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Transfer Masa Panas

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CONSERVATION LAW  1 X A  2 x A     V A A t V G x x           2 1   G x V A t           c x m x x , ,      x m x        , x c x V   ,      G c x m x V A t             , ,     G x m x V V A V A t               ,       G x m x x V AV V A V A V t                   ,     G x x V AV V x A V A V t                                     G t          .       G m V V t                . . .       G V V t                 . . . 3-D PROPERTY CONSERVATION EQUATION MOLECULER AND CONVECTION HEAT TRANSPORT PROCESS (APPLICATION OF EQUATION OF CHANGE) Property Accumulation Rate = Inlet Property Rate - Outlet Property Rate + Property Generation Rate
HEAT TRANSPORT MOLECULER AND CONVECTION HEAT TRANSPORT PROCESS (APPLICATION OF EQUATION OF CHANGE) General heat transport phenomena is expressed as equation of change. Equation of change concerning conduction and convection heat transport is called Energy Equation basically as microscopic energy conservation equation.       G m V V t                . . . =CpT, m  T k q               G T V CpT CpT CpT V t CpT                  . . .        CpT     G G T     Cp k    = thermal diffusivity
HEAT TRANSPORT         v v p q v U t U            : . . ˆ . ˆ          v v T p T q T v t T v C V                                : . . . ˆ ˆ         Dt Dp v q v H t H           : . ˆ . ˆ        v Dt Dp T q T v t T p C p                         : ln ln . . ˆ    OTHER FORMS OF ENERGY EQUATION Expressed in 𝑈 : Expressed in 𝐶𝑣 and T Expressed in 𝐻 Expressed in 𝐶𝑝 and T   V V       : V  Tabel $B.7 MOLECULER AND CONVECTION HEAT TRANSPORT PROCESS (APPLICATION OF EQUATION OF CHANGE) V T k Dt DT p C       2 ˆ
HEAT TRANSPORT 2B x y z L W EXAMPLE -2 Determine temprature distribution in a viscous liquid flowing downward in steady state and laminar between two vertical paralell plate. The two plates are maintained at constant temprature of 𝑇0. Assume constant  and k. Solution: First, we draw sketsc of flow system, Assumptions: 1.Steady state, 2.Laminar flow, 3.Vx=Vy=0, VZ is not function of y 4. Newtonian Fluid, 5.Constant , , k 6. 𝜕𝑇 𝜕𝑦 = 𝜕𝑇 𝜕𝑧 = 0 7. No slip at wall 8. End effect is neglected MOLECULER AND CONVECTION HEAT TRANSPORT PROCESS (APPLICATION OF EQUATION OF CHANGE)
HEAT TRANSPORT 0             z V y V x V t z y x     0    z Vz  0    z Vz z z z z z z z y x x z g z V y V x V z P z V V y V V x V V t V                                             2 2 2 2 2 2 z z g dx V d z P         2 2 0 L dx V d L z 0 2 2      z g P z     1 0 K x L dx dV L z       0 0    dx dV x z x L dx dV L z  0     2 2 0 2 K x L V L z       0    z V B x 2 0 2 2 B L K L       SOLUTION MOLECULER AND CONVECTION HEAT TRANSPORT PROCESS (APPLICATION OF EQUATION OF CHANGE) K1=0
HEAT TRANSPORT                   2 2 1 2 B x L B Vz                  2 max , 1 B x Vz L B Vz  2 2 max ,    2 max . 2 B x V dx dV z z                                        2 2 2 2 2 2 z T y T x T k z T V y T V x T V t T C z y x P                                                                                      2 2 2 2 2 2 2 y V z V x V z V x V y V z V y V x V z y z x y x z y x   0 2 2 2         dx dV dx T d k z  0 4 . 4 2 2 max , 2 2         B x V dx T d k z  3 3 4 2 max , 3 4 K x kB V dx dT z     4 3 4 4 2 max , 3 K x K x kB V T z      ENERGY EQUATION SOLUTION MOLECULER AND CONVECTION HEAT TRANSPORT PROCESS (APPLICATION OF EQUATION OF CHANGE) From table A-5
HEAT TRANSPORT 4 3 4 4 2 max , 3 K x K x kB V T z      0 0    dx dT x 4 4 4 2 max , 3 K x kB V T z     0 T T B x    B.C-1: B.C.-2: 0 3  K k V T K z 3 2 max , 0 4                     4 2 max , 0 1 3 B x k V T T z                       4 2 4 0 1 12 B x k L B T T  SOLUTION MOLECULER AND CONVECTION HEAT TRANSPORT PROCESS (APPLICATION OF EQUATION OF CHANGE)
