1. Introduction

The thermal protection of scramjet depends on the regenerative cooling technology of endothermic hydrocarbon fuels (EHFs) [1,2,3,4]. During a regenerative cooling process, the heat transfer and pyrolysis processes of EHFs are affected by differences in the channel cross-sectional geometry. Therefore, mastering the heat-transfer and pyrolysis processes is important for the design of cooling channels.

At present, most of the existing literature has focused on the pyrolysis characteristics of EHFs in the uniformly heated circular channels [5,6,7]. Ward et al. [8,9] proposed the idea of proportional product distribution (PPD) through a set of experiments in a circular tube. Jiang et al. [10] studied the pyrolysis processes of supercritical hydrocarbon fuel in a circular tube. Zhu et al. [11] experimentally studied the thermal cracking of n-decane at supercritical pressures in an electrically heated vertical circular tube. Zhao et al. [12] proposed the experimental analysis method of regenerative cooling microchannel electric heating tubes and introduced a secondary reaction model, improving the applicability of the cracking mechanism at high temperatures.

However, the rectangular cooling channel is a common structure of scramjet [13]. Bao et al. [1] studied numerically the nonuniformities of the velocity, temperature and conversion of EHFs in an asymmetrically heated rectangular cooling channel. Jiang et al. [14] investigated numerically the effect of geometry on flow processes of EHFs in the asymmetric heating and cooling channels with rectangular, circular, trapezoid or triangular cooling channels. Li et al. [15] investigated experimentally the thermal cracking behavior of EHFs in the circumferentially uniformly heated cooling channels with rectangular, square and circular cross sections. Li et al. [16] studied experimentally the heat transfer and cracking processes of EHFs in rectangular tubes with different aspect ratios.

It should be noted that the flow, heat-transfer and pyrolysis processes of EHFs in the circumferentially uniformly heated rectangular tubes were seldomly studied based on numerical simulation to obtain the differences between microcircular and rectangular tubes. Moreover, the interactions between flow field, cracking and heat transfer in different cooling channel shapes need further study.

In this research, the numerical models, which are composed of shear-stress transport (SST) k–ω turbulence models and a global reaction model with Peng–Robinson equation and one-fluid van der Waals mixing rules, were validated against the experimental data published in the literature. This was done to demonstrate the reliability of the CFD simulations for the supercritical flow and heat-transfer characteristics of n-decane during pyrolysis. Based on the validated model, the influences of the cross-section shape on the flow, heat transfer and cracking processes of supercritical n-decane were numerically studied in the circular and rectangular tubes. The mechanisms of supercritical heat transfer in the circumferentially uniformly heated circular and rectangular tubes were studied and analyzed.

2. Simulation

2.1. Computing Domain and Boundary Conditions

A 2D axisymmetric swirl model and a 3D model were adopted for the uniformly heated horizontal circular and rectangular tubes (Figure 1). Due to the symmetry of the rectangular tube, a quarter of the computing domain was used. The axisymmetric swirl model was adopted because of the axial symmetry of the circular tube. The heated section length was 250 mm, and a 150 mm long insulation section was added at both the inlet and the outlet. With reference to the experimental data provided by Zhou et al. [17], the $\dot{m}$ and inlet temperature of n-decane in our simulation were set to 0.8 g·s⁻¹ and 673.15 K, respectively. At the outlet, a pressure outlet boundary was applied, where the pressure was specified at 3.5 MPa. The q_w of the heated wall was 0.48 MW·m⁻². The walls of the inlet and outlet unheated sections were all treated as adiabatic. All the walls in the models were nonslipping. From Figure 1, the only difference between the two computational domains lay in the geometry of the cross section.

