Heat Transfer of Supercritical Fluid Flows and Compressible Flows

In this chapter, the heat transfer between supercritical fluid flows and solid walls and that between compressible flows and solid walls is described. First, the physical fundamentals of supercritical fluids and compressible flows are explained. Second, methods for estimating the heat-transfer performance according to the physical fundamentals and conventional experimental results are described. Then, the known correlations for estimating the heat-transfer performance are introduced. Finally, examples of practical heat exchangers using supercritical fluid flows and/or compressible flows are presented.


Introduction
The range of use of heat exchangers is being expanded to extensive applications in various fields.In particular, supercritical fluids and high-speed air, that is,, compressible fluids, are suitable as working fluids.
Supercritical fluid is a phase of substances, in addition to the solid, liquid, and gas phases.In particular, in the vicinity of the critical point, many physical properties behave in an unusual way.For example, the density, viscosity, and thermal conductivity drastically change at the critical point, the specific heat and thermal expansion ratios diverge at the critical point, and the sound velocity is zero at the critical point.The physical properties of a supercritical fluid must be evaluated by the appropriate equation of state and equation of the transport properties.
On the other hand, a compressible flow can be assumed as an ideal gas, but additional dynamic energy, that is, the Mach-number effect, must be considered.Therefore, three types of pressures (static, total, and dynamic), four types of temperatures (static, total, dynamic, and recovery), the difference between laminar and turbulent boundary layers, etc., should be distinguished and treated.

Equations of state and transport properties of supercritical fluid
Figure 1 shows the P-T diagram of a pure substance (water in this case), which is also called a phase diagram.The sublimation curve divides the solid and gas phases, the melting curve divides the solid and liquid phases, and the vaporization curve divides the liquid and gas phases.Two phases coexist on these three curves.When the pressure and/or temperature change across these three coexistence curves of solid-gas, solid-liquid, and liquid-gas, the density discontinuously changes.These three coexistence curves meet at the triple point, which is the unique point where solid, liquid, and gas coexist in equilibrium.
The vaporization curve ends at the critical point.On the vaporization curve, liquid is called the saturation liquid, and gas is called the saturation gas (vapor).When approaching the critical point along the vaporization curve, the density of the saturation liquid decreases, and the density of the saturation gas (vapor) increases.Finally, they meet at the critical point.Fluid overtaking the critical point in temperature and pressure is called the "supercritical fluid."

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The phase is thermodynamically determined by the Gibbs free energy G: Where H is the enthalpy, S is the entropy, U is the internal energy, and V is the specific volume [1].
That is, the phase is determined by the balance between the diffusivity caused by the thermal mobility of the molecules and the condensability by intermolecular forces.The diffusivity caused by thermal mobility increases with the temperature.The condensability by intermolecular forces increases with the density.In general, the following relationships hold: In Figure 1, the first-order differentials of the Gibbs free energy dG dT dG dP are discontinuous across the three coexistence curves, but the first-order differentials of the Gibbs free energy are continuous at the critical point.In addition, the second-order differentials of the Gibbs free energy are discontinuous at the critical point.
Here, ρ is the density, C P is the isobaric specific heat, and K T is the isothermal compressibility.At the critical point, the density drastically changes, the specific heat and thermal expansion ratio diverge, and the sound velocity is zero.The most important substances in practical applications are carbon dioxide and water, although all substances have a supercritical-fluid phase.Recently, accurate correlations for the equations of state and the transport properties containing the critical point have been proposed.
For carbon dioxide, Span and Wagner proposed the equation of state from the triple point to 1100 K at pressures up to 800 MPa [2].Their equation of state is briefly introduced here.They expressed the fundamental equation in the form of the Helmholtz energy A: with two independent variables-the density ρ and temperature T. The dimensionless Helmholtz energy φ ¼ A=RT is divided into a part obeying the ideal gas behavior φ and a part that deviates from the ideal gas behavior φ r [2]:  Heat Exchangers-Advanced Features and Applications φðδ, τÞ¼φ ðδ, τÞþφ r ðδ, τÞ; Where δ ¼ ρ=ρ c is the reduced density; τ ¼ T c =T is the inverse reduced temperature; and ρ c and T c are the density and temperature, respectively, at the critical point.Then, all of the other thermodynamic properties can be obtained by the combined derivatives of Eq. ( 7) using the Maxwell relations [1]. Pressure Internal energy Isochoric specific heat Enthalpy Isobaric specific heat then,