HEAT TRANSPORT Example 3 Inlet air at T1 Cooler A system consist of two porous concentric spherical walls with radius R1 and R2. Outer surfase of inner wall is maintained at temprature T1 and inner surface of outer wall is maintained at tempratrure T2. Dry air at temprature T1 is blown radially from inner wall to outer wall. Develop an expression for heat removal rate needed from inner wall as a function of air mass flow rate. Assume steady state laminar flow and low gas rate. MOLECULER AND CONVECTION HEAT TRANSPORT PROCESS (APPLICATION OF EQUATION OF CHANGE)
HEAT TRANSPORT Solution: Assumption: 0 . 1     V V ) (r f Vr  2. T=T(r) ) ( . 3 r      0 1 2 2  r V r dr d r   r V r  2  4 r w  constant Continuity Equation:                   r r r V r dr d r dr d dr d dr dV V 2 2 1   Equation of Motion dr d dr r w d r w r r          2 2 4 4   dr d r wr     5 2 2 8             2 2 5 2 2 8 R r r R r r dr w d                     4 4 2 2 2 2 1 1 32 r R w r R r                          4 2 4 2 2 2 2 1 32 r R R w R r r   MOLECULER AND CONVECTION HEAT TRANSPORT PROCESS (APPLICATION OF EQUATION OF CHANGE) r 2 r 2 2 2 r 2 2 r 2 2 2 2 2 θ r r θ r r r ρg v θ sin r 1 θ v sinθ θ sinθ r 1 r ) v (r r 1 μ r r v v v θ sin r v θ v r v r v v t v ρ                                                      p 𝜕 𝜕𝑟 1 𝑟2 𝜕 𝜕𝑟 𝑟2𝑣𝑟
HEAT TRANSPORT        dr dT r dr d r k dr dT V C r p 2 2 1 ˆ         dr dT r dr d C w k dr dT p r 2 ˆ 4 𝑢 = 𝑟2 𝑑𝑇 𝑑𝑟 = 𝐾1𝑒− 𝑅0 𝑟 2 0 1 0 2 0 0 2 1 2 R R R R R R r R e e e e T T T T / / / /          k C w R P r  4 0 / ˆ  1 2 1 4 R r r q R Q     1 2 1 4 R r dr dT k R           1 1 4 2 1 1 0 1 2 0     R R R R T T k R Q / / exp    2 1 1 2 1 0 1 4 R R T T k R Q /     1 1 0 0       e Q Q Q     k R R R C w R R R R P r 1 2 1 1 1 0 4 1 1   / ˆ /     Energy Equation: Substitution: Heat transafer rate to inner wall is Cooling requirement at inner wall, If there is no air flow MOLECULER AND CONVECTION HEAT TRANSPORT PROCESS (APPLICATION OF EQUATION OF CHANGE) 𝑢 𝑟2 = 1 𝑅0 𝑑 𝑑𝑟 𝑢 → 𝑑𝑟 𝑟2 = 1 𝑅0 𝑑𝑢 𝑢 − 𝑅0 𝑟 + ln 𝐾1 = ln 𝑢 → 𝑢 = 𝐾1𝑒− 𝑅0 𝑟 𝑑𝑇 = 𝐾1 𝑒− 𝑅0 𝑟 𝑟2 𝑑𝑟 𝑠 = 𝑅0 𝑟 → 𝑑𝑠 = − 𝑅0 𝑟2 𝑑𝑟 𝑑𝑇 = 𝑇 = 𝐾1 𝑒− 𝑅0 𝑟 𝑟2 𝑑𝑟 = − 𝐾1 𝑅0 𝑒−𝑠 𝑑𝑠 = 𝐾1 𝑅0 𝑒− 𝑅0 𝑟 + 𝐾2 𝑢 = 𝑟2 𝑑𝑇 𝑑𝑟
EQUATION OF CHANGE TABLE
      0 z ρv y ρv x ρv t ρ z y x                   0 z v ρ θ v ρ r 1 r v r ρ r 1 t ρ z θ r                   0 v ρ rsinθ 1 θ sinθ v ρ rsinθ 1 r v r ρ r 1 t ρ θ r 2 2               Cartesian Coordinate System: Cylindrical Coordinate System: Spherical Coordinate System Table A-1 Continuity Equation
-Table A2Equation of Motion (Equation of Momentum) x zx yx xx x z x y x z x ρg z τ y τ x τ x z v v y v v x v v t v ρ                                          p y zy yy xy y z y y y z y ρg z τ y τ x τ y z v v y v v x v v t v ρ                                          p z zz yz xz z z z y z z z ρg z τ y τ x τ z z v v y v v x v v t v ρ                                          p Cartesian Coordinate System:
  r rz θθ rθ rr r z 2 θ r θ r r r ρg z τ r τ θ τ r 1 r rτ r 1 r z v v r v θ v r v r v v t v ρ                                          p   θ zθ θθ rθ 2 2 θ z θ r θ θ θ r θ ρg z τ θ τ r 1 r τ r r 1 θ r 1 z v v r v v θ v r v r v v t v ρ                                         p   z zz θz rz z z z θ z r z ρg z τ θ τ r 1 x rτ r 1 z z v v θ v r v r v v t v ρ                                      p Cylindrical Coordinate System -Table A2Equation of Motion (Equation of Momentum)
Spherical Coordinate System   r r θθ rθ rr 2 2 2 2 θ r r θ r r r ρg τ rsinθ 1 r τ τ θ sinθ τ rsinθ 1 r τ r r 1 r r v v v rsinθ v θ v r v r v v t v ρ                                                    p   θ rθ θ θθ rθ 2 2 2 θ r θ θ θ θ r θ ρg τ r cotθ r τ τ rsinθ 1 θ sinθ τ rsinθ 1 r τ r r 1 θ r 1 r cotθ v r v v v rsinθ v θ v r v r v v t v ρ                                                    p                 ρg τ r cotθ 2 r τ τ rsinθ 1 θ τ r 1 r τ r r 1 rsinθ 1 cotθ r v v r v v v rsinθ v θ v r v r v v t v ρ θ r θ r 2 2 θ r θ φ r φ                                              p -Table A2Equation of Motion (Equation of Momentum)