2.2. Reaction Model

The global reaction model developed by Zhou et al. [17] is expressed as:

(1)$\begin{array}{ll}{\mathrm{C}}_{10}{\mathrm{H}}_{22}\to & 0.07{\mathrm{H}}_2+0.31{\mathrm{CH}}_4+0.46{\mathrm{C}}_2{\mathrm{H}}_6+0.89{\mathrm{C}}_2{\mathrm{H}}_4+0.17{\mathrm{C}}_3{\mathrm{H}}_8+0.37{\mathrm{C}}_3{\mathrm{H}}_6\\ & +0.05{\mathrm{C}}_4{\mathrm{H}}_{10}+0.09{\mathrm{C}}_4{\mathrm{H}}_8+0.04{\mathrm{C}}_4{\mathrm{H}}_6+0.77{\mathrm{C}}_{5+}\end{array}$

The reaction rate and reaction rate constant are given as follows:

(2)${\omega }_R=d{C}_R/dt=-K{C}_R$

(3)$K=k_0\cdot \exp (-\frac{E_a}{RT})$

2.3. Theoretical Formulation and Numerical Treatment

The mass, momentum, energy and composition conservation equations are as follows:

(4)$\nabla \cdot (\rho \overrightarrow{u})=0$

(5)$\nabla \cdot (\rho \overrightarrow{u}\overrightarrow{u})=-\nabla p+\nabla \cdot {\tau }_{eff}$

(6)$\nabla \cdot (\rho \overrightarrow{u}{e}_t)=\nabla \cdot ({\lambda }_{eff}\nabla T)-\nabla \cdot (p\overrightarrow{u})+s_h$

(7)$\nabla \cdot (\rho \overrightarrow{u}{Y}_j)=-\nabla \overrightarrow{J_j}+R_j$

Zhang et al. [3] and Zhao et al. [18] used the Peng–Robinson equation and SST k–ω turbulence model to study the thermal behavior of the pyrolysis zone. Moreover, the turbulent flow was also simulated using the k–ε model with enhanced wall treatment. Therefore, the SST k–ω and k–ε turbulence models were used in this study. The SST k–ω turbulence model [19,20] is given by:

(8)$\nabla \cdot (\rho \overrightarrow{u}k)=\nabla \cdot ((\mu +\frac{{\mu }_t}{{\sigma }_k})\nabla k)+G_k-Y_k$

(9)$\nabla \cdot (\rho \overrightarrow{u}\omega )=\nabla \cdot ((\mu +\frac{{\mu }_t}{{\sigma }_{\omega }})\nabla \omega )+G_{\omega }-Y_{\omega }+D_{\omega }$

The k–ε turbulence model is given by:

(10)$\nabla \cdot (\rho \overrightarrow{u}k)=\nabla \cdot ((\mu +\frac{{\mu }_t}{{\sigma }_k})\nabla k)+G_k+G_b-\rho \epsilon -Y_M$

(11)$\nabla \cdot (\rho \overrightarrow{u}\epsilon )=\nabla \cdot ((\mu +\frac{{\mu }_t}{{\sigma }_{\epsilon }})\nabla \epsilon )+C_{1\epsilon }\frac{\epsilon }{k}(G_k+C_{3\epsilon }{G}_b)-C_{2\epsilon }\rho \frac{{\epsilon }^2}{k}$

The meaning of each variable is described in [21].

Table 1 presents the comparisons of the k–ε and SST k–ω models. The maximum relative errors of the mass fraction of unreacted n-decane predicted by the SST k–ω and k–ε models were 0.54% and 2.88%, respectively. Therefore, the SST k–ω turbulent model was adopted to calculate the pyrolysis characteristics of n-decane.

2.4. Property Evaluations and Solution Method

As a typical hydrocarbon fuel and a major composition of aviation fuels, the λ and μ of n-decane and the cracking component were calculated via NIST (SUPERTRAPP) software [22]. The critical pressure and the critical temperature of n-decane were 2.15 MPa and 617.7 K, respectively [22]. Thermal cracking occurs when n-decane is heated to approximately 770 K [23]. The Peng–Robinson equation [24] was adopted to solve the density of the mixtures. One-fluid van der Waals mixing rules [25] were used to calculate the critical temperature, critical pressure and critical specific volume of the mixture. The computing methods of other physical properties are described in [1].