Speed of sound
Here,

Heat transfers between supercritical fluid flow and solid
As mentioned in Section 2, the kinematic viscosity of a supercritical fluid is less than those of a liquid and gas; therefore, the Reynolds number, Re, of a supercritical fluid flow is higher than those of a liquid and gas flow with the same velocity, and a turbulent flow is easily formed.For heat transfer in a turbulent flow, Dittus and Boelter proposed a correlation of the Nusselt number using the Re and Prandtl number, Pr, for a liquid flow in a circular automobile radiator [7] as shown in Figure 4.
Here, the superscript n ¼ 0:3 for T wall < T fluid or n ¼ 0:4 for T wall > T fluid , u local is the average velocity across the cross section, D is the diameter of the tube, μ is the viscosity, m is the mass flow rate, κ is the thermal diffusivity, and k is the heat conductivity.For liquid and gas flows, the fluid properties and flow conditions can be regarded as constant throughout the entire region in most practical cases because the fluid properties are insensitive to temperature and pressure changes in the tube.Therefore, the inlet values of the physical properties and flow conditions can be used, and Re and Pr can be regarded as constant throughout the entire tube.
On the other hand, the fluid properties of a supercritical fluid are very sensitive to temperature and pressure changes in the tube.Thus, in the tube, the density gradually changes because of the heat input and/or pressure loss, the local average velocity changes, and even Re and Pr change.Unfortunately, the Dittus-Boelter correlation with the inlet values of the physical properties and flow conditions cannot be directly used for heat transfer in a supercritical turbulent flow.Liao and Zhao measured the rate of the heat transfer between a supercritical carbon dioxide flow and a circular solid tube wall for T wall < T fluid [8].Their tube was set in the horizontal direction.They proposed a correlation of area-averaged Nusselt numbers as functions of the Reynolds and Prandtl numbers defined at the temperatures of the mean bulk and the wall.
Nu ave, turb ¼ 0:128Re Here, T bulk ¼½T in þ T out =2 and T wall are constant.This correlation is applicable in the range of 7.4 MPa <P bulk < 12.0 MPa, 20 C<T bulk < 110 C, 2 C<T bulk −T wall <30 C, 0.02 kg/min < _ m < 0.2 kg/min, 1025 < Gr=Re 2 bulk < 1022 for the horizontal long tubes of 0.50 mm <d < 2.16 mm.Re 0:8 wall and Pr 0:3 wall were originally derived from the Dittus-Boelter correlation.Gr=Re 2 bulk is the effect of buoyancy in the radial direction of a horizontal tube.The density of fluid at a temperature and pressure in the vicinity of the critical point is very sensitive to changes in temperature; thus, the effect of the buoyancy derived from the temperature difference between the bulk and wall cannot be ignored.This effect is enhanced as the diameter of the tube increases.
Ito et al. proposed an airfoil heat exchanger, which is applied between a compressible airflow and a liquid or a supercritical fluid flow [9].It has an outer airfoil shape suitable for high-speed airflow and contains several tubes for a high-pressure liquid or a supercritical fluid flow.The researchers installed a cascade of airfoil heat exchangers into a subsonic wind tunnel at a temperature of T air and measured the heat-transfer coefficient of a liquid or a supercritical fluid flow at a temperature of T scf < T air in a vertical tube.They derived correlations for supercritical carbon dioxide and compressed water at a pressure of P scf ≤30 MPa as follows: Nu ave, turb ¼ 0:0230Re 0:808 Pr 0:300 forH 2 O 0:0231Re 0:823 Pr 0:300 forCO 2 (33) These correlations are very simple and similar to the Dittus-Boelter correlation in Eq. (20) but have sufficient accuracy.Ito et al. used accurate equations of state and the transport properties, as mentioned in Section 2. They said in reference [9] that ordinary correlations (of course, containing the Dittus-Boelter correlation) for liquid and gas can be used when sufficiently accurate equations of state and the transport properties are used.However, the physical properties at a temperature and pressure in the vicinity of the critical point continuously change throughout the tube because of the heat input and/or pressure loss; therefore, changes in these physical properties throughout the tube should be sufficiently considered.For example, the present author recommends the numerical integration of local heat transfer correlations using local accurate physical properties for the entire tube.