x 2 x 2 x 2 2 x 2 x z x y x z x ρg z v y v x v μ x z v v y v v x v v t v ρ                                          p y 2 y 2 2 y 2 2 y 2 y z y y y z y ρg z v y v x v μ y z v v y v v x v v t v ρ                                          p z 2 z 2 2 z 2 2 z 2 z z z y z z z ρg z v y v x v μ z z v v y v v x v v t v ρ                                          p -Table A2Equation of Motion (Equation of Momentum) (Incompressible Newtonian Fluid) Cartesian Coordinate System:
Table A-3 Equation of Motion (Equation of Momentum) (Incompresiible Newtonian Fluid) Cylindrical Coordinate:   r 2 r 2 θ 2 2 r 2 2 r r z 2 θ r θ r r r ρg z v θ v r 2 θ v r 1 rv r r 1 r μ r z v v r v θ v r v r v v t v ρ                                                    p   θ 2 θ 2 r 2 2 θ 2 2 θ θ z θ r θ θ θ r θ ρg z v θ v r 2 θ v r 1 rv r r 1 r μ θ r 1 z v v r v v θ v r v r v v t v ρ                                                  p x 2 z 2 2 z 2 2 z z z z θ z r z ρg z v θ v r 1 r v r r r 1 μ z z v v θ v r v r v v t v ρ                                              p
Table A-3 Equation of Motion ( Equation of Momentum) (Incompressible Newtonian Fluid) Spherical Coordinate r 2 r 2 2 2 r 2 2 r 2 2 2 2 2 θ r r θ r r r ρg v θ sin r 1 θ v sinθ θ sinθ r 1 r ) v (r r 1 μ r r v v v θ sin r v θ v r v r v v t v ρ                                                      p θ 2 2 r 2 2 θ 2 2 2 θ 2 θ 2 2 2 θ r θ θ θ θ r θ ρg v θ sin r cosθ 2 θ v r 2 v θ sin r 1 θ sinθ v sinθ 1 θ r 1 r v r r r 1 μ θ r 1 r cotθ v r v v v rsinθ v θ v r v r v v t v ρ                                                                        p                 ρg v θ sin r cosθ 2 v sinθ r 2 v θ sin r 1 θ sinθ v sinθ 1 θ r 1 r v r r r 1 μ rsinθ 1 cotθ r v v r v v v rsinθ v θ v r v r v v t v ρ θ 2 2 r 2 2 2 2 2 2 2 2 θ r θ r                                                                      p
Table A-4 Components of stress tensor for Newtonian Fluid Koordinat Silinder Koordinat Bola              v . κ x v 2 μ τ x xx              v . κ y v 2 μ τ y yy              v z vz xx . 2                  x v y v μ τ τ y x yx xy               y v z v μ τ τ z y zy yz               z v x v μ τ τ x z xz zx              v . κ r v 2 μ τ r rr                     v . κ r v θ v r 1 2 μ τ r θ θθ              v . κ z v 2 μ τ z zz                 θ v r 1 r /r v r μ τ τ r θ θr rθ               θ v r 1 z v μ τ τ z θ zθ θz               z v r v μ τ τ r z rz zr              v . κ r v 2 μ τ r rr                     v . κ r v θ v r 1 2 μ τ r θ θθ                        v . κ r cotθ v r v v rsinθ 1 2 μ τ θ r                  θ v r 1 r /r) (v r μ τ τ r θ θr rθ                           θ θ θ v rsinθ 1 sinθ v θ r sinθ μ τ τ               r /r) (v r φ v rsinθ 1 μ τ τ φ r r r   3 2 κ  Cartesian Coordinate System
Cylindrical Coordinate Spherical Coordinate   v .  z v y v x v z y x           z v θ v r 1 rv r r 1 z θ r                       v rsinθ 1 sinθ v θ rsinθ 1 v r r r 1 θ r 2 2 Cartesian Coordinate System:
Tabel A-5 Fungsi untuk fluida Newton Coordinate System Cartesian Sylindrical Spherical v   2 2 z x 2 y z 2 x y 2 z 2 y 2 x v . 3 2 x v z v z v y v y v x v z v y v x v 2                                                                            2 2 z r 2 θ z 2 r θ 2 z 2 r θ 2 r v . 3 2 r v z v z v θ v r 1 θ v r 1 r v r r z v r v θ v r 1 r v 2                                                                                2 2 r 2 θ 2 r θ 2 θ r 2 r θ 2 r v . 3 2 r v r r v rsi n θ 1 v rsi n θ 1 si n θ v θ r si n θ θ v r 1 r v r r r cotθ v r v v rsi n θ 1 r v θ v r 1 r v 2                                                                                                         