Figure 2 shows the validation between the simulated fluid density and the NIST data. As illustrated in Figure 2, the relative error was less than 2.6%, which indicated that the Peng–Robinson equation was suitable for calculating the density of the mixtures. The λ and μ are based on NIST data directly, so no verification is required.

The pressure-based solver was chosen to solve the governing equations for the flow and heat-transfer process with pyrolysis. The equations were discretized with the second-order upper difference scheme. Pressure–velocity coupling was solved using the SIMPLE, SIMPLEC, PISO and coupled algorithms in Fluent. The convergence criteria of all equations were less than 10⁻⁶.

Table 2 presents the comparisons of the SIMPLE, SIMPLEC, PISO and coupled algorithms. The relative errors of the unreacted n-decane mass content and fluid temperature between the simulation results calculated by SIMPLE, SIMPLEC, PISO and the coupled algorithms and the experimental data were relatively small. However, the calculation times of SIMPLE, SIMPLEC and the coupled algorithm were 54 min, 93 min and 131 min, respectively. Considering the calculation efficiency, the SIMPLE algorithm was adopted to calculate the pyrolysis characteristics of n-decane.

2.5. Parameter Calculation

The T_f is calculated as follows:

(12)$T_f=\frac{{\displaystyle {\int }_A{c}_p\rho uTdA}}{{\displaystyle {\int }_A{c}_p\rho udA}}$

The h is calculated by Equation (13):

(13)$h=\frac{q_w}{T_w-T_f}$

The T_w in the wet perimeter is calculated as follows:

(14)$T_w=\frac{{\displaystyle {\int }_A{T}_{w,i}dA}}{A}$

The Reynolds number is calculated as follows:

(15)$Re=\frac{\rho u{d}_h}{\mu }=\frac{\dot{m}{d}_h}{A\mu }$

The Prandtl number is calculated as follows:

(16)$Pr=\frac{c_p\mu }{\lambda }$

The Nusselt number is calculated as follows:

(17)$Nu=\frac{h{d}_h}{\lambda }=a{\mathrm{Re}}^b{\mathrm{Pr}}^c=a{(\frac{\stackrel{\cdot }{m}}{A\mu }{d}_h)}^b{(\frac{c_p\mu }{\lambda })}^c$

The pressure drop is calculated by Equation (18) and verified by Equation (19), as recommended by Shi et al. [26]:

(18)$\Delta p=p_{in}-p_{out}$

(19)$\Delta p=\frac{0.3164}{{\mathrm{Re}}^{0.25}}\cdot \frac{l}{d_h}\cdot \frac{1}{2}\cdot \rho \cdot u^2=\frac{0.3164}{d_h^{1.25}}\cdot \frac{l{\stackrel{\cdot }{m}}^{1.75}{\mu }^{0.25}}{2\rho A^2}$

3. Validations

3.1. Grid Independence Study

Several grids with different numbers of elements were generated, and the specifications of the grids are listed in Table 3. In the near wall area of the fluid domain, the computational accuracy of the boundary layer mesh is ensured by defining the distance from the first layer mesh point to the boundary (0.001 mm) and the grid growth rate (1.2). The radial grids were selected from among 36, 50, 70 and 98. The axial grids were selected from among 1326, 1857, 2600 and 3640. From the analysis of the T_f and T_w at different grid combinations, the grid was reduced from 70 × 2600 to 50 × 1857, and the relative errors were 0.1% and 0.1%, respectively. Therefore, a grid size with 70 × 2600 (radial × axial) was used as the calculation baseline for the circular tube. Similarly, a grid size of 600 × 70 × 50 (X × Z × Y) was used as the calculation baseline for the rectangular tube. In this study, y⁺ was kept as less than 1.0 under all conditions.

