M = TAs (35) where As is the change o£ entropy of the transi- tion. For most materials the slope of the Clap- eyron curve is positive implying that heat is absorbed when material transforms from the more dense to the less dense phase and is re- leased when the transition is in the opposite direction. dTi dTn _ qM dx dx K Tn = Tiii = Tc (P) at x =d2 (37) dTn dTm _ — qM dx dx K ///////////////////////////////////////////////////^ T=0| />,A, Pz ^2 PI Al T= 0 x = 0 x = d( x = L/2 x = d2 x=L Fig. 6. Strip model for an internally heated two-phase fluid. The strip model for a two phase fluid is shown in Fig. 6. The phase boundaries are located at di and d2 in the sinking and rising branches of the cell respectively. The strip is then divided into three regions. Phase 1 exists in the section Oíx í di and d2 x :£ L; whereas phase 2 exists to the section digx -<d2. For simplification, we assume that there is uniform mass flow down the strip such that Pl u^ = p2u2 = q, and that the heat sources vary such that Pl = P2‘^2 — p\' Lastly, the thermal conductivity, specific heat, thermal ex- pansivity, and kinematic viscosity of the two phases are assumed equal. Thus Ki = K2 = K; ci = c2 = c; oq = a2 = a; v^ = v2 = v- The heat transport equation (24) must be solved separately in each section of the strip. In addition to the boundary conditions at the ends of the strip, joining conditions are re- quired at the phase boundaries. They are; Ti= Tn = Tc(P) at x = di (36) where Tc (P) is the transition temperature. The latent heat M is assumed to be constant and is defined so that in (36) and (37) M is positive for a normal phase transition. The equation of state is modified slightly because of the phase transition. We have p = Pl( 1-«T); T=§TC(P) (38) p=(Pl +Ap)(l-aT); T^TC(P) This modification is reflected in the equation for the total head. In the present case, the driving head is given by equation (39) where L — d2 — di = AD is the difference in the depths at which the phase change occurs in the ascending and descending limbs of the convec- tion cell. Equation (39) thus contains an addi- tional pressure head due to the phase level difference AD. This head helps drive the con- vection and thus tends to counteract the nega- tive effect of the latent heat. The temperature distribution which satisfies (24), (36) and (37) is given for segments I, II, and III by equations (40), (41) and (42), respec- tively, where T°(x) given by (25) represents the temperature in a fluid without a phase transi- tion. By substituting (40), (41), (42) into (39), the driving head can be determined. Since the relative displacement of the phase boundaries will be small, the temperature and density effects can be treated independently. Hence, the phase levels will be assumed equal in com- puting the head H due to the temperature differences in the fluid. Moreover terms in- volving the product aAp will be neglected in (39). The total head is then given by (43) where now b = cqL/K and b' = cqdi/K. Inserting (43) into the flow equation (8) and multiplying both sides by cL/K yields equation (44). By defining a temperature Ti = pA8L2/K, 26 JÖKULL 23. ÁR

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