : THEORY AND EXPERIMENTS M KUM JA NATIONAL UNIVERSITY OF SINGAPORE 2010 PERFORMANCE OF MICROWAVE-ACTIVATED ADSORPTION CYCLE : THEORY AND EXPERIMENTS M KUM JA (B.Eng, M.Eng) A THESIS SUBMITTED FOR THE DEGREE OF DOCTOR OF PHILOSOPHY DEPARTMENT OF MECHANICAL ENGINEERING NATIONAL UNIVERSITY OF SINGAPORE 2010 Acknowledgements First of all, I would like to praise The LORD, my shepherd, for HE took me from the end of the earth and bless me indeed so that I shall not be in want. I am deeply grateful to my supervisors, Associate Professor Christopher Yap and Professor Ng Kim Choon, for nurturing a very vibrant research environment and for giving me the guidance, insight, encouragement, and independence to pursue a challenging project. I also express my heartfelt gratitude to all my colleges and lab officers of our research group for their kind assistance and insightful suggestions which are greatly helpful for me to advance my research. Last but not least, I wish to express my deepest gratitude to my parents and my family for their unfailing love, unconditional sacrifice, and complete moral support which are far more than I could ever hope for. -i- Table of Contents Acknowledgements i Table of Contents ii Summary vi List of Tables viii List of Figures ix Nomenclature xiii Chapter - Chapter - Introduction 1.1. Factors in Microwave-Activated Desorption 1.2. Objectives of the Present Study 1.3. Scope of the Present Study 1.4. Organization of the Thesis Literature Review 2.1. Introduction 2.2. Adsorption Process 2.2.1. Adsorbent-adsorbate working pair for adsorption cooling system 2.2.2. Enhancement of the adsorption chiller performance 12 16 2.3. Modelling of Microwave-Activated Adsorption Cooling System 17 2.3.1. Microwave frequency ranges 17 2.3.2. Material properties interacting with electromagnetic wave 18 2.3.3. Measuring method for complex permittivity 20 2.3.4. Effect of microwave irradiation on desorption 25 2.3.5. The influence of workload geometry 28 2.3.6. Modelling and simulation of microwave application 29 2.3.7. Improvement of simulation model for adsorption cooling system Chapter - 31 2.4. Microwave Radiation Safety and Health 33 2.5. Cost Effectiveness of Using Microwave irradiation 35 Microwave Activated Adsorption Thermodynamics 38 3.1. Introduction 38 3.2. Frame Work for Mass and Energy Balance - ii - 39 Chapter - 2.2.1. Mass balance equation 39 3.2.2. Momentum balance equation 41 3.2.3. Energy balance equation 42 3.3. Mass Transport of Sorption Process 43 3.4. Theoretical Aspects of Microwave Application in Adsorption 49 3.5. Conclusion 56 Experimental Analysis on Microwave Irradiation Process 59 4.1. Introduction 59 4.2. Measurement of the Complex Permittivity 60 4.2.1. Experiment of measuring complex permittivity 62 4.2.2. Results and discussions 64 4.3. Experimental Analysis of Desorption Process under Microwave Irradiation 70 4.3.1. Experimental apparatus 71 4.3.2. Results and discussion 75 4.4. Analysis of Thermal Physical Properties under Microwave Irradiation 77 4.4.1. Experimental set up 78 4.4.2. Results and discussion 78 4.5. The Experimental Evaluation for Empirical Relation 81 4.5.1. Experimental set up 81 4.5.2. Results and discussion 81 4.6. The Effect of Conducting Metal on the Microwave Energy Chapter - Absorption 85 4.6.1. Experimental set up 85 4.6.2. Electric field intensity and power dissipation 87 4.6.3. Simulation and experimental results 91 4.6.4. Conclusion and discussion 99 Numerical Simulation and Design Analysis for a Microwave-Activated Adsorption Chiller System 101 5.1. Introduction 101 5.2. Frame Work for the Electromagnetic Wave Propagation 102 5.3. Microwave-Activated Application Design 105 5.3.1. Microwave Generator - iii - 105 5.3.2. The rectangular wave guide 106 5.3.2.1. Electromagnetic wave’s distribution mode in wave guide 107 5.3.2.2. Frequency of electromagnetic wave in wave guide 111 5.3.2.3. Optimized coupling method 5.3.3. Multimode resonant cavity 5.4. Simulation of Resonant Cavity with HFSS® Software 113 115 117 5.5. Modeling and Simulation of Microwave-Activated Adsorption Cooling System 122 5.5.1. Non uniform temperature distribution model 124 5.5.2. Effective thermal conductivity 125 5.5.3. Heat transfer resistance between fluid and adsorbent 128 5.5.4. Mathematical model for fluid inside the tube 130 5.5.5. Energy balance equation of bed sub control volume 132 5.5.6. Adsorption and desorption equation 135 5.5.6.1. Adsorption