3.2. Model Validation

The experimental results provided by Zhou et al. [17] were used to verify the model. The experimental conditions are listed in Table 4. Table 5 shows the comparisons of the unreacted n-decane mass content and fluid temperature at X = 400 mm. The relative errors of the fluid temperature and the unreacted n-decane mass content were 1.26% and 0.54%, respectively.

Figure 3 presents the comparisons between the simulated and experimental T_f. The maximum relative error of T_f was 2.4%. Therefore, the current numerical model was adopted to calculate the influence of different channel cross-section shapes on the heat transfer of n-decane with pyrolysis.

Figure 4 shows a comparison between the pressure drops calculated using Equations (18) and (19). The maximum relative error of the pressure drop between the simulated results and the calculation of Equation (19) was 3.1%. Therefore, the current numerical model was adopted to calculate the influence of different channel cross-section shapes on the pressure drop.

4. Results and Analysis

4.1. Influences of Geometry on Flow

Figure 5 indicates that the pressure drop (ΔP) increases gradually along the circular and rectangular channels. However, the flow resistance in the rectangular channel (R) is greater than that of the circular one (C). According to Equation (19), the equivalent diameter (1.78 mm) of the rectangular channel is smaller than that (2 mm) of the circular one. Therefore, the flow resistance in the rectangular channel is greater than that of the circular one. From Figure 5, when the cracking reaction model is adopted in the simulation, the pressure drops in both the circular and the rectangular tubes increases. The mean pressure drop per 20 mm long circular tube increased from 99 Pa to 122 Pa, while the mean pressure drop per 20 mm long rectangular tube increased from 108 Pa to 144 Pa. Therefore, the mean pressure drop in R is 1.18 times as high as that in C with pyrolysis.

Figure 6 indicates the velocity distribution along the diagonal at X = 400 mm in the circular and rectangular tubes. When the pyrolysis reaction is not adopted in the simulation, the velocity in the velocity boundary layer varies greatly. However, the maximum velocity in both the circular and rectangular tubes is 4.3 m/s. From Figure 6, when the cracking reaction is included in the simulation, the velocity in both the circular and the rectangular tubes increases. The maximum velocity in C increased from 4.3 m/s to 5.3 m/s, while the maximum velocity in R increased from 4.3 m/s to 6.3 m/s. Therefore, the maximum velocity in R is 1.18 times as high as that in C with pyrolysis. This is related to the high cracking and low density of R.

4.2. Effects of Geometry on Pyrolysis

Figure 7 presents the cloud plots of T and the conversion in C and R. In Figure 7a, it is observed that the fluid temperature gradually increases from the center to the tube wall and from the inlet to the outlet. From Figure 7b, the local high fluid temperatures are observed at the four corners of R, leading to the nonuniformity of the fluid temperatures in the rectangular section. In addition, the high-temperature zone of any cross-section in R is much larger than that in C at the same axial position. The main reason is that the boundary layers interact in the corners of R, leading to lower velocity gradients and higher wall temperatures around the corners, which are stronger than those at the circumference of C.

Figure 7c shows that the conversion in C gradually increases from the center to the tube wall and from the inlet to the outlet, which is consistent with the trend of temperature change, as shown in Figure 7a. From Figure 7c,d, the area of the high-conversion region in the rectangular tube is much larger than that in the circular tube, which is mainly due to the distribution of the temperature boundary layer in the rectangular tube, as shown in Figure 7b. From Figure 7d, the pyrolysis in the corners of R has a higher conversion, which may enhance coke deposition rates. Similar expressions were observed in [15].

The chemical heat sink is calculated as follows:

(20)$\Delta H_{chem}=\Delta H_{total}-\Delta H_{sen}$

Figure 8a,b shows that the cracking conversion and chemical heat sink of R are higher than those of C under the same heat flux. According to Equations (2) and (3), the cracking conversion mainly depends on residence time and fluid temperature. Moreover, pyrolysis is an endothermic process, and the increasing conversion leads to the increasing chemical heat sink. The average fluid temperature of R was higher than that of C, and the higher flow velocity in R leads to lower residence time. From Figure 8c,d, compared with the circular tube, higher fluid bulk temperatures enhance thermal cracking in the rectangular tube, thus increasing the chemical heat sink. It is shown that the influence of temperature is greater than that of residence time on the chemical heat sink in rectangular tubes. Similar expressions were observed in [27].