(34) The "pressure" (often called "static pressure") P is the potential of the mechanical energy level contained in a stationary fluid.A motional fluid has an additional dynamic energy e dyn [J/kg]: . in addition to e pre ; therefore, . Here, P dyn [Pa] is called "dynamic pressure" and is an index of the dynamic mechanical energy level contained in a motional fluid.Further, e mech [J/kg] is called "total mechanical energy."Moreover, P tot [Pa] is called the "total pressure" and is an index of the total mechanical energy level contained in a motional fluid.Some processes are reversible between mechanical energies of e pre and e dyn in cases where e pre and e dyn transform in the equilibrium processes.For example, using a nozzle, P dyn increases, P decreases, and P tot is constant in an acceleration section, and P dyn decreases, P increases, and P tot is constant in a deceleration section.Some process are irreversible between e pre and e dyn in cases where e pre and e dyn transform in nonequilibrium processes.For example, because of friction, P remains constant, P dyn decreases, and P tot also decreases.
Next, we consider thermal energy.A stationary fluid at an isochoric specific heat of C V [J/(kg K)] stores a relative internal energy of e [J/kg] from e 0 at the standard temperature T 0 : . Here, the internal energy is an index of the thermal energy level contained in a stationary fluid.
In the case of a constant C V , The "temperature" (often called "static temperature") T is an index of the energy level contained in a stationary fluid.
In cases where a fluid is assumed as an ideal gas, where R is the gas constant, and ρ is the density, which is equal to 1=V.Then, . A stationary fluid at an isochoric specific heat of C V [J/(kg K)] stores a relative enthalpy of h [J/kg] from h 0 at the standard temperature of T 0 , a pressure of P 0 ,andaspecificvolume of V 0 .Videlicet, enthalpy is a combination of internal energy and mechanical energy. Here, In the case of a constant C V , where C P is the isobaric specific heat.A motional fluid has an additional dynamic energy e dyn [J/kg], as shown in Eq. ( 35).If a motional fluid suddenly stops, dynamic energy can be converted into enthalpy.Then, the following equation applies: Here, T dyn [K] is called the "dynamic temperature" and is an index of the dynamic energy level contained in a motional fluid.Moreover, T tot [K] is called the "total temperature" and is an index of the total energy level contained in a motional fluid.Some processes are reversible between mechanical energies of h and e dyn in cases where e dyn transforms into PV in equilibrium processes.For example, using a nozzle, in an acceleration section, T dyn increases, h decreases, T tot is constant, and vice versa.Some processes are irreversible in cases where e dyn transforms into C V T in nonequilibrium processes.For example, because of friction, T dyn decreases, T increases, and T tot remains constant; however, T cannot be converted into T dyn again.
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Isentropic change and sound speed of ideal gas
The specific heat ratio γ is defined as: . From Eqs. ( 45) and (49), This equation is substituted into Eqs.( 40) and (44).Then, The change in the entropy ds is defined as: When isentropic change ds ¼ 0, We totally differentiate Eq. ( 41), obtaining the following: We substitute the final equation of Eq. (59) and Eq. ( 45) into the rightmost part of Eq. ( 55): Heat Transfer of Supercritical Fluid Flows and Compressible Flows http://dx.doi.org/10.5772/65931 We integrate Eqs. ( 57) and (62): The sound speed a is defined as: Eqs. ( 63) and ( 41) are substituted into Eq.( 65), yielding the following:

Relationships of static and total values in isentropic compressible flow
The one-dimensional energy equation of an isentropic flow at an arbitrary cross section is derived by using Eq.(46) as: When the enthalpy and velocity are h 1 and u 1 at an arbitrary cross section 1, This relationship is true even if cross section 1 corresponds to the stagnant cross section 0 (h 0 and u 0 ¼ 0); therefore, Eqs. ( 44) and ( 50) are substituted into Eq.( 69), yielding the following: Heat Exchangers-Advanced Features and Applications Eq. ( 66) is substituted into Eq.(70): We multiply by γ−1 a 2 and substitute Eq. (66), obtaining the following: At the stagnant cross section 0, the static temperature T 0 is equal to the total temperature T tot ; therefore, where M is the local Mach number.From Eqs. ( 64) and (73),

Relationships of local Mach number, pressure and temperature of flows on adiabatic walls
Figure 5 shows the pressure distribution on a plane and an airfoil.On both the plane and the airfoil, boundary layers are formed.The pressure P local, bound in a boundary layer is almost equal to the pressure P local, main in a main flow outside of the boundary layer; therefore, the pressure in a boundary layer can be expressed by using relationships of the isentropic main flow.That is, P local, bound ¼ P local, main .Afterwards, both the pressures are expressed as P local .
The pressure distribution on a solid wall is usually expressed by pressure coefficient S local , which is defined as: but is sometimes expressed by another pressure coefficient η local , which is defined as: The two expressions are related as follows: Heat Transfer of Supercritical Fluid Flows and Compressible Flows http://dx.doi.org/10.5772/65931 On a plane, S local is unity everywhere; thus, P local is constant everywhere.On the other hand, on an airfoil, S local varies with the location; thus, P local varies.
Figure 6 shows the temperature distribution on an adiabatic plane and an airfoil.In flows on an adiabatic wall, the total temperature T tot, local remains constant at the inlet total temperature T tot, in .For incompressible flows, that is, with the Mach number M local ¼ 0, the static temperature T local is always the same as T tot, local .Then, T local remains constant everywhere on both an adiabatic plane and an airfoil.On the other hand, for compressible flows, the Mach number M local varies according to the following equation, which is derived from Eq. ( 74): Here, the static temperature T local varies with respect to M local for compressible flows.
On an adiabatic plane, M local is constant.Thus, T local remains constant anywhere on an adiabatic plane, even in cases of compressible flows.On the other hand, on an adiabatic airfoil, M local varies with the location; therefore, T local varies in cases of compressible flows.Heat Exchangers-Advanced Features and Applications

Recovery temperature definition in boundary layer in compressible flow on adiabatic, heating and cooling walls
Eckert surveyed and organized the heat transfer in a boundary layer in a compressible flow on a wall [10].In a boundary layer on an adiabatic plane, the adiabatic-wall temperature reaches T r .This is called the "recovery temperature."Figure 7 shows a schematic of the total temperature T tot and static temperature T profiles, as well as the recovery temperature T r in the vicinity of an adiabatic solid surface with a boundary layer in a compressible flow.As described in Section 4.1, a compressible flow has a measurable dynamic energy; then, the static temperature T in a boundary layer increases because of the braking effect, which converts a dynamic energy to a thermal energy.At the same time, heat generated by the braking effect conducts to the outside of the boundary layer.Therefore, the static temperature T and total temperature T tot in the boundary layer approach the recovery temperature T r on the wall, as shown in the middle in Figure 7.
In cases where a thermal boundary layer is completely inside a momentum boundary layer, that is, Pr ≥ 1 the heat generated by the braking effect uses the rise of the static temperature T..The recovery temperature T r on an adiabatic wall is equal to the total temperature T tot, main of the main flow outside of the boundary layer.On the other hand, in cases where a thermal boundary layer protrudes from the edge of a momentum boundary layer, that is, Pr < 1, only part of the heat generated by the braking effect uses the rise of the static temperature T; then, the recovery temperature T r on an adiabatic wall has an intermediate value between the total temperature T tot, main and the static temperature T main of the main flow outside of the boundary layer.Eckert proposed an equation for the local recovery temperature T r, local on an adiabatic wall.
Here, r local is the "temperature recovery factor," which is the ratio of the recovery temperature to the dynamic temperature of the main flow.Eckert mentioned that heat flux q local in a boundary layer in a compressible flow should be defined as: , where h local is the local heat transfer coefficient between a compressible flow and a solid wall.
In the case where q local ¼ 0, the local wall temperature T solid, local equals the recovery temperature T r, local and is called the "adiabatic wall temperature." Here, Eckert's theory is extended to the recovery temperature T r on a heating and cooling wall.In Eq. ( 80), the first term expressed by the static temperature T main represents the internal energy that a local boundary layer originally has, and the second term expressed by the dynamic temperature T dyn, main r local represents the net dynamic energy that is used to increase the temperature in a local boundary layer.When a local boundary layer is heated or cooled, the first term is affected, but the second term remains constant.The first term should be replaced by the appropriate form suitable for the heating or cooling of a boundary layer.Heating or cooling affects only a thermal boundary layer; therefore, the local total temperature T tot, bound, x at the location x in the flow direction is defined as follows: (86) u x ¼ 0:5u main, x for a laminar boundary layer 0:8u main, x for a turbulent boundary layer ; where T bound, x and ρ x are the static temperature and density, respectively, in a heated or cooled boundary layer, and δ x and u x are thermal boundary layer thickness and average velocity, respectively.Here, evaluations of δ x and u x are used for a but more appropriate expression for a particular target flow field can be used.Finally, Eq. ( 80) is replaced by the following equation for the local recovery temperature of a heated or cooled boundary layer.