and desorption due to the thermal driven source 135 5.5.6.2. Desorption process under the microwave irradiation Chapter - 136 5.5.7. Energy balance equations for evaporator 137 5.5.8. Energy balance equation for condenser 138 5.5.9. Simulation procedure 139 5.6. Results and discussion 143 Conclusions and Recommendations 151 6.1. Conclusions 151 6.2. Recommendations 153 References 155 Appendices Appendix A A.1. SEM photos of various adsorbents 167 A.2. Isotherm equilibrium expression for Maxsorb III Activated Carbon and n-Butane working pair Appendix B 168 B.1. Thermodynamics framework for energy and mass conservation - iv - 179 B.2. Categorize the adsorption operation mode Appendix C Based on the adsorbate concentration 183 B.3. Mass transport equation of sorption process 184 B.4. Derivation of microwave energy flux 187 C.1. Certificate and calibration of infrared temperature sensor 192 C.2. Comparative analysis between the models to evaluate the kinetic uptake. 194 C.3. Surface current’s distribution on the metal surface and photo of experimental set up. Appendix D D.1. Fundamental terms and equations of electricity and magnetism Appendix E 200 201 D.2. Mat lab program code for analytical solution 202 List of Publications 206 -v- Summary Desorption process consumes the most energy is an adsorption cycle. Reduction in energy consumption during this process can be achieved by enhancing the adsorption system’s performance. Conventionally, energy required for desorption is thermally transferred by the temperature gradient between the energy source and adsorbed system. Unfortunately, common adsorbents have high thermal resistances which affect performance of adsorption system. This study proposed a novel energy transport method transferred by electromagnetic activation rather than the conventional thermal activation. In order to achieve in-depth understanding of this electromagnetically transporting method, a theoretical framework for mass and energy transport was studied with microscopic control volume approach. A universal mass transport equation was derived from the Reynolds transport theorem and momentum equations. Model equations for various types of adsorption operations (constant adsorbate concentration or dynamic adsorbate concentration) can be derived by using this general mass transport equation. For the development of energy transport equation, potential energy flux term (ΣJk.Fk) and microwave energy conversion ratio (φ) terms was integrated to the conventional energy balance equation to distinguish the microwave-activated desorption and conventional microwave heating. Extensive experimentations were carried out to understand microwave-activated desorption and microwave irradiation. Interaction of materials with microwave irradiation is normally characterised by the permittivity property of the materials. - vi - Permittivity of the type RD silica gel adsorbent is measured using the Open Co-Axial Probe method. These measurements are vital in simulating the microwave activation process. The experiment of microwave-activated desorption was also carried out by using two different dielectric material adsorbents (FAM-Z01 zeolite and type RD silica gel) to study the difference between thermal and electromagnetic activations. Experimental analysis validated that the activation energy, ∆Ea, of desorption (physical reaction) due to microwave activation is lower than thermal activation. Conventional kinetic desorption could not be applied in microwave-activated desorption simulation because this kinetic is related to ∆Ea which changes under microwave irradiation. For this reason, the empirical relation between electric field intensity and the rate of temperature increase as well as desorption rate were empirically obtained. In order to analyze the effect of conducting metal embedded inside the adsorbent for design of microwave-activated adsorbent bed, numerical and experimental studies were carried out. Based on this analysis result, a parallel fin-tube adsorbent bed was proposed for the microwave-activated adsorption chillers system. Finally, numerical analysis for microwave system was carried out by using Maxwell’s wave propagation equation. Based on the simulation input parameters and empirical equations, non-uniform (lump distributed) model of microwave-activated adsorption chillers system was developed. - vii - List of Tables Table 2.1. Related isotherm equations