Figure 8a,b indicates that the maximum values of the chemical heat sink and conversion in C are 198.8 kJ·kg⁻¹ and 12.99%, respectively, while the maximum values in R are 309.4 kJ·kg⁻¹ and 20.21%, respectively. Therefore, the maximum value of the chemical heat sink in R is 1.6 times as high that in C, and the maximum values of the chemical heat sink and conversion in the rectangular tube are 111 kJ·kg⁻¹ and 7.2% more than those in the circular tube, respectively. From Figure 8c,d, the μ and λ of fluid in R are higher than those in C, and specific heat and density in R are smaller than that in C. The extent of cracking conversion in the rectangular tube is higher, resulting in more small molecular species being produced at the same bulk fluid temperature compared to the circular tube.

4.3. Effects of Geometry on Heat Transfer

Figure 9 indicates the distributions of the T_f, T_w, Re number and Nu number with the circular and rectangular tubes. From Figure 9a,b, the T_f increases gradually, while the T_f and T_w in C are lower than those in R. When the fuel cracking reaction model is included in the simulation, both the T_f and the T_w decrease in the circular and rectangular tubes, which indicates that the endothermic fuel pyrolysis improves the convective heat transfer by decreasing the bulk fluid temperature and increasing the flow velocity. In addition, the difference between the T_w and the T_f at the outlet of rectangular tube is 140 K, which is 17 K more than that of the circular tube. The heat transfer from the wall to the main flow is weakened by the thickening of the heat boundary in the initial heating section. Therefore, the T_w increases sharply at the initial heating section.

Figure 9c shows that the Re number first increases and then decreases with either the circular or rectangular tube. The main reason is that the viscosity coefficient decreases at about 750 K and then increases with the increase in temperature, as shown in Figure 8d. Similar expressions were observed in [19]. From Figure 9c, the Re number of the fluid is greater than 4000, so the flow is turbulent. According to the Equation (15), the Re number is proportional to the equivalent diameter, and the hydraulic diameters of C and R are 2 mm and 1.78 mm, respectively. Therefore, no matter whether the cracking model is added to the simulation, the Re number in C is larger than that in R at the same mass flux, indicating that turbulent diffusion and heat transfer are enhanced in the circular tube. Consequently, the Nu in C is relatively high compared to the Nu in R, as shown in Figure 9d. Moreover, when the cracking reaction model is adopted in the simulation, the Nu number of the fluid in both C and R increases. The maximum value of the Nu number for C is 105, while the maximum value for R is 80. Therefore, the maximum value of the Nu in C is 1.3 times as high that in R with pyrolysis.

4.4. Mechanisms of Heat Transfer in the Circular and Rectangular Tubes

According to Dittus–Boelter equation and Equation (17), h can be calculated as follows:

(21)$h=\frac{0.023}{d_h^{0.2}}{(\frac{\stackrel{\cdot }{m}}{A})}^{0.8}{(\frac{c_p}{\mu })}^{0.4}{\lambda }^{0.6}$

Figure 10a,b presents the variations in the h and the physical properties of n-decane with T_f. The maximum heat capacity and minimum thermal conductivity in the range of temperatures are shown in Figure 10b, and the corresponding temperatures are about 662 K and 692 K, respectively, which are marked by two black dotted lines. In this study, the circular and rectangular tubes have the same mass flow rate and cross-sectional area. When the T_f is greater than 673 K, both c_p and λ first decrease and then increase with an increasing T_f, while μ does not obviously change. According to Equation (21), the variations in h are similar to those in c_p and λ with an increasing T_f, as shown in Figure 10a.