Mach-number distribution on solid walls with various shapes
As described in Section 4 4, the local Mach number M local is constant on a plane but varies with the location on a single airfoil or an airfoil in a cascade.For a single airfoil, when the inlet Mach number M in , the Reynolds number Re airfoil with a representative length of the airfoil chord L C , and the angle of attack α are fixed, as the distribution of the local pressure coefficient S local or η local is uniquely obtained.In cases of a cascade of airfoils, when the stagger angle β and the solidity σ are fixed (see Figure 8), the distribution of the local pressure coefficient S local or η local is obtained.Fortunately, many

Air-temperature distribution in boundary layers on solid walls
Nishiyama described in his book [11] that a developing boundary layer transforms from a laminar boundary layer to a turbulent boundary layer at Re x ≅10 4 in regions with adverse  Heat Exchangers-Advanced Features and Applications pressure gradients, but a developing boundary layer transforms at Re x ≅10 8 in regions with favorable pressure gradients.This means that a developing boundary layer transforms across the minimum pressure point, that is, the maximum of the pressure coefficient S local or η local on the airfoil surface in cases of Re airfoil ≅10 6 .According to the left graph of Figure 9, a developing boundary layer may transform at x=L C ≅0:025 on the lower concave surface and at x=L C ≅0:6on the upper convex surface.Then, the local recovery temperature T r, local is assumed by using Eqs.( 81) and (88) (see Figure 10).This T r, local can be used for the evaluation of the local heat flux q local using Eq. ( 82) if an adequate heat-transfer coefficient h local is employed.
7. Heat transfer through practical heat exchanger with complex shape Ito et al. evaluated the rate of heat transfer from a hot compressible airflow to a cold supercritical-fluid flow through an airfoil heat exchanger, as shown in Figure 8 [10].Heat is transferred from the hot compressible airflow to the outer surface of the airfoil heat exchanger and is conducted from the outer surface to the five inner surfaces in the airfoil heat exchanger.Then, heat is transferred from the five inner surfaces of the airfoil heat exchanger to the cold supercritical-fluid flow inside the five tubes.
First, Ito et al. conducted wind-tunnel experiments.They installed n thermocouples into the airfoil heat exchanger and experimentally measured the temperature at n points inside the exchanger.Simultaneously, the air temperature and the air Mach number at the inlet, the supercritical-fluid temperature and pressure at the inlet, and the supercritical-fluid temperature at the outlet were experimentally measured.
Second, they assumed n heat-transfer coefficients h air, 1 to h air, n for the n parts of the aircontacted outer surface of the airfoil heat exchanger, as well as one heat-transfer coefficient h sfc for the supercritical-fluid-contacted five inner surfaces of the airfoil heat exchanger.
Third, they performed an inverse heat-conduction analysis.The boundary conditions were set according to the experimental results for the distribution of the recovery temperature using the methods described in Sections 4.6, as well as the inlet supercritical-fluid temperature and pressure.Using these boundary conditions, heat-conduction calculations for the airfoil heat exchanger were conducted, and the temperatures at the n points in the airfoil heat exchanger and the outlet supercritical temperature were numerically obtained.
Finally, the n þ 1 numerically obtained temperatures were compared with n þ 1 experimentally obtained temperatures.If the temperatures were equal, the assumed h air, 1 to h air, n and h scf were true.Otherwise, the assumed h air, 1 to h air, n and h scf were corrected, and the inverse heatconduction analysis was repeated.They also obtained a supercritical-fluid Nusselt number correlation Nu scf for the tube flow given by Eq. (33).
Moreover, the heat-transfer rate Q entire of an airfoil heat exchanger is estimated as follows: where ψ is a correction factor for the airfoil heat exchanger, and ψ is the ratio of the actual heattransfer rate to the heat-transfer rate of the ideal counter-flow heat exchanger without thermal resistance.
Here, ξ is an incidence of air at the inlet.The incidence is a flow-direction angle from the airfoil camber (center) line at its leading edge, corresponding to an angle of attack of α ¼ 9:47 for the cascade in Figure 8. φ scf and φ air indicate the temperature effectiveness, as follows: Here, φ scf and φ air are positive for an air-cooled system and negative for an air-heated system.ε SA is the ratio of the heat-capacity rates.
Here, m scf and m air are the mass flow rates of a supercritical-fluid and air, respectively, for an airfoil heat exchanger, and C P, scf and C P, air are the specific heats of a supercritical-fluid and air, respectively.κ is the overall heat-transfer coefficient for an ideal counter-flow heat exchanger without thermal resistance.
Here, A scf and A air are areas of supercritical-fluid-contact and air-contact surfaces, respectively, for an airfoil heat exchanger.ΔT lm, entire is the logarithmic mean temperature difference: Φ is the ratio of the logarithmic mean temperature difference to the temperature difference between the inlet air temperature and the supercritical-fluid temperature.The actual heat-exchange rate is estimated as Q entire ½numberofairfoils.
For example, Ito et al. performed cycle calculations for an intercooled and recuperated jet engine employing several pairs of airfoil heat exchangers whose heat-transfer performance is evaluated by Eqs. ( 91)-(99) [13].
These examples can be used for a cascade of airfoil heat exchangers; therefore, the air Nusselt number correlation in Eq. ( 91) or thermal resistance in Eq. ( 93) might be further modified in the near future according to the progress of research, as knowledge in this field is still developing.