and their parameters for some selected working pairs. Table 3.1. Brief description of mass transport processes in adsorption application. Table 3.2. Examples of microwave energy contribution in desorption processes. Table A.1. The experimental data of adsorption equilibrium isotherm temperature and its pressure. Table A.2. The residual errors of the comparative analysis between Langmuir and D-R equation. Table B.2. Categorize the adsorption operation mode based on the adsorbate concentration. Table C.1. The lists of errors of the comparative analysis among the linear and non linear model of First order and Second order reaction equations. Table D.1. Fundamental terms and equations of electricity and magnetism. - viii - dissipated energy at the control volume due to microwave irradiation can be observed as; Pavg = 2πfε oε ′′E V (B.58) where f denotes the frequency of electromagnetic wave, and V represent the volume of the system. - 191 - APPENDIX - C C.1. Certificate and calibration of infrared temperature sensor 45.0 RTD 4WR INFRA RED TEMPERATURE SENSOR 44.0 MASTER THERMOMETER TEMPERATURE ( C ) 43.0 42.0 41.0 40.0 39.0 38.0 37.0 36.0 35.0 100 200 300 TIME ( Second ) 400 500 600 Figure C.1. Calibration of infrared temperature sensor with 4WRTD and Master thermometer. - 192 - Figure C.2. Calibration certificate of Raytek GmbH Infrared temperature sensor. - 193 - C.2. Comparative analysis between the models to evaluate the kinetic uptake. The objective of this study is to determine the best kinetic uptake model for Type RD Silica gel-Water working pair. In order to reach this achievement, comparative analysis is carried out among the linear and non linear regression models derived from the pseudo first order and second order reaction equations. C.2.1. Determine mass transfer coefficient from First order reaction equation First order reaction equation also known as linear drive force model is widely used in adsorption process because of its simplicity. The equation is as follows; dq = k s a (q * −q) dt (C.1) C.2.1.1. Linear model of First order reaction equation Mass transfer coefficient can be determined from the linear model equations which are developed by integrating the First order reaction equation (Equation C.1). The derivation is stated as follows; - ln ( q*-q ) = ksa t + Constant (C.2) If the initial condition of uptake q is zero at time t is zero, then the constant is as follows; Constant = - ln ( q* ) (C.3) The linear model equation of the first order reaction equation for calculation of mass transfer coefficient can be described as follows; ln ( q* - q ) = ln q* - ksa t - 194 - (C.4) (Or) Log ( q* -q ) = Log q* - ksa t / 2.303 (C.5) C.2.1.2. Non-linear model of First order reaction equation Mass transfer coefficient (ksa) can be calculated from the non-linear model equations which are derived from the First order reaction equation (Equation C.1) by using Laplace Transform method, and derivation is stated as follows; dq = k s a (q * −q) dt (C.6) F (s) ( S – ksa ) = ksa q* / S (C.7) F (s) =ksa q* / { S( S - ksa )} (C.8) 1 = {1 − exp(− at )} S ( S + a) a q (t) = q* { 1-exp( -ksa t )} (C.9) (C.10) C.2.2. Determine mass transfer coefficient from Second order reaction equation Second order reaction equation also known as Pseudo-second order equation has the ability that it can predict the isotherm equilibrium with lesser error than the other method. The equation is as follows; dq = k s a (q * −q) dt (C.11) C.2.2.1. Linear model of Second order reaction equation Mass transfer coefficient can be determined from the linear model equations which are developed by integrating the Second order reaction equation (Equation C.11). The derivation can be stated as follows; - 195 - ( Type V. Blanachchard et al. 1984 ) 1 = ks a t + q * −q q* 1= ( Type I . Ho et al,. 1995 ) q * −q + k s a t (q * −q) q* (C.12) (C.13) q = k s a q * t − k s a qt q* (C.14) t t = + q k s a (q*) q* (C.15) From equation ( C.15 ); 1  + t  q* (Type II K.Vasanth Kumar et al,. 2006) 1 = q k sa (q*) (Type III K.Vasanth Kumar et al,. 2006) k sa (q*) k sa (q*) = − t q q* (C.17) (Type IV. K.Vasanth Kumar et al,. 