Table A-6 Component of Energy Flux Cartesian Cylindrical Spherical z T k q y T k q x T k q z y x             z T k q θ T r 1 k q r T k q z θ r                          T rsinθ 1 k q θ T r 1 k q r T k q φ θ r
Tabel A-7 Energy Equation in energy and momentum flux                                                                                                             y v z v τ x v z v τ x v y v τ z v τ y v τ x v τ v . T p T z q y q x q z T v y T v x T v t T ρC z y yz z x xz y x xy z zz y yy x xx ρ z y x z y x v                                                                                                                      z v θ v r 1 τ z v r v τ θ v r 1 r v r r τ z v τ v θ v r 1 τ r v τ v . T p T z q θ q r 1 rq r r 1 z T v θ T r v r T v t T ρC θ z θz r z rz r θ rθ z zz r θ θθ r rr ρ z θ r z θ r v                                                                                                                                                          v r cotθ v rsinθ 1 θ v r 1 τ r v v rsinθ 1 r v τ r v θ v r 1 r v τ r cotθ v r v v rsinθ 1 τ v θ v r 1 τ r v τ v . T p T q rsinθ 1 θ sinθ q rsinθ 1 q r r r 1 T rsinθ v θ T r v r T v t T ρC θ θ r r θ r θ rθ θ r r θ θθ r rr ρ θ r 2 2 θ r v Cartesian Cylindrical Spherical
Tabel A-8 V                                     μ z T y T x T k z T v y T v x T v t T ρC 2 2 2 2 2 2 z y x p V                                           μ z T θ T r 1 r T r r r 1 k z T v θ T r v r T v t T ρC 2 2 2 2 2 z θ r p V                                                     μ T θ sin r 1 θ T sinθ θ sinθ r 1 r T r r r 1 k T rsinθ v θ T r v r T v t T ρ 2 2 2 2 2 2 2 θ r p    Energy Equation For Incompressible Newtonian Fluid with constant properties Spherical Cylindrical Cartesian 𝜌𝐶𝑝 V                                                     μ T θ sin r 1 θ T sinθ θ sinθ r 1 r T r r r 1 k T rsinθ v θ T r v r T v t T ρ 2 2 2 2 2 2 2 θ r p   
Tabel A-9 Components of molecular Diffusion Flux Spherical z C D J y C D J x C D J A AB Az A AB Ay A AB Ax             z C D J θ C r 1 D J r C D J A AB Az A AB Aθ A AB Ar                          A AB Az A AB Aθ A AB Ar C rsinθ 1 D J θ C r 1 D J r C D J Cartesian Cylindrical
Tabel A-10 Continuity Equation of Component A A Az Ay Ax A R z N y N x N t C                       A Az Aθ Ar A R z N θ N r 1 rN r r 1 t C                       A A Aθ Ar 2 2 A R N rsinθ 1 sinθ N θ rsinθ 1 N r r r 1 t C                       Cartesian Cylindrical Spherical
TabLE A-11 Continuity equation of component A for constant properties A 2 A 2 2 A 2 2 A 2 AB A z A y A x A R z C y C x C D z C v y C v x C v t C                                      A 2 A 2 2 A 2 2 A AB A z A θ A r A R z C θ C r 1 r C r r r 1 D z C v θ C r 1 v r C v t C                                            A 2 A 2 2 2 A 2 A 2 2 AB A A θ A r A R C θ sin r 1 θ C sinθ θ sinθ r 1 r C r r r 1 D C rsin θ 1 v θ C r 1 v r C v t C                                                         Cartesian Cylindrical Spherical
P(x,y,z) y z x y x z CARTESIAN COORDINATE SYSTEM
z   z r P , ,  r CYLINDRICAL COORDINATE SYSTEM
   , , r P   SPHERICAL COORDINATE SYSTEM
NON NEWTONIAN FLUID                       : 2 1 0 0      2 0 : 2 1     0     2 0 : 2 1     0 0         y Vx yx 2 0 2    yx 0    y Vx 2 0 2    yx                1 : 2 1 n m                              2 0 0 : 2 1 1        BINGHAM PLASTIC POWER LAW Model Reiner-Philippof
NON NEWTONIAN FLUID                       : 2 1 0 0      2 0 : 2 1     0     2 0 : 2 1     0 0         y Vx yx 2 0 2    yx 0    y Vx 2 0 2    yx                1 : 2 1 n m                              2 0 0 : 2 1 1        BINGHAM PLASTIC POWER LAW Model Reiner-Philippof