Conclusion
The Nusselt number between supercritical fluid flows and solid walls can be estimated by appropriate conventional correlations using the Reynolds and Prandtl numbers if sufficiently accurate physical properties are used for each local point through the region of supercritical fluid flows.Thus, a numerical integration of local heat flow rate is required when you calculate the entire heat flow rate in a heat exchanger between supercritical fluid flows and solid walls.
The recovery temperature should be considered for the estimation of heat transfer between compressible flows and solid walls.For compressible flows on adiabatic airfoil surfaces, the local recovery temperature varies by each point on the airfoil surface, owing to the accelerating and decelerating effects of the main flow outside of the boundary layer on the airfoil surface.In addition, for compressible flows on cooling and heating airfoil surfaces, the local total temperature on airfoil surfaces in the boundary layer also varies at each point because of cooling and heating effects.The accelerating and decelerating effects can be estimated from the local Mach number distribution on the airfoil shape.The cooling and heating effects can also be estimated when a numerical integration of elapsed variation of the local total temperature along the boundary layer from the leading edge if the detailed solid temperature distribution on the airfoil surface is known.To obtain the detailed solid temperature distribution on the airfoil surface, detailed experimental measurements or an accurate CFD analysis may be required.
To estimate conjugate heat transfer through a practical heat exchanger with a complex shape, one solution is a combination of experimental results in wind tunnel tests and an inverse heat conduction method.The other solution is CFD analysis validated by experimental results in wind tunnel tests.Empirical correlations are very limited for conjugate heat transfer through a practical heat exchanger with complex shape because knowledge in this field is still developing.

Figure 1 .
Figure 1.Phase chart on P-T diagram (for water).

Figures 2 and 3
Figures2 and 3show the isobaric and isothermal changes of the density, viscosity, and kinematic viscosity by using the data from references[2,3].Both the density (derived from

Figure 2 .
Figure 2. Isobaric changes of the density, viscosity, and kinematic viscosity near the critical point where T critical = 304.1282K and P critical = 7.3773MPa (for carbon dioxide).

Figure 3 .
Figure 3. Isothermal changes of the density, viscosity, and kinematic viscosity near the critical point where T critical = 304.1282Kand P critical = 7.3773MPa (for carbon dioxide).

Figure 4 .
Figure 4. Heat transfer between a supercritical fluid flow and a circular solid tube wall.

4 .
Thermofluid dynamics of compressible flow on solid wall 4.1.Meanings of temperature and pressure of compressible flow A stationary fluid pressure of P [Pa], specific volume of V [m 3 /kg], and constant temperature T stores a mechanical energy of e pre [J/kg].Here, Heat Exchangers-Advanced Features and Applications e pre ¼ PV:

Figure 5 .
Figure 5. Pressure distributions of flows on a plane and an airfoil.

Figure 6 .
Figure 6.Temperature distributions of flows on an adiabatic plane and an airfoil.

Figure 7 .
Figure 7. Total-, static-, and recovery-temperature profiles in the vicinity of cooling, adiabatic, and heating solid surfaces with a boundary layer in a compressible flow.

Figure 8 .
Figure 8. Flow field through a cascade of airfoils, where θ is the turning angle.

Figure 9 .
Figure 9. Local Mach-number distributions assumed from pressure-coefficient distribution.

Figure 10 .
Figure 10.Recovery-temperature distribution assumed according to the pressure coefficient and local Mach number distributions in Figure 9.