2006) k sa (q*) q = k sa (q*) − q t q* (C.18) (C.16) K.Vasanth Kumar et al., (2006) carried out the comparative analysis among these five types of linear models derived from Second order reaction equation. The result shows that Type I Ho model (Equation C.15) is able to predict mass transfer coefficient (ksa)with the least error among these models. Therefore, Ho Type model is selected in this study of comparative analysis from these five linear models. C.2.2.2. Non-linear model of Second order reaction equation Mass transfer coefficient (ksa) can be determined by using the non-linear model equations which are derived from the Second order reaction equation (Equation C.14). Then, the Equation C.14 becomes as follows; - 196 - q = k sa q *2 t − k sa q * qt (C.19) ( Ho Non-linear model 1995 ) q= (q*) k sa t qk sa t + (C.20) ( Ritche , 1977, Sobkowsk, 1974 ) q= q * k sa t k sa t + (C.21) C.2.3. Results and Discussion The kinetic uptake data of Type RD silica gel-water working pair yields from the experiment conducted by using Thermal Gravimetric Analyzer (Cahn-2121TGA) method. The systems comprise the following: (i) the pressure control or regulator unit, (ii) the cooling system for the furnace, (iii) the positive displacement vacuum-pump, (iv) the vapour generator, and (v) the pressure and temperature measuring and data acquisition system. The adsorbate (water vapour) is produced by heating a stainless steel vessel containing a pool of water in a tightly sealed chamber. The vapour is delivered to the measuring reaction chamber or tubing via an electric-heater lined flexible s.s. tubing and considerable steps are taken to ensure the tube wall temperature is always maintained above that of the saturation temperature. The experiment results are shown in Figure C.3, C.4, C.5. UPTAKE RATE & PSEUDO SECON ORDER AT 31 C 0.09 4.0E+04 0.08 3.5E+04 0.07 3.0E+04 Q ( kg / kg ) 2.5E+04 0.05 2.0E+04 0.04 1.5E+04 t/Q ( Sec /kg /kg ) 0.06 0.03 y = 11.043x + 2081 R2 = 0.9987 0.02 1.0E+04 5.0E+03 0.01 0.00 0.0 500.0 1000.0 1500.0 2000.0 2500.0 0.0E+00 3000.0 TIME ( Sec ) Figure C.3. Profile of kinetic uptake rate and its linear form at 304.16 K . - 197 - UPTAKE RATE & PSEUDO SECON ORDER AT 37 C 7.0E+04 0.08 0.07 6.0E+04 0.06 Q ( kg / kg ) 0.05 4.0E+04 0.04 3.0E+04 t/Q ( Sec /kg /kg ) 5.0E+04 0.03 2.0E+04 0.02 y = 11.043x + 2081 R2 = 0.9987 1.0E+04 0.01 0.00 0.0 500.0 1000.0 1500.0 2000.0 2500.0 3000.0 3500.0 0.0E+00 4500.0 4000.0 TIME ( Sec ) Figure C.4. Profile of kinetic uptake rate and its linear form at 310.099 K. UPTAKE MASS & PSEUDO SECON ORDER AT 42 C 6.0E+04 0.05 5.0E+04 Q ( kg/kg ) 4.0E+04 0.03 3.0E+04 0.02 t/Q ( Sec / kg / kg ) 0.04 2.0E+04 y = 18.764x + 3281.6 R = 0.9987 0.01 1.0E+04 0.00 0.0E+00 0.0 500.0 1000.0 1500.0 2000.0 2500.0 3000.0 Time ( Sec ) Figure C.5. Profile of kinetic uptake rate and its linear form at 315.1815 K. 70000.0 31 C SEUDO SECOND ORDER 37 C PSEUDO SECOND ORDER 42 C PSEUDO SECON ORDER Linear (31 C SEUDO SECOND ORDER ) Linear (37 C PSEUDO SECOND ORDER ) Linear (42 C PSEUDO SECON ORDER) 60000.0 t/Q ( Sec / kg / kg ) 50000.0 40000.0 30000.0 y = 18.764x + 3281.6 R = 0.9987 y = 12.965x + 2905.2 R = 0.9973 20000.0 y = 10.845x + 2452.2 R = 0.9989 10000.0 0.0 0.0 500.0 1000.0 1500.0 2000.0 2500.0 3000.0 3500.0 4000.0 4500.0 TIME ( Sec ) Figure C.6. The linear relation between t and t/q for Ho linear model. - 198 - Table C.1 shows the list of error of the comparative analysis which is carried out among the linear and non linear model derived from First order and Second order reaction equations. Table C.1. The lists of errors of the comparative analysis among the linear and non linear model of First order and Second order reaction equations. Equation (C.4) Equation (C.10) Equation (C.15) Equation (C.20) Linear Non Linear Linear Non Linear dq/dt = ksa ( q*-q )2 dq/dt = ksa ( q*-q ) 304.96 K 310.09 K 315.18 K R2 * 0.8342 0.6458 0.7405 Ksa Sec-1 0.0004 0.0003 0.0005 R2 * 0.9681 0.9762 0.9801 Ksa Sec-1 0.0038 0.0027 0.0036 R2 * 0.9991 0.9982 0.9987 Ksa Sec-1 0.0451 0.0635 0.0783 R2 * 0.9923 0.9854 0.9923 Ksa Sec-1 0.0587 0.0043 0.0057 This comparative analysis clearly shows that Ho Linear model from Second order reaction equation can perform to achieve the best fit with the experiment result. This finding of the best fit with Ho model for Type Rd Silica gel-water working pair agrees with the result of Activated Carbon-Hydrocarbon fluid working pair conducted by K.Vasanth Kumar et al., (2006). - 199 - C.3. Surface current’s distribution on the metal surface and photo of experimental set up. Metal surface Surface Current Electric Field Figure C.7. The pattern of current flowing on the surface due to electric field intensity vector. Figure C.8. Experimental set-up for the analysis of microwave-activated desorption process. - 200 - APPENDIX – D D.1. Fundamental terms and equations of electricity and magnetism Electricity Magnetism 1. Electrostatic force ( F ) is occurred because of 1. Magnetic force ( £ ) is occurred because of moving charge. static charge ( Column’s Law ).     