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PR_TMP_IUP_2021_CHAP3.pptx

  • 1. CONSERVATION LAW  1 X A  2 x A     V A A t V G x x           2 1   G x V A t           c x m x x , ,      x m x        , x c x V   ,      G c x m x V A t             , ,     G x m x V V A V A t               ,       G x m x x V AV V A V A V t                   ,     G x x V AV V x A V A V t                                     G t          .       G m V V t                . . .       G V V t                 . . . 3-D PROPERTY CONSERVATION EQUATION MOLECULER AND CONVECTION HEAT TRANSPORT PROCESS (APPLICATION OF EQUATION OF CHANGE) Property Accumulation Rate = Inlet Property Rate - Outlet Property Rate + Property Generation Rate
  • 2. HEAT TRANSPORT MOLECULER AND CONVECTION HEAT TRANSPORT PROCESS (APPLICATION OF EQUATION OF CHANGE) General heat transport phenomena is expressed as equation of change. Equation of change concerning conduction and convection heat transport is called Energy Equation basically as microscopic energy conservation equation.       G m V V t                . . . =CpT, m  T k q               G T V CpT CpT CpT V t CpT                  . . .        CpT     G G T     Cp k    = thermal diffusivity
  • 3. HEAT TRANSPORT         v v p q v U t U            : . . ˆ . ˆ          v v T p T q T v t T v C V                                : . . . ˆ ˆ         Dt Dp v q v H t H           : . ˆ . ˆ        v Dt Dp T q T v t T p C p                         : ln ln . . ˆ    OTHER FORMS OF ENERGY EQUATION Expressed in 𝑈 : Expressed in 𝐶𝑣 and T Expressed in 𝐻 Expressed in 𝐶𝑝 and T   V V       : V  Tabel $B.7 MOLECULER AND CONVECTION HEAT TRANSPORT PROCESS (APPLICATION OF EQUATION OF CHANGE) V T k Dt DT p C       2 ˆ
  • 4. HEAT TRANSPORT 2B x y z L W EXAMPLE -2 Determine temprature distribution in a viscous liquid flowing downward in steady state and laminar between two vertical paralell plate. The two plates are maintained at constant temprature of 𝑇0. Assume constant  and k. Solution: First, we draw sketsc of flow system, Assumptions: 1.Steady state, 2.Laminar flow, 3.Vx=Vy=0, VZ is not function of y 4. Newtonian Fluid, 5.Constant , , k 6. 𝜕𝑇 𝜕𝑦 = 𝜕𝑇 𝜕𝑧 = 0 7. No slip at wall 8. End effect is neglected MOLECULER AND CONVECTION HEAT TRANSPORT PROCESS (APPLICATION OF EQUATION OF CHANGE)
  • 5. HEAT TRANSPORT 0             z V y V x V t z y x     0    z Vz  0    z Vz z z z z z z z y x x z g z V y V x V z P z V V y V V x V V t V                                             2 2 2 2 2 2 z z g dx V d z P         2 2 0 L dx V d L z 0 2 2      z g P z     1 0 K x L dx dV L z       0 0    dx dV x z x L dx dV L z  0     2 2 0 2 K x L V L z       0    z V B x 2 0 2 2 B L K L       SOLUTION MOLECULER AND CONVECTION HEAT TRANSPORT PROCESS (APPLICATION OF EQUATION OF CHANGE) K1=0
  • 6. HEAT TRANSPORT                   2 2 1 2 B x L B Vz                  2 max , 1 B x Vz L B Vz  2 2 max ,    2 max . 2 B x V dx dV z z                                        2 2 2 2 2 2 z T y T x T k z T V y T V x T V t T C z y x P                                                                                      2 2 2 2 2 2 2 y V z V x V z V x V y V z V y V x V z y z x y x z y x   0 2 2 2         dx dV dx T d k z  0 4 . 4 2 2 max , 2 2         B x V dx T d k z  3 3 4 2 max , 3 4 K x kB V dx dT z     4 3 4 4 2 max , 3 K x K x kB V T z      ENERGY EQUATION SOLUTION MOLECULER AND CONVECTION HEAT TRANSPORT PROCESS (APPLICATION OF EQUATION OF CHANGE) From table A-5
  • 7. HEAT TRANSPORT 4 3 4 4 2 max , 3 K x K x kB V T z      0 0    dx dT x 4 4 4 2 max , 3 K x kB V T z     0 T T B x    B.C-1: B.C.-2: 0 3  K k V T K z 3 2 max , 0 4                     4 2 max , 0 1 3 B x k V T T z                       4 2 4 0 1 12 B x k L B T T  SOLUTION MOLECULER AND CONVECTION HEAT TRANSPORT PROCESS (APPLICATION OF EQUATION OF CHANGE)