Figure 10c shows changes in the wall shear stress (τ_w) with T_f. From Figure 10a,c, the τ_w and h show a similar change trend with the bulk fluid temperature. The τ_w increases the turbulence in the logarithmic law layers, leading to the increasing h. Based on the effect of pyrolysis on thermophysical properties in Section 4.3, it can be concluded that the rectangular tube has a lower convective heat-transfer coefficient due to its smaller heat capacity, larger viscosity and lower wall shear stress compared to the circular tube with pyrolysis.

Figure 11 shows that the turbulent kinetic energy (k) gradually increases along the flow direction in both C and R. In Figure 11, the k first increase and then decrease from the center to the tube wall, and the k at the wall are zero. From Figure 11a,c, when the fuel cracking reaction model is included in the simulation, the turbulent kinetic energy increases. The main reason is that the cracking reaction results in more small molecular substances, and the larger turbulent kinetic energy is conducive to the energy exchange between fluids. Therefore, the pyrolysis reaction can improve the heat-transfer performance. From Figure 11c,d, there are regions with zero turbulent kinetic energy at the four corners of the rectangle. The lower turbulent kinetic energy is unfavorable to the energy exchange between fluids. Therefore, the temperature in this area is relatively high, as shown in Figure 7b. Figure 11d shows that the four sides of the rectangle have regions with relatively large local turbulent kinetic energy. Higher k leads to the full mixing of the fluid and the destruction of the thermal boundary layer, which helps to improve the local heat-transfer performance, as shown in Figure 7b.

5. Conclusions

In this paper, the effects of different channel cross-section shapes on the heat transfer and pyrolysis characteristics of n-decane were numerically investigated under the same operation condition. The differences in cracking and heat transfer between the circular and rectangular tubes were analyzed. The conclusions can be drawn as follows:

• (1). Compared with the flow resistance in the circular channel with pyrolysis, the mean pressure drop in the rectangular channel is 1.18 times as high due to its smaller equivalent diameter. The maximum velocity in the rectangular channel is 1.18 times as high as that in the circular one with pyrolysis due to the higher pyrolysis and lower density.

• (2). The area of the high-conversion region in the rectangular tube is much larger than that in the circular tube due to the distribution of the temperature boundary layer in the rectangular tube. The maximum value of the chemical heat sink in the rectangular channel is 1.6 times as high as that in the circular one.

• (3). The high-temperature zone of any cross section in the rectangular channel is much larger than that in the circular channel due to the superposition of the boundary layer and lower turbulent kinetic energy in the corners of the rectangular channel. The maximum value of the Nu in the circular channel is 1.3 times as high as that in the rectangular one with pyrolysis due to its larger heat capacity, lower viscosity and higher wall shear stress.

Footnotes

Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content.

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Figure 1. Computational domains of (a) the circular tube and (b) the rectangular tube.

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Figure 2. Validation of the simulated fluid density with temperature at 3.5 MPa.

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Figure 3. Comparisons between the simulated and the experimental bulk temperature.

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Figure 4. Comparisons between the ΔP calculated by Equations (18) and (19).

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Figure 5. Distributions of the ΔP with the circular tube and the rectangular tube.

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Figure 6. Distributions of the velocity with the circular tube and the rectangular tube at X = 400 mm.

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Figure 7. Cloud plots of (a,b) temperature and (c,d) conversion in the circular and rectangular tubes.

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Figure 8. Variations in (a) conversion, (b) chemical heat sink, (c) cp and ρ and (d) λ and μ with the Tf in the circular and rectangular tubes.

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Figure 9. Distributions of (a) Tf, (b) Tw and (c) Re and (d) Nu along the circular and rectangular tubes.

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Figure 10. Variations in (a) heat-transfer coefficient, (b) physical properties of n-decane and (c) τw with Tf at 3.5 MPa.

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Figure 11. Cloud plots of turbulent kinetic energy in the circular and rectangular tubes (a,b) without pyrolysis and (c,d) with pyrolysis.

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