Q1  F1     F2   Q1Q2 F 4 r Q2  £  =  N I Current I or F = Electrostatic force Q = Static Charge ( Columns )  = Magnetic line ( Weba ) r = Distance ( m )  = Absolute Permittivity or Dielectric( F/m) [  =  o r ] o = Free Space or Vacuum Permittivity [ 8.85x10-12 ( F/m ) ] r = Relative Permittivity or Dielectric Constant £ = Magnetic force N = No of wire turns , I = Current [ Unit less ] 2. Electric field intensity ( E ) is defined as the electrostatic 2. Magnetic field intensity ( H ) is defined as the intensity of force magnetic field. exerted on one electron charge and can express with H = B/ vector line.   e e H = Magnetic field intensity ( A/m ) e  = Permeability of material ( H/m) ( Henery/meter ) e e Q  E = F/Q   (  V/m ) e e [  = 0r ] r = Relative permeability of material 0 = Free space or vaccum permeability e [  x 10-7 ( H/m ) ] 3. Electric flux density ( D ) is defined as the density of 3. Magnetic flux density ( B ) is defined as the density of magnetic flux electric field line . line .     = Magnetic line (Weba)  Q+  Q‐  N S A  D  =   E   (  FV/m2 )  A  B = / A , B= H B = Magnetic flux density ( Tesla ) ( Weba/ m2 ) A = cross section area ( m2 ) 4. Current Density ( J ) ( A / m2 ) 5. Conductivity (  ) ( Sieman/meter ) ( S/m ) J = E  = 1/R ( 1/m ) - 201 - D.2. Mat lab program code for analytical solution %__________________________________________________________________ mu_o=4*pi*1e-7; % Permeability of free space eps_o=8.85e-12; % Permittivity of free space %__________________________________________________________________ % Enter the waveguide dimensions and other parameters %__________________________________________________________________ aa=input('Enter the waveguide dimension a in cm (x-axis): '); bb=input('Enter the waveguide dimension b in cm (y-axis): '); cc=input('Enter the length of the waveguide in cm (z-axis): '); a=aa/100; b=bb/100; c=cc/100; %____________________________________________________________________ % Specify the distance at which the field is observed %____________________________________________________________________ plane_y=input('Enter the distance y at which the field is to be observed in the x-z plane (cm): '); plane_z=input('Enter the distance z at which the field is to be observed in the x-y plane (cm): '); plane_yy=plane_y/100; plane_zz=plane_z/100; %____________________________________________________________________ % Enter the mode indices %____________________________________________________________________ disp('Enter the mode indices. Note that the lowest TE mode has indices 1,0'); indexm=input('Enter the mode index "m" of chosen mode : '); indexn=input('Enter the mode index "n" of chosen mode : '); %____________________________________________________________________ % Enter the corresponding frequency %____________________________________________________________________ freq=input('Enter the frequency in GHz (e.g. 2.45): '); %____________________________________________________________________ % Enter the material properties (real part only) %____________________________________________________________________ eps_r=input('Enter the material properties (real part only): '); %__________________________________________________________________ % Mesh generation for field patterns %____________________________________________________________________ [x,y]=meshgrid(0:a/200:a,0:b/200:b); [x,z]=meshgrid(0:a/200:a,0:c/200:c); %____________________________________________________________________ - 202 - % Propagation constants %____________________________________________________________________ kk=(indexm*pi/a)^2+(indexn*pi/b)^2; beta=sqrt(((2e9.*pi.*freq)^2).*mu_o.*eps_o.*eps_r-kk); %____________________________________________________________________ % Fields components %____________________________________________________________________ % Electric fields Ex1=((2e9.*pi.*freq.*mu_o)/kk).*(indexn.*pi/b).* . cos(indexm*pi*x/a).*sin(indexn*pi*y/b).*sin(beta.*plane_zz); Ey1=((-2e9.*pi.*freq.*mu_o)/kk).*(indexm.*pi/a).* . sin(indexm*pi*x/a).*cos(indexn*pi*y/b).*sin(beta.*plane_zz); Ez1=0; Ex11=Ex1.*Ex1; Ey11=Ey1.*Ey1; Ez11=Ez1.