  • 8. HEAT TRANSPORT Example 3 Inlet air at T1 Cooler A system consist of two porous concentric spherical walls with radius R1 and R2. Outer surfase of inner wall is maintained at temprature T1 and inner surface of outer wall is maintained at tempratrure T2. Dry air at temprature T1 is blown radially from inner wall to outer wall. Develop an expression for heat removal rate needed from inner wall as a function of air mass flow rate. Assume steady state laminar flow and low gas rate. MOLECULER AND CONVECTION HEAT TRANSPORT PROCESS (APPLICATION OF EQUATION OF CHANGE)
  • 9. HEAT TRANSPORT Solution: Assumption: 0 . 1     V V ) (r f Vr  2. T=T(r) ) ( . 3 r      0 1 2 2  r V r dr d r   r V r  2  4 r w  constant Continuity Equation:                   r r r V r dr d r dr d dr d dr dV V 2 2 1   Equation of Motion dr d dr r w d r w r r          2 2 4 4   dr d r wr     5 2 2 8             2 2 5 2 2 8 R r r R r r dr w d                     4 4 2 2 2 2 1 1 32 r R w r R r                          4 2 4 2 2 2 2 1 32 r R R w R r r   MOLECULER AND CONVECTION HEAT TRANSPORT PROCESS (APPLICATION OF EQUATION OF CHANGE) r 2 r 2 2 2 r 2 2 r 2 2 2 2 2 θ r r θ r r r ρg v θ sin r 1 θ v sinθ θ sinθ r 1 r ) v (r r 1 μ r r v v v θ sin r v θ v r v r v v t v ρ                                                      p 𝜕 𝜕𝑟 1 𝑟2 𝜕 𝜕𝑟 𝑟2𝑣𝑟
  • 10. HEAT TRANSPORT        dr dT r dr d r k dr dT V C r p 2 2 1 ˆ         dr dT r dr d C w k dr dT p r 2 ˆ 4 𝑢 = 𝑟2 𝑑𝑇 𝑑𝑟 = 𝐾1𝑒− 𝑅0 𝑟 2 0 1 0 2 0 0 2 1 2 R R R R R R r R e e e e T T T T / / / /          k C w R P r  4 0 / ˆ  1 2 1 4 R r r q R Q     1 2 1 4 R r dr dT k R           1 1 4 2 1 1 0 1 2 0     R R R R T T k R Q / / exp    2 1 1 2 1 0 1 4 R R T T k R Q /     1 1 0 0       e Q Q Q     k R R R C w R R R R P r 1 2 1 1 1 0 4 1 1   / ˆ /     Energy Equation: Substitution: Heat transafer rate to inner wall is Cooling requirement at inner wall, If there is no air flow MOLECULER AND CONVECTION HEAT TRANSPORT PROCESS (APPLICATION OF EQUATION OF CHANGE) 𝑢 𝑟2 = 1 𝑅0 𝑑 𝑑𝑟 𝑢 → 𝑑𝑟 𝑟2 = 1 𝑅0 𝑑𝑢 𝑢 − 𝑅0 𝑟 + ln 𝐾1 = ln 𝑢 → 𝑢 = 𝐾1𝑒− 𝑅0 𝑟 𝑑𝑇 = 𝐾1 𝑒− 𝑅0 𝑟 𝑟2 𝑑𝑟 𝑠 = 𝑅0 𝑟 → 𝑑𝑠 = − 𝑅0 𝑟2 𝑑𝑟 𝑑𝑇 = 𝑇 = 𝐾1 𝑒− 𝑅0 𝑟 𝑟2 𝑑𝑟 = − 𝐾1 𝑅0 𝑒−𝑠 𝑑𝑠 = 𝐾1 𝑅0 𝑒− 𝑅0 𝑟 + 𝐾2 𝑢 = 𝑟2 𝑑𝑇 𝑑𝑟
  • 12.       0 z ρv y ρv x ρv t ρ z y x                   0 z v ρ θ v ρ r 1 r v r ρ r 1 t ρ z θ r                   0 v ρ rsinθ 1 θ sinθ v ρ rsinθ 1 r v r ρ r 1 t ρ θ r 2 2               Cartesian Coordinate System: Cylindrical Coordinate System: Spherical Coordinate System Table A-1 Continuity Equation
  • 13. -Table A2Equation of Motion (Equation of Momentum) x zx yx xx x z x y x z x ρg z τ y τ x τ x z v v y v v x v v t v ρ                                          p y zy yy xy y z y y y z y ρg z τ y τ x τ y z v v y v v x v v t v ρ                                          p z zz yz xz z z z y z z z ρg z τ y τ x τ z z v v y v v x v v t v ρ                                          p Cartesian Coordinate System:
  • 14.   r rz θθ rθ rr r z 2 θ r θ r r r ρg z τ r τ θ τ r 1 r rτ r 1 r z v v r v θ v r v r v v t v ρ                                          p   θ zθ θθ rθ 2 2 θ z θ r θ θ θ r θ ρg z τ θ τ r 1 r τ r r 1 θ r 1 z v v r v v θ v r v r v v t v ρ                                         p   z zz θz rz z z z θ z r z ρg z τ θ τ r 1 x rτ r 1 z z v v θ v r v r v v t v ρ                                      p Cylindrical Coordinate System -Table A2Equation of Motion (Equation of Momentum)
  • 15. Spherical Coordinate System   r r θθ rθ rr 2 2 2 2 θ r r θ r r r ρg τ rsinθ 1 r τ τ θ sinθ τ rsinθ 1 r τ r r 1 r r v v v rsinθ v θ v r v r v v t v ρ                                                    p   θ rθ θ θθ rθ 2 2 2 θ r θ θ θ θ r θ ρg τ r cotθ r τ τ rsinθ 1 θ sinθ τ rsinθ 1 r τ r r 1 θ r 1 r cotθ v r v v v rsinθ v θ v r v r v v t v ρ                                                    p                 ρg τ r cotθ 2 r τ τ rsinθ 1 θ τ r 1 r τ r r 1 rsinθ 1 cotθ r v v r v v v rsinθ v θ v r v r v v t v ρ θ r θ r 2 2 θ r θ φ r φ                                              p -Table A2Equation of Motion (Equation of Momentum)
  • 16. x 2 x 2 x 2 2 x 2 x z x y x z x ρg z v y v x v μ x z v v y v v x v v t v ρ                                          p y 2 y 2 2 y 2 2 y 2 y z y y y z y ρg z v y v x v μ y z v v y v v x v v t v ρ                                          p z 2 z 2 2 z 2 2 z 2 z z z y z z z ρg z v y v x v μ z z v v y v v x v v t v ρ                                          p -Table A2Equation of Motion (Equation of Momentum) (Incompressible Newtonian Fluid) Cartesian Coordinate System:
  • 17. Table A-3 Equation of Motion (Equation of Momentum) (Incompresiible Newtonian Fluid) Cylindrical Coordinate:   r 2 r 2 θ 2 2 r 2 2 r r z 2 θ r θ r r r ρg z v θ v r 2 θ v r 1 rv r r 1 r μ r z v v r v θ v r v r v v t v ρ                                                    p   θ 2 θ 2 r 2 2 θ 2 2 θ θ z θ r θ θ θ r θ ρg z v θ v r 2 θ v r 1 rv r r 1 r μ θ r 1 z v v r v v θ v r v r v v t v ρ                                                  p x 2 z 2 2 z 2 2 z z z z θ z r z ρg z v θ v r 1 r v r r r 1 μ z z v v θ v r v r v v t v ρ                                              p
  • 18. Table A-3 Equation of Motion ( Equation of Momentum) (Incompressible Newtonian Fluid) Spherical Coordinate r 2 r 2 2 2 r 2 2 r 2 2 2 2 2 θ r r θ r r r ρg v θ sin r 1 θ v sinθ θ sinθ r 1 r ) v (r r 1 μ r r v v v θ sin r v θ v r v r v v t v ρ                                                      p θ 2 2 r 2 2 θ 2 2 2 θ 2 θ 2 2 2 θ r θ θ θ θ r θ ρg v θ sin r cosθ 2 θ v r 2 v θ sin r 1 θ sinθ v sinθ 1 θ r 1 r v r r r 1 μ θ r 1 r cotθ v r v v v rsinθ v θ v r v r v v t v ρ                                                                        p                 ρg v θ sin r cosθ 2 v sinθ r 2 v θ sin r 1 θ sinθ v sinθ 1 θ r 1 r v r r r 1 μ rsinθ 1 cotθ r v v r v v v rsinθ v θ v r v r v v t v ρ θ 2 2 r 2 2 2 2 2 2 2 2 θ r θ r                                                                      p
  • 19. Table A-4 Components of stress tensor for Newtonian Fluid Koordinat Silinder Koordinat Bola              v . κ x v 2 μ τ x xx              v . κ y v 2 μ τ y yy              v z vz xx . 2                  x v y v μ τ τ y x yx xy               y v z v μ τ τ z y zy yz               z v x v μ τ τ x z xz zx              v . κ r v 2 μ τ r rr                     v . κ r v θ v r 1 2 μ τ r θ θθ              v . κ z v 2 μ τ z zz                 θ v r 1 r /r v r μ τ τ r θ θr rθ               θ v r 1 z v μ τ τ z θ zθ θz               z v r v μ τ τ r z rz zr              v . κ r v 2 μ τ r rr                     v . κ r v θ v r 1 2 μ τ r θ θθ                        v . κ r cotθ v r v v rsinθ 1 2 μ τ θ r                  θ v r 1 r /r) (v r μ τ τ r θ θr rθ                           θ θ θ v rsinθ 1 sinθ v θ r sinθ μ τ τ               r /r) (v r φ v rsinθ 1 μ τ τ φ r r r   3 2 κ  Cartesian Coordinate System
  • 20. Cylindrical Coordinate Spherical Coordinate   v .  z v y v x v z y x           z v θ v r 1 rv r r 1 z θ r                       v rsinθ 1 sinθ v θ rsinθ 1 v r r r 1 θ r 2 2 Cartesian Coordinate System:
  • 21. Tabel A-5 Fungsi untuk fluida Newton Coordinate System Cartesian Sylindrical Spherical v   2 2 z x 2 y z 2 x y 2 z 2 y 2 x v . 3 2 x v z v z v y v y v x v z v y v x v 2                                                                            2 2 z r 2 θ z 2 r θ 2 z 2 r θ 2 r v . 3 2 r v z v z v θ v r 1 θ v r 1 r v r r z v r v θ v r 1 r v 2                                                                                2 2 r 2 θ 2 r θ 2 θ r 2 r θ 2 r v . 3 2 r v r r v rsi n θ 1 v rsi n θ 1 si n θ v θ r si n θ θ v r 1 r v r r r cotθ v r v v rsi n θ 1 r v θ v r 1 r v 2                                                                                                         