*Ez1; EE11=sqrt(Ex11+Ey11+Ez11); Ex2=((2e9.*pi.*freq.*mu_o)/kk).*(indexn.*pi/b).* . cos(indexm*pi*x/a).*sin(indexn*pi*plane_yy/b).*sin(beta.*z); Ey2=((-2e9.*pi.*freq.*mu_o)/kk).*(indexm.*pi/a).* . sin(indexm*pi*x/a).*cos(indexn*pi*plane_yy/b).*sin(beta.*z); Ez2=0; Ex22=Ex2.*Ex2; Ey22=Ey2.*Ey2; Ez22=Ez2.*Ez2; EE22=sqrt(Ex22+Ey22+Ez22); % Magnetic fields Hx1=(beta/kk).*(indexm.*pi/a).* . sin(indexm*pi*x/a).*cos(indexn*pi*y/b).*sin(beta.*plane_zz); Hy1=(beta/kk).*(indexn.*pi/b).* . cos(indexm*pi*x/a).*sin(indexn*pi*y/b).*sin(beta.*plane_zz); Hz1=cos(indexm*pi*x/a).*cos(indexn*pi*y/b).*cos(beta.*plane_zz); Hx11=Hx1.*Hx1; Hy11=Hy1.*Hy1; Hz11=Hz1.*Hz1; HH11=sqrt(Hx11+Hy11+Hz11); Hx2=(beta/kk).*(indexm.*pi/a).* . sin(indexm*pi*x/a).*cos(indexn*pi*plane_yy/b).*sin(beta.*z); Hy2=(beta/kk).*(indexn.*pi/b).* . cos(indexm*pi*x/a).*sin(indexn*pi*plane_yy/b).*sin(beta.*z); Hz2=cos(indexm*pi*x/a).*cos(indexn*pi*plane_yy/b).*cos(beta.*z); Hx22=Hx2.*Hx2; Hy22=Hy2.*Hy2; Hz22=Hz2.*Hz2; HH22=sqrt(Hx22+Hy22+Hz22); % Plots the electric field patterns in x-y plane subplot(2,2,1); mesh(x,y,EE11); figure(gcf); hold on; xlabel('x-axis (m)'); - 203 - ylabel('y-axis (m)'); zlabel('Calculated electric field (V/m)'); figure(gcf); hold on subplot(2,2,2); contour(x,y,EE11); xlabel('x-axis (m)'); ylabel('y-axis (m)'); figure(gcf); % Plots the electric field patterns in x-z plane subplot(2,2,3); mesh(x,z,EE22); figure(gcf); hold on; xlabel('x-axis (m)'); ylabel('z-axis (m)'); zlabel('Calculated electric field (V/m)'); figure(gcf); hold on subplot(2,2,4); contour(x,z,EE22); xlabel('x-axis (m)'); ylabel('z-axis (m)'); figure(gcf); disp(' disp(' disp(' '); '); Press "Enter" to see the magnetic field patterns '); pause clf; hold off; % Plots the magnetic field patterns in x-y plane subplot(2,2,1); mesh(x,y,HH11); figure(gcf); hold on; xlabel('x-axis (m)'); ylabel('y-axis (m)'); zlabel('Calculated magnetic field (A/m)'); figure(gcf); hold on subplot(2,2,2); contour(x,y,HH11); xlabel('x-axis (m)'); ylabel('y-axis (m)'); figure(gcf); % Plots the magnetic field patterns in x-z plane subplot(2,2,3); mesh(x,z,HH22); figure(gcf); hold on; xlabel('x-axis (m)'); ylabel('z-axis (m)'); - 204 - zlabel('Calculated magnetic field (A/m)'); figure(gcf); hold on subplot(2,2,4); contour(x,z,HH22); xlabel('x-axis (m)'); ylabel('z-axis (m)'); figure(gcf); clc; end; - 205 - LIST OF PUBLICATIONS 1. B. B. Saha, A. Chakraborty, S. Koyama, S. H. Yoon, M. Kumja, C. R. Yap and K.C.Ng, Isotherms and thermodynamics for the adsorption of n-butane on Maxsorb III, International Journal of Heat and Mass Transfer, Volume 51, Issues 7-8, April 2008, Pages 1582-1589. 2. Wai Soong Loh, Kum Ja M, Kazi Afzalur Rahman, Kim Choon Ng, B. B. Saha, S. Koyama, Ibrahim I.El-Sharkawy; The adsorption thermodynamics and performance analysis of an idealized adsorption cycle using HFC-134a and activated carbon; Heat Transfer Engineering . 3. M Kumja, Ng Kim Choon, Christopher Yap, H Yanagi , S. Koyama,B. B. Saha, A.Chakarborty. Modeling of a Novel Desorption Cycle Used by Dielectric Heating Method. Modern Physics Letters B, Vol. 23, No.3(2009)425-428. Conferences Papers 1. M Kumja, Ng Kim Choon, Christopher Yap, Ibrahim I.El-Sharkawy,Wan Jinbao, A. Chakraborty, B. B. Saha, S. Koyama; Numerical and experimental investigations on a two-bed mode adsorption chiller; The 22nd IIR International Congress of Refrigeration, August, 2007, ICR07-E2-1063. 2. M Kumja, Ng Kim Choon, Wai Soong Loh, Mark Aaron Chan,Christopher Yap. Numerical and Experimental Study on Heat Transfer Process under Microwave Irradiation Using Reflector to Enhance Energy Absorption Rate, 2008 ASME Summer Heat Transfer Conference, August, 2008, Jacksonville, FL, USA. 3. M Kumja, Ng Kim Choon, Christopher Yap, H Yanagi , S. Koyama,B. B. Saha, A.Chakarborty. Modeling of a Novel Desorption Cycle Used by Dielectric Heating Method. The Second International Symposium on Physics of Fluids (ISPF2)June, 2008, Jiuzhaigou, China. 4. M Kumja, Ng Kim Choon, Christopher Yap, S. Koyama, B. B. Saha, Modeling and Simulation of a Novel Microwave Driven Sorption Cycle. ( ISHP 2008 ) International Sorption Heat Pump Conference, September, 2008, Seoul, KOREA. - 206 - [...]