  • 22. Table A-6 Component of Energy Flux Cartesian Cylindrical Spherical z T k q y T k q x T k q z y x             z T k q θ T r 1 k q r T k q z θ r                          T rsinθ 1 k q θ T r 1 k q r T k q φ θ r
  • 23. Tabel A-7 Energy Equation in energy and momentum flux                                                                                                             y v z v τ x v z v τ x v y v τ z v τ y v τ x v τ v . T p T z q y q x q z T v y T v x T v t T ρC z y yz z x xz y x xy z zz y yy x xx ρ z y x z y x v                                                                                                                      z v θ v r 1 τ z v r v τ θ v r 1 r v r r τ z v τ v θ v r 1 τ r v τ v . T p T z q θ q r 1 rq r r 1 z T v θ T r v r T v t T ρC θ z θz r z rz r θ rθ z zz r θ θθ r rr ρ z θ r z θ r v                                                                                                                                                          v r cotθ v rsinθ 1 θ v r 1 τ r v v rsinθ 1 r v τ r v θ v r 1 r v τ r cotθ v r v v rsinθ 1 τ v θ v r 1 τ r v τ v . T p T q rsinθ 1 θ sinθ q rsinθ 1 q r r r 1 T rsinθ v θ T r v r T v t T ρC θ θ r r θ r θ rθ θ r r θ θθ r rr ρ θ r 2 2 θ r v Cartesian Cylindrical Spherical
  • 24. Tabel A-8 V                                     μ z T y T x T k z T v y T v x T v t T ρC 2 2 2 2 2 2 z y x p V                                           μ z T θ T r 1 r T r r r 1 k z T v θ T r v r T v t T ρC 2 2 2 2 2 z θ r p V                                                     μ T θ sin r 1 θ T sinθ θ sinθ r 1 r T r r r 1 k T rsinθ v θ T r v r T v t T ρ 2 2 2 2 2 2 2 θ r p    Energy Equation For Incompressible Newtonian Fluid with constant properties Spherical Cylindrical Cartesian 𝜌𝐶𝑝 V                                                     μ T θ sin r 1 θ T sinθ θ sinθ r 1 r T r r r 1 k T rsinθ v θ T r v r T v t T ρ 2 2 2 2 2 2 2 θ r p   
  • 25. Tabel A-9 Components of molecular Diffusion Flux Spherical z C D J y C D J x C D J A AB Az A AB Ay A AB Ax             z C D J θ C r 1 D J r C D J A AB Az A AB Aθ A AB Ar                          A AB Az A AB Aθ A AB Ar C rsinθ 1 D J θ C r 1 D J r C D J Cartesian Cylindrical
  • 26. Tabel A-10 Continuity Equation of Component A A Az Ay Ax A R z N y N x N t C                       A Az Aθ Ar A R z N θ N r 1 rN r r 1 t C                       A A Aθ Ar 2 2 A R N rsinθ 1 sinθ N θ rsinθ 1 N r r r 1 t C                       Cartesian Cylindrical Spherical
  • 27. TabLE A-11 Continuity equation of component A for constant properties A 2 A 2 2 A 2 2 A 2 AB A z A y A x A R z C y C x C D z C v y C v x C v t C                                      A 2 A 2 2 A 2 2 A AB A z A θ A r A R z C θ C r 1 r C r r r 1 D z C v θ C r 1 v r C v t C                                            A 2 A 2 2 2 A 2 A 2 2 AB A A θ A r A R C θ sin r 1 θ C sinθ θ sinθ r 1 r C r r r 1 D C rsin θ 1 v θ C r 1 v r C v t C                                                         Cartesian Cylindrical Spherical
  • 31. NON NEWTONIAN FLUID                       : 2 1 0 0      2 0 : 2 1     0     2 0 : 2 1     0 0         y Vx yx 2 0 2    yx 0    y Vx 2 0 2    yx                1 : 2 1 n m                              2 0 0 : 2 1 1        BINGHAM PLASTIC POWER LAW Model Reiner-Philippof
  • 32. NON NEWTONIAN FLUID                       : 2 1 0 0      2 0 : 2 1     0     2 0 : 2 1     0 0         y Vx yx 2 0 2    yx 0    y Vx 2 0 2    yx                1 : 2 1 n m                              2 0 0 : 2 1 1        BINGHAM PLASTIC POWER LAW Model Reiner-Philippof