... in-depth understanding of the microwaveactivated desorption process, which enables an improvements in the design and operation of microwave- activated adsorption cooling systems Therefore, the objectives of the present study are: (1) To gain in-depth understanding of the desorption process under microwave Irradiation, (2) To develop a numerical model for microwave- activated adsorption cooling and optimize... thermally activated adsorption cycles have relatively low coefficient of performance due to porous structure of adsorbent, high thermal resistance between adsorbent and metal tube/fin, and negative effect of endothermic heat (Hads) Numerous researchers are trying to improve the performance of adsorption cycle by the enhancement of heat and mass transfer rate in various ways such as consolidation of adsorbent,... desorption evap evaporator f fluid i inside m number of half cycle of sinusoidal variation of intensity mic microwave n number of half cycle of sinusoidal variation of intensity nylon nylon o outside p number of half cycle of sinusoidal variation of intensity s silica gel - xviii - CHAPTER - 1 Introduction The term adsorption was firstly coined by Kayser in 1881, and this process continues to play an important... fundamentals of adsorption and their various industrial applications This study emphasizes on the characteristics of the adsorption working pair since it plays a critical role in the performance of an adsorption cooling system The enhancement of the adsorption cooling performance is also reviewed In the second part of this Chapter, literature on the behavior of various materials under the microwave irradiation... schematic diagram of adsorption beds sub control volume (sub model) Figure 5.19 Algorithm of system equations for non uniform temperature distribution model Figure 5.20 The temperature profile of each element and major components of evaporator and condenser Figure 5.21 The Microwave COP, Microwave line electricity COP, Conventional COP and average cooling capacity varied with sorption time and microwave irradiation... desorption rate and temperature increasing rate, is also presented Finally, this study -6- presents the simulation and experimental analysis of the effect of conducting material inside workload under microwave irradiation Chapter 5 presents the facets of analysis for the optimum design of the microwave applicator and a wave guide as well as it describes the simulation model of the microwave- activated adsorption. .. intensity can enhance the microwave energy absorption This phenomenon is observed in the experiment of the thesis (Section 4.6) With these advances, the microwave- activated adsorption cooling/heating system would become economically and technologically competitive for future applications of cooling and heating process of an adsorption cycle -3- 1.2 Objectives of the Present Study The aim of the current work... of workload geometry under microwave irradiation is described Finally, an investigation of the modelling and simulation techniques of microwave and adsorption cooling system are presented 2.2 Adsorption Process The term adsorption was applied to describe the observations of gases accumulation on free surfaces of adsorbent and to make a contrast between this observation and gaseous absorption where... second part of this chapter discusses the fact that according to the dielectric properties of adsorbent and adsorbate, microwave energy can be transformed into totally or partially thermal and potential energy flux In conclusion of this chapter, mass transport equations for various adsorption operations and the characteristic of microwave energy conversion based on the properties of adsorbent and adsorbate... However, the recognized drawback of adsorption cycles is that the heat and mass transfer rates of the adsorbent bed are low this is due to inherent low thermal conductivity of adsorbent pellets and high contact resistance between pallets and metal tube/fin (Lijun et al 1999, Marletta et al 2002) Hence numerous researchers have attempted enhancing the performance of adsorption cycle by finding the optimum . PERFORMANCE OF MICROWAVE -ACTIVATED ADSORPTION CYCLE : THEORY AND EXPERIMENTS M KUM JA NATIONAL UNIVERSITY OF SINGAPORE 2010 PERFORMANCE OF MICROWAVE- ACTIVATED. m number of half cycle of sinusoidal variation of intensity mic microwave n number of half cycle of sinusoidal variation of intensity nylon nylon o outside p number of half cycle of sinusoidal. distinguish the microwave- activated desorption and conventional microwave heating. Extensive experimentations were carried out to understand microwave- activated desorption and microwave irradiation.

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  • G-COVER1.pdf

  • G-COVER2

  • G-FRONT OF THESIS-1

  • G-CH-1.INTRODUCTION (correction)

    • CHAPTER - 1

    • Introduction

  • G-CH-2. LITERATURE. (Correction)

    • Electrical and fire hazards: extremely high electromagnetic field intensity can induced exceeds voltage which can caused electrical arcs in the surrounding medium if the voltage is higher than the breakdown voltage. This fact can lead to break out the...

    • Safety precaution for conducting the experiment against the hazards: Typically improper installation, connection and inefficient enclosure could result in the biological, fire, and electrical hazards. Following the instruction and careful installatio...

  • G-CH-3.THEORY (Correction)

    • The presence of spatial velocity would induce a corresponding pressure change which is described by the Ergun Equation as follows.

    • (3.25)

  • G-CH- 4. Experimental Analysis (Correction)

  • CH-5.MODELLING. (Correction)

  • G-CH- 6. CONCLUSION Ng(Correction)

  • G-REFERENCES

    • Osepchuk, J.M. The history of the microwave oven: A critical review Microwave Symposium Digest, 2009. MTT '09. IEEE MTT-S International Publication Date: 7-12 June 2009.

  • G-Appendix A

  • G-Appendix-B

  • G-Appendix C

  • G-Appendix D

  • G-PUBLICATION LIST

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